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Sugarcane cultivation with source potassium low water-soluble

Cultivo da cana-de-açúcar com fonte de potássio pouco solúvel em água

ABSTRACT.

Thermopotash is a fertilizer with low solubility but has a release level compatible with plant demands. This study aimed to compare the effect of Thermopotash to that of KCl in sugarcane. Field work was conducted during two crop seasons, in a randomised block design. Treatments were applied to the bases of the furrows before planting the sugarcane, arranged in a 2 x 5 factorial design to evaluate two K sources (TK47 - Thermopotash, KCl - potassium chloride) at five levels of K (0, 50, 100, 150, and 200 kg ha-1 K2O). The variables analysed included leaf and soil K, Ca, Mg and Si, soil pH and productivity. The effects of the TK47 fertilizer on sugarcane stalk production were not initially superior to that of the soluble source, but over time, differences between the soluble and insoluble sources increased. The maximum expected sugarcane productivity for both sources was 133 Mg ha-1, which was achieved at an application level of 121 kg ha-1 K2O. TK47 fertilizer provided K, Si, Ca and Mg to the sugarcane in both the first and second harvests. Thus, TK47 may be a viable source of K for sugarcane.

Keywords:
thermopotash; potassium chloride; soil; Saccharum spp

RESUMO.

Termopotássio é um fertilizante com baixa solubilidade em água mas possui uma taxa de liberação compatível com a demanda da planta. Esse estudo objetivou avaliar os efeitos do termopotássio em relação ao cloreto de potássio no cultivo da cana. O trabalho foi realizado no campo durante duas safras agrícolas, em delineamento de blocos casualizados. Os tratamentos foram aplicados no sulco antes do plantio da cana, organizados em esquema fatorial 2x5, sendo duas fontes K (TK47-Termopotássio e KCl-cloreto de potássio) e cinco doses de K (0, 50, 100, 150 e 200 kg ha-1 de K2O). As variáveis analisadas foram: teores de K, Ca, Mg e Si nas folhas e solo, pH do solo e produtividade. Os efeitos do adubo TK47 sobre a produção foram similares aos da fonte solúvel na cana planta, e ao longo do tempo, as diferenças entre fontes solúveis e insolúveis aumentaram. A produtividade máxima esperada da cana planta para ambas as fontes foi de 133 Mg ha-1, com a aplicação de 121 kg ha-1 de K2O. O adubo TK47 forneceu K, Si, Ca e Mg para a cana planta e para a cana soca. Assim, o TK47 pode ser uma fonte viável de K para a cana-de-açúcar.

Palavras-chave:
termopotássio; cloreto de potássio; solo; Saccharum spp

Introduction

Potassium (K) deposits containing soluble K minerals occur predominantly in the northern hemisphere, mainly in Canada and Russia. Production tonnage and prices do not take into account the needs of farmers; therefore, as needs continually evolve, alternatives to soluble salts have been explored to produce K fertilizers (Ciceri, Manning, & Allanore, 2015Ciceri, D., Manning, D. A. C., & Allanore, A. (2015). Historical and technical developments of potassium resources. Science of The Total Environment, 502(2), 590-601. doi: 10.1016/j.scitotenv.2014.09.013.
https://doi.org/10.1016/j.scitotenv.2014...
). The investigation of K silicate minerals and their host rocks as alternative sources of K is especially relevant in systems with highly weathered soils that lack significant cation exchange capacity (Manning, 2010Manning, D. A. C. (2010). Mineral sources of potassium for plant nutrition. Agronomy for Sustainable Development, 30(2), 281-294. doi: 10.1051/agro/2009023.
https://doi.org/10.1051/agro/2009023....
).

Verdete is a sedimentary rock that stands out among potential potassium sources and is found in Serra da Saudade (Alto Paranaíba Region of Minas Gerais State, Brazil), which lies atop the San Francisco craton. This rock has low water-soluble K content, indicating a certain limitation in its use as a K fertilizer in its natural state, especially for short cycle crops. Nevertheless, the total K content of Verdete indicates the potential of this rock as a raw material for the production of K fertilizer (Santos et al., 2015Santos, W. O., Mattielo, E. M., Costa, L. M., Abrahão, W. A. P., Novais, R. F., & Cantarutti, R. B. (2015). Thermal and chemical solubilization of verdete for use as potassium fertilizer. International Journal of Mineral Processing, 140(10), 72-78. doi: 10.1016/j.minpro.2015.05.003
https://doi.org/10.1016/j.minpro.2015.05...
). One means to increase the K availability of this rock is through chemical and thermal processing and mixing with CaCO3 at 1,100°C. This process results in a fertilizer called Thermopotash that has lower solubility then soluble K minerals, such as sylvite (KCl) and arcanite (K2SO4), but has a release level compatible with plant demands and a possible residual effect. This is a desirable feature given that the effects of the fertilizer last longer and losses from leaching are minimised compared to soluble fertilizers (Nunes, Kautzmann, & Oliveira, 2014Nunes, J. M .G., Kautzmann, R. M., & Oliveira, C. (2014). Evaluation of the natural fertilizing potential of basalt dust waste from the mining district of Nova Prata (Brazil). Journal of Cleaner Production, 84(1), 649-656. doi: 10.1016/j.jclepro.2014.04.032.
https://doi.org/10.1016/j.jclepro.2014.0...
).

Assessing the dynamics of nutrient release from sources with low water solubility requires long-term field studies. Fertilization in sugarcane increases plant height and plant dry matter (Thengavelu, 2009Thangavelu, S. (2009). Mineral nutrition in sugarcane crop production and improvement. Texas, US: Stadium Press LLC.). Sugarcane is a good candidate for this type of study given its long crop cycle, extremely high K requirements, and economic significance in Brazil.

Therefore, this study aimed to compare the effect of Thermopotash (TK47 fertilizer) to that of KCl on sugarcane productivity, nutrient uptake and soil nutrient availability.

Material and method

The experiment was conducted with sugarcane cultivar SP 832847 grown in an Ustoxic soil and was set up in June, 2011 in Chaveslandia, Minas Gerais State, Brazil (19°04’07.49”S and 50°22’19.70”W). The 0-20 cm layer of the soil had the following characteristics: pH in water = 4.4, P (Mehlich 1) = 2.0 mg dm-3, K (Mehlich 1) = 0.04 cmolc dm-3, Ca2+ (KCl) = 0.6 cmolc dm-3, Mg2+ (KCl) = 0.3 cmolc dm-3, Si (CaCl2 0.01 mol L-1) = 3.0 mg dm-3, H+Al = 2.44 cmolc dm-3, CEC = 3,34 cmolc dm-3, sand = 860 g kg-1, silt = 10 g kg-1, and clay = 130 g kg-1.

Accumulated rainfall totalled 1,323 mm before the first sugarcane harvest and 1,223 mm before the second harvest. Soil preparation consisted of an application of dolomitic limestone (1 Mg ha-1) over the entire experimental area followed by harrowing and levelling. Before planting the sugarcane, 250 kg ha-1 monoammonium phosphate (MAP) was applied to the base of the furrow using a plough. Next, the K sources (KCl and TK47 fertilizer) at the various application levels were distributed manually in the sugarcane furrow. After the first harvest, gypsum (1 t ha-1) and dolomitic limestone (1 t ha-1) were superficially applied throughout the entire experimental area.

The experiment was carried out at a sugarcane plant and set up in a randomised block design with five replication blocks for a total of 50 plots. Each experimental plot covered 150 m2 and consisted of five 20-m-long rows of sugarcane spaced 1.5 m apart. Treatments were arranged in a 2 x 5 factorial design, evaluating two K sources (TK47 fertilizer - Thermopotash and KCl) at five levels of K (0, 50, 100, 150, and 200 kg ha-1 K2O).

TK47 is a mineral fertilizer developed by Verde Fertilizantes and is obtained by mixing limestone, Verdete and special reagents at a ratio of approximately 1 (CaCO3): 5 (Verdete). After mixing, the particle size is greatly reduced, and the mixture is then heat treated in a thermal reactor at approximately 1,000°C.

The K sources were characterised physically and chemically (MAPA, 2017Ministério da agricultura, Pecuária e Abastecimento. [MAPA] (2017). Manual de métodos analíticos oficiais para fertilizantes e corretivos. Brasília, DF: MAPA.). TK47 is a grained fertilizer (granulometry is between 2.83 and 4.80 mm) and is characterised chemically by total K2O = 7%, soluble K2O in 2% citric acid = 6%, total Si = 28%, total Ca = 22%, and total Mg = 1%. It has a salt index of 0.5, and the neutralising power was determined as 55% EqCaCO3. KCl has K2O = 60%, Cl = 47%, and a salt index of 116. Thus, these sources are capable of providing other nutrients in addition to K. Therefore, to provide 200 kg of K2O, 2,857 kg ha-1 TK47 and 333 kg ha-1 KCl were applied (Table 1).

After application of the treatments, sugarcane sets of cultivar SP 832847 were manually planted in the furrows at a density of 17 buds per metre. Earthing-up and an application of ammonium nitrate (80 kg ha-1) were carried out 90 days after planting.

To evaluate the residual effect of the K applications on the ratoon cane, all plots received applications of nitrogen (150 kg ha-1) as ammonium nitrate (33% N) and 70 kg ha-1 P2O5 as triple superphosphate (46% P2O5). There were no reapplications of the K sources.

Table 1
Quantities of Ca, Mg, Si and K supplied by KCl or TK47 K fertilizers.

Leaves were collected in February 2012 (cane plant) and in February 2013 (ratoon cane), and an analysis of K, Ca, Mg (Raij, Andrade, Cantarella, & Quaggio, 2001Raij, B. van, Andrade, J. C., Cantarella, H., & Quaggio, J. A. (2001). Análise química para avaliação da fertilidade de solos tropicais. Campinas, SP: Editora do Instituto Agronômico.) and Si (Datnoff, Snyder, & Korndörfer, 2001Datnoff, L. E., Snyder, G. H., & Korndörfer, G. H. (2001). Silicon in agriculture. Amsterdam, NE: Elsevier.) content was undertaken. Soil samples were taken immediately after sugarcane harvest (cane plant and ratoon) at depths of 0-20 cm and 20-40 cm in rows. Measurements were taken of K, Ca, Mg, pH (Raij et al., 2001Raij, B. van, Andrade, J. C., Cantarella, H., & Quaggio, J. A. (2001). Análise química para avaliação da fertilidade de solos tropicais. Campinas, SP: Editora do Instituto Agronômico.) and Si (Datnoff et al., 2001Datnoff, L. E., Snyder, G. H., & Korndörfer, G. H. (2001). Silicon in agriculture. Amsterdam, NE: Elsevier.). After 12 months of growth, the sugarcane was harvested manually and was not burned. The stalks were weighed with the aid of a tensile load cell.

The results were submitted for analysis of variance using the SISVAR program (Ferreira, 2011Ferreira, D. F. (2011). SISVAR: Um sistema computacional de análise estatística. Ciência e Agrotecnologia, 35(6), 1039-1042. doi: 10.1590/S1413-70542011000600001.
https://doi.org/10.1590/S1413-7054201100...
). Averages were compared at the 5% significance level. Quantitative treatments were evaluated using regression analysis, and the qualitative results were evaluated using the Tukey test.

Result and discussion

In the first harvest, the TK47 fertilizer produced the same stalk yield (128.6 Mg ha-1) as that of KCl (123.7 t ha-1), considering the average of the K levels applied (Table 2). In this harvest, according to a quadratic model (y = 0.0012X2+ 0.2905X+115.03), sugarcane productivity was 115.03 t ha-1 for the control treatment (without K application) but reached 132.61 t ha-1 with application of 121.04 kg ha-1 K2O, regardless of source. Sugarcane stalk productivity decreased at higher application levels (Figure 1A, harvest 1).

Averaging the different K levels, sugarcane productivity in the second harvest was 5.44% higher using TK47 fertilizer application versus the use of KCl (Table 2). Figure 1A shows a linear response of production to dose increase.

Table 2
Effects of K levels and sources on stalk productivity for sugarcane variety SP832847, 2011/12 and 2012/13 crops (Usina Vale do São Simão, Chaveslandia, Minas Gerais State, Brazil).

The accumulated result (sum of the 1st and 2nd harvests) clearly shows that, regardless of K level, sugarcane stalk productivity was higher using the TK47 fertilizer versus using KCl (Figure 2). Furthermore, a quadratic fit shows that without K applications, productivity was 224.3 Mg ha-1, but with K applications, regardless of source, productivity increased up to a maximum of 253.3 Mg ha-1 with an application of 135 kg ha-1 K2O (Figure 1B). These data demonstrate that for sugarcane production, the residual effect of TK47 is more effective than that of KCl. Duarte, Sousa, Korndorfer, and Pereira (2015Duarte, I. N., Sousa, R. T. X., Korndorfer, G. H., & Pereira, H. S. (2015). Alternative potash fertilizer source for millet crop. Journal of Plant Nutrition, 38(12), 1961-1972. doi: 10.1080/01904167.2015.1009097.
https://doi.org/10.1080/01904167.2015.10...
) studied different K sources and reported that millet absorbed K from Alfa 02, a K source produced by mixing limestone and Verdete with subsequent heat treatment, in both the first and second crops, thereby demonstrating a residual effect from this source.

The TK47 fertilizer increased Si availability in the soil (Tables 4 and 5) (Figures 4 and 5) and Si leaf concentrations (Table 3 and Figure 3). The supply of Si may also have contributed to increases in sugarcane productivity. Datnoff et al. (2001Datnoff, L. E., Snyder, G. H., & Korndörfer, G. H. (2001). Silicon in agriculture. Amsterdam, NE: Elsevier.) observed that silicate applications were associated with increases of up to 17% in cane plant productivity and up to 20% in ratoon productivity.

An evaluation of cane plant nutrition showed that, in the first harvest, the only significant interaction between source and application level was related to leaf K and Ca. KCl was associated with higher leaf K levels compared to the TK47 fertilizer at application levels of 100, 150, and 200 kg ha-1 K2O in the cane plant and at all application levels in the ratoon cane (Table 3). However, average leaf K in crops for both K sources ranged between 10 and 20 g kg-1, which is adequate for sugarcane (Fageria, Baligar, & Jones, 2011Fageria, N. K., Baligar, V. C., & Jones, C. A. (2011). Growth and mineral nutrition of field crops (3rd ed.). London, UK: CRC Press.).

Figure 1
Effects of K levels and sources on sugarcane productivity for sugarcane variety SP832847, 2011/12 and 2012/13 crops (Usina Vale do São Simão, Chaveslandia, Minas Gerais State, Brazil). TK47 = Thermopotash; KCl = Potassium chloride; 5% significance level.

Figure 2
Total productivity (1st + 2nd harvests) of the sugarcane (Usina Vale do São Simão, Chaveslandia, Minas Gerais State, Brazil). Means followed by distinct lower case letters differ according to the Tukey test at 5% significance regarding K sources (LSD = 10.95). TK47 = Thermopotash; KCl = Potassium chloride.

Although sugarcane absorbs more K when it is fertilised using KCl than when it is fertilised using TK47, this difference does not translate into increased productivity (Table 2), indicating that these plants had K levels that are more than sufficient. According to Setiyono, Walters, Cassman, Witt, and Dobermann (2010Setiyono, T. D., Walters, D. T., Cassman, K. G., Witt, C., & Dobermann, A. (2010). Estimating maize nutriente uptake requirements. Field Crops Research, 118(2), 158-168. doi: 10.1016/j.fcr.2010.05.006.
https://doi.org/10.1016/j.fcr.2010.05.00...
), plants have the ability to absorb more K than is required for full development, a situation that is commonly referred to as luxury consumption.

Leaf Ca concentration was higher when using TK47 fertilizer than when using KCl at levels of 150 and 200 kg ha-1 K2O in the plant cane and for all levels in the ratoon cane (Table 3) and appeared to be within the optimum range (Raij, 2011Raij, B. V. (2011). Fertilidade do solo e manejo dos nutrientes. Piracicaba, SP: Editora International Plant Nutrition Institute.) in both harvests. This occurred because the limestone used to correct the soil acidity also supplies Ca, whereas the TK47 fertilizer contains CaO from limestone. The K sources did not affect leaf Mg and Si in the plant cane crop; however, in the second harvest, the levels of leaf Mg were higher for the TK47 treatment, regardless of application level (Table 3). However, leaf Si was higher when using the TK47 fertilizer than when using KCl at 150 and 200 kg ha-1 K2O (Table 3), but these concentrations were still not high enough to be considered ideal for sugarcane cultivation (6 g kg-1) (McCray et al., 2010McCray, J. M., Ji, S., Powell, G., Montes, G., Perdomo, R., & Luo, Y. (2010). Boundary lines used to determine sugarcane production limits at leaf nutrient concentrations less than optimum. Communications in Soil Science and Plant Analysis, 41(5), 606-622. doi: 10.1080/00103620903531185.
https://doi.org/10.1080/0010362090353118...
).

A linear fit or direct relationship was found between higher K application levels and increases in leaf nutrient levels. This relationship was observed for KCl in the first sugarcane harvest and for KCl and the TK47 fertilizer in the second harvest (Figure 3A). This direct relationship existed for leaf Ca the TK47 fertilizer treatment in the first harvest (Figure 3B) and for leaf Si in the TK47 fertilizer treatment after the second harvest (Figure 3C).

Table 3
Effects of K levels and sources on leaf concentrations of K, Ca, Mg, and Si for sugarcane variety SP832847, 2011/12 and 2012/13 crops (Usina Vale do São Simão, Chaveslandia, Minas Gerais State, Brazil).

Figure 3
Effects of K levels and sources on leaf concentrations of K, Ca, and Si for sugarcane variety SP832847, 2011/12 and 2012/13 crops (Usina Vale do São Simão, Chaveslandia, Minas Gerais State, Brazil). TK47 = Thermopotash; KCl = Potassium chloride; 5% significance level (*).

Table 4
Effects of K levels and sources on soil availability of K, Ca, Mg, and Si in the 0-20 cm soil layer after the sugarcane harvest for variety SP832847, 2011/12 and 2012/13 crops (Usina Vale do São Simão, Chaveslandia, Minas Gerais State, Brazil).

Leaf K levels in the first harvest were higher than those in the second harvest. These differences indicate lower K availability in the soil due to the absence of subsequent K applications. The TK47 fertilizer produced higher soil K availability compared to KCl in the 0-20 cm layer at application levels of 100, 150, and 200 kg ha-1 K2O after the first harvest and at all levels of K2O after the second harvest (Table 4). In the 20-40 cm layer, the TK47 fertilizer produced higher soil K availability compared to KCl at application levels of 150 and 200 kg ha-1 K2O (after the first and second harvests) (Table 5).

Soil Si was higher using the TK47 fertilizer than when using KCl (Tables 4 and 5). This occurred in the 0-20 cm layer after the first and second harvests at levels of 100, 150, and 200 kg ha-1 K2O (Table 4). The same was found in the 20-40 cm layer at levels of 150 and 200 kg ha-1 K2O after the first harvest and at 50, 100, 150, and 200 kg ha-1 K2O after the second harvest (Table 5). Si availability in the soil was higher under the TK47 treatment compared to KCl given that Thermopotash contains Si (Table 1) and that this Si is available to the soil (Figures 4D and 5D) and plant (Figure 3C).

Figure 4
Effects of K levels and sources on soil availability of K, Ca, Mg, and Si in the 0-20 cm soil layer after the sugarcane harvest for variety SP832847, 2011/12 and 2012/13 crops (Usina Vale do São Simão, Chaveslandia, Minas Gerais State, Brazil).

Table 5
Effects of K levels and sources on soil availability of K, Ca, Mg, and Si in the 20-40 cm soil layer after the sugarcane harvest for variety SP832847, 2011/12 and 2012/13 crops (Usina Vale do São Simão, Chaveslandia, Minas Gerais State, Brazil).

Sugarcane has a high demand for potassium. The response of sugarcane to potassium fertilization is dependent on the available K of the soil (Kumawat, Rajawat, & Rathod, 2016Kumawat, P. D., Rajawat, B. S., & Rathod, A. D. (2016). Role of potassium nutrition in improving growth, yield and quality of sugarcane. Asian Journal of Science and Technology, 7(9), 3609-3613.). Available K at both depths and after the first and second sugarcane harvests is considered low and very low (as classified by Raij, 2011Raij, B. V. (2011). Fertilidade do solo e manejo dos nutrientes. Piracicaba, SP: Editora International Plant Nutrition Institute.) for the KCl treatment, respectively, while they are considered adequate for TK47, thereby demonstrating the residual effect of the Thermopotash. According to Chiba, Natale, Cruz, Teixeira, and Centurion (2008Chiba, M. K., Natale,W., Cruz, M. C. P., Teixeira, L. A. J., & Centurion, J. F. (2008). Potássio nas frações texturais de um Latossolo. Acta Scientiarum. Agronomy, 30(4), 581-587. doi: 10.4025/actasciagron.v30i4.5321.
https://doi.org/10.4025/actasciagron.v30...
), the amount of K absorbed by the plants was often greater than the variation of exchangeable K content, suggesting that non ex changeable forms are being taken up.

The TK47 fertilizer yielded higher soil Ca after both harvests in the 0-20 cm layer (Table 4) and in the 20-40 cm layer (Table 5), except at 0 kg ha-1 K2O for both layers and in the 20-40 cm layer at 50 and 100 kg ha-1 K2O (after the first and second harvests). This soil Ca availability is greater than 0.7 cmolc dm-3 and is therefore considered high (Raij et al., 2001Raij, B. van, Andrade, J. C., Cantarella, H., & Quaggio, J. A. (2001). Análise química para avaliação da fertilidade de solos tropicais. Campinas, SP: Editora do Instituto Agronômico.). The higher levels of available soil Ca in the TK47 fertilizer treatments are a result (Table 1) of the limestone used in the production of this fertilizer. The application of KCl and the TK47 fertilizers did not affect soil Mg availability in the 0-20 cm (Table 4) and 20-40 cm (Table 5) layers after the first and second harvests. According to Raij (2011Raij, B. V. (2011). Fertilidade do solo e manejo dos nutrientes. Piracicaba, SP: Editora International Plant Nutrition Institute.), soil Mg availability is considered high when it is greater than 0.8 cmolc dm-3, a level that was not achieved in the present study.

Polynomial regressions showed that there was a linear fit only for Mehlich K (Figure 4), Ca (Figure 4B), and Si (Figure 4D) in the 0-20 cm soil layer after the first harvest. The K and Si availability increased, whereas the soil Ca decreased with higher TK47 fertilizer application levels. Conversely, soil Si decreased with higher KCl application levels. After the second harvest, soil K availability (Figure 4A) increased with higher K application levels for both sources. However, Si availability only increased with higher TK47 fertilizer levels (Figure 4D). A quadratic fit was found between soil Mg (0-20 cm layer) and KCl availability (Figure 4C). Soil Mg increased until a maximum of 0.71 cmolc dm-3 with an application of 85 kg ha-1 K2O (KCl), and at higher application levels, soil Mg tended to decrease. In the 20-40 cm layer, after the first and second harvests, higher TK47 fertilizer applications increased soil K (Figure 5A), Ca (Figure 5B) and Si (Figure 5D). Mg (Figure 5C) and soil pH (Figure 5E) also increased with greater TK47 fertilizer applications, but only after the first harvest.

The aim of this experiment was not to evaluate the corrective capacity of this fertilizer; therefore, lime was applied at recommended levels throughout. Nevertheless, the TK47 fertilizer did neutralise soil acidity because of the Ca and Mg oxides in this product.

Sandy soils with low levels of organic matter have low cation-exchange capacity (CEC) and therefore retain small amounts of cations and are more susceptible to nutrient leaching (Raij, 2011Raij, B. V. (2011). Fertilidade do solo e manejo dos nutrientes. Piracicaba, SP: Editora International Plant Nutrition Institute.). Thus, the higher soil pH caused by the TK47 fertilizer probably contributed to a higher soil CEC that in turn led to the greater availability of K, Ca, and Mg in the soil and consequently the sugarcane. This occurs because the soil used in the present study has a low CEC (Raij, 2011Raij, B. V. (2011). Fertilidade do solo e manejo dos nutrientes. Piracicaba, SP: Editora International Plant Nutrition Institute.) and contains clay minerals with predominantly pH-dependent charges. Additionally, it was found that in the 20-40 cm layer, after the first harvest, KCl reduced Ca (Figure 5B) and Mg (Figure 5C) availability as soil K availability increased. This was probably due to the chlorine released from the KCl.

According to Raij et al. (2001Raij, B. van, Andrade, J. C., Cantarella, H., & Quaggio, J. A. (2001). Análise química para avaliação da fertilidade de solos tropicais. Campinas, SP: Editora do Instituto Agronômico.), most soils have a predominance of negative charges, and anions such as NO3, Cl- and SO4- are not adsorbed and can thus be leached. These anions in the soil solution obey the electroneutrality principle and thus carry equivalent quantities of cations such as Ca2+, Mg2+, and K+.

Therefore, many of the Cl- anions stay in soil solution and can take up cations. This may have occurred with Ca and Mg, which decreased with higher levels of K from KCl.

In the current experiment, the highest sugarcane productivity was achieved with the application of 121 kg ha-1 K2O. The application level to be used for the TK47 fertilizer is a viable 1.72 t ha-1. Even though the K level in TK47 (7% K2O) is low, its effect is residual, avoiding the need for repeated applications. Furthermore, TK47 can also supply other nutrients (Ca, Mg, and Si) and increase soil pH.

Figure 5
Effects of K levels and sources on soil availability of K, Ca, Mg, and Si and pH in the 20-40 cm soil layer after the sugarcane harvest for variety SP832847, 2011/12 and 2012/13 crops (Usina Vale do São Simão, Chaveslandia, Minas Gerais State, Brazil). TK47 = Thermopotash; KCl = Potassium chloride; 5% significance level (*).

Conclusion

The TK47 fertilizer has a residual effect and can be used as a K source for sugarcane. This source of poorly water-soluble K was not initially advantageous compared to soluble sources, but over time, this source was found to be superior to soluble sources.

The maximum expected productivity of sugarcane variety SP832847 using TK47 fertilizer is 132.61 t ha-1 at an application level of 121 kg ha-1 K2O.

The TK47 fertilizer applied to the sugarcane plant provided K, Si, Ca, and Mg and raised the soil pH in both the cane crop and the first ratoon crop.

Acknowledgements

We are grateful to the Brazilian organisations Capes, Fapemig and CNPq. We are also grateful to Verde Fertilizante for supplying Thermopotash and to the owners and employees of the Usina Vale do São Simão.

References

  • Chiba, M. K., Natale,W., Cruz, M. C. P., Teixeira, L. A. J., & Centurion, J. F. (2008). Potássio nas frações texturais de um Latossolo. Acta Scientiarum. Agronomy, 30(4), 581-587. doi: 10.4025/actasciagron.v30i4.5321.
    » https://doi.org/10.4025/actasciagron.v30i4.5321.
  • Ciceri, D., Manning, D. A. C., & Allanore, A. (2015). Historical and technical developments of potassium resources. Science of The Total Environment, 502(2), 590-601. doi: 10.1016/j.scitotenv.2014.09.013.
    » https://doi.org/10.1016/j.scitotenv.2014.09.013.
  • Datnoff, L. E., Snyder, G. H., & Korndörfer, G. H. (2001). Silicon in agriculture Amsterdam, NE: Elsevier.
  • Duarte, I. N., Sousa, R. T. X., Korndorfer, G. H., & Pereira, H. S. (2015). Alternative potash fertilizer source for millet crop. Journal of Plant Nutrition, 38(12), 1961-1972. doi: 10.1080/01904167.2015.1009097.
    » https://doi.org/10.1080/01904167.2015.1009097.
  • Fageria, N. K., Baligar, V. C., & Jones, C. A. (2011). Growth and mineral nutrition of field crops (3rd ed.). London, UK: CRC Press.
  • Ferreira, D. F. (2011). SISVAR: Um sistema computacional de análise estatística. Ciência e Agrotecnologia, 35(6), 1039-1042. doi: 10.1590/S1413-70542011000600001.
    » https://doi.org/10.1590/S1413-70542011000600001.
  • Kumawat, P. D., Rajawat, B. S., & Rathod, A. D. (2016). Role of potassium nutrition in improving growth, yield and quality of sugarcane. Asian Journal of Science and Technology, 7(9), 3609-3613.
  • Manning, D. A. C. (2010). Mineral sources of potassium for plant nutrition. Agronomy for Sustainable Development, 30(2), 281-294. doi: 10.1051/agro/2009023.
    » https://doi.org/10.1051/agro/2009023.
  • McCray, J. M., Ji, S., Powell, G., Montes, G., Perdomo, R., & Luo, Y. (2010). Boundary lines used to determine sugarcane production limits at leaf nutrient concentrations less than optimum. Communications in Soil Science and Plant Analysis, 41(5), 606-622. doi: 10.1080/00103620903531185.
    » https://doi.org/10.1080/00103620903531185.
  • Ministério da agricultura, Pecuária e Abastecimento. [MAPA] (2017). Manual de métodos analíticos oficiais para fertilizantes e corretivos Brasília, DF: MAPA.
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Publication Dates

  • Publication in this collection
    2018

History

  • Received
    23 Mar 2017
  • Accepted
    17 Oct 2017
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