Open-access Effects of forest structure on litter production, soil chemical composition and litter-soil interactions

ABSTRACT

Litter production in forest ecosystems is a major indicator of primary productivity because litter helps incorporate carbon and nutrients from plants into the soil and is directly involved in plant-soil interactions. To our knowledge, few studies have investigated the relationship between species diversity and ecosystem processes in subtropical forest fragments. In this work, we determined forest structural parameters and assessed seasonal leaf litter input, leaf decomposition rate, litter quality and soil characteristics in two subtropical Atlantic Forest fragments. Litter production was greater in the native fragment with the higher species diversity (FN1). The two native fragments (FN1 and FN2) differed in basal area, volume and dominance in the upper stratum, which were positively correlated with litter production in FN1 but negatively correlated in FN2. Soil in FN1 exhibited higher contents of organic C, available phosphorus and exchangeable calcium, and the leaf litter had a higher C:N ratio. Although these results are consistent with a plant-soil feedback, which suggests the presence of a complementary effect, the dominance of certain families in subtropical forest fragments results in a selection effect on litter productivity and decomposition.

Keywords biodiversity; carbon; decomposition; phosphorus; selection effect

Introduction

Productivity in terrestrial ecosystems is directly linked to nutrient cycling among the various components of the plant-soil system (Vitousek 1984; Terror et al. 2011). In forest ecosystems, primary production is usually evaluated through litter production because litter is the main source of soil organic C and plant nutrient cycling (Vitousek 1982); in addition, it can also usually be evaluated from tree diameter and height measurements, using an allometric equation (Chambers et al. 2001). The close relationship between forest structure, climate and soil makes this system an ideal model for evaluating the relationship between litter production and decomposition, nutrient cycling and abiotic factors (Aerts & Chapin 2000).

Litter decomposition results in the incorporation of organic C into soil and in the cycling of plant nutrients, which provide readily available resources for plant growth (Austin & Vivanco 2006; Cheng et al. 2010). In addition, the release of secondary metabolites by plants may affect ecological interactions and the soil microbial community. The decomposition rate of litter varies with the quality of the substrate, and also with the amount and activity of decomposers (Xiaogai et al. 2013), which are closely associated (Wardle et al. 2006). Litter decomposition can also influence soil properties and alter the stability of soil organic C and cation exchange processes in plant-soil interactions (Sausen et al. 2014).

Forest decomposition systems have been the focus of several studies in recent years (Pimenta et al. 2011; Terror et al. 2011; Wang et al. 2013; Sausen et al. 2014). However, the influence of species richness and litter composition on nutrient cycling remains a topic of hot debate (Szanser et al . 2011). The biochemical quality of litter is crucial for proper ecosystem functioning (Hättenschwiler et al. 2011); in fact, the higher tree species richness is, the greater is the diversity of the microbial communities involved in decomposition processes (Wardle et al. 2006; Manzoni et al. 2012; Prescott & Grayston 2013).

Most studies on nutrient cycling and litter decomposition have focused on only one or two species of trees in the dominant vegetation structure (Jacob et al. 2010). However, this commonly used model does not reflect the decomposition dynamics in native forest ecosystems, where tree diversity is usually very high (Fuqiang et al. 2010; Xiaogai et al. 2013). Several studies using bags of mixed litter from species constituting the forest stratum suggest that litter in forests with a high tree diversity decompose rapidly, especially when nutrient concentrations differ between species (Quested et al. 2002; Wickings et al. 2012; Ge et al. 2013; Xiong et al. 2014).

Although structure in subtropical forest fragments has been the subject of several studies (Budke et al. 2010; Müller et al. 2012; Mélo et al. 2013), few have examined the relationship between the structural characteristics of vegetation (particularly species diversity) and ecosystem functioning processes. Litter production provides important information on ecosystem functioning; in fact, it relates nutrient cycling, decomposition dynamics and soil organic carbon incorporation according to species diversity and structural parameters of vegetation to tree size and abundance in a forest community (Hack et al. 2005; Gilliam 2007; Aragão et al. 2009).

The primary purposes of this work were (1) to relate the structural characteristics of vegetation with litter production, and (2) to examine the dynamics of litter decomposition and litter-soil interactions, in two Atlantic Forest fragments in southern Brazil. The working hypotheses were that forest fragments with an increased species diversity will have also increased basal area and volume leading to differences between lower and upper strata, and that such differences are associated with increased litter production and with soil and litter chemical composition.

Materials and methods

Study areas

Two subtropical Atlantic Forest fragments were studied. Both are bordered by 3rd order streams and located in southern Brazil. One of the native fragments (FN1) is located at 27º28'39''S 52º31'45''W and 27º39'40''S 52º20'24''W, and the other (FN2) at 27º30'21"S 52º11'10"W and 27º40'43''S 52º02'15''W. The study was conducted over a period of 12 months, and measurements made on a monthly basis from January to December 2013. The mean rainfall for the period was 175 mm (range 90-316 mm) and the mean monthly temperatures ranged from 13 to 22 °C.

The target forest fragments were representative of the typical Atlantic Forest vegetation, where the native forest is highly fragmented and degraded, and the sites with

the greatest cover are located where steep slope factors such as ground, shallow soils and the presence of rocky outcrops make soil difficult or impossible to use for agricultural purposes (Decian et al. 2009). A total of 20 plots 10 × 10 m in size were established in each fragment, with 10 units on each side of the stream, totalling a sample area of 0.2 ha.

Litter production

Litter produced in the two study areas was collected monthly by using 1 m long × 1 m wide × 0.15 m deep wood collectors furnished with a fine nylon mesh screen 1 mm thick. A total of 10 collectors were randomly distributed in each of the study areas (five on each side of the streams). Samples were collected on a monthly basis from January to December 2013 and transferred to the Plant Ecology and Systematics Laboratory of the Universidade Regional Integrada do Alto Uruguai e das Missões for drying to a constant weight in an oven at 60 °C and weighing. Seasonal litter productivity for the winter, spring, summer and autumn seasons was calculated from the combined monthly masses, and seasonal means were expressed in t ha-1.

Vegetation structure

Vegetation structure was characterized in a phytosociological survey of the lower and upper strata in 10 sampling units in the target areas. All species were identified in loco . Plants less than 0.3 m high and having a diameter at breast height (DBH) not greater than 15 cm were assigned to the lower stratum, whereas those with DBH > 0.15 m were assigned to the upper stratum. The phytosociological parameters for the two strata were estimated by using the software Fitopac 2 (Shepherd 2010) to calculate basal area, absolute dominance and volume for each species in two forest fragments.

Litter decompositionDecomposition rate was evaluated in the leaf fraction (viz., the main component of litter), using the mixed litter bag method (Berg et al. 1993; Xiong et al. 2014). Bags were prepared according to the following criteria: (i) species from the most abundant families in the study areas; (ii) the most abundant species from each family in each forest fragment; and (iii) leaf size for bag incubation for 12 months. The most abundant families in the study areas were Myrtaceae, Lauraceae, Sapindaceae and Euphorbiaceae. Detailed information about the species survey is provided as Table S01 in Supplementary Material.

The species meeting the selection criteria were Nectandra megapotamica (Spreng.) Mez. (Lauraceae), Cupania vernalis Cambess. (Sapindaceae), Allophylus puberulus (Cambess.) Radlk. (Sapindaceae), Sebastiania brasiliensis Spreng. (Euphorbiaceae) and Myrcianthes pungens (O.Berg) D. Legrand (Myrtaceae) in FN1; N. megapotamica , C. vernalis , A. puberulus , S. brasiliensis and Campomanesia xanthocarpa O.Berg (Myrtaceae) in FN2. All were evergreen species.

An amount of approximately 2.5 ± 0.1 g dry matter (60ºC, 24 h) of senescent leaves was weighed and placed in a nylon mesh bag (mesh 10 mm, size 10 × 10 cm). A total of 25 litter bags were placed on the soil surface near the litter collectors in each forest fragment. Five litter bags in each fragment were placed on the soil surface and collected after 1, 2, 4, 6 and 12 months. Leaf decomposition rate was expressed as the percent of leaf mass remaining in the bags after each time.

The decomposition rate was calculated as Mt = M 0 e-k t (Olson 1963), where M t denotes leaf mass at time t , M 0 the initial mass and k the decomposition rate. The rate was used to estimate the mean time needed for the leaf litter fraction to decompose, in days.

Chemical composition of the soil and quality of the leaf litter

Individual soil samples for analysis were collected by using a cutting blade in a 0.5 × 0.5 m area from the 0-10 cm layer at six different locations in each fragment and combined to obtain composite samples. Each composite sample was split into three subsamples for analysis for organic C by dry combustion on Shimadzu (VCSH TOC instrument), macronutrients (N, P, K, Ca, Mg and S) and micronutrients (Cu, Zn, Fe, Mn and B) in the leaf litter fraction each season. The samples were dried at 60 °C for 24 h and ground in a porcelain mortar, a 10 g subsample being stored for chemical analysis. For soil and leaf litter nutrient analyses, 10 g of each sample was sent to the Soil Analysis Laboratory of the Federal University of Rio Grande do Sul School of Agronomy. Leaf litter nutrients were quantified according to Tedesco et al. (1995) and expressed in g kg−1 or mg kg−1.

Data analysis

Seasonal litter productivity was assessed via a two-way analysis of variance (two-way ANOVA) for comparison of mean total productivity between seasons and study areas. A two-way ANOVA was also used to evaluate differences in seasonal leaf litter productivity between areas and seasons. All data were subjected to logarithmic transformation to reduce the homoscedasticity of the data.

Seasonal litter productivity was related to species richness in the upper and lower tree strata via Pearson's correlation coefficient, and so were structural parameters (absolute dominance, basal area and volume) in the two strata to total litter productivity. Correlation was assumed when r ≥ 0.30. Differences in parameters between the structured areas for each stratum (upper and lower) were assessed via a t -test. Differences in decomposition dynamics between the study areas were also evaluated via a t -test, with p ≤ 0.05 being considered significant.

Differences in soil characteristics between the study areas were evaluated via a t -test for each soil component (organic C, macronutrients and micronutrients). Differences in macro- and micronutrients contents, and in C:N ratio, between areas and seasons were assessed by two-way ANOVA, and those in leaf litter nutrients via a t -test. All analyses were performed in the statistical environment R (R Core Team 2013).

Results

Seasonal litter production

Total and leaf litter production changed seasonally in both forest fragments (p ≤ 0.0001 in FN1 and p = 0.005 in FN2), with differences in autumn and spring (Fig. 1A-B). Litter production was greatest in spring in both fragments, and greater in FN1 than in FN2.

Figure 1
A) Seasonal production of total litter and B) leaf litter in the two forest fragments. Different letters indicate differences between study areas and seasons. (n = 8-10).

Relationship between vegetation structure and litter production

In the upper stratum, FN1 exhibited an increased higher basal area (p = 0.004), volume (p = 0.04) and dominance p = 0.004) relative to FN2. This was also the case with basal area (p = 0.02) and absolute dominance (p = 0.02) in the lower stratum, but not with volume, which was similar in the two areas (p = 0.13).

Relating litter production to structural parameters revealed a positive correlation between dominance, basal area and volume in the upper stratum in FN1 (r > 0.4, Tab. 1), and also a negative correlation between dominance, basal area and volume in the same stratum in FN2 (r = 0.3, Tab. 1). On the other hand, the structural characteristics of the lower stratum in FN1 and FN2 were uncorrelated with litter production.

Table 1
Relationship of litter production with absolute dominance (ADo), basal area (BA) and volume (vol.) in the lower and upper stratum of the two forest fragments (FN1 and FN2).

Litter decomposition

The study areas exhibited no difference in final mass loss (percent weight lost at t = 12 months) or decomposition rate of the leaf litter fraction (p = 0.47). The reduction in leaf litter mass after 12 months (365 days) of incubation in litter bags was 74.8% in FN1 and 73.9% in FN2. The decay constant was 1.27 ± 0.55 (mean ± standard error) in FN1 and 1.05 ± 0.63 in FN2; therefore, total decomposition of litter would require a long time in both areas (463 days in FN1 and 383 days in FN2). The weight loss in FN1 was greatest within the first month (22.7%) and from the tenth to the twelfth (12.5%); and that in FN2 maximal within the first month (27.7%) and from the fourth to the sixth (19.4%) (Fig. 2).

Soil chemical composition and leaf litter C:N ratio

Figure 2
Leaf decomposition rate, expressed as the percent reduction in mass over the course of 12 months in the two forest fragments. Bars represent mean standard deviations (n = 5).

As can be seen from Table 2, the chemical composition of the soil in the two areas differed except in the contents in potassium, magnesium and zinc, and in potential acidity (H+Al). The organic carbon, phosphorus and calcium concentration contents were significantly higher in FN1 than in FN2 (p = 0.0001). The contents in the micronutrients manganese and sodium differed between the two areas, and were higher in FN1. Finally, the C:N ratio differed between seasons and areas (Tab. 3), and was higher in FN1 throughout the year.

Table 2
Contents in soil organic C, macronutrients and micronutrients in the two forest fragments (n = 6).

Table 3
F- and P-values obtained in two-way ANOVAs used to identify differences in C: N ratio of leaf litter between forest fragments (FN1 and FN2) and seasons.

The chemical analyses of plant tissue revealed differences in nitrogen, phosphorus and iron contents of the leaf litter between the study areas in the summer, autumn and spring seasons. The contents in potassium and copper of leaf litter differed in summer, winter and spring; those in manganese and sulphur in summer and autumn; and that in zinc in all seasons except spring (see Tab. S02 in Supplementary Material). There were no differences in potassium, calcium, copper, manganese or boron between the study areas in autumn.

Discussion

The biodiversity influences ecosystem functioning via two different mechanisms (Ruiz-Benito et al. 2014). One, known as the "complementary effect", is associated with the partitioning and facilitation of niches where species diversity increases efficiency in resource use and nutrient retention. The other, known as the "selection effect", increases the probability of the more productive species to become the dominant species in a plant community. The influence of some species on ecosystem functioning has indeed been observed in several studies (Gaston 2010; Cardinale et al. 2012; Cadotte et al. 2013) where the losses in some species were offset by other species in the same functional group (Joner et al. 2011).

Based on our results, the studied forest fragments differ structurally and the differences are related to litter production, which affects the two fragments in opposite ways. Litter production in the two fragments exhibited seasonal variation (especially during spring). Pearse et al. (2014) point out that the phenological characteristics of the species are associated with the observed differences in litter production. Also, the strong presence of some species in our fragments was possibly related in a direct manner with the greater dominance and basal area of the tree strata, which were positively correlated with litter productivity in FN1. Thus, the structural pattern of the fragments was seemingly responsible for their differences in litter production in the absence of substantial differences in species composition between the two.

The relationship between forest structure and litter productivity in spring may also be associated with the presence or dominance of certain species through a selection effect (Ruiz-Benito et al. 2014). In fact, the presence of dominant species may have been responsible for most leaf fall in spring. Also, the absence of differences in litter production in the other seasons may also have resulted from the dominance of some species. The analysis of forest structure and litter composition revealed a strong presence of certain species such as N. megapotamica , Allophylus edulis , A. puberulus , Matayba eleagnoides and Styrax leprosus in both fragments. These species exhibited marked leaf loss throughout the year and may have been the greatest contributors to the similarity in litter production between the two areas in the summer, autumn and winter seasons.

The marked differences in forest structure did not reflect in the litter decomposition dynamics. In fact, both forest fragments exhibited similar weight losses throughout. Thus, mass loss at the end of the 12-month period was approximately 75% in FN1 and FN2, and suggestive of rapid decomposition of the leaf litter fraction. Litter in forest fragments is known to decompose more rapidly under a subtropical climate than under a tropical climate, which suggests an effect of climate (Scheer 2008; Terror et al. 2011; Oliveira et al. 2013) through precipitation seasonality in subtropical regions. However, leaf decomposition in exotic species from the same region was previously found to be slower than in this study (Sausen et al. 2014; Vieira et al. 2014).

It should be borne in mind that we used mixed litter (Wickings et al. 2012) containing evergreen and secondary species in both study areas. In addition, the areas were located in the same region, so no major differences in abiotic conditions (precipitation) potentially influencing the litter decomposition dynamics existed. However, given their close relationship (Vitousek & Sanford 1986; Berg & McClaugherty 2008), litter production and decomposition in forest fragments with a strong presence of certain species may be subject to a selection effect.

The contents in macro- and micronutrients of soil, and the C:N ratio of leaf litter, differed between the study areas, and the latter also between seasons. These results indicate that litter production in FN1 was markedly seasonal, evidenced by the production during the spring, as suggested by the increased C:N ratio of leaf litter and nutrient contents of soil (particularly phosphorus, calcium and organic C). The other fragment, FN2, exhibited increased micronutrient contents in the soil. These results suggest that litter-soil interactions may be subject not only to a selection effect, but also to a complementary effect. The structural differences between the fragments may be related to differences in resource use efficiency and explain the plant-soil feedback observed. Thus, the increased contents in soil macronutrients (especially calcium and phosphorus) and also increased leaf litter C:N ratio in FN1 may be responsible for the increased soil organic carbon content observed.

We can therefore conclude that productivity and leaf litter decomposition were similar in the two study areas, with vegetation structure and seasonality influencing litter production. These ecosystem processes are subject to selection mechanisms, whereas soil nutrient and organic C contents, and leaf litter quality, are subject to complementary effects. Interestingly, both types of effect may operate in the functioning processes of the target ecosystem, where everything has a specific role.

Conclusions

The dominance of certain families in subtropical forest fragments results in a selection effect on litter productivity and decomposition. However, plant-soil feedback in such fragments is seemingly governed by soil contents in organic C, phosphorus and calcium, which suggests the presence of a complementary effect.

Acknowledgements

The authors are grateful to the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq, Brazil) for funding this work, and to the Fundação de Amparo a Pesquisa do Rio Grande do Sul (FAPERGS, Brazil) for award of a graduate fellowship to E.S.C.

References

  • Aerts R, Chapin FSIII. 2000. The mineral nutrition of wild plants revisited: a re-evaluation of processes and patterns. Advances in Ecological Research 30: 1-45.
  • Aragão LEOC, Malhi Y, Metcalfe DBJ, et al. 2009. Above- and belowground net primary productivity across the Amazonian forests on contrasting soils. Biogeosciences 6: 2759-2778.
  • Austin AT, Vivanco L. 2006. Plant litter decomposition in a semi-arid ecosystem controlled by photodegradation. Nature 442: 555-558.
  • Berg B, McClaugherty C. 2008. Plant litter, decomposition, humus formation, carbon sequestration. 2nd. edn. Berlin, Springer.
  • Berg B, McClaugherty C, Johansson M. 1993. Litter mass-loss rates in late stages of decomposition at some climatically and nutritionally different pine sites. Long-term decomposition in a Scots pine forest VIII. Canadian Journal of Botany 71: 680-692.
  • Budke JC, Jarenkow JA, Oliveira-Filho AT. 2010. Intermediary disturbance increases tree diversity in riverine forest of southern Brazil. Biodiversity Conservation 19: 2371-2387.
  • Cadotte MW. 2013. Experimental evidence that evolutionarily diverse assemblages result in higher productivity. Ecology Letters 110: 8996-9000.
  • Cardinale BJ, Duffy JE, Gonzales A, et al. 2012. Biodiversity loss and its impact on humanity. Nature 486: 56-67.
  • Chambers JQ, dos Santos J, Ribeiro RJ, Higuchi N. 2001. Tree damage, allometric relationships, and above-ground net primary production in central Amazonia forest. Forest Ecology and Management 152: 73-84.
  • Cheng X, Luo Y, Su B, et al. 2010. Experimental warming and clipping altered litter carbon and nitrogen dynamics in a tallgrass prairie. Agriculture, Ecosystems & Environment 138: 206-213.
  • Decian VZanin EM, Henke C, et al. 2009. Uso da terra na região Alto Uruguai do Rio Grande do Sul e obtenção de um banco de dados relacional de fragmentos de vegetação arbórea. Perspectiva 33: 165-176.
  • Fuqiang S, Xiaoxu F, Ruiqing S. 2010. Review of mixed forest litter decomposition researches. Acta Ecologica Sinica 30: 221-225.
  • Gaston KJ. 2010. Valuing common species. Science 327: 154-155.
  • Ge XZeng L, Xiao W, et al. 2013. Effect of litter substrate quality and soil nutrients on forest litter decomposition: a review. Acta Ecologica Sinica 33: 102-10.
  • Gilliam FS. 2007. The ecological significance of the herbaceous layer in temperate forest ecosystems. BioSience 57: 845-858.
  • Hack C, Longhi SJ, Boligon AA, et al. 2005. Análise fitossociológica de um fragmento de floresta estacional decidual no município de Jaguari, RS. Revista Ciência Rural 35: 1083-1091.
  • Hättenschwiler SCoq S, Barantal S, et al. 2011. Leaf traits and decomposition in tropical rainforests: revisiting some commonly held views and towards a new hypothesis. New Phytologist 189: 950-965.
  • Jacob M,Viedenz K, Polle A, et al. 2010. Leaf litter decomposition in temperate deciduous forest stands with a decreasing fraction of beech (Fagus sylvat ica). Oecologia 164: 1083-1094.
  • Joner F, Specht G, Müller SC, et al. 2011. Functional redundancy in a clipping experiment on grassland plant communities. Oikos 120: 1420-1426.
  • Manzoni S, Piñeiro G, Jackson RB, et al. 2012. Analytical models of soil and litter decomposition: Solutions for mass loss and time-dependent decay rates. Soil Biology & Biochemistry 50: 66-76.
  • Mélo MA, Budke JC, Henke-Oliveira C. 2013. Relationships between structure of the tree component and environmental variables in a subtropical seasonal forest in the upper Uruguay River valley, Brazil. Acta Botanica Brasilica 27: 751-760.
  • Müller SC, Overbeck GE, Pfadenhauer J, et al. 2012. Woody species patterns at forest-grassland boundaries in southern Brazil. Flora 207: 586-598.
  • Niro E, Marzaioli R, Crescenzo S, et al. 2016. Effects of the allelochemical coumarin on plants and soil microbial community. Soil Biology and Biochesmistry 95: 30-39.
  • Oliveira CV, Barreto PAB, Gomes AS, et al. 2013. Efeito de borda e decomposição da serapilheira foliar de um fragmento florestal, em Vitória da Conquista - BA. Enciclopédia Biosfera 9: 1150-1161.
  • Oliveira-Filho AT, Budke JC, Jarenkow JA, et al. 2013. Delving into the variations in tree species composition and richness across South American subtropical Atlantic and Pampean forests. Journal of Plant Ecology 2: 1-23.
  • Olson JS. 1963. Energy storage and the balance of procedures and decomposers in ecological systems. Ecology 44: 322-331.
  • Pearse ISCobb RC, Karban R, et al. 2014. The phenology-substrate-match hypothesis explains decomposition rates of evergreen and deciduous oak leaves. Journal of Ecology 102: 28-35.
  • Pimenta JA, Rossi LB, Torezan JMD, et al. 2011. Produção de serapilheira e ciclagem de nutrientes de um reflorestamento e de uma floresta estacional semidecidual no sul do Brasil. Acta Botanica Brasilica 25: 53-57.
  • Prescott CE, Grayston SJ. 2013. Tree species influence on microbial communities in litter and soil: current knowledge and research needs. Forest Ecology and Management 309: 19-27.
  • Quested HM, Press MC, Callaghan TV, et al. 2002. The hemiparasitic angiosperm Bartsia alp ina has the potential to accelerate decomposition in sub-arctic communities. Oecologia 130: 88-95.
  • R Core Team. 2013. R: a language and environment for statistical computing. Vienna, R Foundation for Statistical Computing.
  • Ruiz-Benito P, Gómez-Aparicio L, Paquette A, et al. 2014. Diversity increases carbon storage and tree productivity in Spain forest. Global Ecology and Biogeography 23: 311-322.
  • Sausen TL, Shaefer GFP, Tomazi M, et al. 2014. Clay content drives carbon stocks in soils under a plantation of Eucalyptus sali gna Labill. in southern Brazil. Acta Botanica Brasilica 28: 266-273.
  • Scheer MB. 2008. Decomposição e liberação de nutrientes da serapilheira foliar em um trecho de Floresta Ombrófila Densa Aluvial em regeneração, Guaraqueçaba (PR). Floresta 38: 253-266.
  • Schuman MC, Dam NM, Beran, F, Harpole WS. 2016. How does plant chemical diversity contribute to biodiversity at higher trophic levels? Current Opinion in Insect Science 14: 46-55.
  • Shepherd GJ. 2010. Fitopac 2.1. Manual do usuário. Campinas, UNICAMP.
  • Szanser M, Ilieva-Makulec K, Kajak A, et al. 2011. Impact of litter species diversity on decomposition processes and communities of soil organisms. Soil Biology & Biochemistry 43: 9-19.
  • Tedesco MJ, Gianello C, Bissani CA, et al. 1995. Análises do Solo, Plantas e Outros Materiais. Porto Alegre, Universidade Federal do Rio Grande do Sul.
  • Terror VL, Sousa HC, Kozovits AR. 2011. Produção, decomposição e qualidade nutricional da serapilheira foliar em uma floresta paludosa de altitude. Acta Botanica Brasilica 25: 113-121.
  • Vieira M, Schumacher MV, Araújo EF. 2014. Disponibilização de nutrientes via decomposição da serapilheira foliar em um plantio de Eucalyptus urophyl la x Eucalyptus globu lus. Floresta e Ambiente 21: 307-315.
  • Vitousek P. 1982. Nutrient cycling and nutrient use efficiency. The American Naturalist 119: 553-572.
  • Vitousek P. 1984. Litterfall, nutrient cycling, and nutrient limitation in tropical forests. Ecology 65: 285-298.
  • Vitousek PM, Sanford RL. 1986. Nutrient cycling in moist tropical forest. Annual Review of Ecology, Evolution, and Systematics 17: 137-167.
  • Wang H Liu S, Wang J, et al. 2013. Dynamics and speciation of organic carbon during decomposition of leaf litter and fine roots in four subtropical plantations of China. Forest Ecology and Management 300: 43-52.
  • Wardle DA, Yeates GW, Barker GM, et al. 2006. The influence of plant litter diversity on decomposer abundance and diversity. Soil Biology & Biochemistry 38: 1052-1062.
  • Wickings K,Grandy AS, Reed SC, et al. 2012. The origin of litter chemical complexity during decomposition. Ecology Letters 15: 1180-1188.
  • Xiaogai G, Lixiong Z, Wenfa X, Zhilin H, Xiansheng G, Benwang T. 2013. Effect of litter substrate quality and soil nutrients on forest litter decomposition: a review. Acta Ecologica Sinica 3: 102-108.
  • Xiong Y Zeng H, Xia H, et al. 2014. Interactions between leaf litter and soil organic matter on carbon and nitrogen mineralization in six forest litter-soil systems. Plant Soil 379: 217-229.

Publication Dates

  • Publication in this collection
    04 July 2016
  • Date of issue
    Jul-Sep 2016

History

  • Received
    12 Feb 2016
  • Accepted
    10 May 2016
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