Nitrogen and Potassium in Narrow-Row Cotton

Kappes, Claudinei; Zancanaro, Leandro; Francisco, Eros Artur Bohac

doi:10.1590/18069657rbcs20150103

ABSTRACT

Information on fertilizer management for cotton in narrow-row cropping system is scarce; therefore, studies are needed to improve nutrient stewardship for such systems. The aim of this study was to evaluate the effects of nitrogen and potassium application on yield and fiber quality of cotton under a narrow-row system. A field trial was carried out for three years, where the treatments were set up in an incomplete factorial arrangement [(4 × 4) + 1] under a randomized block design, with four N rates (20, 40, 60, and 80 kg ha^-1), four K₂O rates (0, 40, 80, and 120 kg ha^-1), and one control (no N or K₂O), for a total of 17 treatments, with four replicates. Urea and potassium chloride were applied on the soil surface 20 days after crop emergence. Varieties used were FMT 701 (2009/2010 and 2010/2011) and FMT 709 (2011/2012). Cotton yield and fiber quality parameters were measured. In the narrow-row cropping system, cotton lint yield was positively affected by N and K application. Cotton yield in relation to K applications was not dependent on N rates. Potassium application increased the micronaire index and fiber resistance, whereas high N rates reduced fiber resistance.

Gossypium hirsutum; nitrogen; potassium; narrow-row cotton

INTRODUCTION

Cotton (Gossypium hirsutum L.) has been grown in different row spacing systems, such as conventional (≥0.9 m), narrow row (0.39 to 0.76 m), and ultra-narrow row (0.19 to 0.38 m), with populations ranging from 50,000 to 320,000 plants ha^-1 (Silva et al., 2006Silva AV, Chiavegato EJ, Carvalho LH, Kubiak DM. Crescimento e desenvolvimento do algodoeiro em diferentes configurações de semeadura. Bragantia. 2006;65:407-11.). Narrow-row-space cotton, originally studied and cultivated in marginal lands of the American cotton belt and in Australia, was brought to Brazil as a development to shorten the season, hence reducing production costs (Yamaoka and Belot, 2011Yamaoka RS, Belot JL. Sistema de produção do algodão adensado. In: Freire EC, editor. Algodão no Cerrado do Brasil. 2ª. ed. Aparecida de Goiânia: Abrapa; 2011. p.827-66.; Alves et al., 2012Alves LRA, Gottardo LCB, Ferreira Filho JBS, Osaki M, Ribeiro RG, Ykeda VY. Custo de produção de algodão em sistema adensado no Estado de Mato Grosso/Brasil. Custos Agroneg. 2012;8:24-42.).

Growing cotton as a second crop in narrow-row after soybeans, in the same season, was a system initially suggested in Mato Grosso, Brazil, in 2009, with this configuration: (i) seeding time ranging from mid-January to early February, following the soybean harvest, (ii) row spacing from 0.45 to 0.5 m, and (iii) double the plant population used in conventional systems. Lower water availability and temperature during the second crop decreases yield per plant, but benefits cotton yield per hectare in response to higher population (Gottardo, 2012Gottardo LCB. Resposta do algodoeiro adensado ao nitrogênio no cultivo em sucessão [dissertação]. Piracicaba: Escola Superior de Agricultura Luiz de Queiroz; 2012.).

Narrow row spacing in cotton favors intensification of the cropping system, with the possibility of growing two crops within a season and its use in crop rotation. However, information on nutrient management in the narrow-row cropping system is scarce, and farmers apply the same fertilizer strategy used for conventional cotton with no further criteria (Carvalho et al., 2011cCarvalho MCS, Ferreira GB, Staut, LA. Nutrição, calagem e adubação do algodoeiro. In: Freire EC, editor. Algodão no Cerrado do Brasil. 2ªed. Aparecida de Goiânia: Abrapa; 2011c. p.677-752.), which demonstrates the need for research in this area.

Nutrient application, especially N and K, is crucial for high yield cotton. Higher rates of N may be required in narrow row spacing due to higher populations compared to conventional systems. Nevertheless, excessive use of N can reduce yield because plants will grow taller and take longer to mature (Bell et al., 2003Bell PF, Boquet DJ, Millhollon E, Moore S, Ebelhar W, Mitchell CC, Varco J, Funderburg ER, Kennedy C, Breitenbeck GA, Craig C, Holman M, Baker W, Mcconnell JS. Relationships between leaf-blade nitrogen and relative seed cotton yields. Crop Sci. 2003;43:1367-74. doi:10.2135/cropsci2003.1367), which is not desired in narrow-row systems. Hence, N rates must be appropriate for avoiding excessive growth in a long cycle.

Application of high N rates in narrow-row cotton is restrictive since plants grow under low water and temperature as of May, reducing crop response to N, and excessive plant growth may require higher rates of plant growth regulator (Yamaoka and Belot, 2011Yamaoka RS, Belot JL. Sistema de produção do algodão adensado. In: Freire EC, editor. Algodão no Cerrado do Brasil. 2ª. ed. Aparecida de Goiânia: Abrapa; 2011. p.827-66.). The narrow-row cotton did not require higher N rates compared to conventional spacing, and that recommended rates must be based on expected yield and on factors related to crop response to N (Carvalho et al., 2011bCarvalho MCS, Ferreira ACB, Borin AL. Adubação NPK do algodoeiro adensado de safrinha no cerrado de Goiás. In: Anais do 8º. Congresso Brasileiro de Algodão; 1ª. Cotton EXPO [CD-ROM]; 2011; São Paulo. Campina Grande: Embrapa Algodão; 2011b. p.1495-502.).

Cotton takes up great amounts of K, which plays an important role in plant development and fiber quality (Carvalho et al., 2011cCarvalho MCS, Ferreira GB, Staut, LA. Nutrição, calagem e adubação do algodoeiro. In: Freire EC, editor. Algodão no Cerrado do Brasil. 2ªed. Aparecida de Goiânia: Abrapa; 2011c. p.677-752.). However, one hypothesis is that narrow-row cotton may demand more N and K during the boll filling stages in response to higher plant population and low availability of these nutrients because of water shortage in the soil, leading to the need for higher application rates. Research data on this subject have not been conclusive so far. The objective of this study is to evaluate the effect of N and K application on gross and lint yield and on fiber quality of cotton in narrow-row spacing systems.

MATERIALS AND METHODS

Field trial

The study was carried out in an experimental station in Itiquira, Mato Grosso, Brazil, located at 17° 09’ S and 54° 42’ W, 490 m asl, in a Latossolo Vermelho Distrófico (Santos et al., 2013Santos HG, Jacomine PKT, Anjos LHC, Oliveira VA, Lumbreras JF, Coelho MR, Almeida JA, Cunha TJF, Oliveira JB, editores. Sistema brasileiro de classificação de solos. 3ª. ed. Brasília, DF: Embrapa; 2013.), a Typic Haplorthox (Soil Survey Staff, 2014Soil Survey Staff. Keys to soil taxonomy. 12th.ed. Washington, DC: United States Department of Agriculture, Natural Resources Conservation Service; 2014.), of the Cerrado (Brazilian tropical savanna), where the climate type is Aw with dry winters, according to Köppen classification (Ribeiro and Walter, 1998Ribeiro JF, Walter BMT. Fitofisionomias do bioma Cerrado. In: Sano SM, Almeida SP, editores. Cerrado: ambiente e flora. Planaltina: Embrapa Cerrados; 1998. p.89-166.), with average rainfall ranging from 1,200 to 1,800 mm per year and average temperature between 22 and 23 °C (Figure 1). Soil characteristics are shown in table 1.

Figure 1
Daily values of rainfall and average temperature in the 2009/10, 2010/11, and 2011/12 crop seasons (arrows indicate seeding time).

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Table 1
Soil properties of the 0.0-0.2 and 0.2-0.4 m layers before the beginning of the trial

Land use in the area had been for cattle grazing (Urochloa decumbens L.) for 18 years prior to the start of the trial in the fall of 2008, at which time the following operations were performed: disking (14 × 32”) to a 0.2 m depth, subsoiling to a depth of 0.3 m, liming (4 Mg ha^-1), and disking (14 × 32”) to a 0.2 m depth. Afterwards, Millet sp. was sown as cover crop. The trial was set up in 2009 after desiccation of the cover crop, which was carried out for three consecutive seasons, the period of the experiment. Cotton was grown in the fall after summer fallow.

Treatments and experimental design

The field trial was set up in a completely randomized block design in an incomplete factorial arrangement [(4 × 4) + 1], with four N rates (20, 40, 60, and 80 kg ha^-1), four K₂O rates (0, 40, 80, and 120 kg ha^-1), and one additional treatment (control, no NK), with four replicates. Treatments were applied by hand using urea (45 % of N) as a source of N, and potassium chloride (60 % of K₂O) as a source of K, broadcasting these fertilizers 20 days after seedling emergence. Plots were 6.3 m wide by 6.0 m long. All treatment plots, except the control, received 30 kg ha^-1 N plus 40 kg ha^-1 K₂O in the planting furrow as a starter.

Field trial activities

For trial set-up, a disk seeder was used to mark the rows, then 0.1 m deep furrows were opened by hand and 70 kg ha^-1 P₂O₅ plus 2.5 kg ha^-1 B were applied, annually, via triple superphosphate and Borogran (oxi-sulphate B source), respectively. After that, the furrows were closed and the seeder was driven over the plots, seeding 10 cotton seeds per meter. In the 2010/11 and 2011/12 seasons, all plots received phosphogypsum application at the rate of 0.3 and 3.0 Mg ha^-1, respectively, prior to cotton seeding. The cotton variety used in the 2009/10 and 2010/11 seasons was FMT 701, while in the 2011/12 season, the variety was FMT 709. Seeds were treated with fungicides (carbendazin + thiram: 30 + 70 g/100 kg seeds; plus thiamethoxam: 70 g/100 kg seeds) and sowed on Jan. 25, 2010, Jan. 21, 2011, and Jan. 25, 2012 in the respective crop seasons. Weed, insect, and disease control was carried out according to regional recommendations. A growth regulator (mepiquat chloride) was applied as necessary.

Parameters and statistics

The nutritional status of the plants was evaluated annually via leaf analysis sampling, according to Zancanaro and Kappes (2012)Zancanaro L, Kappes C. Levantamento da área, amostragem de solo e de folhas. In: Belot JL, editor. Manual de boas práticas de manejo do algodoeiro em Mato Grosso. Cuiabá: IMAmt/AMPA; 2012. p.54-6.. Lab analysis for macronutrient content was performed according to Malavolta et al. (1997)Malavolta E, Vitti GC, Oliveira SA. Avaliação do estado nutricional das plantas: princípios e aplicações. 2ª. ed. Piracicaba: Potafos; 1997.. Just before harvest, final population and plant height were measured in two rows of 4.0 m length at two different spots in each plot. At harvest (which took place on Jul. 29, 2010, Jul. 26, 2011, and Aug. 2, 2012, respectively), 20 ready-for-harvest bolls were collected from each plot to determine boll weight and lint percentage. In addition, all the bolls from plants present in two rows of 4.0 m length at two different spots in each plot were collected and weighed to determine gross yield. After that, a sample from each plot was sent for analysis of lint quality using the HVI method.

After harvest, soil samples were collected using a probe at twelve points in each plot (eight points in the rows plus four points between rows) at a depth of 0.2 m. Samples were analyzed according to Claessen (1997)Claessen MEC, organizador. Manual de métodos de análise de solo. 2ª ed. Rio de Janeiro: Centro Nacional de Pesquisa de Solos; 1997.. Data were subjected to ANOVA and regression analysis using the software Assistat (Silva and Azevedo, 2002Silva FAS, Azevedo CAV. Versão do programa computacional Assistat para o sistema operacional Windows. Rev Bras Produc Agroind. 2002;4:71-8.).

RESULTS AND DISCUSSION

Yield parameters

Throughout the period of this study, plant population was not affected by any of the treatments, and there was no interaction effect of the factors studied on any yield parameter (Table 2). Nevertheless, N and K rates positively affected plant height in the second year (2010/11), while K rates alone affected it in 2011/12. In both seasons, plant height was higher when N and K were applied as compared to the control. The linear response of this parameter to N rates (Figure 2a), which is in agreement with Carvalho et al. (2011a), who concluded that N rates (16, 64, 144, and 256 kg ha^-1 N) caused a linear increase in plant height of narrow-row-space cotton (0.45 m).

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Table 2
Analysis of variance, coefficients of variation (CV), and mean values for plant population (PP), plant height (PH), boll weight (BW), lint percentage (LP), gross yield (GY), micronaire (Mic), strength (Str), mean length (Len), short fiber index (SFI), elongation (Elg), uniformity index (Unf), and maturity (Mat) of cotton fiber in a narrow-row-space system in response to nitrogen and potassium application, in the 2009/10, 2010/11, and 2011/12 crop seasons

Figure 2
Plant height and gross yield of narrow-row-space cotton in response to nitrogen rates applied in the 2009/10, 2010/11, and 2011/12 crop seasons. **: significant at 1 % by F test.

The NPK supply on narrow-row-space cotton in the Cerrado of the state of Goiás was studied by Carvalho et al. (2011b), which found no interaction effect on plant height, but only an isolated effect from N rates (40, 80, and 120 kg ha^-1 N) on a linear increase in plant height in the second year of the study. Authors emphasized that increasing plant height for narrow-row-space cotton is not desirable because it interferes with harvest. Furthermore, high N rates lead the plants into continuous growth, lengthening the cycle and reducing yield (Bell et al., 2003Bell PF, Boquet DJ, Millhollon E, Moore S, Ebelhar W, Mitchell CC, Varco J, Funderburg ER, Kennedy C, Breitenbeck GA, Craig C, Holman M, Baker W, Mcconnell JS. Relationships between leaf-blade nitrogen and relative seed cotton yields. Crop Sci. 2003;43:1367-74. doi:10.2135/cropsci2003.1367). Other studies found similar results of N rates leading to taller plants (Bogiani et al., 2011Bogiani JC, Ferreira GB, Smiderle OJ, Mourão Júnior M, Borin ALDC. Adubação com potássio e nitrogênio de cultivares de algodoeiro sob sistema de cultivo adensado. In: Anais do 8º Congresso Brasileiro de Algodão; 1ª Cotton EXPO [CD-ROM]; 2011; São Paulo. Campina Grande: Embrapa Algodão; 2011. p.1451-58.; Gottardo, 2012Gottardo LCB. Resposta do algodoeiro adensado ao nitrogênio no cultivo em sucessão [dissertação]. Piracicaba: Escola Superior de Agricultura Luiz de Queiroz; 2012.; Galhardo et al., 2013Galhardo, LNA, Carvalho, MCS, Santos, LN, Ferreira, ACB, Borin, AL Adubação NPK do algodoeiro em cultivo adensado de safrinha no Cerrado de Goiás - safra 2010/11. In: Anais do 34º. Congresso Brasileiro de Ciência do Solo [CD-ROM]; 2013; Florianópolis. Florianópolis: Sociedade Brasileira de Ciência do Solo; 2013.).

Increasing K rates promoted linear response in plant height in the 2010/11 and 2011/12 crop seasons (Figure 3a), but no effect was observed in the first year (2009/10). Furthermore, Kaneko et al. (2014)Kaneko FH, Leal AJF, Dias AR, Anselmo JL, Buzetti S, Dal Bem EA, Gitti DC, Nascimento V. Resposta do algodoeiro em cultivo adensado a doses de nitrogênio, fósforo e potássio. Rev Agrarian. 2014;7:382-9. did not observe any effect of K rates (0, 60, 80, 100, and 120 kg ha^-1 K₂O) on plant height of narrow-row-space cotton, in agreement with other studies (Bogiani et al., 2011Bogiani JC, Ferreira GB, Smiderle OJ, Mourão Júnior M, Borin ALDC. Adubação com potássio e nitrogênio de cultivares de algodoeiro sob sistema de cultivo adensado. In: Anais do 8º Congresso Brasileiro de Algodão; 1ª Cotton EXPO [CD-ROM]; 2011; São Paulo. Campina Grande: Embrapa Algodão; 2011. p.1451-58.; Carvalho et al., 2011b; Freitas et al., 2011Freitas FB, Roque CG, Minotto VA, Leal AJF, Oliveira LA. Avaliação de diferentes doses de potássio na cultura do algodão adensado. In: Anais do 33º. Congresso Brasileiro de Ciência do Solo [CD-ROM]; 2010; Uberlândia. Uberlândia: Sociedade Brasileira de Ciência do Solo; 2011.; Galhardo et al., 2013Galhardo, LNA, Carvalho, MCS, Santos, LN, Ferreira, ACB, Borin, AL Adubação NPK do algodoeiro em cultivo adensado de safrinha no Cerrado de Goiás - safra 2010/11. In: Anais do 34º. Congresso Brasileiro de Ciência do Solo [CD-ROM]; 2013; Florianópolis. Florianópolis: Sociedade Brasileira de Ciência do Solo; 2013.). The results for plant height observed in this study (Table 2) are considered adequate for narrow-row-space cotton to be harvested using the stripper system, as pointed out by Silva et al. (2010)Silva ORRF, Sofiatti V, Belot JL. A colheita do algodão adensado. In: Belot JL, Vilela PA, editores. O sistema de cultivo do algodoeiro adensado em Mato Grosso. Cuiabá: Defanti; 2010. p.293-309.: 0.53, 0.58, and 0.72 m in 2009/10, 2010/11, and 2011/12, respectively.

Figure 3
Plant height and gross yield of narrow-row-space cotton in response to potassium rates applied in the 2009/10, 2010/11, and 2011/12 crop seasons. **: significant at 1 % by F test.

Gross yield of narrow-row-space cotton was positively influenced by K rates (years 1 and 2) and N rates (year 2) as well (Table 2). The effect of N rates on gross yield, and a linear model fitted to data of the 2010/11 season allows calculation of 5.7 kg of gross yield per kg of N applied (Figure 2b). The highest values of gross yield observed with 80 kg ha^-1 N represented an increase of 24 % as compared to the lowest rate applied (20 kg ha^-1 N). Such results are in agreement with other studies (Bogiani et al., 2011Bogiani JC, Ferreira GB, Smiderle OJ, Mourão Júnior M, Borin ALDC. Adubação com potássio e nitrogênio de cultivares de algodoeiro sob sistema de cultivo adensado. In: Anais do 8º Congresso Brasileiro de Algodão; 1ª Cotton EXPO [CD-ROM]; 2011; São Paulo. Campina Grande: Embrapa Algodão; 2011. p.1451-58.; Gottardo, 2012Gottardo LCB. Resposta do algodoeiro adensado ao nitrogênio no cultivo em sucessão [dissertação]. Piracicaba: Escola Superior de Agricultura Luiz de Queiroz; 2012.; Galhardo et al., 2013Galhardo, LNA, Carvalho, MCS, Santos, LN, Ferreira, ACB, Borin, AL Adubação NPK do algodoeiro em cultivo adensado de safrinha no Cerrado de Goiás - safra 2010/11. In: Anais do 34º. Congresso Brasileiro de Ciência do Solo [CD-ROM]; 2013; Florianópolis. Florianópolis: Sociedade Brasileira de Ciência do Solo; 2013.) that observed higher values for gross yield of narrow-row cotton in response to N rates.

Effect of NPK supply on the yield of narrow-row cotton grown after soybean harvest was studied by Carvalho et al. (2011b), which found an increase of 8.4 % from the lowest (40 kg ha^-1 N) to the highest (120 kg ha^-1 N) rate of N applied. The authors concluded that narrow-row cotton did not demand more N than conventional cotton and that rate recommendation should be based on expected yield and other factors limiting response to N fertilization.

Regarding the effects of K rates on gross yield, linear models fitted to data show that 3.4 and 5.3 kg ha^-1 of cotton yield were obtained per kg ha^-1 of K₂O applied in the 2009/10 and 2010/11 crop seasons, respectively (Figure 3b). The higher values of gross yield observed with 120 kg ha^-1 K₂O represented an increase of 81 and 54 % in the first two years of the study, respectively, as compared to the control. Such a significant positive response is in agreement with the fact that K is the nutrient that is most taken up and its supply is crucial for plant development and high yields, as pointed out by Carvalho et al. (2011c).

Other studies reported the positive effect of K supply on narrow-row cotton yield (Bogiani et al., 2011Bogiani JC, Ferreira GB, Smiderle OJ, Mourão Júnior M, Borin ALDC. Adubação com potássio e nitrogênio de cultivares de algodoeiro sob sistema de cultivo adensado. In: Anais do 8º Congresso Brasileiro de Algodão; 1ª Cotton EXPO [CD-ROM]; 2011; São Paulo. Campina Grande: Embrapa Algodão; 2011. p.1451-58.; Freitas et al., 2011Freitas FB, Roque CG, Minotto VA, Leal AJF, Oliveira LA. Avaliação de diferentes doses de potássio na cultura do algodão adensado. In: Anais do 33º. Congresso Brasileiro de Ciência do Solo [CD-ROM]; 2010; Uberlândia. Uberlândia: Sociedade Brasileira de Ciência do Solo; 2011.). In contrast, Carvalho et al. (2011b), Sofiatti et al. (2013)Sofiatti V, Bogiani J, Pedrosa MB, Azevedo D, Alencar A, Silva L. Adubações nitrogenada e potássica de cobertura no algodoeiro em sistema adensado no oeste da Bahia. In: Anais do 9º. Congresso Brasileiro de Algodão; 2013; Brasília. Brasília, DF: AMPA/Abrapa; 2013., and Kaneko et al. (2014)Kaneko FH, Leal AJF, Dias AR, Anselmo JL, Buzetti S, Dal Bem EA, Gitti DC, Nascimento V. Resposta do algodoeiro em cultivo adensado a doses de nitrogênio, fósforo e potássio. Rev Agrarian. 2014;7:382-9. did not observe higher yields of narrow-row cotton from increasing K rates. According to the last two studies cited, the reasons might be: (i) K recycling from deeper layers of the soils by cover crops in rotation, and (ii) soil K level was already adequate for high yield (63 mg dm^-3 in the top 0.2 m). In the third year of this study, no effect on lint percentage or gross yield was observed in response to N or K application (Table 2). This may be explained by the residual effect of previous applications in the first two years.

The values for gross yield observed in this study are below the yield attainable for narrow-row cotton in Mato Grosso, based on the most recent seasons (Conab, 2015Companhia Nacional de Abastecimento - Conab. Acompanhamento da safra brasileira: grãos, 12º levantamento, julho/2015. Brasília, DF: 2015.). This may be related to the low soil fertility at the beginning of the trial, the time of seeding, the weather conditions, and to the row spacing applied. In the first year, a severe drought that occurred in April 2010 as plants were filling their bolls had a significant impact on yield (Figure 1). This is important to mention because weather conditions in the season can greatly impact yield, and water is the most limiting factor. Hence, to grow cotton in a narrow-row system as a second crop, even before analyzing nutrient supply, it is important to evaluate the soil capability to supply water to the crop throughout the cycle, and lower yields may be expected compared to conventional systems.

In all seasons, a significant effect of treatments over the control was observed on lint percentage (Table 2). In the first two years, K rates affected lint percentage positively and by the quadratic model that was fitted, it was possible to calculate the K rate that promoted the maximum values for each season: 45.4 % at 115 kg ha^-1 K₂O in the 2009/2010 crop season, and 39.2 % at 50 kg ha^-1 K₂O in the 2010/2011 crop season (Figure 4a). Nevertheless, Carvalho et al. (2011b) showed no response of lint percentage to K rates (40, 80, and 120 kg ha^-1 of K₂O), but instead a positive response to N. Other studies corroborate the results of this study where no effect of N rates was observed on lint percentage (Carvalho et al., 2011a; Gottardo, 2012Gottardo LCB. Resposta do algodoeiro adensado ao nitrogênio no cultivo em sucessão [dissertação]. Piracicaba: Escola Superior de Agricultura Luiz de Queiroz; 2012.; Galhardo et al., 2013Galhardo, LNA, Carvalho, MCS, Santos, LN, Ferreira, ACB, Borin, AL Adubação NPK do algodoeiro em cultivo adensado de safrinha no Cerrado de Goiás - safra 2010/11. In: Anais do 34º. Congresso Brasileiro de Ciência do Solo [CD-ROM]; 2013; Florianópolis. Florianópolis: Sociedade Brasileira de Ciência do Solo; 2013.).

Figure 4
Lint percentage, micronaire, and boll weight of narrow-row-space cotton in response to potassium rates applied in the 2009/10, 2010/11, and 2011/12 crop seasons. ** and *: significant at 1 and 5 %, respectively, by F test.

Boll weight was positively affected by K rates in 2009/10 and 2010/11 (Table 2), while in 2011/12 there was significant difference between treatments and control for this variable. As observed for plant height, K rates resulted in a linear response of boll weight (Figure 4c), which is in agreement with Freitas et al. (2011)Freitas FB, Roque CG, Minotto VA, Leal AJF, Oliveira LA. Avaliação de diferentes doses de potássio na cultura do algodão adensado. In: Anais do 33º. Congresso Brasileiro de Ciência do Solo [CD-ROM]; 2010; Uberlândia. Uberlândia: Sociedade Brasileira de Ciência do Solo; 2011., who studied the effect of K rates (0, 40, 80, 100, and 120 kg ha^-1 of K₂O) on narrow-row-space cotton. Potassium is a nutrient that plays a direct role in metabolism of carbohydrates, which is directly related to the fiber components. However, some studies present opposite results: Carvalho et al. (2011b), Galhardo et al. (2013)Galhardo, LNA, Carvalho, MCS, Santos, LN, Ferreira, ACB, Borin, AL Adubação NPK do algodoeiro em cultivo adensado de safrinha no Cerrado de Goiás - safra 2010/11. In: Anais do 34º. Congresso Brasileiro de Ciência do Solo [CD-ROM]; 2013; Florianópolis. Florianópolis: Sociedade Brasileira de Ciência do Solo; 2013., and Kaneko et al. (2014)Kaneko FH, Leal AJF, Dias AR, Anselmo JL, Buzetti S, Dal Bem EA, Gitti DC, Nascimento V. Resposta do algodoeiro em cultivo adensado a doses de nitrogênio, fósforo e potássio. Rev Agrarian. 2014;7:382-9. reported no effect of K rates on boll weight. Regarding N rates, no effect was observed on boll weight, as also found by Carvalho et al. (2011aCarvalho LH, Silva NM, Kondo JI, Chiavegato EJ, Almeida WP, Carvalho HR. Diferentes doses de nitrogênio e cloreto de mepiquat em plantio adensado do algodoeiro, na presença de nematoides. In: Anais do 8º. Congresso Brasileiro de Algodão; 1ª Cotton EXPO [CD-ROM]; 2011; São Paulo. Campina Grande: Embrapa Algodão; 2011a. p.913-7.,bCarvalho MCS, Ferreira ACB, Borin AL. Adubação NPK do algodoeiro adensado de safrinha no cerrado de Goiás. In: Anais do 8º. Congresso Brasileiro de Algodão; 1ª. Cotton EXPO [CD-ROM]; 2011; São Paulo. Campina Grande: Embrapa Algodão; 2011b. p.1495-502.), which may be related to its role as a nutrient in the plant. Unlike K, in which one of the functions is to help with transport of carbohydrates into the bolls, N is responsible for adjusting the plant cycle and promoting fiber quality, especially related to strength, length, and micronaire (Carvalho et al., 2011cCarvalho MCS, Ferreira GB, Staut, LA. Nutrição, calagem e adubação do algodoeiro. In: Freire EC, editor. Algodão no Cerrado do Brasil. 2ªed. Aparecida de Goiânia: Abrapa; 2011c. p.677-752.), that is, it makes no direct contribution to fiber weight.

Fiber quality

In the 2009/10 and 2010/11 crop seasons, micronaire was positively affected by K rates (Table 2), and a significant effect was observed between all treatments compared to the control. In the third year, only the latter effect described was observed. The micronaire presented a linear response to K rates in the first two seasons (Figure 4b), which is in agreement with Carvalho and Ferreira (2006)Carvalho MCS, Ferreira GB. Calagem e adubação do algodoeiro no Cerrado. Campina Grande: Embrapa Algodão; 2006. (Circular Técnica, 92). and Carvalho et al. (2011c)Carvalho MCS, Ferreira GB, Staut, LA. Nutrição, calagem e adubação do algodoeiro. In: Freire EC, editor. Algodão no Cerrado do Brasil. 2ªed. Aparecida de Goiânia: Abrapa; 2011c. p.677-752., who reported better fiber quality in response to K application since its supply helps to regulate the cycle, sustain leaf activity, and promote higher deposit of cellulose inside the fibers, which has a direct impact on micronaire. Despite the benefits of K supply to fiber quality, as also reported by Carvalho and Bernardi (2005)Carvalho MCS, Bernardi ACC. Resposta do algodoeiro à adubação potássica. In: Yamada T, Roberts TL, editores. Potássio na agricultura brasileira. Piracicaba: Associação Brasileira para Pesquisa do Potássio e do Fosfato; 2005. and Echer (2008)Echer FR. Fontes de potássio na adubação de cobertura do algodoeiro: produtividade, diagnose foliar, qualidade de fibras e análise econômica [dissertação]. Presidente Prudente: Universidade do Oeste Paulista; 2008., definition of the right rate of K is important because high rates of this nutrient may negatively affect uptake of other cations, especially Mn.

Fiber resistence was influenced by all factors, and even interaction of the factors of N and K application rate, in the 2010/11 crop season (Table 2). The rest of the parameters evaluated in regard to fiber quality were not affected by the interaction of N and K rates. Higher N rates caused linear reduction in fiber resistence when associated with 40 and 120 kg ha^-1 K₂O (Table 3). In contrast, for the effect of K rates, it was only possible to fit regression models for low rates of N. For the application of 20 kg ha^-1 N, a quadratic model best described the response of fiber resistence to K rates, showing that a value of 34.8 g tex^-1 could be obtained with the application of 75 kg ha^-1 K₂O. For the application of 40 kg ha^-1 N, a linear model was adjusted. For the other rates of N and K, regression analysis did not show any significance.

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Table 3
Strength of fiber from narrow-row-space cotton in response to nitrogen and potassium rates, in the 2010/11 crop season

The short fiber index, elongation, and uniformity index were not influenced by treatments during the period of the study (Table 2). However, a significant effect was observed for elongation in 2010/11 and the uniformity index in response to NK application in 2011/12, compared to the control. Bogiani et al. (2011)Bogiani JC, Ferreira GB, Smiderle OJ, Mourão Júnior M, Borin ALDC. Adubação com potássio e nitrogênio de cultivares de algodoeiro sob sistema de cultivo adensado. In: Anais do 8º Congresso Brasileiro de Algodão; 1ª Cotton EXPO [CD-ROM]; 2011; São Paulo. Campina Grande: Embrapa Algodão; 2011. p.1451-58., Gottardo (2012)Gottardo LCB. Resposta do algodoeiro adensado ao nitrogênio no cultivo em sucessão [dissertação]. Piracicaba: Escola Superior de Agricultura Luiz de Queiroz; 2012., and Sofiatti et al. (2013)Sofiatti V, Bogiani J, Pedrosa MB, Azevedo D, Alencar A, Silva L. Adubações nitrogenada e potássica de cobertura no algodoeiro em sistema adensado no oeste da Bahia. In: Anais do 9º. Congresso Brasileiro de Algodão; 2013; Brasília. Brasília, DF: AMPA/Abrapa; 2013. did not observe any effect of NK application on the length and uniformity index of narrow-row cotton.

According to official classifications from the Brazilian Ministry of Agriculture (Brasil, 2002Brasil. Ministério da Agricultura, Pecuária e Abastecimento. Instrução Normativa nº 63, de 5 de dezembro de 2002. Aprova o regulamento técnico de identidade e de qualidade para a classificação do algodão em pluma. Diário Oficial da União, Brasília, DF, 2002. Seção 1, p.6-8.), using overall mean values as a reference and considering weather conditions, the fiber harvested in this study was classified as high strength (>31 g tex^-1), high elongation (6.8 to 7.6 %), medium micronaire (4.0 to 4.9 µg pol^-1), high uniformity index (>85 %), low short fiber index (6.0 to 9.0 %), and mature (86 to 100 %).

Nutritional parameters

No interaction of N and K rates on leaf nutrient concentration was observed in this study. Nevertheless, leaf N concentration was significantly affected by K rates and by all treatments, compared to the control, in the first year of the study (Table 4). Nitrogen application did not affect leaf N concentration, as reported by other studies such as Gottardo (2012)Gottardo LCB. Resposta do algodoeiro adensado ao nitrogênio no cultivo em sucessão [dissertação]. Piracicaba: Escola Superior de Agricultura Luiz de Queiroz; 2012. and Carvalho et al. (2011b)Carvalho MCS, Ferreira ACB, Borin AL. Adubação NPK do algodoeiro adensado de safrinha no cerrado de Goiás. In: Anais do 8º. Congresso Brasileiro de Algodão; 1ª. Cotton EXPO [CD-ROM]; 2011; São Paulo. Campina Grande: Embrapa Algodão; 2011b. p.1495-502.. In contrast, the results of this study showed a linear increase in leaf N concentration in response to K rates applied (Figure 5a), which is in agreement with Bogiani et al. (2011)Bogiani JC, Ferreira GB, Smiderle OJ, Mourão Júnior M, Borin ALDC. Adubação com potássio e nitrogênio de cultivares de algodoeiro sob sistema de cultivo adensado. In: Anais do 8º Congresso Brasileiro de Algodão; 1ª Cotton EXPO [CD-ROM]; 2011; São Paulo. Campina Grande: Embrapa Algodão; 2011. p.1451-58.. This effect may be explained by the synergy between N and K as related to nitrate translocation in the plant (Ferreira et al., 2007Ferreira GB, Silva Filho JL, Pedrosa MB, Santos JB, Véras R, Alencar AR, Oliveira WP, Freire RMM, Valença AR. Tecnologia de adubação e manejo do algodoeiro no Cerrado da Bahia. In: Silva Filho JL, Pedrosa MB, Santos JB, editores. Pesquisas com algodoeiro no Estado da Bahia - safra 2005/2006. Campina Grande: Embrapa Algodão; 2007. p.59-152. (Documentos, 164).).

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Table 4
Analysis of variance, coefficients of variation (CV), and mean values for leaf macronutrient concentration in narrow-row-space cotton and soil potassium availability in response to nitrogen and potassium application, in the seasons 2009/10, 2010/11, and 2011/12 crop seasons

Figure 5
Leaf concentration of nitrogen (N), potassium (K), calcium (Ca), magnesium (Mg), and sulfur (S) in narrow-row-space cotton in response to potassium rates applied in the 2009/10, 2010/11, and 2011/12 crop seasons. ** and *: significant at 1 and 5 %, respectively, by F test.

Leak P concentration was not affected by any treatment (Table 4), also as reported by Bogiani et al. (2011)Bogiani JC, Ferreira GB, Smiderle OJ, Mourão Júnior M, Borin ALDC. Adubação com potássio e nitrogênio de cultivares de algodoeiro sob sistema de cultivo adensado. In: Anais do 8º Congresso Brasileiro de Algodão; 1ª Cotton EXPO [CD-ROM]; 2011; São Paulo. Campina Grande: Embrapa Algodão; 2011. p.1451-58.. In this study, annual application of 70 kg ha^-1 P₂O₅ was enough to supply P to plants. The NPK supply to narrow-row cotton was studied by Carvalho et al. (2011b), who observed synergy between N and P as leaf P concentration increased along with the N rates applied.

Leak K concentration was positively affected by K rates and all treatments, as compared to the control, in every crop season of this study (Table 4). This result does not agree with Bogiani et al. (2011)Bogiani JC, Ferreira GB, Smiderle OJ, Mourão Júnior M, Borin ALDC. Adubação com potássio e nitrogênio de cultivares de algodoeiro sob sistema de cultivo adensado. In: Anais do 8º Congresso Brasileiro de Algodão; 1ª Cotton EXPO [CD-ROM]; 2011; São Paulo. Campina Grande: Embrapa Algodão; 2011. p.1451-58. and Carvalho et al. (2011b), who reported no significant effect of K application on leaf K concentration. The original level of K in the soil (Table 1), classified as medium by Sousa and Lobato (2004)Sousa DMG, Lobato E. Cerrado: correção do solo e adubação. 2ª. ed. Brasília, DF: Embrapa Informação Técnica; 2004., plus the K rates applied yearly were not enough to keep leaf K concentration at the level of sufficiency (13.7 to 18.2 g kg^-1 K), as estimated by DRIS (Kurihara et al., 2013Kurihara CH, Alvarez VVH, Neves JCL, Novais RF, Staut LA. Faixas de suficiência para teores foliares de nutrientes em algodão e em soja, definidas em função de índices DRIS. Rev Ceres. 2013;60:412-9. doi:10.1590/S0034-737X2013000300015) in the first year of the study (Figure 5b). Throughout the period of this study, the average of leaf K concentration increased gradually, which is related to annual K fertilizer application, although it was not sufficient to reduce or avoid crop response. Hence, gross yield was still affected by K rates applied every year.

Leaf Ca concentration was affected by N rates in 2009/10 and by K rates in 2011/12 (Table 4). Also, a significant effect on Ca leaf content was observed from all treatments, compared to the control. Leaf calcium concentration values decreased with the increase in K rates (Figure 5c), as also observed by Bogiani et al. (2011)Bogiani JC, Ferreira GB, Smiderle OJ, Mourão Júnior M, Borin ALDC. Adubação com potássio e nitrogênio de cultivares de algodoeiro sob sistema de cultivo adensado. In: Anais do 8º Congresso Brasileiro de Algodão; 1ª Cotton EXPO [CD-ROM]; 2011; São Paulo. Campina Grande: Embrapa Algodão; 2011. p.1451-58., and with the increase in N rates (Figure 6a), but still remained above the sufficiency level of 16.9 g kg^-1 Ca proposed by Kurihara et al. (2013)Kurihara CH, Alvarez VVH, Neves JCL, Novais RF, Staut LA. Faixas de suficiência para teores foliares de nutrientes em algodão e em soja, definidas em função de índices DRIS. Rev Ceres. 2013;60:412-9. doi:10.1590/S0034-737X2013000300015.

Figure 6
Leaf concentration of calcium (Ca), magnesium (Mg), and sulfur (S) in narrow-row-space cotton in response to nitrogen rates applied in the 2009/10, 2010/11, and 2011/12 crop seasons. ** and *: significant at 1 and 5 %, respectively, by F test.

Leaf Mg concentration was affected by K rates in 2009/10 and 2010/11, and by N rates in 2010/11 (Table 4). As described for Ca, leaf Mg concentration values decreased with the increase in K rates (Figure 5d). High K rates could decrease cation uptake, especially Mg, were reported by Carvalho and Ferreira (2006)Carvalho MCS, Ferreira GB. Calagem e adubação do algodoeiro no Cerrado. Campina Grande: Embrapa Algodão; 2006. (Circular Técnica, 92).. Competition between K and Mg for the same absorption sites in the root can lead to lower uptake of such nutrients and lower yields, but when soil cation levels are adequate, roots can take up nutrients more easily (Rosolem and Bogiani, 2014Rosolem CA, Bogiani JC. Nutrição e estresses nutricionais em algodoeiro. In: Echer FR, editor. O algodoeiro e os estresses abióticos: temperatura, luz, água e nutrientes. Cuiabá: IMAmt/AMPA; 2014. p.103-21.). Nevertheless, no visual symptoms related to Mg deficiency were identified in the trial, and leaf Mg concentration remained in the sufficiency range of 2.7 to 3.4 g kg^-1 Mg (Kurihara et al., 2013Kurihara CH, Alvarez VVH, Neves JCL, Novais RF, Staut LA. Faixas de suficiência para teores foliares de nutrientes em algodão e em soja, definidas em função de índices DRIS. Rev Ceres. 2013;60:412-9. doi:10.1590/S0034-737X2013000300015). A quadratic model was fitted to leaf Mg concentration in response to N rates, and the maximum value was calculated as 6.1 g kg^-1 Mg at the rate of 45 kg ha^-1 N (Figure 6b), which is in agreement with Mengel and Kirkby (2001)Mengel K, Kirkby EA. Principles of plant nutrition. 5th ed. Dordrecht: Kluwer Academic; 2001.. The authors found that high levels of cations in the soil, especially K and NH₄⁺, can reduce Mg uptake by the plant. This parameter was also affected by all treatments compared to the control for every season of the study.

The N and K rates affected leaf S concentration only in 2009/10 (Table 4). A linear decrease in leaf S was observed with the increase in K rates (Figure 5e), as also presented by Bogiani et al. (2011)Bogiani JC, Ferreira GB, Smiderle OJ, Mourão Júnior M, Borin ALDC. Adubação com potássio e nitrogênio de cultivares de algodoeiro sob sistema de cultivo adensado. In: Anais do 8º Congresso Brasileiro de Algodão; 1ª Cotton EXPO [CD-ROM]; 2011; São Paulo. Campina Grande: Embrapa Algodão; 2011. p.1451-58.. According to the authors, this fact may be explained by a decrease in Ca and Mg uptake, due to competition for the same sites in the roots, leading to a decrease in S uptake while it was acting as a companion ion to the cations. The effect of treatments compared to the control was also observed for leaf S concentration in the first and second year of the trial.

Although no visual symptom of S deficiency was observed in the study, leaf S concentration was lower than the sufficiency range described by Kurihara et al. (2013)Kurihara CH, Alvarez VVH, Neves JCL, Novais RF, Staut LA. Faixas de suficiência para teores foliares de nutrientes em algodão e em soja, definidas em função de índices DRIS. Rev Ceres. 2013;60:412-9. doi:10.1590/S0034-737X2013000300015, 3.8 to 5.4 g kg^-1, in the first year. Lower leaf S values associated with narrow-row spacing in cotton were observed by Ferrari et al. (2014)Ferrari JV, Furlani Junior E, Ferrari S, Luques APPG. Estado nutricional e produtividade de algodoeiro em função de diferentes espaçamentos e aplicação de regulador de crescimento. Semina: Cienc Agrár. 2014;35:2285-96. doi:10.5433/1679-0359.2014v35n5p2285. In addition, a synergetic effect was observed between N and S due to the linear increase in leaf S concentration in response to N rates applied (Figure 6c). Both nutrients are part of amino acids and this interaction shows the need for S in soils that are high yielding and responsive to N, as pointed out by Yamada et al. (2006)Yamada T, Abdalla SRS, Vitti GC. Nitrogênio e enxofre na agricultura brasileira. In: Anais do Simpósio sobre Nitrogênio e Enxofre na Agricultura Brasileira; 2006; Piracicaba. Piracicaba: IPNI; 2006. p.1-6.. It is also likely that higher N rates promoted root development, which may have contributed to more S uptake from deeper layers. This hypothesis can be confirmed by the lack of synergetic effect in the last years of this study when 0.3 and 3 Mg ha^-1 of phosphogypsum were applied in the second and third year, respectively.

The level of available K in the top 0.2 m of the soil was affected by K rates applied in every season of the study, and also by the treatments compared to the control (Table 4). Unlike Bogiani et al. (2011)Bogiani JC, Ferreira GB, Smiderle OJ, Mourão Júnior M, Borin ALDC. Adubação com potássio e nitrogênio de cultivares de algodoeiro sob sistema de cultivo adensado. In: Anais do 8º Congresso Brasileiro de Algodão; 1ª Cotton EXPO [CD-ROM]; 2011; São Paulo. Campina Grande: Embrapa Algodão; 2011. p.1451-58., a linear increase in K content was observed with an increase in K rates (Figure 7).

Figure 7
Soil potassium availability in the 0.0-0.2 m layer in response to potassium rates applied in the 2009/10, 2010/11, and 2011/12 crop seasons. **: significant at 1 % by F test.

CONCLUSIONS

Potassium application is a key practice for cotton grown in narrow row systems. Cotton uptakes high amounts of K, that can be affect by low soil K availability due to no application or low water content in the soil. High K rates applied to cotton in narrow row systems, grown as a second crop after soybeans, sustains higher yields and fiber quality.

The use of high N rates for cotton grown in narrow row with higher plant population, as compared to conventional systems, is not a requirement for higher yields, although it can reduce fiber quality. More plants in the field will compete for light, water, and nutrients, which will compensate plant height and yield.

ACKNOWLEDGMENTS

The authors thank the Instituto Mato-grossense do Algodão (IMAmt) [Mato Grosso Cotton Institute] for financial support.

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Publication Dates

Publication in this collection
17 May 2016

History

Received
19 Feb 2015
Accepted
3 Sept 2015

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[1] Alves LRA, Gottardo LCB, Ferreira Filho JBS, Osaki M, Ribeiro RG, Ykeda VY. Custo de produção de algodão em sistema adensado no Estado de Mato Grosso/Brasil. Custos Agroneg. 2012;8:24-42.

[2] Bogiani JC, Ferreira GB, Smiderle OJ, Mourão Júnior M, Borin ALDC. Adubação com potássio e nitrogênio de cultivares de algodoeiro sob sistema de cultivo adensado. In: Anais do 8º Congresso Brasileiro de Algodão; 1ª Cotton EXPO [CD-ROM]; 2011; São Paulo. Campina Grande: Embrapa Algodão; 2011. p.1451-58.

[3] Bell PF, Boquet DJ, Millhollon E, Moore S, Ebelhar W, Mitchell CC, Varco J, Funderburg ER, Kennedy C, Breitenbeck GA, Craig C, Holman M, Baker W, Mcconnell JS. Relationships between leaf-blade nitrogen and relative seed cotton yields. Crop Sci. 2003;43:1367-74. doi:10.2135/cropsci2003.1367

[4] Brasil. Ministério da Agricultura, Pecuária e Abastecimento. Instrução Normativa nº 63, de 5 de dezembro de 2002. Aprova o regulamento técnico de identidade e de qualidade para a classificação do algodão em pluma. Diário Oficial da União, Brasília, DF, 2002. Seção 1, p.6-8.

[5] Carvalho LH, Silva NM, Kondo JI, Chiavegato EJ, Almeida WP, Carvalho HR. Diferentes doses de nitrogênio e cloreto de mepiquat em plantio adensado do algodoeiro, na presença de nematoides. In: Anais do 8º. Congresso Brasileiro de Algodão; 1ª Cotton EXPO [CD-ROM]; 2011; São Paulo. Campina Grande: Embrapa Algodão; 2011a. p.913-7.

[6] Carvalho MCS, Bernardi ACC. Resposta do algodoeiro à adubação potássica. In: Yamada T, Roberts TL, editores. Potássio na agricultura brasileira. Piracicaba: Associação Brasileira para Pesquisa do Potássio e do Fosfato; 2005.

[7] Carvalho MCS, Ferreira ACB, Borin AL. Adubação NPK do algodoeiro adensado de safrinha no cerrado de Goiás. In: Anais do 8º. Congresso Brasileiro de Algodão; 1ª. Cotton EXPO [CD-ROM]; 2011; São Paulo. Campina Grande: Embrapa Algodão; 2011b. p.1495-502.

[8] Carvalho MCS, Ferreira GB. Calagem e adubação do algodoeiro no Cerrado. Campina Grande: Embrapa Algodão; 2006. (Circular Técnica, 92).

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Depth	pH(CaCl₂)	P	K	Ca²⁺	Mg²⁺	Al³⁺	H⁺	CEC	m	V	OM	Clay	Sand	Silt
m		---mg dm^-3---		-------- cmol_c dm^-3 --------					----% ----		g dm^-3	-------- g kg^-1 --------
0.0-0.2	4.9	3.3	36	2.1	1.5	0.0	5.5	9.2	0	40	38.9	635	215	150
0.2-0.4	4.3	1.5	19	0.6	0.5	0.5	5.7	7.3	30	16	30.4	-	-	-

N rate	Control	K₂O rate				Equation	R²

		0	40	80	120
kg ha^-1		--------------------- kg ha^-1 ---------------------
	Strength of fiber (g tex^-1) (2010/11)
Control	32.8	-	-	-	-
20	-	32.4	34.3	34.3	33.7	ŷ = 32.5 + 0.06 x - 0.0004* x²	0.98
40	-	33.3	33.8	34.8	34.2	ŷ = 33.5 + 0.009* x	0.60
60	-	32.8	34.0	33.0	33.3	ŷ = ӯ = 33.3	-
80	-	33.0	32.1	34.1	32.8	ŷ = ӯ = 33.0	-
Equation	-	ŷ = ӯ = 32.9	ŷ = 35.1 - 0.03** x	ŷ = ӯ = 34.0	ŷ = 34.4 - 0.02* x
R²	-	-	0.70	-	0.58

Factor	DF	PP	PH	BW	LP	GY	Mic	Str	Len	SFI	Elg	Unf	Mat
		plants ha^-1	cm	g	%	kg ha^-1	µg pol^-1	g tex^-1	in	-----------% -----------
		2009/10
N rate	3	ns	ns	ns	ns	ns	ns	ns	ns	ns	ns	ns	ns
K₂O rate	3	ns	ns	*	**	**	**	ns	ns	ns	ns	ns	ns
N × K₂O	9	ns	ns	ns	ns	ns	ns	ns	ns	ns	ns	ns	ns
Factorial vs control	1	ns	ns	ns	*	**	**	ns	ns	ns	ns	ns	ns
Rep	3	*	*	ns	ns	ns	ns	ns	ns	ns	ns	ns	ns
Residue	48	-	-	-	-	-	-	-	-	-	-	-	-
CV (%)	-	8.4	11.3	8.0	1.7	13.3	5.1	3.5	2.1	7.9	5.2	1.0	1.0
Mean	-	183,415	53.1	4.65	44.5	772	4.2	32.4	1.1	7.6	7.5	85.7	87.0
		2010/11
N rate	3	ns	*	ns	ns	**	ns	**	ns	ns	ns	ns	ns
K₂O rate	3	ns	**	**	*	**	**	**	ns	ns	ns	ns	ns
N × K₂O	9	ns	ns	ns	ns	ns	ns	**	ns	ns	ns	ns	ns
Factorial vs control	1	ns	**	ns	**	**	**	*	**	ns	ns	ns	ns
Rep	3	ns	**	ns	**	ns	ns	**	ns	ns	ns	ns	*
Residue	48	-	-	-	-	-	-	-	-	-	-	-	-
CV (%)	-	15.9	9.6	5.2	1.7	9.0	2.8	2.0	1.1	2.2	5.7	0.7	0.9
Mean	-	181,683	57.7	4.22	38.9	1,590	4.0	33.5	1.2	7.0	6.2	87.0	86.0
		2011/12
N rate	3	ns	ns	ns	ns	ns	ns	ns	ns	ns	ns	ns	ns
K₂O rate	3	ns	**	ns	ns	ns	ns	ns	ns	ns	ns	ns	ns
N × K₂O	9	ns	ns	ns	ns	ns	ns	ns	ns	ns	ns	ns	ns
Factorial vs control	1	ns	**	*	*	**	**	ns	ns	ns	ns	ns	**
Rep	3	ns	ns	ns	ns	**	ns	ns	ns	ns	*	ns	ns
Residue	48	-	-	-	-	-	-	-	-	-	-	-	-
CV (%)	-	7.86	11.2	8.6	3.5	16.5	4.8	3.6	2.1	10.6	5.7	0.9	0.6
Mean	-	173,284	71.8	4.82	44.7	2,823	4.9	30.4	1.2	6.5	6.8	85.0	87.7

Factor	DF	N	P	K	Ca	Mg	S	K
		--------------------- g kg^-1 ---------------------						mg dm^-3
	2009/10
N rate	3	ns	ns	ns	**	ns	**	ns
K₂O rate	3	*	ns	**	ns	**	**	**
N x K₂O	9	ns	ns	ns	ns	ns	ns	ns
Factorial vs control	1	*	ns	**	ns	*	*	**
Rep	3	ns	**	ns	**	**	ns	ns
Residue	48	-	-	-	-	-	-	-
CV (%)	-	8.4	9.2	21.0	8.9	15.5	14.9	18.5
Mean	-	27.3	1.3	3.4	27.2	6.7	3.0	31.7
	2010/11
N rate	3	ns	ns	ns	ns	**	ns	ns
K₂O rate	3	ns	ns	**	ns	*	ns	**
N x K₂O	9	ns	ns	ns	ns	ns	ns	ns
Factorial vs control	1	ns	ns	**	ns	**	*	**
Rep	3	ns	**	*	**	ns	**	ns
Residue	48	-	-	-	-	-	-	-
CV (%)	-	5.4	16.2	12.0	11.7	10.4	11.3	16.6
Mean	-	39.3	2.6	14.4	19.0	5.8	4.6	54.1
	2011/12
N rate	3	ns	ns	ns	ns	ns	ns	ns
K₂O rate	3	ns	ns	**	**	ns	ns	**
N x K₂O	9	ns	ns	ns	ns	ns	ns	ns
Factorial vs control	1	ns	ns	**	*	*	ns	**
Rep	3	ns	**	**	ns	ns	*	ns
Residue	48	-	-	-	-	-	-	-
CV (%)	-	7.4	12.0	14.4	8.3	13.2	10.9	12.1
Mean	-	38.7	2.9	20.2	27.0	6.1	3.8	46.5