Abstract
Diatom assemblages and coastal sedimentary facies succession in the deltaic plain of the Colorado River (Argentina) were studied in order to reconstruct the environment conditions in response to Holocene eustatic sea-level changes and delta progradation. Samples were selected from a 200˗cm core (39°35’52” S, 62°6’43” W). Chronology was based on radiocarbon datings in bulk samples and mollusk shells. Nine lithological units were recognized where fine and very fine sand predominate. The core sediments were dominated by tychoplanktonic coastal-marine diatoms. The accompanying flora included stable marine-coastal taxa and allochthonous fluvial fresh-brackish species. Three diatom zones (DZ) were established based on cluster analyses. The LCH site was significantly affected by Late Pleistocene and Holocene sea˗level fluctuations, and the progradation of the deltaic lobe during the last ca. 7,000 14C yr. BP. Ancient tidal channels were flooded in the early Holocene postglacial transgression. Erosive and re˗working processes associated with the formation of estuarine channels, affected valves preservation, yielding with barren sections. Tidal flats and marshes have developed in the area during the late Holocene regression phase. The comparison of the sedimentary sequence with deltaic facies evolution models, confirm the presence of a hiatus, which masks the Holocene Maximum and highstand.
Key words
deltaic facies; diatoms; Holocene; Northern Patagonia; progradation; sea-level change
INTRODUCTION
The Colorado River Delta is one of the two active deltaic systems in Argentina. It is located at the south of Buenos Aires province and prograde into the open mesotidal coast of the Atlantic Ocean (Isla & Toldo 2013ISLA FI & TOLDO EE. 2013. ENSO impacts on Atlantic watersheds of South America. Quat Environ Geosci 4: 34˗41.). Since the 1970s deltas have been classified as rivers-, waves- and tidal dominated (Li et al. 2011LI W, BHATTACHARYA JP & WANG Y. 2011. Delta asymmetry: Concepts, characteristics, and depositional models. Pet Sci 8(3): 278-289.). The variation of natural forcing factors and anthropogenic pressure can affect the rate of progradation and deltaic growth. These include hydrological and climate changes in the fluvial basin (discharge factor), the tectonic activity (relief, slope and subsidence) and changes of the sedimentary balance (Chiocci & Normark 1992CHIOCCI FL & NORMARK WR. 1992. Effect of sea level variation on upper-slope depositional processes offshore of Tiber Delta, Tyrrhenian Sea, Italy. Mar Geol 104: 109-122., Hori et al. 2011HORI K, USAMI S & UEDA H. 2011. Sediment facies and Holocene deposition rate of near˗coastal fluvial systems: An example from the Nobi Plain, Japan. J Asian Earth Sci 41: 195-203.). The deltaic evolution shows complex and dynamic sedimentary processes over time and supposes continuous reworking events (Colombo et al. 2014COLOMBO F, SERRA J & RIVERO L. 2014. Río de la Plata inner estuary (Argentina): main forms, sedimentary infill and Holocene evolution. In: MARTINI IW (Ed), Sedimentary Coastal Zones from High to Low Latitudes: Similarities and Differences. Geol Soc Spec Publ, 388 p.). Different portions of the delta may be in the growth process, while other areas may be subject to destructive conditions by waves and tides due variations in water-sedimentary fluvial processes (Elliott 1986ELLIOTT T. 1986. Deltas. In: READING HG (Ed). Sedimentary environments and facies. Blackwell, 2nd ed., Oxford, p. 113-154., Spalletti & Isla 2003SPALLETTI LA & ISLA FI. 2003. Características y evolución del delta del Río Colorado “colú˗leuvú”, Provincia de Buenos Aires, República Argentina. AAS Revista 10: 23˗37.). The sudden abandonment of sectors of the deltaic plain by avulsion processes, temporary migration of distributary channels, deactivation/activation of paleochannels in oxbow lakes and changes in depositational input by flow regulation by dams or irrigation channels, among others (Frazier 1967FRAZIER DF. 1967. Recent deltaic deposits of the Mississippi Delta: their development and chronology. Transactions Gulf Coast Assoc Geol Soc 17: 287-315., Stouthamer & Berendsen 2007STOUTHAMER E & BERENDSEN HJ. 2007. Avulsion: the relative roles of autogenic and allogenic processes. Sediment Geol 198(3-4): 309-325., Makaske et al. 2012MAKASKE B, MAATHUIS BH, PADOVANI CR, STOLKER C, MOSSELMAN E & JONGMAN RH. 2012. Upstream and downstream controls of recent avulsions on the Taquari megafan, Pantanal, south-western Brazil. Earth Surf Proc Land 37(12): 1313-1326., Akter et al. 2015AKTER J, SARKER MH, POPESCU I & ROELVINK D. 2015. Evolution of the Bengal Delta and its prevailing processes. J Coastal Res 32: 1212-1226., Pierik et al. 2018PIERIK HJ, STOUTHAMER E, SCHURING T & COHEN KM. 2018. Human-caused avulsion in the Rhine-Meuse delta before historic embankment (The Netherlands). Geology 46(11): 935-938.). When these modifications of depositional factors are conjugated with changing eustatic environments, their effects on the deltaic architecture are accentuated (Spalletti & Isla 2003SPALLETTI LA & ISLA FI. 2003. Características y evolución del delta del Río Colorado “colú˗leuvú”, Provincia de Buenos Aires, República Argentina. AAS Revista 10: 23˗37., Hori et al. 2004HORI K, TANABE S, SAITO Y, HARUYAMA S, NGUYEN V & KITAMURA A. 2004. Delta initiation and Holocene sea-level change: example from the Song Hong (Red River) delta, Vietnam. Sediment Geol 164(3-4): 237-249., Ta et al. 2005TA TK, NGUYEN VL, TATEISHI M, KOBAYASHI I & SAITO Y. 2005. Holocene delta evolution and depositional models of the Mekong River Delta, southern Vietnam. Society for Sedimentary Geology. River Deltas—Concepts, Models, and Examples SEPM (Society for Sedimentary Geology) Special Publication 83: 453-463.).
Most modern deltaic systems were formed during the later stages of the postglacial transgression of the mid-late Holocene (Ta et al. 2001TA TK, NGUYEN VL, TATEISHI M, KOBAYASHI I & SAITO Y. 2001. Sedimentary facies, diatom and foraminifer assemblages in a late Pleistocene-Holocene incised valley sequence from the Mekong River Delta, Bentre Province, Southern Vietnam:the BT2 core. J Asian Earth Sci 20(1): 83-94., 2005, Zong et al. 2009ZONG Y, HUANG G, SWITZER A, YU F & YIM WS. 2009. An evolutionary model for the Holocene formation of the Pearl River delta, China. The Holocene 19(1): 129-142., Colombo et al. 2014COLOMBO F, SERRA J & RIVERO L. 2014. Río de la Plata inner estuary (Argentina): main forms, sedimentary infill and Holocene evolution. In: MARTINI IW (Ed), Sedimentary Coastal Zones from High to Low Latitudes: Similarities and Differences. Geol Soc Spec Publ, 388 p., Wei & Wu 2011WEI X & WU C. 2011. Holocene delta evolution and sequence stratigraphy of the Pearl River Delta in South China. Sci China Earth Sci 54(10): 1523-1541., Jeong et al. 2018JEONG EJ, WOO HJ, KANG J, LEE JH & CHOI JU. 2018. Study of Holocene paleo-environmental evolution using cores from the downstream area of the Nakdong River Delta, Korea. J Coastal Res 85(1): 626-630.). Holocene eustatic sea level changes have modified coastlines, and baseline variations had effects over the fluvial sediment supply (Woodroffe et al. 1993WOODROFFE C, MULRENNAN M & CHAPPELL J. 1993. Estuarine infill and coastal progradation, southern van Diemen Gulf, northern Australia. Sediment Geol 83: 257˗275.). In the Northern Hemisphere, the Holocene sea-level-rise was persistent; however, during the last ca. 8,000-6,000 years BP, a relative slowdown of this rise favored deltaic progradation (Nguyen et al. 2000NGUYEN VL, TA TK & TATEISHI M. 2000. Late Holocene depositional environments and coastal evolution of the Mekong River Delta, Southern Vietnam. J Asian Earth Sci 18(4): 427-439., Stanley & Warne 1994STANLEY DJ & WARNE AG. 1994. Worldwide initiation of Holocene marine deltas by deceleration of sea-level rise. Science 265(5169): 228-231., Ta et al. 2002aTA TK, NGUYEN VL, TATEISHI M, KOBAYASHI I, SAITO Y & NAKAMURA T. 2002a. Sediment facies and Late Holocene progradation of the Mekong River Delta in Bentre Province, southern Vietnam: an example of evolution from a tide-dominated to a tideand wave-dominated delta. Sediment Geol 152(3-4): 313-325., b, Wei & Wu 2011WEI X & WU C. 2011. Holocene delta evolution and sequence stratigraphy of the Pearl River Delta in South China. Sci China Earth Sci 54(10): 1523-1541.). In contrast, in the Southern Hemisphere the sea-level increased until a maximum level ca. 7,000-5,000 years BP and later it fell to the present level, which allowed the construction of deltaic lobes (Spalletti & Isla 2003SPALLETTI LA & ISLA FI. 2003. Características y evolución del delta del Río Colorado “colú˗leuvú”, Provincia de Buenos Aires, República Argentina. AAS Revista 10: 23˗37., Cavallotto et al. 2004CAVALLOTTO JL, VIOLANTE RA & PARKER G. 2004. Sea-level fluctuations during the last 8,600 years in the de la Plata River (Argentina). Quatern Int 114(1): 155-165., Castro et al. 2013CASTRO DF, ROSSETTI DF, COHEN MC, PESSENDA LC & LORENTE FL. 2013. The growth of the Doce River Delta in northeastern Brazil indicated by sedimentary facies and diatoms. Diatom Res 28(4): 455-466., Melo et al. 2013MELO W, PERILLO G, PERILLO M, SCHILIZZI R & PICCOLO MC. 2013. Late Pleistocene–Holocene deltas in southern Buenos Aires Province, Argentina. IAHS Publ 358: 187-195.).
Evolutive analysis of the present deltaic conformations incorporates time as a variable and the fluctuations in Holocene sea level (Boyd et al. 1992BOYD R, DALRYMPLE R & ZAITLIN B. 1992. Classification of clastic coastal depositional environments. Sediment Geol 80(3-4): 139-150., Dalrymple et al. 1992DALRYMPLE RW, ZAITLIN BA & BOYD R. 1992. Estuarine facies models; conceptual basis and stratigraphic implications. J Sediment Res 62(6): 1130-1146.). According to Boyd et al. (1992)BOYD R, DALRYMPLE R & ZAITLIN B. 1992. Classification of clastic coastal depositional environments. Sediment Geol 80(3-4): 139-150. the regressive deltaic geoforms prograde to transgressive and regressive stages; however, if during the transgression the contribution of fluvial sediments was scarce, the ancient fluvial valley is flooded, dominating the erosive features and the formation of estuaries (Boyd et al. 1992BOYD R, DALRYMPLE R & ZAITLIN B. 1992. Classification of clastic coastal depositional environments. Sediment Geol 80(3-4): 139-150.). During the subsequent regressive phase, estuaries become clogged due to delta progradation, forming extensive tidal flats and salt marshes (Dalrymple et al. 2003DALRYMPLE RW, BAKER EK, HARRIS PT & HUGHES MG. 2003. Sedimentology and stratigraphy of a tide-dominated, foreland-basin delta (Fly River, Papua New Guinea). In: SIDI F, NUMMEDAL D, IMBERT P, DARMAN H AND POSAMENTIER H (Eds), Tropical deltas of South East Asia-Sedimentology, Stratigraphy and Petroleum Geology. SEPM Special Publication 76: 147-173., Dalrymple & Choi 2007DALRYMPLE RW & CHOI K. 2007. Morphologic and facies trends through the fluvialmarine transition in tide-dominated depositional systems: a schematic framework for environmental and sequence-stratigraphic interpretation. Earth-Sci Rev 81(3-4): 135-174.). After that, different authors have documented the succession of transgressive and regressive facies in Holocene sequences extracted from the deltaic plains (Ta et al. 2002bTA TK, NGUYEN VL, TATEISHI M, KOBAYASHI I, TANABE S & SAITO Y. 2002b. Holocene delta evolution and sediment discharge of the Mekong River, southernVietnam. Quaternary Sci Rev 21(16-17): 1807-1819., 2005, Hori et al. 2004HORI K, TANABE S, SAITO Y, HARUYAMA S, NGUYEN V & KITAMURA A. 2004. Delta initiation and Holocene sea-level change: example from the Song Hong (Red River) delta, Vietnam. Sediment Geol 164(3-4): 237-249., Castro et al. 2013CASTRO DF, ROSSETTI DF, COHEN MC, PESSENDA LC & LORENTE FL. 2013. The growth of the Doce River Delta in northeastern Brazil indicated by sedimentary facies and diatoms. Diatom Res 28(4): 455-466., Jeong et al. 2018JEONG EJ, WOO HJ, KANG J, LEE JH & CHOI JU. 2018. Study of Holocene paleo-environmental evolution using cores from the downstream area of the Nakdong River Delta, Korea. J Coastal Res 85(1): 626-630.).
The reconstructions from sediment cores are characterized by high-resolution analysis of sedimentary facies supported by micropaleontological evidence (Wei & Wu 2011WEI X & WU C. 2011. Holocene delta evolution and sequence stratigraphy of the Pearl River Delta in South China. Sci China Earth Sci 54(10): 1523-1541.). Due to their sensitivity to salinity changes, the diatoms represent one of the most used proxies to reinforce the interpretation of sedimentary facies and deltaic evolution based on eustatic variations (Ta et al. 2001TA TK, NGUYEN VL, TATEISHI M, KOBAYASHI I & SAITO Y. 2001. Sedimentary facies, diatom and foraminifer assemblages in a late Pleistocene-Holocene incised valley sequence from the Mekong River Delta, Bentre Province, Southern Vietnam:the BT2 core. J Asian Earth Sci 20(1): 83-94., Castro et al. 2013CASTRO DF, ROSSETTI DF, COHEN MC, PESSENDA LC & LORENTE FL. 2013. The growth of the Doce River Delta in northeastern Brazil indicated by sedimentary facies and diatoms. Diatom Res 28(4): 455-466.). These siliceous unicellular microalgae are excellent indicators due to its high ubiquity in aquatic or humid habitats, short generation times and sensitivity to environmental changes, high abundances and diversity (Round et al. 1990ROUND FE, CRAWFORD RM & MANN DG. 1990. The diatoms: biology and morphology of the genera. Cambridge University Press, Oxford, 747 p., Vos & De Wolf 1988VOS PC & DE WOLF H. 1988. Methodological aspects of palaeoecological diatom research in coastal areas of the Netherlands. Geol Mijnbouw 67: 31-40., 1993, Flower 2005FLOWER RJ. 2005. A review of diversification trends in diatom research with special reference to taxonomy and environmental applications using examples from Lake Baikal and elsewhere. Proc Calif Acad Sci 56(1/17): 107-128.). Biogenic siliceous walls resist the diagenetic degradation and award them a high preservation capacity (Cooper et al. 2010COOPER S, GAISER E & WACHNICKA A. 2010. Estuarine paleoenvironmental reconstructions using diatoms. In: SMOL JP & STROEMER EF (Eds). The diatoms: applications for the environmental and earth sciences (Ed. 2), New York, Cambridge University Press, p. 324-345.). In consecuence, diatoms form abundants and representative fossil records of phytoplankton and microphytobenthos, and provide detailed archives of paleolimnological data (Taffs et al. 2017TAFFS KH, SAUNDERS KM, WECKSTRÖM K, GELL PA & GREGORY SC. 2017. Introduction to the Application of Paleoecological Techniques in Estuaries. Weckström K, Saunders K, Gell P & Skilbeck C (Eds), Applications of Paleoenvironmental Techniques in Estuarine studies, Developments in Paleoenvironmental Research. Springer, Dordrecht. vol 20., Espinosa et al. 2020ESPINOSA MA, VÉLEZ-AGUDELO CA & ISLA FI. 2020. Diatom responses to natural and anthropogenic environmental changes in a Patagonian river, Argentina. J S Am Earth Sci 102: 102677.).
In Argentina, the diatoms have been successfully used as proxies for Holocene paleoenvironmental reconstructions in numerous studies. Qualitative and quantitative diatomological analysis of estuarine-coastal transitional environments have been usefull to infer variations in salinity, conductivity, turbidity, depth, sedimentation rates and changes of the coastline positions in the past. These inferences have allowed to reconstruct Holocene transgressive or regressive processes and their influence on the evolution of the coastal geoforms (Hassan et al. 2009HASSAN GS, ESPINOSA MA & ISLA FI. 2009. Diatom-based inference model for paleosalinity reconstructions in estuaries along the northeastern coast of Argentina. Palaeogeogr Palaeocl 275(1-4): 77-91., 2011, Espinosa & Isla 2011ESPINOSA MA & ISLA FI. 2011. Diatom and sedimentary record during the Mid˗Holocene evolution of the San Blas estuarine complex, Northern Patagonia, Argentina. Ameghiniana 48: 411˗423., Espinosa et al. 2012ESPINOSA MA, HASSAN GS & ISLA FI. 2012. Diatom-inferred salinity changes in relation to Holocene sea-level fluctuations in estuarine environments of Argentina. Alcheringa 36: 373-386., Fayó & Espinosa 2014FAYÓ R & ESPINOSA MA. 2014. Reconstrucción paleoambiental de la planicie costera de Mar Chiquita (Provincia de Buenos Aires, Argentina) durante el Holoceno, basada en diatomeas. Ameghiniana 51: 510˗528., Isla et al. 2015ISLA FI, ESPINOSA MA, RUBIO B, ESCANDELL A, GERPE M, MIGLIORANZA K, REY D & VILAS F. 2015. Avulsion at a drift-dominated mesotidal estuary: The Chubut River outlet, Patagonia, Argentina. J Hydrol 529(2): 632-639.).
Most of the Quaternary estuarine-coastal reconstructions based on diatoms in Argentina were carried out in the last three decades, and were concentrated in the province of Buenos Aires (Espinosa 2008ESPINOSA MA. 2008. Diatoms from Patagonia and Tierra del Fuego. In: Rabassa J (Ed), Late Cenozoic of Patagonia and Tierra del Fuego. Developments in Quaternary Sciences, Elsevier, p. 383-392.). Despite the fact that the Argentine deltaic systems are located in this province, studies of deltaic fossil floras and paleoenvironmental reconstructions are extremely scarce, generating an underestimation of real diatom diversity and biased and incomplete regional interpretations. Recently, Fayó et al. (2018FAYÓ R, ESPINOSA MA & ISLA FI. 2020a. Diatomeas holocenas del delta del río Colorado, Argentina. Una aproximación paleoambiental a partir del estudio de “fragilarioides pequeñas”. Rev Bras Paleontolog 23(3): 209-221., 2020aFAYÓ R, PAN J & ESPINOSA MA. 2020b. Microbial mat and surface sediment communities from a shallow oxbow lake in the Colorado River floodplain, Argentina, Geomicrobiol J 37(10): 937-949.) performed the study of two sedimentary sequences in the deltaic plain of the Colorado River at 37 and 22 km inland from the present coastline. These studies together with the modern flora analyses of the middle-lower Colorado River basin (Vélez-Agudelo et al. 2017) allowed to identify a stable and diverse composition of Holocene diatom flora, distinguishing typical assemblages of delta. A classic autoecological approach with modern analogs, allowed to identify changes in salinity and water depth in response to variations in the position of the coastline.
In this contribution, diatom assemblages of a coastal sedimentary succession in the deltaic plain of the Colorado River (Argentina) were studied, in order to reconstruct the paleoenvironmental conditions of the delta in response to Holocene sea-level changes, the variation of the coastline position and the progradation processes. The specific objectives were: (1) to analyze the diversity of the Holocene diatomological flora in the region; (2) to identify paleoenvironments based on changes in salinity and depth, through the variation in the fossil assemblage’s composition and autoecology data, and (3) to propose the succession of sedimentary facies in deltaic environments based on micropaleontological and sedimentological evidence.
Regional setting and study area
The Colorado is an allochthonous river that flows across central Argentina (Spalletti & Isla 2003SPALLETTI LA & ISLA FI. 2003. Características y evolución del delta del Río Colorado “colú˗leuvú”, Provincia de Buenos Aires, República Argentina. AAS Revista 10: 23˗37.). It is born in the Andean zone, from the confluence of the Barrancas and the Grande rivers, and runs E-SE for 923 km until its outlet, draining 34,100 km2 (González Uriarte 1985GONZÁLEZ URIARTE M. 1985. Geomorfología del área interfluvial de los cursos inferiores de los ríos Colorado y Negro (provincia de Buenos Aires). I Jornadas Geológicas Bonaerenses, p. 713-730., Alcalde 2014ALCALDE R. 2014. Programa integral de calidad del agua del río Colorado˗Calidad del medio acuático. COIRCO (Comité Interjurisdiccional del río Colorado), Secretaría de Energía de la Nación, Grupo Interempresario, Argentina, 396 p.). Of all Patagonian rivers it carries the highest sediment load (mean annual solid 569,000 tons), which favors the formation of an extensive fluvial˗deltaic system (Blasi 1986BLASI A. 1986. Sedimentología del Río Colorado. Doctoral Thesis. Facultad de Ciencias Naturales y Museo, Universidad Nacional de La Plata, La Plata. Doctorate degree dissertation, 238 p.). According to the Galloway`s (1975)GALLOWAY WE.1975. Process framework for describing the morphologic and stratigraphic evolution of deltaic depositional systems. In: BROUSSARD ML (Ed) Deltas, Models for Exploration. HGS Bulletin, p. 87-98. ternary classification scheme, the Colorado River form a regressive delta dominated by waves (Spalletti & Isla 2003SPALLETTI LA & ISLA FI. 2003. Características y evolución del delta del Río Colorado “colú˗leuvú”, Provincia de Buenos Aires, República Argentina. AAS Revista 10: 23˗37.). The Holocene delta extends from the “Peninsula Verde” (northern limit) to the “Otero” Island to the south, and includes ancient non-functional deltaic lobes, subject to destructive conditions by waves and tides, extending about 900 km2 (Codignotto & Marcomini 1993CODIGNOTTO JO & MARCOMINI SC. 1993. Argentine deltas morphology. In: MAGOON O, WILSON WS, CONVERSE H & TOBIN LT (Eds), Coastal Zone’93, Proc 8th Symp on Coastal and Ocean Management. ASCE, New Orleans, p. 323-336, Spalletti & Isla 2003SPALLETTI LA & ISLA FI. 2003. Características y evolución del delta del Río Colorado “colú˗leuvú”, Provincia de Buenos Aires, República Argentina. AAS Revista 10: 23˗37.). The dating of ancient coastlines of its deltaic plain has allowed estimating a progradation rate of 5 m/year in the last 1,000 years (Fayó et al. 2020a).
In the delta plain, the river forms three active or intermittent meandering distributary channels and numerous afunctional courses and oxbow lakes (Weiler 1988WEILER N. 1988. Depósitos litorales del Pleistoceno tardío y Holoceno en bahía Anegada, provincia de Buenos Aires. Segunda Reunión Argentina de Sedimentología, Buenos Aires, Actas, p. 245-249., Fayó et al. 2018FAYÓ R, ESPINOSA MA, VÉLEZ-AGUDELO CA, PAN J & ISLA FI. 2018. Diatombased reconstruction of Holocene hydrological changes along the Colorado River floodplain (northern Patagonia, Argentina). J Paleolimnol 60(3): 427-443., 2020b). The active river courses include from north to south, the Colorado Nuevo, the Colorado and the Colorado Viejo arms, the last one discharging into the Anegada Bay (Figure 1).
Location map of the Colorado River Basin, Argentina. The study site “La Chiquita” (LCH) is located at the deltaic plain (1.2 km from the coast). Dotted lines: Holocene’s coastline positions (Modified from Codignotto & Weiler 1980CODIGNOTTO JO & WEILER N. 1980. Evolución Morfodinámica del sector costero comprendido entre punta Laberinto e isla Olga, provincia de Buenos Aires. Simposio sobre problemas geológicos del litoral atlántico bonaerenses, Mar del Plata, p. 35-43.).
The river is characterized by a pluvio-nival hydrological regime, without a significant current contribution of water by its tributaries (Butacó and Curacó streams). The lower basin has a mean annual flow of 140 m3seg-1, with maximum values in December (summer, 818 m3seg-1) and minimum values in August (winter-spring, 32 m3seg-1), and it has also registered extraordinary seasonal floods by rainfall effects of 650 m3seg-1 (Cappannini & Lores 1966CAPPANNINI DA & LORES RR. 1966. Los suelos del valle inferior del río Colorado. Instituto Nacional de Tecnología Agropecuaria, Argentina, 127 p.). Due to its great extension, the Colorado River runs through a precipitation gradient that increases towards the east, passing through arid to semi-arid-temperate conditions and presents 384 mm of mean annual rainfall in the lower basin (Alcalde 2014ALCALDE R. 2014. Programa integral de calidad del agua del río Colorado˗Calidad del medio acuático. COIRCO (Comité Interjurisdiccional del río Colorado), Secretaría de Energía de la Nación, Grupo Interempresario, Argentina, 396 p.). The Colorado River runs through old saline substrates with little drainage, because of this it has brackish-fresh waters (Spalletti & Isla 2003SPALLETTI LA & ISLA FI. 2003. Características y evolución del delta del Río Colorado “colú˗leuvú”, Provincia de Buenos Aires, República Argentina. AAS Revista 10: 23˗37., Biasotti et al. 2014BIASOTTI AE, ÁLVAREZ SB, BAZÁN GI & MARTÍNEZ DE FABRICIUS AL. 2014. Variación estacional de la comunidad microfitoplactónica del curso medio del río Colorado (La Pampa˗Argentina). Biología Acuática 30: 249-258.). Salinities are of 0.5±0.6‰ in summer and 0.84±0.13‰ in winter, and its concentration increases towards at the mouth due to the marine influence (6.4˗29.7‰; Vélez-Agudelo et al. 2017). In historical times, the river occasionally received hypersaline waters from the Curacó River (Isla & Toldo 2013ISLA FI & TOLDO EE. 2013. ENSO impacts on Atlantic watersheds of South America. Quat Environ Geosci 4: 34˗41.).
The Colorado River tectonic basin is one of the basins of the Atlantic margin that was originated as part of a Rift system during the mid-late Jurassic or late Jurassic-early Cretaceous, as a consequence of the Gondwana breakup (Fryklund et al. 1996FRYKLUND B, MARSHALL A & STEVENS J. 1996. Cuenca del Colorado. In: Ramos VA & Turic M (Eds), Geología y Recursos Naturales de la Plataforma Continental Argentina. 13º Congreso Geológico Argentino and 3º Congreso de Exploración de Hidrocarburos, Relatorio 8: 138-158., Juan et al. 1996JUAN R, DE JAGER J, RUSSELL J & GEBHARD I. 1996. Flanco norte de la cuenca del Colorado. In: Ramos VA & Turic MA (Eds), Geología y Recursos Naturales de la Plataforma Continental Argentina. 13º Congreso Geológico Argentino y 3º Congreso de Exploración de Hidrocarburos, Buenos Aires, Relatorio 7: 117-133.). Its sedimentary fill would have a maximum thickness of 7,000 m and extends to the late Miocene-Late Pliocene, corresponding to the Fm. Río Negro (Visconti et al. 2003VISCONTI G, DE ELORRIAGA EE & PARRAS A. 2003. Sedimentitas marinas de la Formación Barranca Final (Mioceno medio-superior de la cuenca del Colorado), aflorantes en el sureste de la provincia de La Pampa, Argentina. RAGA 58(2): 187-193., Folguera et al. 2015FOLGUERA A, ZÁRATE M, TEDESCO A, DÁVIL F & RAMOS VA. 2015. Evolution of the Neogene Andean foreland basins of the Southern Pampas and Northern Patagonia (34⁰41`S), Argentina. J S Am Earth Sci 64: 452-466.). Over the tectonic basin can be distinguished an extensive fluvial agradational plain with a succession of staggered river levels (terraces); this plain decreases in a W-E direction, between 100 and 10 m and was formed by the Colorado and the Negro River (González Uriarte 1985GONZÁLEZ URIARTE M. 1985. Geomorfología del área interfluvial de los cursos inferiores de los ríos Colorado y Negro (provincia de Buenos Aires). I Jornadas Geológicas Bonaerenses, p. 713-730.). Traditionally the deltaic plain of Colorado River has been considered a tectonically stable region. Recently, Seitz et al. (2019)SEITZ C, VÉLEZ MI & PERILLO GM. 2019. Cenozoic Geologic evolution of the Lower Colorado River Basin, Northern Patagonia, Argentina. Andean geology: Formerly. Rev Geol Chile 46(1): 7-7. stated that the Andean orogeny during the Miocene reactivated pre-existing structures and produced neotectonic geomorphological changes during the Upper Pleistocene.
The geological and morphological evolution of the Colorado River delta plain has been mainly explained as a result of eustatic and climatic changes (Codignotto & Weiler 1980CODIGNOTTO JO & WEILER N. 1980. Evolución Morfodinámica del sector costero comprendido entre punta Laberinto e isla Olga, provincia de Buenos Aires. Simposio sobre problemas geológicos del litoral atlántico bonaerenses, Mar del Plata, p. 35-43., Weiler 2000WEILER N. 2000. Evolución de los depósitos litorales en bahía Anegada, provincia de Buenos Aires, durante el Cuaternario Tardío. Doctorate degree dissertation.University of Buenos Aires, Buenos Aires, Argentina, 184 p., Spalletti & Isla 2003SPALLETTI LA & ISLA FI. 2003. Características y evolución del delta del Río Colorado “colú˗leuvú”, Provincia de Buenos Aires, República Argentina. AAS Revista 10: 23˗37., Melo et al. 2003MELO W, SCHILLIZZI R, PERILLO G & PICCOLO MC. 2003. Influencia del área continental pampeana en la evolución morfológica del estuario de Bahía Blanca. Revista de la Asociación Argentina de Sedimentología 10: 39˗52., 2013, Martínez et al. 2019MARTÍNEZ G, MARTÍNEZ GA, STOESSEL L & ALCARÁZ AP. 2019. Geoarchaeology and taphonomy: Deciphering site formation processes for late Holocene archaeological settings in the eastern Pampean-Patagonian transition, Argentina. Quatern Int 511: 94-106.). Today, the Colorado River delta is the remnant of a deltaic system with greater extension during the Pleistocene-Early Holocene (Spalleti & Isla 2003, Melo et al. 2003MELO W, SCHILLIZZI R, PERILLO G & PICCOLO MC. 2003. Influencia del área continental pampeana en la evolución morfológica del estuario de Bahía Blanca. Revista de la Asociación Argentina de Sedimentología 10: 39˗52., 2013). Most of these studies inicially outlined the influence of Holocene stages in the delta evolution, using the paleontological information as a complementary biochronological tool (Charó et al. 2015CHARÓ MP, FUCKS EE & GORDILLO S. 2015. Late Pleistocene-Recent marine malacological assemblages of the Colorado River delta (south of Buenos Aires Province): Paleoecology and paleoclimatology. Quatern Int 377: 52-70.). However, in the last ten-years, regional palaeoenvironmental reconstructions based on different lines of evidence have started to be made it: malacological evidence (Fucks et al. 2012FUCKS E, CHARÓ M & PISANO F. 2012. Aspectos estratigráficos y geomorfológicos del sector oriental patagónico bonaerense. Rev Soc Geol Esp 25(1-2): 29-44., Charó et al. 2013CHARÓ MP, GORDILLO S & FUCKS E. 2013. Paleoecological significance of Late Quaternary molluscan faunas of the Bahía San Blas area, Argentina. Quatern Int 301: 135-149., 2015), diatoms (Fayó et al. 2018FAYÓ R, ESPINOSA MA, VÉLEZ-AGUDELO CA, PAN J & ISLA FI. 2018. Diatombased reconstruction of Holocene hydrological changes along the Colorado River floodplain (northern Patagonia, Argentina). J Paleolimnol 60(3): 427-443., 2020a), forams on the continental shelf of the basin (Caramés & Malumián 2000CARAMÉS A & MALUMIÁN N. 2000. Foraminíferos bentónicos del Cenozoico del pozo Estrella x-1, Cuenca del Colorado, plataforma continental argentina. Ameghiniana 37(4): 387-419., Bernasconi & Cusminsky 2015BERNASCONI E & CUSMINSKY G. 2015. Study of the distribution of Elphidium aff. poeyanum (D’ORBIGNY) and Buccella peruviana (D’Orbigny) from the Colorado basin (South America): Holocene paleoenvironmental inferences. The Holocene 25: 810-819.), the palynological evidence (Fernández 2014FERNÁNDEZ AL. 2014. Palinología del Cuaternario tardío en la cuenca inferior de río Colorado, provincia de Buenos Aires, Argentina. Universidad Nacional del Sur, Doctorate degree dissertation, 300 p.), and the geoarchaeology studies (Martínez & Martínez 2011MARTÍNEZ G & MARTÍNEZ GA. 2011. Late Holocene environmental dynamics in fluvial and aeolian depositional settings: Archaeological record variability at the lower basin of the Colorado river (Argentina). Quatern Int 245: 89˗102., Martínez et al. 2019MARTÍNEZ G, MARTÍNEZ GA, STOESSEL L & ALCARÁZ AP. 2019. Geoarchaeology and taphonomy: Deciphering site formation processes for late Holocene archaeological settings in the eastern Pampean-Patagonian transition, Argentina. Quatern Int 511: 94-106.).
MATERIALS AND METHODS
The vibracore was obtained in February 2014 at a site located 1.2 km inland from the Colorado Nuevo River mouth (39°35’52” S, 62°6’43” W, Figure 1). The LCH-core, was removed on the left margin of the river, sealed and stored for laboratory analyses. Once it was longitudinally opened, a visual lithological description was based on sediment colors, grain sizes, sedimentary structures, presence of mollusk shells, and lithological units were photographed. The core was subsampled at each 2 cm intervals. A total of 20 sub-samples were selected for the grain-size analysis, while 43 sub-samples were selected for diatom analysis. The diatom sub-samples were concentrated by serial decantations. Subsequently an aliquot of the concentrated sample (3 ml) was oxidized with 30 % H2O2 and 10 % HCl to remove organic matter and carbonates respectively, after diatom sub-samples were washed with destilled water until reaching neutral pH (Battarbee et al. 2001BATTARBEE RW, JONES VJ, FLOWER RJ, CAMERON NG, BENNION H, CARVALHO L & JUGGINS S. 2001. Diatoms. In: SMOL J, BIRKS H & LAST W (Eds), Tracking environmental change using lake sediments: terrestrial, algal, and siliceous indicators. Springer, Netherlands, p. 155-202.). 20˗µl sample aliquots were transferred onto a coverslip, oven˗dried (60°C) and then mounted in permanent diatom slides using Naphrax® resin (Brunel Laboratory, RI=1.75) for taxonomic identification and counting. In order to calculate the relative frequency of diatom species, a total of 300 valves were counted at 1,000X magnification with a Zeiss Axiostar plus light microscope -LM- (equipped with phase contrast optics). Those samples with abundance <10 valves/ slides were considered sterile. When the identification of taxa required a higher level of detail Scanning Electron Microscopy -SEM- (JEOL JSM˗64000 LV, operated at 15 KV) photographs, were taken. The identification of species was based on local and standard diatom taxonomic literature. Diatom synonymy was updated by the Algaebase (Guiry & Guiry 2020GUIRY MD & GUIRY GM. 2020. AlgaeBase. World-wide electronic publication, National University of Ireland, Galway. https://www.algaebase.org; searched on December 2019.
https://www.algaebase.org; searched on D...
) and Diatombase (Kociolek et al. 2018KOCIOLEK J ET AL. 2018. DiatomBase. http://www.diatombase.org. Accessed on 09/25/2020.
http://www.diatombase.org...
). The grain-size analysis consisted of processing 20 gr of dry sediment with hydrogen peroxide (H2O2, 30%) and hydrochloric acid (HCl, 10%) to remove organic matter and carbonates respectively and disaggregate the sample. The separation of granulometric categories was carried out by dry sieving with a Rotap sieve shaker and a column of ASTM sieves each half phi grade (Krumbein & Pettijohn 1938KRUMBEIN W & PETTIJOHN F. 1938. Manual of Sedimentary Petrology. In: CENTURY- CROFT A (Ed) Plenum, New York, 549 p.). The categories of grain size considered were medium sand (250˗500 μm), fine sand (125˗250 μm), very fine sand (63˗125 μm) and mud (silt and clay <63 μm). The results were expressed as a percentage of each of the categories. The organic matter or total carbon content of the sediment was determined by weight loss on ignition (LOI) according to the methodology of Davies (1974)DAVIES BE. 1974. Loss-on-ignition as an estimate of soil organic matter 1. Soil Sci Soc Am J 38(1): 150-151.. The measurement was carried out in duplicate and the results were expressed as a percentage. The pumicite content of the median sand fraction was determined by flotation in a dense aqueous medium. The total median sand fraction was separated by dry sieving using the ASTM 60 sieve (Phi 2). Due to its porosity, the pumicite was retained in the supernatant and recovered on a wet sieve, it was dried in an oven at 60ºC and the results were expressed as a percentage with respect to the initial weight.
Four sediment samples rich in organic matter were collected from the core for dating. Chronology of core was based on radiocarbon datings from bulk sediment in Accelerator Mass Spectrometry (DirectAMS Laboratory, Washington, EEUU). Radiocarbon ages (14C yr. BP) were calibrated (cal yr. BP ± 2δ) by CALIB 5.0.1 using the SHCal13 calibration curve for the Southern Hemisphere. Malacological fossil remains, located at a distance of 300 m east of the LCH site, were also dated by traditional radiocarbon dating methods in LATYR˗CIG/UNLP (Argentina). These shells of Tagelus plebeius (Lightfood 1786) were found emerged, articulated and in living/trophic position on a surface level of silty sediment.
Data analyses
Diatom species were classified in relation to salinity tolerance and life form, following the ecological classifications of Vos & de Wolf (1993)VOS PC & DE WOLF H. 1993. Diatoms as a tool for reconstructing sedimentary environments in coastal wetlands; methodological aspects. Twelfth International Diatom Symposium. Springer, p. 285˗296. and Denys (1991/1992). Diatom counts were expressed as relative frequencies in percentages. Only those taxa with an occurrence >5% in at least one sample were included.
Diatom zones in the fossil sequence were defined using constrained hierarchical clustering (CONISS) based on Bray˗Curtis distance and variables transformed in x2. The analysis was carried out respecting the stratigraphic order of the samples.The statistically significance number of diatomological zones was assessed using the Broken˗stick model (Bennett 1996BENNETT KD. 1996. Determination of the number of zones in a biostratigraphical sequence. New Phytologist 132: 155-170.). The diatomologyc analyses were conducted with the statistical R version 3.2.2 (R Development Core Team 2015), using the packages “rioja” version 0.9˗5 (Juggins 2015JUGGINS S. 2015. Rioja: analysis of quaternary science data. R package version 0.9˗5. https://cran.r˗project.org/package=rioja. Accessed on 07/15/2020.
https://cran.r˗project.org/package=rioja...
) and “vegan” version 2.3˗0 (Oksanen et al. 2015OKSANEN J, BLANCHET G, KINDT R, LEGENDRE P, MINCHIN PR, O’HARA RB, SIMPSON GL, SOLYMOS P, STEVENS MHH. & WAGNER H. 2015. Vegan: community ecology package. R package version 2.3˗0.). The granulometrics analyses were performed with software Gradistat (Blott & Pye 2001BLOTT SJ & PYE K. 2001. GRADISTAT: a grain size distribution and statistics package for the analysis of unconsolidated sediments. Earth Surf Processes 26(11): 1237-1248).
RESULTS
Chronology and sedimentologic analyses
The sedimentary succession LCH presented 200 cm of length, 7 cm of diameter and it extended from the Late Pleistocene to Holocene. The basal age of the sedimentary succession, determined from bulk sediment to 168˗170 cm depth, was 11,434 ± 63 14C yr. BP (13,091˗13,374 cal. yr. BP). It was corroborated with a new dating of organic matter in sediments at 2 cm (164˗166 cm depth) and it was 10,397 ± 53 14C yr. BP (11,994˗12,417 cal. yr. BP). The third dating carried out at 106 cm of depth was 7,800 ± 45 14C yr. BP (6,660˗6,474 cal. yr. BP). And the fourth dating made from a layer of organic matter at 62 cm depth gave an age of 1,279 ± 31 14C yr. BP (1,068˗1,189 cal. yr. BP). Valves of Tagelus plebeius presented ages of ca. 350 ± 50 14C yr. BP.
Nine lithological units were recognized according to grain size and the presence of sedimentary structures (Figure 2). The succession is mainly composed of fine and very fine brown sand (abundances 70˗90%), massive or laminated with levels of pumicite. The mud was scarce (with abundance <10%) except a peak at the central section. The section from the base at 87 cm depth is dominated by fine brown sand (41˗63%), accompanied by very fine sand (45˗27%) and to a lesser extent by mud (<15%) and medium sand (<11%). In this section, six lithological units are distinguished: the basal unit U1 (200˗188 cm depth), horizontal sheets of light color with different thickness (3˗10 mm) and broken shells of Heleobia sp. The layers are mainly made up of pumicite clasts with medium sand (22˗75%). Overlying U2 (170˗188 cm), dominated by fine sand and whitish laminations of pumicite. In the ascending direction, the U3 (170˗158 cm deep) is dominated by fine sand (43%) and presents mud levels (35%) from which radiocarbon dating was made. The top of the lithological unit U3 is defined by a 5 mm thick arched plate. U4 (158˗110 cm) presents massive brown fine sand without sedimentary structures. Above this, the U5 (110˗96 cm) is dominated by fine brown sand with light wavy laminations, broken shells and two entire valves from the gastropod (Calyptraeidae) Crepidula argentina (Simone 2000). The U6 (96˗87 cm) is characterized by the dominance of massive brown fine sand without sedimentary structures. The U7 (87˗60 cm depth), is the only lithological unit where mud dominates over the sands. The mud is found in a percentage of 63˗86%, the fine sand 7˗14% and the very fine sand 4˗20%. At the same time, a maximum percentage of organic matter in sediment is recognized (1.0˗1.2%, Figure 2). At the base and towards the top of the unit, different sedimentary structures are identified such as flasers (87˗82 cm), banded and lenticular laminations. A 3 mm thick sheet of organic matter was also recognized at the top of it, from which one of the dating was made. The succession of the sedimentary structures refers to intertidal environments. The two superficial lithological units are again dominated by fine brown sand (58˗83%), accompanied by very fine sand (3˗17%) and mud (15˗23%). In ascending order, U8 (60˗37 cm) has stratification of fine brown sand (70%) and medium sand (35%) composed of 30˗60% pumicite and has broken shells. Surface unit U9 (37˗0 cm) is dominated by fine brown sand and presents intraformational clasts of mud and organic matter.
Lithological profile and granulometric analysis of LCH core. The grain size categories are: very fine, fine, median sand and mud (%). Additionally, it shows pumicite of median sand and organic matter in percentages (%).
The LCH core has a wide temporal range, thus it is a condensed sequence. Due to the age difference between the dating of the lithological units U5 and U7, the existence of a hiatus between them is inferred.
Diatomological analysis
The diatomological analysis of the 43 subsamples allowed the identification of 256 taxa (including species and varieties). Seven of the analyzed samples presented scarce abundance (<10 valves/slide) and were considered sterile. One barren zone was found in the lower˗middle section of the sedimentary succession, between 110˗132 cm depth, and isolated barren subsamples were also recorded (22˗24cm, 110˗112cm, 114˗116cm, 120˗122cm, 124˗126cm, 130˗132cm, 178˗180 cm).
The diatom analysis of the 36 remaining samples allowed the identification of 16 species of diatoms with abundance greater than 5% in at least one sample. Three statistically representative diatomological zones (DZI, II and III) were defined using the CONISS cluster analysis and the Broken˗stick model. The relative proportions of the species in each subsample of the sedimentary succession and the diatomological zones were synthesized in the diagram of relative frequencies (Figure 3).
Relative frequencies diagram showing the most abundant diatoms taxa (> 5%) of the LCH-core and diatom zones (DZI to DZIII) obtained by CONISS (Bray Curtis distance). Sedimentary facies are based in the Ta et al. (2001)TA TK, NGUYEN VL, TATEISHI M, KOBAYASHI I & SAITO Y. 2001. Sedimentary facies, diatom and foraminifer assemblages in a late Pleistocene-Holocene incised valley sequence from the Mekong River Delta, Bentre Province, Southern Vietnam:the BT2 core. J Asian Earth Sci 20(1): 83-94. model.
The whole sedimentary succession was dominated by marine˗coastal species, most of which are tychoplanktonic. The two dominant species were Paralia sulcata (Ehrenberg) Cleve (tychoplankton) and Cymatosira belgica Grunow (tychoplankton) with maximum abundances close to 50% alternately. They were accompanied by a stable set of marine˗coastal species whose proportion varied between 10˗15%. This accompanying flora included the species as Rhaphoneis amphiceros (Ehrenberg) Ehrenberg (tychoplanktonic), Delphineis minutissima (Hustedt) Simonsen (tychoplanktonic), Schionodiscus oestrupii (Ostenfeld) Alverson, Kang and Theriot (planktonic), Diploneis aestuarii Hustedt (benthic), Tryblionella granulata (Grunow) Mann (benthic), and brackish-freshwater species such as Luticola mutica (Kütsing) Mann (aerophile) and small “fragilarioids” taxa. The presence of Pseudopodosira boltovskoyi (Sar, Lavigne, Wetzel, Ector and Sunesen) was identified as part of the accompanying marine flora and constitutes the first record of this species in holocene sediments from Argentina, however it was not represented in the frequency diagrams due its low abundance. LM photomicrographs (and one SEM) of the Holocene diatoms of the LCH-core in valvar and cingular view are shown in a Figure 4.
Light photomicrographs of Holocene diatoms taxa from the LCH core. a: Paralia sulcata; b: Cymatosira belgica; c: Rhaphoneis amphiceros; d: Pseudopodosira boltovskoyi; e: Delphineis minutissima; f: Diploneis aestuarii; g: Tryblionella granulata; h: Schionodiscus oestrupii; i: Campylosira cymbelliformis; j: “naviculoid” taxon; k: Staurosira venter; l: Punctastriata glubokoensis; m: Punctastriata lancettula; n: Staurosira binodis. Scalebar = 10µm (in c, h, k, l, scalebar = 5 µm).
The basal diatom zone DZI (200˗110 cm) represents the hydro˗ecological conditions of the early Holocene (ca. 11,000 14C yr. BP) and integrates the lithological units U1˗U4. It was characterized by the dominance of Paralia sulcata (47%) and secondly Cymatosira belgica (29%). Accompanying marine species were recorded with abundances ~10%. The freshwater species presented abundance ~5% and were composed of Luticola spp. and a set of small “fragilarioids”: Staurosira venter (Ehrenberg) Cleve and Möller, Punctastriata glubokoensis Williams, Chudaev & Gololobova, Punctastriata lancettula (Schumann) Hamilton & Siver, and Staurosira binodis (Ehrenberg) Lange˗Bertalot. At the top of the DZI was observed a 22 cm sterile section (110˗132 cm depth). These five samples analyzed shown extremely low abundance (<10 valves / slide) for which they were not considered in the statistical analyzes. However, the presence of poorly preserved Paralia sulcata and Cymatosira belgica was recorded as fragments of valves.
The DZII include the U5˗U6 (110˗87 cm depth). The base was dated at 7,800±45 14C yr. BP (6,660˗6,474 cal. yr. BP). It is dominated by Cymatosira belgica (55%) and Paralia sulcata (35%). The accompanying taxa are mainly marine and present abundances <10%. Only in this zone it is noted the presence of the epipsammitic diatom Campylosira cymbelliformis (Schimdt) Grunow ex Van Heurck (13%) and a peak of abundance of “naviculoid” taxon (25%) that could not be recognized at a specific level. Freshwater species are practically absent.
The DZIII (87 cm at the top) integrated three lithological units U7˗U9 and the late Holocene, covered the last 1,279±31 14C yr. BP (1,068˗1,189 cal. yr. BP). It is mainly dominated by Paralia sulcata and Cymatosira belgica too. The abundances of C. cymbelliformis and a “naviculoid” taxon decrease steeply and a significant increase in the brackish˗freshwater accompanying flora is identified (<15%), represented by Luticola mutica and Luticola sp., Punctastriata glubokoensis, Punctastriata lancettula, Staurosira binodis and Staurosira venter.
DISCUSSION
Organic-matter and ash layers
Patagonian estuarine regressive sequences used to be crowned by marsh or peaty levels rich in organic matter (Isla et al. 2015ISLA FI, ESPINOSA MA, RUBIO B, ESCANDELL A, GERPE M, MIGLIORANZA K, REY D & VILAS F. 2015. Avulsion at a drift-dominated mesotidal estuary: The Chubut River outlet, Patagonia, Argentina. J Hydrol 529(2): 632-639.). This is also the case for the organic-rich layer of the LCH sequence (U7).
The estuarine Holocene sequences of Patagonia can content ash or pumicite layers from the Andean volcanoes commonly derived by westerly winds (Hildreth & Drake 1992HILDRETH W & DRAKE RE. 1992. Volcán Quizapu, Chilean Andes. B Volcanol 54(2): 93-125.). During the Holocene, several eruptions have taken place and dated from the Hudson, Mentolat and Sollipulli volcanoes (Naranjo et al. 1993NARANJO JA, MORENO H, EMPARAN C & MURPHY M. 1993. Volcanismo explosivo reciente en la caldera del volcán Sollipulli. Rev Geol Chile 20: 167-191., Stern 2004STERN CHR. 2004. Active Andean volcanism: its geologic and tectonic setting. Rev Geol Chile 31: 161-206., 2008STERN CHR. 2008. Holocene tephrochronology record of large explosive eruptions in the southernmost Patagonian Andes. B Volcanol 70: 435-454., Lachowycz et al. 2015LACHOWYCZ SM, PYLE DM, GILBERT JS, MATHER TA, MEE K, NARANJO JA & HOBBS LK. 2015. Glaciovolcanism at Volcán Sollipulli, Southern Chile: Lithofacies analysis and interpretation. J Volcanol Geoth Res 303: 59-78., Bendle et al. 2017BENDLE JM, PALMER AP, THORNDYCRAFT VR & MATTHEWS IP. 2017. High-resolution chronology for deglaciation of the Patagonian Ice Sheet at Lago Buenos Aires (46.5° S) revealed through varve chronology and Bayesian age modeling. Quaternary Sci Rev 177: 314-339.) although other ash concentrations were described without precise reference to any known eruption. For example, at the Claromecó estuarine sequence (Buenos Aires Province) ash fragments layers were recorded between 1,310 and 640 yrs BP (Hassan et al. 2004HASSAN GS, ESPINOSA MA & ISLA FI. 2004. Análisis paleoambiental de una secuencia del Holoceno tardío del arroyo Claromecó (Provincia de Buenos Aires, Argentina) basado en diatomeas. Ameghiniana 41(2): 161-170.).
Composition and autoecology of diatom assemblages
The totality of the LCH sedimentary succession is dominated by tychoplanktonic coastal-marine diatom assemblages indicating a marine-dominate influence. Tychoplanktonic diatoms are those capable of carrying out reproductive and metabolic processes in the water column, although they originate from other habitats such as benthos or periphyton, for which they are partially associated with the substrate (Denys 1991DENYS L. 1991/1992. A check˗list of the diatoms in the Holocene deposits of the Western Belgian coastal plain with the survey of their apparent ecological requirements. Introduction, ecological code and complete list. Geological Service of Belgium, Professional Paper 246: 1˗41./1992). Paralia sulcata grow in the benthos of coastal environments, although they are abundantly recorded in plankton, transported under mixed conditions by winds and tides (Zong 1997ZONG Y. 1997. Mid-and late-Holocene sea-level changes in Roudsea Marsh, northwest England: a diatom biostratigraphical investigation. The Holocene 7(3): 311-323., Santos˗Fischer et al. 2016). It has been widely recorded in marginal coastal-marine environments of the planet, particularly abundant in those with fine sediments, rich in organic matter and with a wide range of salinity, such as marshes, tidal channels, bays, coastal lagoons and coral reefs (Weiss et al. 1978WEISS D, GEITZENAUER K & SHAW FC. 1978. Foraminifera, diatom and bivalve distribution in recent sediments of the Hudson estuary. Estuar Coast Shelf S 7(4): 393-400., Cooper 1995COOPER SR. 1995. Chesapeake Bay watershed historical land use: impact on water quality and diatom communities. Ecol Appl 5(3): 703-723., 1999COOPER SR. 1999. Estuarine paleoenvironmental reconstructions using diatoms. In: SMOL JP & STOERMER EF (Edits). The diatoms: applications for the environmental and Earth Sciences, p. 352-375.). Actually, P. sulcata is abundantly recorded along the entire Argentine coastline, living in different marginal coastal-marine environments and estuarine areas with tidal influence (Parodi & Barría de Cao 2003PARODI ER & BARRÍA DE CAO S. 2003. Benthic microalgal communities in the inner part of the Bahía Blanca estuary (Argentina): a preliminary qualitative study. Oceanol Acta 25(5): 279-284., Garibotti et al. 2011GARIBOTTI IA, FERRARIO ME, ALMANDOZ GO & CASTAÑOS C. 2011. Seasonal diatom cycle in Anegada Bay, El Rincón estuarine system, Argentina. Diatom Res 26(2): 227-241., Pucci et al. 1996PUCCI A, HOFFMEYER M, FREIJE H, BARRÍA M, POPOVICH C, RUSANSKY C & ASTEASUAIN RO. 1996. Características de las aguas y del plancton en un sector del estuario del Río Negro (República Argentina). Pollution Processes in Coastal Environments, p. 146-151., Santinelli & Esteves 1993SANTINELLI N & ESTEVES JL. 1993. Características químicas y fitoplanctónicas del estuario del Río Chubut (Patagonia, Argentina). Naturalia Patagónica. Ciencias Biológicas 1(1): 22-34., Espinosa & Isla 2015ESPINOSA MA & ISLA FI. 2015. Modern diatom assemblages in surface sediments from meso-macrotidal estuaries of Patagonia, Argentina. Pan-American Journal of Aquatic Sciences 10(1): 29-43.).
The codominant diatom of the LCH sedimentary succession Cymatosira belgica is a centric coastal-marine species with bipolar morphology (Hasle et al. 1983HASLE G, VON STOSCH H & SYVERTSEN E. 1983. Cymatosiraceae, a new diatom family. Bacillaria 6: 9-156.). The C. belgica has a cosmopolitan distribution and its life form is epipsammitic (associated with sands), although it can also be found in silty sediments and occasionally in plankton (Underwood 1994UNDERWOOD GJ. 1994. Seasonal and spatial variation in epipelic diatom assemblages in the Severn estuary. Diatom Res 9(2): 451-472.). C. belgica is abundant in sandy marginal coastal areas such as open beaches or bays and tidal channels at depths of 3˗10 m (Vos & de Wolf 1988VOS PC & DE WOLF H. 1988. Methodological aspects of palaeoecological diatom research in coastal areas of the Netherlands. Geol Mijnbouw 67: 31-40., García 2016GARCÍA M. 2016. Taxonomy, morphology and distribution of Cymatosiraceae (Bacillariophyceae) in the littorals of Santa Catarina and Rio Grande do Sul. Biota Neotrop 16(2): e20150139.). Currently, there is abundance of this species at the mouth of coastal lagoons such as the Patos Lagoon, southern Brazil (da Silva et al. 2010DA SILVA JG, TORGAN LC & DE SOUZA CARDOSO L. 2010. Diatomáceas (Bacillariophyceae) em marismas no sul do Brasil. Acta Bot Bras 24(4): 935-947.) and dominates the epipelitic community at the mouth of deltaic systems with significant tidal influence (Manoylov & Dominy 2013MANOYLOV KM & DOMINY JR JN. 2013. Changes in epipelic diatom diversity from the Savannah River Estuary. J Environ Prot 4(02): 172-179.).
The marine-coastal accompanying flora of the LCH core is stable, as a whole these species present an abundance of ~30% and persist throughout the entire sedimentary sequence. It is composed mainly by Rhaphoneis amphiceros, Delphineis minutissima, Diploneis aestuarii, Shionodiscus oestrupii and Tryblionella granulate (Figures 4.c, e-h). These species have been found together with Paralia sulcata and Cymatosira belgica in plankton and the surface sediments of estuarine and coastal environments in the Buenos Aires province and Patagonia, Argentina (Sar et al. 2001SAR EA, SUNESEN I & CASTAÑOS C. 2001. Marine diatoms from Buenos Aires coastal waters (República Argentina). I. Thalassiosiraceae. Nova Hedwigia 73(1-2): 199-228., 2007SAR EA, SUNESEN I & FERNANDEZ PV. 2007. Marine diatoms from Buenos Aires coastal waters (Argentina). II. Thalassionemataceae and Rhaphoneidaceae. Rev Chil Hist Nat 80(1): 63-79., Ferrario et al. 2003FERRARIO M, ALMANDOZ G, GARIBOTTI I & LICEA S. 2003. Nuevos registros de diatomeas típicas de sedimento en el plancton de la costa del mar argentino. B So Argent Bot 38: 123-129., Hassan et al. 2007HASSAN GS, ESPINOSA MA & ISLA FI. 2007. Dead diatom assemblages in surface sediments from a low impacted estuary: the Quequen Salado river, Argentina. Hydrobiologia 579(1): 257-270., Garibotti et al. 2011GARIBOTTI IA, FERRARIO ME, ALMANDOZ GO & CASTAÑOS C. 2011. Seasonal diatom cycle in Anegada Bay, El Rincón estuarine system, Argentina. Diatom Res 26(2): 227-241., Espinosa & Isla 2015ESPINOSA MA & ISLA FI. 2015. Modern diatom assemblages in surface sediments from meso-macrotidal estuaries of Patagonia, Argentina. Pan-American Journal of Aquatic Sciences 10(1): 29-43.). Currently, this assemblage is found abundant at meso-tidal estuaries such as Negro and Colorado Rivers, where salinity variations fluctuate from 0 to 26.9‰ and 6.5 to 29‰, respectively (Escandell et al. 2009ESCANDELL A, ESPINOSA MA & ISLA FI. 2009. Diatomeas como indicadoras de variaciones de salinidad durante el Holoceno tardío en el río Negro, Patagonia Norte, Argentina. Ameghiniana 46(3): 461-468., Vélez˗Agudelo et al. 2017VÉLEZ˗AGUDELO CA ESPINOSA MA, FAYÓ R & ISLA FI. 2017. Modern diatoms from a temperate river in South America: the Colorado River (North Patagonia, Argentina). Diatom Res 32(2): 133-152.) and in tidal banks and marshes of macro-tidal estuaries of Patagonia (Espinosa & Isla 2015ESPINOSA MA & ISLA FI. 2015. Modern diatom assemblages in surface sediments from meso-macrotidal estuaries of Patagonia, Argentina. Pan-American Journal of Aquatic Sciences 10(1): 29-43.).
The composition of the fossil diatomological assemblages of the LCH core is the same as the modern assemblages of the lower course of the Colorado Nuevo River, where a tidal channel environment develops (Vélez-Agudelo et al. 2017). This result is congruent with the observations made by Vos & de Wolf (1993)VOS PC & DE WOLF H. 1993. Diatoms as a tool for reconstructing sedimentary environments in coastal wetlands; methodological aspects. Twelfth International Diatom Symposium. Springer, p. 285˗296., who stated that the dominance of marine planktonic and tychoplanktonic species in estuarine sediments is an indicator of tidal channels; where the influence of tides and the speed of the current are maximum, conditioning the growth of epiphytic and benthic species.
The presence of Pseudopodosira boltovskoyi was identified as part of the accompanying marine flora en the LCH core (<5%, Figure 4.d). This specie was recently descripted by Sar et al. (2017)SAR EA, LAVIGNE A, WETZEL CE, ECTOR L & SUNESEN I. 2017. Pseudopodosira boltovskoyi sp. nov. (Pseudopodosiraceae, Bacillariophyta) from coastal waters of Argentina. Phycologia 56(3): 239-252. from phytoplankton samples from marine coastal waters and surface sediments of littoral environments in Buenos Aires Province (Bahia Anegada). This finding constitutes the first record of the P. boltovskoyi species in the Holocene sediments of Argentina.
In addition to coastal-marine taxa, the fossil samples of the core have few accompanying brackish-fresh diatoms represented by “small fragilarioids” taxa (Punctastriata glubokoensis, Punctastriata lancettula, Staurosira binodis and Staurosira venter; Figures 4.k-n), and two aerophilous species of the genus Luticola, capable of living in humid, temporarily dry sites or even outside water bodies (van Dam et al. 1994VAN DAM H, MERTENS A & SINKELDAM J. 1994. A coded checklist and ecological indicator values of freshwater diatoms from the Netherlands. Aquatic Ecology 28: 117-133.). They are present in the DZI and DZIII zones and absent in DZII. The term “small fragilarioids” is a generalization that refers to the araphid diatoms of the family Frafilariaceae whose valves sizes do not exceed 20 µm (Li et al. 2016LI CL, ASHWORTH MP, WITKOWSKI A, LOBBAN CS, ZGŁOBICKA I, KURZYDŁOWSKI KJ & QIN S. 2016. Ultrastructural and molecular characterization of diversity among small araphid diatoms all lacking rimoportulae. I. Five new genera, eight new species. J Phycol 52: 1018-1036.). They are important components of the assemblages of planktonic and benthic microalgae from continental brackish-fresh and coastal-marine environments (Morales 2005MORALES EA. 2005. Observations of the morphology of some known and new fragilarioid diatoms (Bacillariophyceae) from rivers in the USA. Phycol Res 53: 113-133., Witkowski et al. 2000WITKOWSKI A, LANGE-BERTALOT H & METZELTIN D. 2000. Diatom Flora of Marine Coasts I. Iconographia Diatomologica 7: 1-925., Metzeltin & Lange-Bertalot 2007METZELTIN D & LANGE-BERTALOT H. 2007. Tropical diatoms of South America II. Special remarks on biogeographic disjunction. Iconographia Diatomológica 18: 1-877.). They generally form chains and are associated to fine sediments, sand, rocks, algae or submerged macrophytes (Morales et al. 2010MORALES EA, WETZEL CE & ECTOR L. 2010. Two short-striated species of Staurosirella (Bacillariophyceae) from Indonesia and the United States. Pol Bot J 55: 107-117., Cejudo˗Figueiras et al. 2011, García et al. 2017GARCÍA ML, MAIDANA NI, ECTOR L & MORALES EA. 2017. Staurosira patagonica sp. nov., a new diatom (Bacillariophyta) from southern Argentina, with a discussion on the genus Staurosira Ehrenberg. Nova Hedwigia 146: 103-123.); Frequently they are found in plankton, which is why they are considered facultative planktonic or tychoplanktonic species (Gell et al. 2007GELL P, TIBBY J, LITTLE F, BALDWIN D & HANCOCK G. 2007. The impact of regulation and salinisation on floodplain lakes: the lower River Murray, Australia. Hydrobiologia 591: 135-146.). Although the small representatives of the Fragilariaceae family are very abundant in aqueous environments and have been exhaustively studied during the last two decades, the taxonomic determination of the species and genera is still subject to discussions due to important change in the identification criteria. (Guerrero et al. 2019GUERRERO JM, GARCÍA ML & MORALES EA. 2019. Staurosirella andino-patagonica sp. nov. (Bacillariophyta) from lake sediments in Patagonia, Argentina. Phytotaxa 402: 131-144., Li et al. 2019LI CL, WITKOWSKI A, ASHWORTH MP, DĄBEK P, SATO S, ZGŁOBICKA I, WITAK M, KHIM JS & KWON CJ. 2019. The morphology and molecular phylogenetics of some marine diatom taxa within the Fragilariaceae, including twenty undescribed species and their relationship to Nanofrustulum, Opephora and Pseudostaurosira. Phytotaxa 355: 1-104.).
In Argentina, ʺsmall fragilarioidsʺ are abundant in surface sediments, periphyton and plankton of lakes, rivers, streams, wetlands, ponds and reservoirs (Maidana & Díaz˗Villanueva 2001, Espinosa & Isla 2015ESPINOSA MA & ISLA FI. 2015. Modern diatom assemblages in surface sediments from meso-macrotidal estuaries of Patagonia, Argentina. Pan-American Journal of Aquatic Sciences 10(1): 29-43., Vélez˗Agudelo et al. 2017). They have also been recorded in sedimentary sequences of estuaries and freshwater environments of Buenos Aires and Patagonia (Espinosa 2008ESPINOSA MA. 2008. Diatoms from Patagonia and Tierra del Fuego. In: Rabassa J (Ed), Late Cenozoic of Patagonia and Tierra del Fuego. Developments in Quaternary Sciences, Elsevier, p. 383-392., Escandell et al. 2009ESCANDELL A, ESPINOSA MA & ISLA FI. 2009. Diatomeas como indicadoras de variaciones de salinidad durante el Holoceno tardío en el río Negro, Patagonia Norte, Argentina. Ameghiniana 46(3): 461-468., Hassan et al. 2009HASSAN GS, ESPINOSA MA & ISLA FI. 2009. Diatom-based inference model for paleosalinity reconstructions in estuaries along the northeastern coast of Argentina. Palaeogeogr Palaeocl 275(1-4): 77-91., 2011, Espinosa et al. 2012ESPINOSA MA, HASSAN GS & ISLA FI. 2012. Diatom-inferred salinity changes in relation to Holocene sea-level fluctuations in estuarine environments of Argentina. Alcheringa 36: 373-386., Fayó & Espinosa 2014FAYÓ R & ESPINOSA MA. 2014. Reconstrucción paleoambiental de la planicie costera de Mar Chiquita (Provincia de Buenos Aires, Argentina) durante el Holoceno, basada en diatomeas. Ameghiniana 51: 510˗528.). Only the most recent contributions address the taxonomic identification of fossil diatoms with the new classification criteria and the combined use of LM and SEM analysis (e.g., García & Maidana 2015GARCÍA ML & MAIDANA NI. 2015. Diatomeas (Bacillariophyceae) subfósiles del Brazo Blest del Lago Nahuel Huapi, Argentina. B Soc Argent Bot 50: 123-140., Grana et al. 2018GRANA L, MORALES EA, MAIDANA NI & ECTOR L. 2018. Two new species of Staurosira and Pseudostaurosira (Bacillariophyta) from the highlands of Argentina (south-central Andes) and two new nomenclatural combinations. Phytotaxa 365: 60–72., Fayó et al. 2018FAYÓ R, ESPINOSA MA, VÉLEZ-AGUDELO CA, PAN J & ISLA FI. 2018. Diatombased reconstruction of Holocene hydrological changes along the Colorado River floodplain (northern Patagonia, Argentina). J Paleolimnol 60(3): 427-443., 2020a). Along the Colorado River, Vélez˗Agudelo et al. (2017) studied the composition and spatial distribution of modern diatomological flora in surface sediments of the middle and lower basin and identified Staurosira venter (Ehrenberg) Cleve & Möller, as the dominant species of the brackish-freshwater fluvial assemblages. Also, they established the first record in Argentina of P. glubokoensis and P. lancettula as part of the accompanying fluvial flora of the Colorado River. Later, from a diatomological study of two sedimentary sequences of the deltaic plain, Fayó et al. (2018, 2020a) corroborated the presence and persistence of “small fragilarioids” taxa mentioned as stable components of the fluvial-deltaic environment of the Colorado River since ca. 7,300 years BP to the present. The new findings of ʺsmall fragilarioids in the LCH core (DZI and DZIII), confirm the temporal range of the ubiquity of the genera Punctastriata and Staurosira in Northern Patagonia throughout the Late Pleistocene and Holocene.
Ecological studies and records of Punctastriata in general are very scarce in the literature and particularly in South America (Fayó et al. 2020a). According to Vélez˗Agudelo et al. (2017), Punctastriata glubokoensis has a tolerance to salinity of 0 to 2.1‰, while Punctastriata lancettula tolerates even more restricted ranges (0 to 1.68‰). The low abundance and ecological incompatibility of these fresh-brackish species in a coastal-marine environment allows to infer that the “small fragilarioid” and the Luticola species found in DZI and DZIII, are allochthonous taxa, that were transported downstream from fluvial reaches without marine influence during the Holocene.
DZII zone lacks the brackish-freshwater species as accompanying flora. These taxa were replaced for Campylosira cymbelliformis and “naviculoid” species that could not be identified (Figures 4.i, j). C. cymbelliformis is a bipolar-centric marine and epipsammitic specie, common in shallow and dissipative open coasts (García-Baptista 1993GARCIA-BAPTISTA M. 1993. Psammic algae from Praia Azul, Brazil. Berlin, J. Cramer. Bibliotheca Phycologica 94: 6-14.) Generally, is found with C. belgica in sandy environments (García 2016GARCÍA M. 2016. Taxonomy, morphology and distribution of Cymatosiraceae (Bacillariophyceae) in the littorals of Santa Catarina and Rio Grande do Sul. Biota Neotrop 16(2): e20150139.); this is consistent with the grain sizes of the lithological units U5 and U6. Despite an extensive bibliographic review, this “naviculoid” species has not been consistently assigned to a generic or specific taxonomic category. Its dimensions and valve morphology were obtained by LM analysis (n = 40) but require a further MB study for valve ultrastructure details.
Along the LCH core, the dominance of tychoplanktonic forms have been recorded in previous investigations carried out in this coastal plain (Vélez-Agudelo et al. 2017, Fayó et al. 2020a) and other deltaic environments. In the Ebro River delta (Spain), Benito et al. (2015)BENITO J, TROBAJO R & IBÁÑEZ C. 2015. Benthic diatoms in a Mediterranean delta: ecological indicators and a conductivity transfer function for paleoenvironmental studies. J Paleolimnol 54: 171-188. interpreted the dominance of tychoplanktonic diatoms as indications of habitats with a shallow water column and environmental conditions with a certain degree of physical instability (scarce light availability and significant turbulence due to winds and tides). Shallow environments present inherent processes of sedimentary resuspension caused by the action of waves, tides and/or winds, and constitute physical variables that influence on the composition of diatom assemblages since they favor the detachment of benthic diatoms and epiphytes from macrophytes and their incorporation into the water column (Schweizer 1997SCHWEIZER A. 1997. From littoral to pelagial: comparing the distribution of phytoplankton and ciliated protozoa along a transect. J Plankton Res 19: 829-848.). However, in the estuary of the Severn River estuary (England), the dominance of the tychoplanktonic forms could represent a survival strategy to avoid burial in waters with significant load sedimentary (Underwood & Paterson 1993UNDERWOOD GJ & PATERSON DM. 1993. Seasonal changes in diatom biomass, sediment stability and biogenic stabilization in the Severn Estuary. J Mar Biol Assoc UK 73(4): 871-887.). The partial relationships between tychoplanktonic diatoms with the substrate and the continuous resuspension in the water column, would allow the development of benthic diatoms that are incapable of moving and to escape from burial (as is the case of the araphids), allowing their burial in estuarine or deltaic context.
Palaeoenvironmental reconstruction of the LCH site and Holocene eustatic variations.
Numerous palaeoenvironmental reconstructions reflect that the South American Atlantic coast has been extensively affected by the Holocene sea level fluctuations. Therefore, the inferred paleoenvironmental conditions in each of the evolutionary phases of the LCH core were interpreted in a changing eustatic context. On the basis of diatom analysis of LCH sedimentary succession, the integration of the chronological and lithological results, and the analysis of the autoecology of the most abundant species, it has been possible to reconstruct three phases in the evolution in the coastal sector of the deltaic plain from the Late Pleistocene-Early Holocene transition to the present.
The abundance and persistence of marine-coastal tychoplanktonic in LCH core indicates that the marine influence prevailed at the site during the last 11,000 years, with important bedload and resuspension processes. According to the Holocene sea-level fluctuations recorded in Argentina (Isla 1989ISLA FI. 1989. The Southern Hemisphere sea level fluctuation. Quaternary Sci Rev 8 (4): 359-368., Isla & Espinosa 1998ISLA FI & ESPINOSA MA. 1998. Modelo sedimentario de colmatación de pequeños estuarios dominados por limo, provincia de Buenos Aires. Actas 7° Reunión Argentina de Sedimentología, p. 24-36., Cavallotto et al. 2004CAVALLOTTO JL, VIOLANTE RA & PARKER G. 2004. Sea-level fluctuations during the last 8,600 years in the de la Plata River (Argentina). Quatern Int 114(1): 155-165., Spagnuolo 2005SPAGNUOLO J. 2005. Evolución geológica de la región costera-marina de Punta Alta, provincia de Buenos Aires. Doctorate degree . dissertation, Universidad Nacional del Sur, 269 p., Isla 2013ISLA FI. 2013. The flooding of the San Matías Gulf: the Northern Patagonia sea-level curve. Geomorphology 203: 60-65., Prieto et al. 2017PRIETO AR, MOURELLE D, PELTIER WR, DRUMMOND R, VILANOVA I & RICCI L. 2017. Relative sea˗level changes during the Holocene in the Río de la Plata, Argentina and Uruguay: A review. Quatern Int 442: 35˗49.), evolutionary phase I and II (DZI-II, early and middle Holocene, respectively) occurred during sea level rise, while the most recent phase (DZ III) occurred under regressive conditions (Late Holocene).
The dominance of Paralia sulcata in Holocene sediments from different parts of the world has been related to sea levels higher than the modern one and the evolution of various eustatically dependent littoral environments (Mc Quoid & Nordberg 2003MC QUOID MR & NORDBERG K. 2003. The diatom Paralia sulcata as an environmental indicator species in coastal sediments. Estuar Coast Shelf S 56(2): 339-354., Weschenfelder et al. 2008WESCHENFELDER J, MEDEANIC S, CORRÊA IC & ALIOTTA S. 2008. Holocene paleoinlet of the Bojuru region, Lagoa dos Patos, southern Brazil. J Coastal Res 24(1): 99-109., Medeanic et al. 2009MEDEANIC S, CARVALHO TORGAN L, PINHEIRO CLEROT LC & SANTOS-FISCHER BC. 2009. Holocene marine transgression in the coastal plain of Rio Grande do Sul, Brazil: palynomorph and diatom evidence. J Coastal Res 25: 224-233., Santos-Fischer et al. 2016SANTOS-FISCHER CB, CORRÊA IC, WESCHENFELDER J, TORGAN LC & STONE JR. 2016. Paleoenvironmental insights into the Quaternary evolution of the southern Brazilian coast based on fossil and modern diatom assemblages. Palaeogeogr Palaeocl 446: 108-124., 2018). On the micro-tidal coast of Buenos Aires Province, its dominance was indicated in sedimentary sequences extracted from the coastal plain of the Mar Chiquita lagoon at ca. 6,020–4,170 14C yr. BP (Espinosa & Isla 2011ESPINOSA MA & ISLA FI. 2011. Diatom and sedimentary record during the Mid˗Holocene evolution of the San Blas estuarine complex, Northern Patagonia, Argentina. Ameghiniana 48: 411˗423., Fayó & Espinosa 2014FAYÓ R & ESPINOSA MA. 2014. Reconstrucción paleoambiental de la planicie costera de Mar Chiquita (Provincia de Buenos Aires, Argentina) durante el Holoceno, basada en diatomeas. Ameghiniana 51: 510˗528.), indicating marginal coastal-marine paleoenvironments during periods immediately to the maximum transgressive and prior to the restriction of the coastal lagoon, while during its establishment the presence of P. sulcata was persistent only in tidal channels (Hassan et al. 2011HASSAN GS, ESPINOSA MA & ISLA FI. 2011. Fluctuaciones de salinidad durante el Holoceno en la laguna costera de Mar Chiquita (Provincia de Buenos Aires): una aproximación cuantitativa basada en diatomeas. Ameghiniana 48: 496-507.). It is also abundant in the Holocene sediments of the Quequén Grande River estuary (7,040 ± 50 14C yr. BP), where the development of an extensive estuarine lagoon was inferred by the transgressive flooding of ancient river valley (Espinosa et al. 2012ESPINOSA MA, HASSAN GS & ISLA FI. 2012. Diatom-inferred salinity changes in relation to Holocene sea-level fluctuations in estuarine environments of Argentina. Alcheringa 36: 373-386.).
In contrast, in the meso-tidal coast at the south of Buenos Aires province and northern Patagonia, Paralia sulcata and Cymatosira belgica are frequent in Holocene and modern sediments, so they are considered good proxies of tidal environments of the patagonian coasts (Espinosa & Isla 2011ESPINOSA MA & ISLA FI. 2011. Diatom and sedimentary record during the Mid˗Holocene evolution of the San Blas estuarine complex, Northern Patagonia, Argentina. Ameghiniana 48: 411˗423.). Coastal-marine assemblages similar to those found in LCH-core are identified in Holocene sediments of two sites of Negro River estuary, 170 km to the south of LCH core (Escandell et al. 2009ESCANDELL A, ESPINOSA MA & ISLA FI. 2009. Diatomeas como indicadoras de variaciones de salinidad durante el Holoceno tardío en el río Negro, Patagonia Norte, Argentina. Ameghiniana 46(3): 461-468., Escandell & Espinosa 2012ESCANDELL A & ESPINOSA MA. 2012. Evolución paleoambiental de estuarios mesomareales de Patagonia. Las diatomeas como indicadores ambientales durante el Holoceno en la costa norpatagónica argentina. Editorial Académica Española, Verlag, Saarbrücken, 93 p.). Its dominance was associated with the clogging of tidal channels in a regressive context. The codominance of these species was also recorded in Holocene sedimentary successions from San Blas Bay (115 km south of LCH site) in a full-length core at the Puente San Blas site from 4,904 ± 70 14C yr. BP to the present, and at the base of the Paso Seco core from 4,904 ± 70 and 987 ± 43 14C yr. BP. Its abundance was also interpreted as the clogging of tidal channels during Late Holocene (Espinosa & Isla 2011ESPINOSA MA & ISLA FI. 2011. Diatom and sedimentary record during the Mid˗Holocene evolution of the San Blas estuarine complex, Northern Patagonia, Argentina. Ameghiniana 48: 411˗423.). In Chubut River marsh, the dominance of P. sulcata in a Holocene succession (Magagna site), was interpreted as a coastal-marine paleoenvironment dominated by tides ca. 4,376 ± 69 14C yr. BP (Escandell & Espinosa 2012ESCANDELL A & ESPINOSA MA. 2012. Evolución paleoambiental de estuarios mesomareales de Patagonia. Las diatomeas como indicadores ambientales durante el Holoceno en la costa norpatagónica argentina. Editorial Académica Española, Verlag, Saarbrücken, 93 p., Isla et al. 2015ISLA FI, ESPINOSA MA, RUBIO B, ESCANDELL A, GERPE M, MIGLIORANZA K, REY D & VILAS F. 2015. Avulsion at a drift-dominated mesotidal estuary: The Chubut River outlet, Patagonia, Argentina. J Hydrol 529(2): 632-639.). In the same way, its dominance in Holocene sediments at the mouth of the Negro River and in the Sauce Grande lagoon, was interpreted as the development of paleoenvironments of tidal flats associated with sea levels higher than today (Gutierrez-Tellez & Schillizzi 2002GUTIERREZ-TÉLLEZ B & SCHILLIZZI R. 2002. Asociaciones de diatomeas en paleoambientes cuaternarios de la costa sur de la provincia de Buenos Aires, Argentina. Pesquisas em Geociências 29(1): 59-70., Schillizzi et al. 2012SCHILLIZZI RA, GUTIERREZ-TELLEZ BM, LUNA LI & CABALLERO N. 2012. Paleoambientes holocénicos en el paraje Playa Chica, costa norte del río Negro, Provincia de Buenos Aires, Argentina. Pesquisas em Geociências 39(2): 147-159.).
Recently, 22 km upstream from LCH, Fayó et al. (2020a) performed a diatomological analysis of a core from the deltaic plain of the Colorado river (Las Isletas, LI) and registered a maximum abundance of P. sulcata and C. belgica (25%) in the basal section of the sequence (DZI: ca. 7,315 ± 64 14C yr. BP) and its decrease towards the middle section of the core (DZII). Both species are considered allochthonous by the authors due to the scarcity and poor preservation valves. However, their presence allowed them to infer that the LI site was affected by the Holocene fluctuations of sea level. So, during the transgressive periods of maximum marine influence, the tide was the transport agent in LI site, depositing marine-coastal species upstream, while the gradual decrease of allochthonous marine-coastal species between 7,315 ± 64 and 2,218 ± 29 14C yr. BP it was associated with an increase in fluvial influence due to the development of the deltaic lobe and the progradation of the coastline towards the East.
The abundance of Paralia sulcata in Argentina is consistent with records from Uruguay and Brazil that also indicate the regional trend of sea level rise. In Brazil, they were identified in Holocene sediments of the Barra Falsa channel (Weschenfelder et al. 2008WESCHENFELDER J, MEDEANIC S, CORRÊA IC & ALIOTTA S. 2008. Holocene paleoinlet of the Bojuru region, Lagoa dos Patos, southern Brazil. J Coastal Res 24(1): 99-109., Santos-Fischer et al. 2018SANTOS-FISCHER CB, WESCHENFELDER J, CORRÊA ICS, STONE JR, APPEL DEHNHARDT B & BORTOLIN EC. 2018. A Drowned Lagunar Channel in the Southern Brazilian Coast in Response to the 8.2-ka Event: Diatom and Seismic Stratigraphy. Estuar Coasts 41: 1601-1625.), on Cassino Beach (Medeanic et al. 2009MEDEANIC S, CARVALHO TORGAN L, PINHEIRO CLEROT LC & SANTOS-FISCHER BC. 2009. Holocene marine transgression in the coastal plain of Rio Grande do Sul, Brazil: palynomorph and diatom evidence. J Coastal Res 25: 224-233.), in the coastal lagoon Peixe (Santos 2015SANTOS CB. 2015. Paleoecologia de diatomáceas como subsídios para o conhecimento da evolução paleogeográfica da região costeira do Rio Grande do Sul, Brasil. Doctorate degree dissertation. Instituto de Geociências. Universidade Federal do Rio Grande do Sul, Porto Alegre, Brasil, 213 p.), on Hermenegildo beach (Lima 2008LIMA LG. 2008. Estratigrafia e evolução da barreira holocênica na praia do Hermenegildo (RS). Instituto de Geociências, Universidade Federal do Rio Grande do Sul, Porto Alegre/RS. Master’s degree dissertation Unpublished, 78 p.) and in the Patos Lagoon (Santos-Fischer et al. 2016SANTOS-FISCHER CB, CORRÊA IC, WESCHENFELDER J, TORGAN LC & STONE JR. 2016. Paleoenvironmental insights into the Quaternary evolution of the southern Brazilian coast based on fossil and modern diatom assemblages. Palaeogeogr Palaeocl 446: 108-124.), among others. In the southeast of Uruguay P. sulcata dominates the transgressive Holocene sediments of different coastal lagoons (García-Rodríguez & Witkowski 2003GARCÍA-RODRÍGUEZ F & WITKOWSKI A. 2003. Inferring sea level variation from relative percentages of Pseudopodosira kosugii in Rocha lagoon, SE Uruguay. Diatom Res 18(1): 49-59., García-Rodríguez et al. 2004GARCÍA-RODRÍGUEZ F, SPRECHMANN P, METZELTI D, SCAFATI L, MELENDI D, VOLKHEIMER W, MAZZEO N, HILLER A, VON TÜMPLING W & SCASSO F. 2004. Holocene trophic state changes in relation to sea level variation in Lake Blanca, SE Uruguay. J Paleolimnol 31(1): 99-115., García-Rodríguez 2012GARCÍA-RODRÍGUEZ F. 2012. South America, Holocene Coastal Lagoons. In L Bengtsson, Herschy RW & Fairbridge RW (Eds). Encyclopedia of Lakes and Reservoirs. Dordrecht: Springer Netherlands, p. 723-734.).
Based on previous paleoenvironmental reconstructions from northern Patagonia and the similarity between the fossil and current assemblages, it could infer the evolutionary phase I of the LCH site (DZI: U1˗U4), as a sandy marginal coastal-marine environment with high deposition energy, similar to the current tidal channel that develops at the mouth of the Colorado Nuevo River. These it would have been established since the late Pleistocene/Early Holocene ca. from 11,434 ± 63 14C yr. BP (13,091˗ 13,374 cal. yr. BP, DZI) to 7,800 ± 45 14C yr. BP. During the early Holocene (ca. 11,000 14C yr. BP), different lines of evidence indicate a low and rising sea level, which would have favored the development of marginal coastal environments in what currently makes up the continental marine platform of the Colorado River basin (Ponce et al. 2011PONCE JF, RABASSA J, CORONATO A & BORROMEI AM. 2011. Palaeogeographical evolution of the Atlantic coast of Pampa and Patagonia from the last glacial maximum to the Middle Holocene. Biol J Linn Soc 103: 363˗379., Bernasconi & Cusminsky 2015BERNASCONI E & CUSMINSKY G. 2015. Study of the distribution of Elphidium aff. poeyanum (D’ORBIGNY) and Buccella peruviana (D’Orbigny) from the Colorado basin (South America): Holocene paleoenvironmental inferences. The Holocene 25: 810-819.). Despite a position of the coastline shifted to the East in response to a low sea level, the presence and persistence of the coastal-marine tychoplanktonic assemblage at the LCH site, indicates that an important marine influence and tidal action reached the site early during the Holocene (Figure 5).
a-d. Conceptual model of the three phases in the hydrological evolution of the LCH site based on diatom zones (pink) and its integration with others evidence from the area (Holocene’s coastline positions and LI-core diatom assemblages’ interpretation). a- Late Pleistocene-Early Holocene. Tidal flats developed in the sea level rising and tidal channels from the LCH site were clogged (DZI).b- Early-Middle Holocene. After 7,800 14C yrs. BP, the coastline was close to the LCH site and estuarine channels were clogging in the coastal deltaic plain (DZII). c- Holocene Sea-level Maximum. ca. 6,600 14C yr. BP the coastline was located 16 km inland (red dotted lines: modified from Codignotto & Weiler 1980CODIGNOTTO JO & WEILER N. 1980. Evolución Morfodinámica del sector costero comprendido entre punta Laberinto e isla Olga, provincia de Buenos Aires. Simposio sobre problemas geológicos del litoral atlántico bonaerenses, Mar del Plata, p. 35-43.) and allochthonous coastal marine diatom assemblages were transported to the LI site (DZI in green, Fayó et al. 2020a). The ocean surpasses the LCH site and the transgressive reworking sediment and erosive features produce a gap in the LCH sedimentary record (pink DZII/DZIII boundary) which masks the transgressive signal. d- Last ca. 1,300 years BP. A progressive decrease in sea level and deltaic progradation during the regressive phase, formed parallel littoral ridges located at 16.5 km to 400 m from the present coastline (red dotted lines: modified from Alberó et al. 1980ALBERÓ M, ANGIOLINI F, BALBUENA J, CODIGNOTTO J, LINARES E & WEILER N. 1980. Primeras edades Carbono-14 de afloramientos de conchillas de la República Argentina. RAGA 35(3): 363-374.; Codignotto & Weiler 1980CODIGNOTTO JO & WEILER N. 1980. Evolución Morfodinámica del sector costero comprendido entre punta Laberinto e isla Olga, provincia de Buenos Aires. Simposio sobre problemas geológicos del litoral atlántico bonaerenses, Mar del Plata, p. 35-43.). Stable Fluvial diatom assemblages are established on the site LI (DZII in green, Fayó et al. 2020a). In the LCH site the fluvial influence is accentuated (DZIII): the tidal channels that crossed the coastal delta plain and marshes were clogging towards the present.
In the upper section of the DZI (U4: 132˗110 cm depth), the abundance of diatoms declines abruptly, as well as the state of preservation of the valves, indicating the occurrence of drastic changes in environmental conditions or a period of instability of the system ca. 7,800 14C yr. BP. The absence of diatoms in sandy sedimentary successions has been previously recorded in littoral areas, as being attributed to a low resistance of the valves to high-energy deposition conditions, and/or their washing due to the porosity of the sandy deposits. (Espinosa 1998, Castro et al. 2013CASTRO DF, ROSSETTI DF, COHEN MC, PESSENDA LC & LORENTE FL. 2013. The growth of the Doce River Delta in northeastern Brazil indicated by sedimentary facies and diatoms. Diatom Res 28(4): 455-466.). In this sense, the poor preservation stage and the lack of diatoms in the sterile section of the LCH-core are associated with high-energy coastal environments deposited in the marine transgression during the early-mid Holocene. During this period, intrinsic marine transgressive characteristics such as the reworking of coastal sediments and erosive features represented unfavorable conditions for the development and preservation of diatoms in the LCH registry (DZI).
According to the new diatomological evidence during the transgressive period, the coastline would have moved west from the early Holocene to the Middle Holocene, favoring the clogging of pre-existing tidal channels in the delta plain (DZI, Figure 5.a). In this context of rising sea level, the tides and waves reworked the littoral sediments of the deltaic plain (Spalletti & Isla 2003SPALLETTI LA & ISLA FI. 2003. Características y evolución del delta del Río Colorado “colú˗leuvú”, Provincia de Buenos Aires, República Argentina. AAS Revista 10: 23˗37.), which could affect the preservation of fossil remains contained and generate sterile areas of siliceous microfossils.
Paleoenvironmental conditions inferred during phase II (DZII: U5 and U6) were similar to those of the early Holocene (DZI) and analogous to a tidal channel. However, the lack of small allochthonous “fragilarioid” species in DZII and the presence of Campylosira cymbelliformis, give indications of a greater marine influence and/or a less fluvial influence than the remaining phases. Additionally, the lithological units of this phase present horizontal and inclined sandy laminations and the presence of Crepidula argentina shells. C. argentina is an epifaunal gastropod that integrates currently beach associations and Quaternary beach deposits in the Colorado River delta and Anegada Bay (Charó et al. 2015CHARÓ MP, FUCKS EE & GORDILLO S. 2015. Late Pleistocene-Recent marine malacological assemblages of the Colorado River delta (south of Buenos Aires Province): Paleoecology and paleoclimatology. Quatern Int 377: 52-70.). The lithological and malacological evidences support the interpretation of greater marine influence at the LCH site ca. of the 7,800 ± 45 14C yr. BP (6,660˗6,474 cal. yr. BP). Thus, during the middle Holocene (phase II) a coastline position similar to the current one (and near to LCH site), would have allowed the growth of coastal-marine diatoms, indicating reestablishment of stable littoral conditions, similar to current tidal channels with significant marine influence (estuarine channel, Figure 5.b).In addition to the diatomological evidence, the deltaic plain of the Colorado River presents diverse geomorphological and malacological records of the transgression during the middle Holocene and the subsequent regression process (Spalletti & Isla 2003SPALLETTI LA & ISLA FI. 2003. Características y evolución del delta del Río Colorado “colú˗leuvú”, Provincia de Buenos Aires, República Argentina. AAS Revista 10: 23˗37., Melo et al. 2013MELO W, PERILLO G, PERILLO M, SCHILIZZI R & PICCOLO MC. 2013. Late Pleistocene–Holocene deltas in southern Buenos Aires Province, Argentina. IAHS Publ 358: 187-195.). Among the remarkable evidences, it presents a series of parallel littoral ridges, oriented N-S and successively, located from 16.5 km to 400 m from the current coast that represent old coastlines (Codignotto & Weiler 1980CODIGNOTTO JO & WEILER N. 1980. Evolución Morfodinámica del sector costero comprendido entre punta Laberinto e isla Olga, provincia de Buenos Aires. Simposio sobre problemas geológicos del litoral atlántico bonaerenses, Mar del Plata, p. 35-43., Figure 5). Radiocarbon dating of the malacological contents confirmed ages decreasing towards the east from ca. 6,630 ± 120 to 407 ± 100 14C yr. BP, indicating the progradation of the coast in the regressive stage (Alberó et al. 1980ALBERÓ M, ANGIOLINI F, BALBUENA J, CODIGNOTTO J, LINARES E & WEILER N. 1980. Primeras edades Carbono-14 de afloramientos de conchillas de la República Argentina. RAGA 35(3): 363-374., Codignotto & Weiler 1980CODIGNOTTO JO & WEILER N. 1980. Evolución Morfodinámica del sector costero comprendido entre punta Laberinto e isla Olga, provincia de Buenos Aires. Simposio sobre problemas geológicos del litoral atlántico bonaerenses, Mar del Plata, p. 35-43., Fucks et al. 2012FUCKS E, CHARÓ M & PISANO F. 2012. Aspectos estratigráficos y geomorfológicos del sector oriental patagónico bonaerense. Rev Soc Geol Esp 25(1-2): 29-44.). The interpretations based on diatoms agree with Codignotto & Weiler (1980)CODIGNOTTO JO & WEILER N. 1980. Evolución Morfodinámica del sector costero comprendido entre punta Laberinto e isla Olga, provincia de Buenos Aires. Simposio sobre problemas geológicos del litoral atlántico bonaerenses, Mar del Plata, p. 35-43. hypothesis, who claim that the coastline was located 16 km upstream ca. 6,600 years 14C BP (Figure 5.c). According to the new evidence during the maximum transgressive event, the coastline would have been located past the LCH site to the west near Las Isletas site, as indicated by the transport of P. sulcata and C. belgica at the base of the LI core ca. 7,315 ± 64 14C yr. BP (Fayó et al. 2020a, Figure 5.c).
Phase III (DZIII: U7˗U9) occurs during the late Holocene ca. 1,279 ± 14C yr. BP (1,068˗1,189 years cal BP) and continues to the present. The coastal-marine assemblage is similar to that of the previous phases and to that found in the current tidal channel of the Colorado Nuevo distributary channel. Geomorphological studies of the Colorado River delta plain and surrounding areas indicate that tidal channel clogging was a widespread process during the Late Holocene (Weiler 2000WEILER N. 2000. Evolución de los depósitos litorales en bahía Anegada, provincia de Buenos Aires, durante el Cuaternario Tardío. Doctorate degree dissertation.University of Buenos Aires, Buenos Aires, Argentina, 184 p.). The increase in the abundance of the accompanying brackish-fresh diatom flora (Punctastriata, Staurosira and Luticola), refers to an increase in fluvial influence during this period. As mentioned above, the presence of fragilarioids taxa in the LCH sequence can be associated with the post-mortem transport of valves in the direction of river flow and their deposition during periods with greater fluvial influence associated to delta progradation (Figure 5.d). According to a previous diatomological research, fragilarioids species have a vast ubiquity in the region and constitute the main component of fluvial assemblages without marine influence of the Colorado River since the Holocene to the present (Fayó et al. 2020a, b, Vélez-Agudelo et al. 2017). The abundance peaks of continental freshwater taxa of the DZIII (such as those obtained in 48 and 44 cm depth), can be associated to sporadic pulses or extraordinary floods of fresh water that occurred during the last ca. 1,279 ± 31 14C yr. BP (1,068˗1,189 cal. yr. BP). The flaser bedding and lenticular laminations of the basal section of this phase (U7) indicate intertidal marine-coastal conditions, while the levels of organic matter and the increase of mud towards the surface section (U9) support a greater fluvial influence towards the surface.
Although the accompanying assemblages do not change abruptly at the limit of phase (DZ II/III), there is a wide temporal range between the lithological units dated U5: 7,800 ± 45, and U7: 1,279 ± 31 14C yr. BP. This difference between the dates allows us to infer the occurrence of a hiatus in the record at the limit between U6 and U7 (DZII/DZIII boundary; Figure 5.c).
Located in the vicinity of the LCH site, a level of articulated valves of Tagelus plebeius in living / trophic position was identified with ages of 350 ± 50 14C yr. BP. The shells of estuarine mollusks are widely used as reliable samples for radiocarbon dating (Gómez et al. 2008GÓMEZ EA, BOREL CM, AGUIRRE ML & MARTÍNEZ DE. 2008. Radiocarbon reservoir ages and hardwater effect for the northeastern coastal waters of Argentina. Radiocarbon 50(1): 119-129.). T. plebeius is a euryhaline infaunal organism that is distributed from North America to San Matías Gulf (41°S, Argentina, Morris & Rosenberg 2005MORRIS P & ROSENBERG G. 2005. Search interface and documentation for Malacolog, an online database of Western Atlantic marine Mollusks (version 4.1.1). Accessed online at http://www.malacolog.org.
http://www.malacolog.org...
). This species lives gregariously in shallow environments in sub-coastal areas, where it digs caves up to 50 cm deep (Golfieri et al. 1998GOLFIERI GA, FERRERO L & ZÁRATE M. 1998. Tafonomía y paleoecología de Tagelus plebieus (Lightfoot, 1786) (Mollusca, Bivalvia) en sedimentos holocenos de río Quequén Grande, provincia de Buenos Aires, Argentina. Ameghiniana 33(3): 255-264.). Buenos Aires province has a lot of Holocene deposits with a high density of articulated T. plebeius in living position (Charó et al. 2013CHARÓ MP, GORDILLO S & FUCKS E. 2013. Paleoecological significance of Late Quaternary molluscan faunas of the Bahía San Blas area, Argentina. Quatern Int 301: 135-149.). Their abundance has been interpreted as mass die-offs due to changes in sea level, sediment burial, or overlapping of temporally different populations (Schnack et al. 1982SCHNACK EJ, FASANO JL & ISLA FI. 1982. The evolution of Mar Chiquita lagoon coast, Buenos Aires Province, Argentina. Holocene sea level fluctuations, magnitude and causes. IGCP 61, Univ. S. Carolina, Columbia (Colquhoun, DJ), p. 143-155., Golfieri et al. 1998GOLFIERI GA, FERRERO L & ZÁRATE M. 1998. Tafonomía y paleoecología de Tagelus plebieus (Lightfoot, 1786) (Mollusca, Bivalvia) en sedimentos holocenos de río Quequén Grande, provincia de Buenos Aires, Argentina. Ameghiniana 33(3): 255-264.). In the area of the Colorado Nuevo River, three grayish sandy-silt deposits with these malacological evidences, were interpreted as past tidal flats, formed when the sea level was higher than today (Charó et al. 2013CHARÓ MP, GORDILLO S & FUCKS E. 2013. Paleoecological significance of Late Quaternary molluscan faunas of the Bahía San Blas area, Argentina. Quatern Int 301: 135-149.). Similar malacofaunas were also identified at the base of a Holocene sedimentary succession from the Estancia San Antonio archaeological site, 4 km from the current coastline, indicating greater marine influence in the vicinity of the study area ca. 1,500 14C yr. BP (Martínez & Martínez 2011MARTÍNEZ G & MARTÍNEZ GA. 2011. Late Holocene environmental dynamics in fluvial and aeolian depositional settings: Archaeological record variability at the lower basin of the Colorado river (Argentina). Quatern Int 245: 89˗102.). Both interpretations are consistent with the dates obtained by Codignotto & Weiler (1980)CODIGNOTTO JO & WEILER N. 1980. Evolución Morfodinámica del sector costero comprendido entre punta Laberinto e isla Olga, provincia de Buenos Aires. Simposio sobre problemas geológicos del litoral atlántico bonaerenses, Mar del Plata, p. 35-43. and represent evidence of the regressive phase during the late Holocene. In contrast, the level of T. plebeius dated close to the LCH-core indicates the development of intertidal marine conditions during historical times. Later and in a context of regressive coast, the meso-tidal flat was vegetated forming a marsh while other parts of the deposit were eroded by the river channel, exposing the valves on the surface.
Deltaic sedimentary facies based on diatoms
Consistent with the sedimentary evolutionary models of deltas (Boyd et al. 1992BOYD R, DALRYMPLE R & ZAITLIN B. 1992. Classification of clastic coastal depositional environments. Sediment Geol 80(3-4): 139-150.) and Dalrymple et al. (1992)DALRYMPLE RW, ZAITLIN BA & BOYD R. 1992. Estuarine facies models; conceptual basis and stratigraphic implications. J Sediment Res 62(6): 1130-1146., the regressive deltaic reconstructions based on diatoms, indicate the succession of estuarine-transgressive stages to progradational-regressive stages, during the middle and late Holocene respectively (Ta et al. 2001TA TK, NGUYEN VL, TATEISHI M, KOBAYASHI I & SAITO Y. 2001. Sedimentary facies, diatom and foraminifer assemblages in a late Pleistocene-Holocene incised valley sequence from the Mekong River Delta, Bentre Province, Southern Vietnam:the BT2 core. J Asian Earth Sci 20(1): 83-94., Castro et al. 2013CASTRO DF, ROSSETTI DF, COHEN MC, PESSENDA LC & LORENTE FL. 2013. The growth of the Doce River Delta in northeastern Brazil indicated by sedimentary facies and diatoms. Diatom Res 28(4): 455-466.). The transgressive stage is associated with the flooding of the river valleys and the consequent formation of estuaries and bays with significant marine influence, which is inferred by the increase in marine and marine-brackish planktonic diatoms (Ta et al. 2021, 2002a, b, Santos-Fischer et al. 2018SANTOS-FISCHER CB, WESCHENFELDER J, CORRÊA ICS, STONE JR, APPEL DEHNHARDT B & BORTOLIN EC. 2018. A Drowned Lagunar Channel in the Southern Brazilian Coast in Response to the 8.2-ka Event: Diatom and Seismic Stratigraphy. Estuar Coasts 41: 1601-1625.). When the estuary occupies the ancient valley and the process of flocculation of clays at the interface of fresh-salty water occurs, generating muddy depocentres inland (Cavallotto et al. 2004CAVALLOTTO JL, VIOLANTE RA & PARKER G. 2004. Sea-level fluctuations during the last 8,600 years in the de la Plata River (Argentina). Quatern Int 114(1): 155-165.). In consequence, the increasing number of planktonic diatoms is accompanied by pelitic sedimentary textures as a signal to maximum transgressive events. In subsequent regressive-prograding stages, paleoestuaries gradually fill up and fluvial or continental influence increases due to delta progradation. Thus, marine planktonic assemblages are replaced by brackish-marine and freshwater diatoms, and sand grain sizes interfingered with silts, typical of regressive facies (Ta et al. 2001TA TK, NGUYEN VL, TATEISHI M, KOBAYASHI I & SAITO Y. 2001. Sedimentary facies, diatom and foraminifer assemblages in a late Pleistocene-Holocene incised valley sequence from the Mekong River Delta, Bentre Province, Southern Vietnam:the BT2 core. J Asian Earth Sci 20(1): 83-94., 2002a, 2005).
Ta et al. (2001)TA TK, NGUYEN VL, TATEISHI M, KOBAYASHI I & SAITO Y. 2001. Sedimentary facies, diatom and foraminifer assemblages in a late Pleistocene-Holocene incised valley sequence from the Mekong River Delta, Bentre Province, Southern Vietnam:the BT2 core. J Asian Earth Sci 20(1): 83-94. used a combination of diatoms, foraminifera and lithological units from a 71˗m core from the coastal delta plain of the Mekong River (Southeast Asia), to investigate the succession of deltaic sedimentary facies in relation to changes in sea level during the last ca. 13,000 cal yr BP. The authors identified nine depositional facies and described the assemblages of fossil diatoms and ecological groups associated to them, based on the transgressive and regressive phases of sea level (Ta et al. 2001TA TK, NGUYEN VL, TATEISHI M, KOBAYASHI I & SAITO Y. 2001. Sedimentary facies, diatom and foraminifer assemblages in a late Pleistocene-Holocene incised valley sequence from the Mekong River Delta, Bentre Province, Southern Vietnam:the BT2 core. J Asian Earth Sci 20(1): 83-94., 2005). Like the Colorado River, the Mekong River delta is another regressive system, without significant tectonic activity, and dominated by a mesotidal regime. This deltaic system has progradated for the last ca. 6,000 yr. BP at different speeds and presents a greater influence of waves for the last ca. 3,000 yr. BP (Ta et al. 2002bTA TK, NGUYEN VL, TATEISHI M, KOBAYASHI I, TANABE S & SAITO Y. 2002b. Holocene delta evolution and sediment discharge of the Mekong River, southernVietnam. Quaternary Sci Rev 21(16-17): 1807-1819.). It has an important fluvial contribution due to the tropical climate and monsoonal regime, which favors the construction of a delta of extended areal and depths. In contrast, the Colorado River delta is a more restricted and shallow system, built with minor and discontinuous fluvial inputs, due to the semi˗arid Patagonian climate. This causes that the development of the lithological units of both deltaic systems different. Even so, it is possible to recognize similar deltaic facies in the sedimentary successions of both deltas in base to dominant ecological groups of diatoms. According to Ta et al. (2001)TA TK, NGUYEN VL, TATEISHI M, KOBAYASHI I & SAITO Y. 2001. Sedimentary facies, diatom and foraminifer assemblages in a late Pleistocene-Holocene incised valley sequence from the Mekong River Delta, Bentre Province, Southern Vietnam:the BT2 core. J Asian Earth Sci 20(1): 83-94., the transgressive stages in the sedimentary succession of the Mekong River are represented by the following biofacies in ascending order: Estuarine channel/Tidal river sandy silt, Salt marsh / Mudy tidal flat, Estuary marine sand, Transition sandy silt and Open bay mud. The mudy facies represent the maximum marine influence of the Holocene transgression in the ancient fluvial valley ca. 5,300 cal yr BP. The succession of diatom assemblages described from the Estuarine channel facies to the Open bay mud facies (see A˗D in Ta et al. 2001TA TK, NGUYEN VL, TATEISHI M, KOBAYASHI I & SAITO Y. 2001. Sedimentary facies, diatom and foraminifer assemblages in a late Pleistocene-Holocene incised valley sequence from the Mekong River Delta, Bentre Province, Southern Vietnam:the BT2 core. J Asian Earth Sci 20(1): 83-94.), shows the gradual replacement of a mixture of freshwater and brackish euryhaline species (characteristic of tidal environments) by marine planktonic ecologycal groups of diatoms, and where brackish and freshwater taxa are subordinate. This floristic replacement is also accompanied by an abrupt increase in open˗sea foraminifers and by lithological replacing the silt˗sandy sediments with parallel laminations and flaser, with massive pelitic sediments. In the overlying section of the Mekong River sedimentary succession, four regressive biofacies were identified, in ascending order: Prodelta mud, Delta front Sandy silt, Sub˗to Inter˗tidal flat Sandy silt, Subaerial delta plain channel (marsh and beach ridge). During this succession of facies, the marine planktonic diatoms gradually decrease and the abundance of brackish and freshwater diatoms increases due to the progradation of the delta (Ta et al. 2001TA TK, NGUYEN VL, TATEISHI M, KOBAYASHI I & SAITO Y. 2001. Sedimentary facies, diatom and foraminifer assemblages in a late Pleistocene-Holocene incised valley sequence from the Mekong River Delta, Bentre Province, Southern Vietnam:the BT2 core. J Asian Earth Sci 20(1): 83-94.).
On the other hand, in Brazil, Castro et al. (2013)CASTRO DF, ROSSETTI DF, COHEN MC, PESSENDA LC & LORENTE FL. 2013. The growth of the Doce River Delta in northeastern Brazil indicated by sedimentary facies and diatoms. Diatom Res 28(4): 455-466. analyzed the succession of sedimentary facies and the diatomological evidence of an 11-m core extracted from the deltaic system of the Doce River, as a function of transgressive and regressive Holocene events. Like the Colorado River, the Doce River delta is a regressive system that was built in a mesotidal environment during the mid-late Holocene and was affected by fluctuations in sea level of the same order of magnitude. However, the delta of this River presents a greater sedimentary contribution due to the tropical climate of the region. In its delta plain a succession of four association facies was identified, where the continental influence increases over time: Estuarine channel, Estuarine central basin, Lake / Ria and Fluvial channel / Marsh. As in the Mekong River, the Doce River has clay estuarine deposits ca. 7,000˗5,000 14C yr. BP (in Estuarine central basin facies), where planktonic and marine taxa are dominant and freshwater diatoms are subordinate. According to the authors, Tryblionella punctata, Paralia sulcata, Tryblionella granulata and Diploneis gruendleri dominate. This association of coastal˗ marine diatoms is similar to the assemblage that currently grows in the Rio de la Plata (Argentina) and constitutes an indicator of estuarine paleoenvironments with significant marine influence (Pérez et al. 2017PÉREZ L, GARCÍA-RODRÍGUEZ F & HANEBUTH TJ. 2017. Paleosalinity Changes in the Río de la Plata Estuary and on the Adjacent Uruguayan Continental Shelf over the Past 1200 Years: An Approach Using Diatoms as a Proxy. In: KWECKSTRÖM, SAUNDERS KM, GELL PA & SKILBECK CG (Eds), Applications of paleoenvironmental techniques in estuarine studies, Developments in paleoenvironmental research, Springer, Dordrecht 20: 529-549.). The upper section of the Doce River core shows a gradual floristic replacement associated to regressive phases and deltaic progradation, where brackish-fresh water diatoms become dominant.
The sedimentological and diatomological evidence of the basal and middle section of the LCH core (DZI and DZII, 200˗87 cm depth) was interpreted as a tidal channel between ca. 11,434 ± 63 14C yr. BP and 7,800 ± 45 14C yr. BP, similar to that exist today. This interpretation is consistent with the transgressive facies of the sandy Estuarine channel / Tidal river sandy silt /salt marsh and Estuarine channel, (Ta et al. 2001TA TK, NGUYEN VL, TATEISHI M, KOBAYASHI I & SAITO Y. 2001. Sedimentary facies, diatom and foraminifer assemblages in a late Pleistocene-Holocene incised valley sequence from the Mekong River Delta, Bentre Province, Southern Vietnam:the BT2 core. J Asian Earth Sci 20(1): 83-94., Castro et al. 2013CASTRO DF, ROSSETTI DF, COHEN MC, PESSENDA LC & LORENTE FL. 2013. The growth of the Doce River Delta in northeastern Brazil indicated by sedimentary facies and diatoms. Diatom Res 28(4): 455-466.), respectively. However, the overlying section of the LCH core (DZIII) does not present the massive muddy sedimentary facies associated to assemblages of marine planktonic diatoms typical of the paleoestuary facies (Open bay mud /Estuarine central basin) as recorded in both deltaic evolutionary models. The absence of massive muddy facies, the lack of marine planktonic diatoms and the time difference between the dating of the lithological units U5 and U7, allow to corroborate the occurrence of a hiatus in the sedimentary record of LCH core at the U7/U6 limit.
According to the regional reconstructions carried out in the Mekong River, the muddy facies are produced due to the flocculation of estuaric clays as the ancient’s valley became flooded (Estuarine channel facies), at the maximum flood level (Open bay mud facies) and also during the initial regressive stages (Prodelta mud facies, Ta et al. 2001TA TK, NGUYEN VL, TATEISHI M, KOBAYASHI I & SAITO Y. 2001. Sedimentary facies, diatom and foraminifer assemblages in a late Pleistocene-Holocene incised valley sequence from the Mekong River Delta, Bentre Province, Southern Vietnam:the BT2 core. J Asian Earth Sci 20(1): 83-94.). In this sense, Ta et al. (2002a, 2005) and Wei & Wu (2011)WEI X & WU C. 2011. Holocene delta evolution and sequence stratigraphy of the Pearl River Delta in South China. Sci China Earth Sci 54(10): 1523-1541. indicate that the regressive Delta front Sandy silt facies represent high energy palaeoenvironmental conditions with significant tidal currents, high sedimentation rates and erosion surfaces. Sometimes, these features in regressive facies might impact on the record and cause the alteration or absence of muddy transgressive facies. Based on this background, it is inferred that the hiatus in the LCH sedimentary succession could have occurred during high-energy stages in incipient regressive or transgressive phases, masking the signals of the Colorado River paleoestuary/bay and prodelta facies. The inference of high energy deposition conditions during the regressive stage is also supported by the shelly ridges found in the deltaic plain ca. 6,000˗400 14C yr. BP (Codignotto & Weiler 1980CODIGNOTTO JO & WEILER N. 1980. Evolución Morfodinámica del sector costero comprendido entre punta Laberinto e isla Olga, provincia de Buenos Aires. Simposio sobre problemas geológicos del litoral atlántico bonaerenses, Mar del Plata, p. 35-43.). These littoral geoforms represent ancient coastlines, formed during the progradation of the delta; their formation involves the reworking by storms.
The upper section of the LCH sequence (DZIII) presents lithological units with defined sedimentary structures, similar to those described in regressive deltaic facies of the Mekong River. The Inter˗tidal flat Sandy silt (U7) and Subaerial delta plain facies (tidal channel/marsh) in U8 and U9 are identified in ascending order (Figure 3). Regarding the diatomological evidence, section (DZIII) is dominated by marine-coastal euryhaline species; planktonic species are scarce and an increase in brackish-freshwater diatoms is observed towards the top, indicating an increase in continental influence associated to the progradation of the deltaic lobe. The succession of regressive facies at the LCH site allowed to infer the establishment of a shallow coastal-marine prograding environment with significant tidal action, in which the fluvial/continental influence gradually increased, favoring its colonization by halophilic plants. The paleoenvironments of the tidal flats and the marsh would then have been established sequentially from the late Holocene ca. 1.279 ± 31 14C yr. BP to the present.
CONCLUSIONS
These results and interpretations represent the first paleolimnological study based on diatoms in a deltaic system in Argentina. Increasing worldwide research indicates that diatoms related to sediments are very valuable information for paleoenvironmental reconstructions involving eustatic changes.
Three evolutionary stages were identified at the site during the last ca. 11,000 years BP in response to sea level fluctuations, delta progradation and fluvial dynamics.
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The dominance and persistence of coastal-marine tychoplanktonic diatoms in the core, indicate that marine and tidal influence dominated during the Late Pleistocene and Holocene, significantly affected by the coastal advances and retreats associated with eustatic variations.
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The coastal LCH sequence represents the clogging of tidal channels in a mesotidal environment of the Patagonia coast. During the Late Pleistocene-Early Holocene (DZI: ca. 11,000 14C yr. BP) a tidal channel was flooded when the transgression occupied this area. The pumicite were transported and deposited forming sandy layers at the high-tide levels. The resuspension and erosion processes associated with the marine influence and the transgressive context affected the preservation of the diatom valves and generated barren sections in the record. About 7,800 ± 45 14C yr. BP (DZII), a higher proportion of coastal-marine epipsammic diatoms and the absence of fresh water species, indicates the higher marine influence. Stable palaeoenvironmental conditions, similar to a tidal channel with significant marine influence, are re-established due to a coastline position. In the regressive stages of the late Holocene (DZIII, the last 1,300 14C yr. BP), the increase in the abundance of allochthonous fluvial fresh-brackish taxa (mainly ʺsmall fragilarioidsʺ) indicates a greater fluvial influence with respect to the previous phases. These environmental conditions are consistent with the re-establishment of tidal plains and marshes crossed by tidal channels (similar to those exist today) and deltaic progradation.
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This new micropaleontological evidences constitutes the first record of Pseudopodosira boltovkoyi in Holocene sediments from Argentina, and temporarily extends the ubiquity of small fragilarioids in the Colorado River delta since the Late Pleistocene.
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The ccomparison of the LCH sedimentary succession with different deltaic evolutionary models based in sedimentary facies and diatomological evidence allowed to confirm the absence of transgressive paleoestuary facies (massive muddy facies associated to assemblages of marine planktonic diatoms -Open bay mud/Estuarine central basin) as a consequence of a sedimentary hiatus at the U6 / U7 boundary. This masks the Holocene Maximum and Highstand sea level. In addition, the succession of tidal-flat to marshes (regressive facies) was identified as proofs of delta progradation during the Late Holocene.
ACKNOWLEDGMENTS
The authors acknowledge the collaboration of and J. Bedmar (field sampling), C.A. Vélez-Agudelo (helping in statistical processing of data), M. Albisetti and M. Quiroz (design of maps) and M. Oppedisano (SEM microphotography). This work was supported by the Agencia Nacional de Promoción Científica y Tecnológica (PICT 1146/2016).
REFERENCES
- AKTER J, SARKER MH, POPESCU I & ROELVINK D. 2015. Evolution of the Bengal Delta and its prevailing processes. J Coastal Res 32: 1212-1226.
- ALBERÓ M, ANGIOLINI F, BALBUENA J, CODIGNOTTO J, LINARES E & WEILER N. 1980. Primeras edades Carbono-14 de afloramientos de conchillas de la República Argentina. RAGA 35(3): 363-374.
- ALCALDE R. 2014. Programa integral de calidad del agua del río Colorado˗Calidad del medio acuático. COIRCO (Comité Interjurisdiccional del río Colorado), Secretaría de Energía de la Nación, Grupo Interempresario, Argentina, 396 p.
- BATTARBEE RW, JONES VJ, FLOWER RJ, CAMERON NG, BENNION H, CARVALHO L & JUGGINS S. 2001. Diatoms. In: SMOL J, BIRKS H & LAST W (Eds), Tracking environmental change using lake sediments: terrestrial, algal, and siliceous indicators. Springer, Netherlands, p. 155-202.
- BENDLE JM, PALMER AP, THORNDYCRAFT VR & MATTHEWS IP. 2017. High-resolution chronology for deglaciation of the Patagonian Ice Sheet at Lago Buenos Aires (46.5° S) revealed through varve chronology and Bayesian age modeling. Quaternary Sci Rev 177: 314-339.
- BENITO J, TROBAJO R & IBÁÑEZ C. 2015. Benthic diatoms in a Mediterranean delta: ecological indicators and a conductivity transfer function for paleoenvironmental studies. J Paleolimnol 54: 171-188.
- BENNETT KD. 1996. Determination of the number of zones in a biostratigraphical sequence. New Phytologist 132: 155-170.
- BERNASCONI E & CUSMINSKY G. 2015. Study of the distribution of Elphidium aff. poeyanum (D’ORBIGNY) and Buccella peruviana (D’Orbigny) from the Colorado basin (South America): Holocene paleoenvironmental inferences. The Holocene 25: 810-819.
- BIASOTTI AE, ÁLVAREZ SB, BAZÁN GI & MARTÍNEZ DE FABRICIUS AL. 2014. Variación estacional de la comunidad microfitoplactónica del curso medio del río Colorado (La Pampa˗Argentina). Biología Acuática 30: 249-258.
- BLASI A. 1986. Sedimentología del Río Colorado. Doctoral Thesis. Facultad de Ciencias Naturales y Museo, Universidad Nacional de La Plata, La Plata. Doctorate degree dissertation, 238 p.
- BLOTT SJ & PYE K. 2001. GRADISTAT: a grain size distribution and statistics package for the analysis of unconsolidated sediments. Earth Surf Processes 26(11): 1237-1248
- BOYD R, DALRYMPLE R & ZAITLIN B. 1992. Classification of clastic coastal depositional environments. Sediment Geol 80(3-4): 139-150.
- CAPPANNINI DA & LORES RR. 1966. Los suelos del valle inferior del río Colorado. Instituto Nacional de Tecnología Agropecuaria, Argentina, 127 p.
- CARAMÉS A & MALUMIÁN N. 2000. Foraminíferos bentónicos del Cenozoico del pozo Estrella x-1, Cuenca del Colorado, plataforma continental argentina. Ameghiniana 37(4): 387-419.
- CASTRO DF, ROSSETTI DF, COHEN MC, PESSENDA LC & LORENTE FL. 2013. The growth of the Doce River Delta in northeastern Brazil indicated by sedimentary facies and diatoms. Diatom Res 28(4): 455-466.
- CAVALLOTTO JL, VIOLANTE RA & PARKER G. 2004. Sea-level fluctuations during the last 8,600 years in the de la Plata River (Argentina). Quatern Int 114(1): 155-165.
- CEJUDO-FIGUEIRAS C, MORALES EA, WETZEL CE, BLANCO S, HOFFMANN L & ECTOR L. 2011. Analysis of the type of Fragilaria construens var. subsalina (Bacillariophyceae) and description of two morphologically related taxa from Europe and the United States. Phycologia 50(1): 67-77.
- CHARÓ MP, FUCKS EE & GORDILLO S. 2015. Late Pleistocene-Recent marine malacological assemblages of the Colorado River delta (south of Buenos Aires Province): Paleoecology and paleoclimatology. Quatern Int 377: 52-70.
- CHARÓ MP, GORDILLO S & FUCKS E. 2013. Paleoecological significance of Late Quaternary molluscan faunas of the Bahía San Blas area, Argentina. Quatern Int 301: 135-149.
- CHIOCCI FL & NORMARK WR. 1992. Effect of sea level variation on upper-slope depositional processes offshore of Tiber Delta, Tyrrhenian Sea, Italy. Mar Geol 104: 109-122.
- CODIGNOTTO JO & MARCOMINI SC. 1993. Argentine deltas morphology. In: MAGOON O, WILSON WS, CONVERSE H & TOBIN LT (Eds), Coastal Zone’93, Proc 8th Symp on Coastal and Ocean Management. ASCE, New Orleans, p. 323-336
- CODIGNOTTO JO & WEILER N. 1980. Evolución Morfodinámica del sector costero comprendido entre punta Laberinto e isla Olga, provincia de Buenos Aires. Simposio sobre problemas geológicos del litoral atlántico bonaerenses, Mar del Plata, p. 35-43.
- COLOMBO F, SERRA J & RIVERO L. 2014. Río de la Plata inner estuary (Argentina): main forms, sedimentary infill and Holocene evolution. In: MARTINI IW (Ed), Sedimentary Coastal Zones from High to Low Latitudes: Similarities and Differences. Geol Soc Spec Publ, 388 p.
- COOPER SR. 1995. Chesapeake Bay watershed historical land use: impact on water quality and diatom communities. Ecol Appl 5(3): 703-723.
- COOPER SR. 1999. Estuarine paleoenvironmental reconstructions using diatoms. In: SMOL JP & STOERMER EF (Edits). The diatoms: applications for the environmental and Earth Sciences, p. 352-375.
- COOPER S, GAISER E & WACHNICKA A. 2010. Estuarine paleoenvironmental reconstructions using diatoms. In: SMOL JP & STROEMER EF (Eds). The diatoms: applications for the environmental and earth sciences (Ed. 2), New York, Cambridge University Press, p. 324-345.
- DA SILVA JG, TORGAN LC & DE SOUZA CARDOSO L. 2010. Diatomáceas (Bacillariophyceae) em marismas no sul do Brasil. Acta Bot Bras 24(4): 935-947.
- DALRYMPLE RW, BAKER EK, HARRIS PT & HUGHES MG. 2003. Sedimentology and stratigraphy of a tide-dominated, foreland-basin delta (Fly River, Papua New Guinea). In: SIDI F, NUMMEDAL D, IMBERT P, DARMAN H AND POSAMENTIER H (Eds), Tropical deltas of South East Asia-Sedimentology, Stratigraphy and Petroleum Geology. SEPM Special Publication 76: 147-173.
- DALRYMPLE RW & CHOI K. 2007. Morphologic and facies trends through the fluvialmarine transition in tide-dominated depositional systems: a schematic framework for environmental and sequence-stratigraphic interpretation. Earth-Sci Rev 81(3-4): 135-174.
- DALRYMPLE RW, ZAITLIN BA & BOYD R. 1992. Estuarine facies models; conceptual basis and stratigraphic implications. J Sediment Res 62(6): 1130-1146.
- DAVIES BE. 1974. Loss-on-ignition as an estimate of soil organic matter 1. Soil Sci Soc Am J 38(1): 150-151.
- DENYS L. 1991/1992. A check˗list of the diatoms in the Holocene deposits of the Western Belgian coastal plain with the survey of their apparent ecological requirements. Introduction, ecological code and complete list. Geological Service of Belgium, Professional Paper 246: 1˗41.
- ELLIOTT T. 1986. Deltas. In: READING HG (Ed). Sedimentary environments and facies. Blackwell, 2nd ed., Oxford, p. 113-154.
- ESCANDELL A & ESPINOSA MA. 2012. Evolución paleoambiental de estuarios mesomareales de Patagonia. Las diatomeas como indicadores ambientales durante el Holoceno en la costa norpatagónica argentina. Editorial Académica Española, Verlag, Saarbrücken, 93 p.
- ESCANDELL A, ESPINOSA MA & ISLA FI. 2009. Diatomeas como indicadoras de variaciones de salinidad durante el Holoceno tardío en el río Negro, Patagonia Norte, Argentina. Ameghiniana 46(3): 461-468.
- ESPINOSA MA. 2008. Diatoms from Patagonia and Tierra del Fuego. In: Rabassa J (Ed), Late Cenozoic of Patagonia and Tierra del Fuego. Developments in Quaternary Sciences, Elsevier, p. 383-392.
- ESPINOSA MA, HASSAN GS & ISLA FI. 2012. Diatom-inferred salinity changes in relation to Holocene sea-level fluctuations in estuarine environments of Argentina. Alcheringa 36: 373-386.
- ESPINOSA MA & ISLA FI. 2011. Diatom and sedimentary record during the Mid˗Holocene evolution of the San Blas estuarine complex, Northern Patagonia, Argentina. Ameghiniana 48: 411˗423.
- ESPINOSA MA & ISLA FI. 2015. Modern diatom assemblages in surface sediments from meso-macrotidal estuaries of Patagonia, Argentina. Pan-American Journal of Aquatic Sciences 10(1): 29-43.
- ESPINOSA MA, VÉLEZ-AGUDELO CA & ISLA FI. 2020. Diatom responses to natural and anthropogenic environmental changes in a Patagonian river, Argentina. J S Am Earth Sci 102: 102677.
- FAYÓ R & ESPINOSA MA. 2014. Reconstrucción paleoambiental de la planicie costera de Mar Chiquita (Provincia de Buenos Aires, Argentina) durante el Holoceno, basada en diatomeas. Ameghiniana 51: 510˗528.
- FAYÓ R, ESPINOSA MA & ISLA FI. 2020a. Diatomeas holocenas del delta del río Colorado, Argentina. Una aproximación paleoambiental a partir del estudio de “fragilarioides pequeñas”. Rev Bras Paleontolog 23(3): 209-221.
- FAYÓ R, ESPINOSA MA, VÉLEZ-AGUDELO CA, PAN J & ISLA FI. 2018. Diatombased reconstruction of Holocene hydrological changes along the Colorado River floodplain (northern Patagonia, Argentina). J Paleolimnol 60(3): 427-443.
- FAYÓ R, PAN J & ESPINOSA MA. 2020b. Microbial mat and surface sediment communities from a shallow oxbow lake in the Colorado River floodplain, Argentina, Geomicrobiol J 37(10): 937-949.
- FERNÁNDEZ AL. 2014. Palinología del Cuaternario tardío en la cuenca inferior de río Colorado, provincia de Buenos Aires, Argentina. Universidad Nacional del Sur, Doctorate degree dissertation, 300 p.
- FERRARIO M, ALMANDOZ G, GARIBOTTI I & LICEA S. 2003. Nuevos registros de diatomeas típicas de sedimento en el plancton de la costa del mar argentino. B So Argent Bot 38: 123-129.
- FLOWER RJ. 2005. A review of diversification trends in diatom research with special reference to taxonomy and environmental applications using examples from Lake Baikal and elsewhere. Proc Calif Acad Sci 56(1/17): 107-128.
- FOLGUERA A, ZÁRATE M, TEDESCO A, DÁVIL F & RAMOS VA. 2015. Evolution of the Neogene Andean foreland basins of the Southern Pampas and Northern Patagonia (34⁰41`S), Argentina. J S Am Earth Sci 64: 452-466.
- FUCKS E, CHARÓ M & PISANO F. 2012. Aspectos estratigráficos y geomorfológicos del sector oriental patagónico bonaerense. Rev Soc Geol Esp 25(1-2): 29-44.
- FRAZIER DF. 1967. Recent deltaic deposits of the Mississippi Delta: their development and chronology. Transactions Gulf Coast Assoc Geol Soc 17: 287-315.
- FRYKLUND B, MARSHALL A & STEVENS J. 1996. Cuenca del Colorado. In: Ramos VA & Turic M (Eds), Geología y Recursos Naturales de la Plataforma Continental Argentina. 13º Congreso Geológico Argentino and 3º Congreso de Exploración de Hidrocarburos, Relatorio 8: 138-158.
- GALLOWAY WE.1975. Process framework for describing the morphologic and stratigraphic evolution of deltaic depositional systems. In: BROUSSARD ML (Ed) Deltas, Models for Exploration. HGS Bulletin, p. 87-98.
- GARCÍA M. 2016. Taxonomy, morphology and distribution of Cymatosiraceae (Bacillariophyceae) in the littorals of Santa Catarina and Rio Grande do Sul. Biota Neotrop 16(2): e20150139.
- GARCIA-BAPTISTA M. 1993. Psammic algae from Praia Azul, Brazil. Berlin, J. Cramer. Bibliotheca Phycologica 94: 6-14.
- GARCÍA ML & MAIDANA NI. 2015. Diatomeas (Bacillariophyceae) subfósiles del Brazo Blest del Lago Nahuel Huapi, Argentina. B Soc Argent Bot 50: 123-140.
- GARCÍA ML, MAIDANA NI, ECTOR L & MORALES EA. 2017. Staurosira patagonica sp. nov., a new diatom (Bacillariophyta) from southern Argentina, with a discussion on the genus Staurosira Ehrenberg. Nova Hedwigia 146: 103-123.
- GARCÍA-RODRÍGUEZ F. 2012. South America, Holocene Coastal Lagoons. In L Bengtsson, Herschy RW & Fairbridge RW (Eds). Encyclopedia of Lakes and Reservoirs. Dordrecht: Springer Netherlands, p. 723-734.
- GARCÍA-RODRÍGUEZ F, SPRECHMANN P, METZELTI D, SCAFATI L, MELENDI D, VOLKHEIMER W, MAZZEO N, HILLER A, VON TÜMPLING W & SCASSO F. 2004. Holocene trophic state changes in relation to sea level variation in Lake Blanca, SE Uruguay. J Paleolimnol 31(1): 99-115.
- GARCÍA-RODRÍGUEZ F & WITKOWSKI A. 2003. Inferring sea level variation from relative percentages of Pseudopodosira kosugii in Rocha lagoon, SE Uruguay. Diatom Res 18(1): 49-59.
- GARIBOTTI IA, FERRARIO ME, ALMANDOZ GO & CASTAÑOS C. 2011. Seasonal diatom cycle in Anegada Bay, El Rincón estuarine system, Argentina. Diatom Res 26(2): 227-241.
- GELL P, TIBBY J, LITTLE F, BALDWIN D & HANCOCK G. 2007. The impact of regulation and salinisation on floodplain lakes: the lower River Murray, Australia. Hydrobiologia 591: 135-146.
- GOLFIERI GA, FERRERO L & ZÁRATE M. 1998. Tafonomía y paleoecología de Tagelus plebieus (Lightfoot, 1786) (Mollusca, Bivalvia) en sedimentos holocenos de río Quequén Grande, provincia de Buenos Aires, Argentina. Ameghiniana 33(3): 255-264.
- GÓMEZ EA, BOREL CM, AGUIRRE ML & MARTÍNEZ DE. 2008. Radiocarbon reservoir ages and hardwater effect for the northeastern coastal waters of Argentina. Radiocarbon 50(1): 119-129.
- GONZÁLEZ URIARTE M. 1985. Geomorfología del área interfluvial de los cursos inferiores de los ríos Colorado y Negro (provincia de Buenos Aires). I Jornadas Geológicas Bonaerenses, p. 713-730.
- GRANA L, MORALES EA, MAIDANA NI & ECTOR L. 2018. Two new species of Staurosira and Pseudostaurosira (Bacillariophyta) from the highlands of Argentina (south-central Andes) and two new nomenclatural combinations. Phytotaxa 365: 60–72.
- GUERRERO JM, GARCÍA ML & MORALES EA. 2019. Staurosirella andino-patagonica sp. nov. (Bacillariophyta) from lake sediments in Patagonia, Argentina. Phytotaxa 402: 131-144.
- GUIRY MD & GUIRY GM. 2020. AlgaeBase. World-wide electronic publication, National University of Ireland, Galway. https://www.algaebase.org; searched on December 2019
» https://www.algaebase.org; searched on December 2019 - GUTIERREZ-TÉLLEZ B & SCHILLIZZI R. 2002. Asociaciones de diatomeas en paleoambientes cuaternarios de la costa sur de la provincia de Buenos Aires, Argentina. Pesquisas em Geociências 29(1): 59-70.
- HASLE G, VON STOSCH H & SYVERTSEN E. 1983. Cymatosiraceae, a new diatom family. Bacillaria 6: 9-156.
- HASSAN GS, ESPINOSA MA & ISLA FI. 2004. Análisis paleoambiental de una secuencia del Holoceno tardío del arroyo Claromecó (Provincia de Buenos Aires, Argentina) basado en diatomeas. Ameghiniana 41(2): 161-170.
- HASSAN GS, ESPINOSA MA & ISLA FI. 2007. Dead diatom assemblages in surface sediments from a low impacted estuary: the Quequen Salado river, Argentina. Hydrobiologia 579(1): 257-270.
- HASSAN GS, ESPINOSA MA & ISLA FI. 2009. Diatom-based inference model for paleosalinity reconstructions in estuaries along the northeastern coast of Argentina. Palaeogeogr Palaeocl 275(1-4): 77-91.
- HASSAN GS, ESPINOSA MA & ISLA FI. 2011. Fluctuaciones de salinidad durante el Holoceno en la laguna costera de Mar Chiquita (Provincia de Buenos Aires): una aproximación cuantitativa basada en diatomeas. Ameghiniana 48: 496-507.
- HILDRETH W & DRAKE RE. 1992. Volcán Quizapu, Chilean Andes. B Volcanol 54(2): 93-125.
- HORI K, TANABE S, SAITO Y, HARUYAMA S, NGUYEN V & KITAMURA A. 2004. Delta initiation and Holocene sea-level change: example from the Song Hong (Red River) delta, Vietnam. Sediment Geol 164(3-4): 237-249.
- HORI K, USAMI S & UEDA H. 2011. Sediment facies and Holocene deposition rate of near˗coastal fluvial systems: An example from the Nobi Plain, Japan. J Asian Earth Sci 41: 195-203.
- ISLA FI. 1989. The Southern Hemisphere sea level fluctuation. Quaternary Sci Rev 8 (4): 359-368.
- ISLA FI. 2013. The flooding of the San Matías Gulf: the Northern Patagonia sea-level curve. Geomorphology 203: 60-65.
- ISLA FI & ESPINOSA MA. 1998. Modelo sedimentario de colmatación de pequeños estuarios dominados por limo, provincia de Buenos Aires. Actas 7° Reunión Argentina de Sedimentología, p. 24-36.
- ISLA FI, ESPINOSA MA, RUBIO B, ESCANDELL A, GERPE M, MIGLIORANZA K, REY D & VILAS F. 2015. Avulsion at a drift-dominated mesotidal estuary: The Chubut River outlet, Patagonia, Argentina. J Hydrol 529(2): 632-639.
- ISLA FI & TOLDO EE. 2013. ENSO impacts on Atlantic watersheds of South America. Quat Environ Geosci 4: 34˗41.
- JEONG EJ, WOO HJ, KANG J, LEE JH & CHOI JU. 2018. Study of Holocene paleo-environmental evolution using cores from the downstream area of the Nakdong River Delta, Korea. J Coastal Res 85(1): 626-630.
- JUAN R, DE JAGER J, RUSSELL J & GEBHARD I. 1996. Flanco norte de la cuenca del Colorado. In: Ramos VA & Turic MA (Eds), Geología y Recursos Naturales de la Plataforma Continental Argentina. 13º Congreso Geológico Argentino y 3º Congreso de Exploración de Hidrocarburos, Buenos Aires, Relatorio 7: 117-133.
- JUGGINS S. 2015. Rioja: analysis of quaternary science data. R package version 0.9˗5. https://cran.r˗project.org/package=rioja Accessed on 07/15/2020.
» https://cran.r˗project.org/package=rioja - KOCIOLEK J ET AL. 2018. DiatomBase. http://www.diatombase.org Accessed on 09/25/2020.
» http://www.diatombase.org - KRUMBEIN W & PETTIJOHN F. 1938. Manual of Sedimentary Petrology. In: CENTURY- CROFT A (Ed) Plenum, New York, 549 p.
- LACHOWYCZ SM, PYLE DM, GILBERT JS, MATHER TA, MEE K, NARANJO JA & HOBBS LK. 2015. Glaciovolcanism at Volcán Sollipulli, Southern Chile: Lithofacies analysis and interpretation. J Volcanol Geoth Res 303: 59-78.
- LI CL, ASHWORTH MP, WITKOWSKI A, LOBBAN CS, ZGŁOBICKA I, KURZYDŁOWSKI KJ & QIN S. 2016. Ultrastructural and molecular characterization of diversity among small araphid diatoms all lacking rimoportulae. I. Five new genera, eight new species. J Phycol 52: 1018-1036.
- LI CL, WITKOWSKI A, ASHWORTH MP, DĄBEK P, SATO S, ZGŁOBICKA I, WITAK M, KHIM JS & KWON CJ. 2019. The morphology and molecular phylogenetics of some marine diatom taxa within the Fragilariaceae, including twenty undescribed species and their relationship to Nanofrustulum, Opephora and Pseudostaurosira. Phytotaxa 355: 1-104.
- LI W, BHATTACHARYA JP & WANG Y. 2011. Delta asymmetry: Concepts, characteristics, and depositional models. Pet Sci 8(3): 278-289.
- LIMA LG. 2008. Estratigrafia e evolução da barreira holocênica na praia do Hermenegildo (RS). Instituto de Geociências, Universidade Federal do Rio Grande do Sul, Porto Alegre/RS. Master’s degree dissertation Unpublished, 78 p.
- MC QUOID MR & NORDBERG K. 2003. The diatom Paralia sulcata as an environmental indicator species in coastal sediments. Estuar Coast Shelf S 56(2): 339-354.
- MAIDANA NI & DÍAZ VILLANUEVA V. 2001. Diatomeas de lagos oligotróficos andinos (Provincia de Neuquén, Argentina). B Soc Argent Bot 36: 15-27.
- MAKASKE B, MAATHUIS BH, PADOVANI CR, STOLKER C, MOSSELMAN E & JONGMAN RH. 2012. Upstream and downstream controls of recent avulsions on the Taquari megafan, Pantanal, south-western Brazil. Earth Surf Proc Land 37(12): 1313-1326.
- MANOYLOV KM & DOMINY JR JN. 2013. Changes in epipelic diatom diversity from the Savannah River Estuary. J Environ Prot 4(02): 172-179.
- MARTÍNEZ G & MARTÍNEZ GA. 2011. Late Holocene environmental dynamics in fluvial and aeolian depositional settings: Archaeological record variability at the lower basin of the Colorado river (Argentina). Quatern Int 245: 89˗102.
- MARTÍNEZ G, MARTÍNEZ GA, STOESSEL L & ALCARÁZ AP. 2019. Geoarchaeology and taphonomy: Deciphering site formation processes for late Holocene archaeological settings in the eastern Pampean-Patagonian transition, Argentina. Quatern Int 511: 94-106.
- MEDEANIC S, CARVALHO TORGAN L, PINHEIRO CLEROT LC & SANTOS-FISCHER BC. 2009. Holocene marine transgression in the coastal plain of Rio Grande do Sul, Brazil: palynomorph and diatom evidence. J Coastal Res 25: 224-233.
- MELO W, PERILLO G, PERILLO M, SCHILIZZI R & PICCOLO MC. 2013. Late Pleistocene–Holocene deltas in southern Buenos Aires Province, Argentina. IAHS Publ 358: 187-195.
- MELO W, SCHILLIZZI R, PERILLO G & PICCOLO MC. 2003. Influencia del área continental pampeana en la evolución morfológica del estuario de Bahía Blanca. Revista de la Asociación Argentina de Sedimentología 10: 39˗52.
- METZELTIN D & LANGE-BERTALOT H. 2007. Tropical diatoms of South America II. Special remarks on biogeographic disjunction. Iconographia Diatomológica 18: 1-877.
- MORALES EA. 2005. Observations of the morphology of some known and new fragilarioid diatoms (Bacillariophyceae) from rivers in the USA. Phycol Res 53: 113-133.
- MORALES EA, WETZEL CE & ECTOR L. 2010. Two short-striated species of Staurosirella (Bacillariophyceae) from Indonesia and the United States. Pol Bot J 55: 107-117.
- MORRIS P & ROSENBERG G. 2005. Search interface and documentation for Malacolog, an online database of Western Atlantic marine Mollusks (version 4.1.1). Accessed online at http://www.malacolog.org
» http://www.malacolog.org - NARANJO JA, MORENO H, EMPARAN C & MURPHY M. 1993. Volcanismo explosivo reciente en la caldera del volcán Sollipulli. Rev Geol Chile 20: 167-191.
- NGUYEN VL, TA TK & TATEISHI M. 2000. Late Holocene depositional environments and coastal evolution of the Mekong River Delta, Southern Vietnam. J Asian Earth Sci 18(4): 427-439.
- OKSANEN J, BLANCHET G, KINDT R, LEGENDRE P, MINCHIN PR, O’HARA RB, SIMPSON GL, SOLYMOS P, STEVENS MHH. & WAGNER H. 2015. Vegan: community ecology package. R package version 2.3˗0.
- PARODI ER & BARRÍA DE CAO S. 2003. Benthic microalgal communities in the inner part of the Bahía Blanca estuary (Argentina): a preliminary qualitative study. Oceanol Acta 25(5): 279-284.
- PÉREZ L, GARCÍA-RODRÍGUEZ F & HANEBUTH TJ. 2017. Paleosalinity Changes in the Río de la Plata Estuary and on the Adjacent Uruguayan Continental Shelf over the Past 1200 Years: An Approach Using Diatoms as a Proxy. In: KWECKSTRÖM, SAUNDERS KM, GELL PA & SKILBECK CG (Eds), Applications of paleoenvironmental techniques in estuarine studies, Developments in paleoenvironmental research, Springer, Dordrecht 20: 529-549.
- PIERIK HJ, STOUTHAMER E, SCHURING T & COHEN KM. 2018. Human-caused avulsion in the Rhine-Meuse delta before historic embankment (The Netherlands). Geology 46(11): 935-938.
- PONCE JF, RABASSA J, CORONATO A & BORROMEI AM. 2011. Palaeogeographical evolution of the Atlantic coast of Pampa and Patagonia from the last glacial maximum to the Middle Holocene. Biol J Linn Soc 103: 363˗379.
- PRIETO AR, MOURELLE D, PELTIER WR, DRUMMOND R, VILANOVA I & RICCI L. 2017. Relative sea˗level changes during the Holocene in the Río de la Plata, Argentina and Uruguay: A review. Quatern Int 442: 35˗49.
- PUCCI A, HOFFMEYER M, FREIJE H, BARRÍA M, POPOVICH C, RUSANSKY C & ASTEASUAIN RO. 1996. Características de las aguas y del plancton en un sector del estuario del Río Negro (República Argentina). Pollution Processes in Coastal Environments, p. 146-151.
- R DEVELOPMENT CORE TEAM. 2015. R: Language and environmental for statistical computing. R Foundation for Statistical Computing Viena, Austria. ISBN 3˗900051˗07˗0.
- ROUND FE, CRAWFORD RM & MANN DG. 1990. The diatoms: biology and morphology of the genera. Cambridge University Press, Oxford, 747 p.
- SANTINELLI N & ESTEVES JL. 1993. Características químicas y fitoplanctónicas del estuario del Río Chubut (Patagonia, Argentina). Naturalia Patagónica. Ciencias Biológicas 1(1): 22-34.
- SANTOS CB. 2015. Paleoecologia de diatomáceas como subsídios para o conhecimento da evolução paleogeográfica da região costeira do Rio Grande do Sul, Brasil. Doctorate degree dissertation. Instituto de Geociências. Universidade Federal do Rio Grande do Sul, Porto Alegre, Brasil, 213 p.
- SANTOS-FISCHER CB, CORRÊA IC, WESCHENFELDER J, TORGAN LC & STONE JR. 2016. Paleoenvironmental insights into the Quaternary evolution of the southern Brazilian coast based on fossil and modern diatom assemblages. Palaeogeogr Palaeocl 446: 108-124.
- SANTOS-FISCHER CB, WESCHENFELDER J, CORRÊA ICS, STONE JR, APPEL DEHNHARDT B & BORTOLIN EC. 2018. A Drowned Lagunar Channel in the Southern Brazilian Coast in Response to the 8.2-ka Event: Diatom and Seismic Stratigraphy. Estuar Coasts 41: 1601-1625.
- SAR EA, LAVIGNE A, WETZEL CE, ECTOR L & SUNESEN I. 2017. Pseudopodosira boltovskoyi sp. nov. (Pseudopodosiraceae, Bacillariophyta) from coastal waters of Argentina. Phycologia 56(3): 239-252.
- SAR EA, SUNESEN I & CASTAÑOS C. 2001. Marine diatoms from Buenos Aires coastal waters (República Argentina). I. Thalassiosiraceae. Nova Hedwigia 73(1-2): 199-228.
- SAR EA, SUNESEN I & FERNANDEZ PV. 2007. Marine diatoms from Buenos Aires coastal waters (Argentina). II. Thalassionemataceae and Rhaphoneidaceae. Rev Chil Hist Nat 80(1): 63-79.
- SCHILLIZZI RA, GUTIERREZ-TELLEZ BM, LUNA LI & CABALLERO N. 2012. Paleoambientes holocénicos en el paraje Playa Chica, costa norte del río Negro, Provincia de Buenos Aires, Argentina. Pesquisas em Geociências 39(2): 147-159.
- SCHNACK EJ, FASANO JL & ISLA FI. 1982. The evolution of Mar Chiquita lagoon coast, Buenos Aires Province, Argentina. Holocene sea level fluctuations, magnitude and causes. IGCP 61, Univ. S. Carolina, Columbia (Colquhoun, DJ), p. 143-155.
- SCHWEIZER A. 1997. From littoral to pelagial: comparing the distribution of phytoplankton and ciliated protozoa along a transect. J Plankton Res 19: 829-848.
- SEITZ C, VÉLEZ MI & PERILLO GM. 2019. Cenozoic Geologic evolution of the Lower Colorado River Basin, Northern Patagonia, Argentina. Andean geology: Formerly. Rev Geol Chile 46(1): 7-7.
- SPAGNUOLO J. 2005. Evolución geológica de la región costera-marina de Punta Alta, provincia de Buenos Aires. Doctorate degree . dissertation, Universidad Nacional del Sur, 269 p.
- SPALLETTI LA & ISLA FI. 2003. Características y evolución del delta del Río Colorado “colú˗leuvú”, Provincia de Buenos Aires, República Argentina. AAS Revista 10: 23˗37.
- STANLEY DJ & WARNE AG. 1994. Worldwide initiation of Holocene marine deltas by deceleration of sea-level rise. Science 265(5169): 228-231.
- STERN CHR. 2004. Active Andean volcanism: its geologic and tectonic setting. Rev Geol Chile 31: 161-206.
- STERN CHR. 2008. Holocene tephrochronology record of large explosive eruptions in the southernmost Patagonian Andes. B Volcanol 70: 435-454.
- STOUTHAMER E & BERENDSEN HJ. 2007. Avulsion: the relative roles of autogenic and allogenic processes. Sediment Geol 198(3-4): 309-325.
- TA TK, NGUYEN VL, TATEISHI M, KOBAYASHI I & SAITO Y. 2001. Sedimentary facies, diatom and foraminifer assemblages in a late Pleistocene-Holocene incised valley sequence from the Mekong River Delta, Bentre Province, Southern Vietnam:the BT2 core. J Asian Earth Sci 20(1): 83-94.
- TA TK, NGUYEN VL, TATEISHI M, KOBAYASHI I & SAITO Y. 2005. Holocene delta evolution and depositional models of the Mekong River Delta, southern Vietnam. Society for Sedimentary Geology. River Deltas—Concepts, Models, and Examples SEPM (Society for Sedimentary Geology) Special Publication 83: 453-463.
- TA TK, NGUYEN VL, TATEISHI M, KOBAYASHI I, SAITO Y & NAKAMURA T. 2002a. Sediment facies and Late Holocene progradation of the Mekong River Delta in Bentre Province, southern Vietnam: an example of evolution from a tide-dominated to a tideand wave-dominated delta. Sediment Geol 152(3-4): 313-325.
- TA TK, NGUYEN VL, TATEISHI M, KOBAYASHI I, TANABE S & SAITO Y. 2002b. Holocene delta evolution and sediment discharge of the Mekong River, southernVietnam. Quaternary Sci Rev 21(16-17): 1807-1819.
- TAFFS KH, SAUNDERS KM, WECKSTRÖM K, GELL PA & GREGORY SC. 2017. Introduction to the Application of Paleoecological Techniques in Estuaries. Weckström K, Saunders K, Gell P & Skilbeck C (Eds), Applications of Paleoenvironmental Techniques in Estuarine studies, Developments in Paleoenvironmental Research. Springer, Dordrecht. vol 20.
- UNDERWOOD GJ. 1994. Seasonal and spatial variation in epipelic diatom assemblages in the Severn estuary. Diatom Res 9(2): 451-472.
- UNDERWOOD GJ & PATERSON DM. 1993. Seasonal changes in diatom biomass, sediment stability and biogenic stabilization in the Severn Estuary. J Mar Biol Assoc UK 73(4): 871-887.
- VAN DAM H, MERTENS A & SINKELDAM J. 1994. A coded checklist and ecological indicator values of freshwater diatoms from the Netherlands. Aquatic Ecology 28: 117-133.
- VÉLEZ˗AGUDELO CA ESPINOSA MA, FAYÓ R & ISLA FI. 2017. Modern diatoms from a temperate river in South America: the Colorado River (North Patagonia, Argentina). Diatom Res 32(2): 133-152.
- VISCONTI G, DE ELORRIAGA EE & PARRAS A. 2003. Sedimentitas marinas de la Formación Barranca Final (Mioceno medio-superior de la cuenca del Colorado), aflorantes en el sureste de la provincia de La Pampa, Argentina. RAGA 58(2): 187-193.
- VOS PC & DE WOLF H. 1988. Methodological aspects of palaeoecological diatom research in coastal areas of the Netherlands. Geol Mijnbouw 67: 31-40.
- VOS PC & DE WOLF H. 1993. Diatoms as a tool for reconstructing sedimentary environments in coastal wetlands; methodological aspects. Twelfth International Diatom Symposium. Springer, p. 285˗296.
- WEI X & WU C. 2011. Holocene delta evolution and sequence stratigraphy of the Pearl River Delta in South China. Sci China Earth Sci 54(10): 1523-1541.
- WEILER N. 1988. Depósitos litorales del Pleistoceno tardío y Holoceno en bahía Anegada, provincia de Buenos Aires. Segunda Reunión Argentina de Sedimentología, Buenos Aires, Actas, p. 245-249.
- WEILER N. 2000. Evolución de los depósitos litorales en bahía Anegada, provincia de Buenos Aires, durante el Cuaternario Tardío. Doctorate degree dissertation.University of Buenos Aires, Buenos Aires, Argentina, 184 p.
- WEISS D, GEITZENAUER K & SHAW FC. 1978. Foraminifera, diatom and bivalve distribution in recent sediments of the Hudson estuary. Estuar Coast Shelf S 7(4): 393-400.
- WESCHENFELDER J, MEDEANIC S, CORRÊA IC & ALIOTTA S. 2008. Holocene paleoinlet of the Bojuru region, Lagoa dos Patos, southern Brazil. J Coastal Res 24(1): 99-109.
- WITKOWSKI A, LANGE-BERTALOT H & METZELTIN D. 2000. Diatom Flora of Marine Coasts I. Iconographia Diatomologica 7: 1-925.
- WOODROFFE C, MULRENNAN M & CHAPPELL J. 1993. Estuarine infill and coastal progradation, southern van Diemen Gulf, northern Australia. Sediment Geol 83: 257˗275.
- ZONG Y. 1997. Mid-and late-Holocene sea-level changes in Roudsea Marsh, northwest England: a diatom biostratigraphical investigation. The Holocene 7(3): 311-323.
- ZONG Y, HUANG G, SWITZER A, YU F & YIM WS. 2009. An evolutionary model for the Holocene formation of the Pearl River delta, China. The Holocene 19(1): 129-142.
Publication Dates
-
Publication in this collection
05 Dec 2022 -
Date of issue
2022
History
-
Received
15 Feb 2021 -
Accepted
24 May 2021