Microsoft Word - 5-Agra_36709_faltaresumoecentralizarfigura 861 Original Article Biosci. J., Uberlândia, v. 33, n. 4, p. 861-870, July/Aug. 2017 PERFORMANCE OF ORGANOMINERAL FERTILIZER IN WINTER AND RAINY POTATO CROP PERFOMANCE DO FERTILIZANTE ORGANOMINERAL NA SAFRA DE INVERNO E DAS ÁGUAS NO CULTIVO DA BATATEIRA Atalita Francis CARDOSO1; Regina Maria Quintão LANA2; Walyson SOARES3; Joicy Vitória Miranda PEIXOTO4; José Magno Queiroz LUZ5 1. Doutora em Fitotecnia pela Universidade Federal de Uberlândia, Uberlândia, MG, Brasil. atalitacardoso@yahoo.com.br; 2. Professora e pesquisadora da Universidade Federal de Uberlândia, Instituto de Ciências Agrárias, Uberlândia, MG; 3. Mestrando em Fitotecnia pela Universidade Federal de Uberlândia, Uberlândia, MG, Brasil; 4. Doutoranda em Fitotecnia pela Universidade Federal de Uberlândia, Uberlândia, MG, Brasil; 5. Professor e pesquisador da Universidade Federal de Uberlândia, Instituto de Ciências Agrárias, Uberlândia, MG ABSTRACT: The Agata potato is the most important economic sources of food in Brazil. However, fertilization for this crop has been carried out incorrectly, increasing production costs. Thus, the use of organomineral fertilizer reduces the amount of nutrient applied, facilitates the release of nutrients more slowly and brings improvement in the chemical, physical and biological attributes of the soil. The objective of this work was to evaluate the efficiency of organomineral fertilizers rates and comparate with mineral source on the potato crop in differents seasons. The experimental design was in randomized blocks, with five rates and four replications in the winter season. In the harvest of the rainy season the experiment consisted of 6 rates and four replications. Treatments were 1629.0; 2444.0; 3258.0; 4073.0; 4887.0 kg ha-1 of the organomineral fertilizer which equals 40; 60; 80; 100 and 120% of the rate in relation to the mineral fertilizer of 2800 kg ha-1 of formulation 03-32-06. There weren`t significant difference of the organomineral fertilizer in relation to the mineral in the total, commercial and special class of tubers in the winter crop. In the harvest of rainy crop, the average total productivity of potato tubers at all rates of organomineral fertilizer was 29 t ha-1, which represents 22% higher than mineral fertilizer. The organomineral fertilizer presented agronomic efficiency for potato cultivation and could replace NPK mineral sources. The 4887.0 kg ha-1 organomineral rate generated higher total yield, commercial and special class of tubers. KEYWORDS: Solanum tuberosum. Organic fertilization. Tubers. INTRODUCTION The potato crop originates in the Andean highlands of South America and represents one of the most economically important sources of food in Brazil (GARCIA, 2015; SILVA, 2014). The cultivar of potato most planted by the producers is cv. Agate, which is characterized by desirable characteristics due to early tuberization, good tuber appearance and productivity (PINELI, 2006; SILVA, 2013). In Brazil, potato planting can be carried out in all months of the year depending on the specific climatic conditions of each region. The planting is carried out in three harvests: 1st harvest - from the rainy season (August to November), 2nd crop - dry season (January to March) and 3rd harvest – winter season (May to July) (CARDOSO et al., 2015). The first harvest represents 50% of the Brazilian production of tubers and the average productivity reached by the producers in the state of Minas Gerais in the year 2015 was 30.62 t ha-1 (SECRETARIA DE ESTADO DE AGRICULTURA, 2015; CARDOSO et al. 2015). This crop is characterized by the high cost of production due to the application of pesticides and pest and disease control products, which are favored by climatic conditions such as precipitation and temperature. In the third crop, it is characterized by the use of a technological package to increase tuber productivity, which is superior to that of water because of the need to use supplementary irrigation (CARDOSO et al., 2015). The use of high mineral fertilizers rates is one of the factors that increase the costs for potato production, which can lead to a negative response as nutritional imbalance, soil compaction due to increased input use and environmental contamination (MESQUITA et al. 2012). According to Ferreira (2015) the mixture of mineral fertilizers and organic waste minimizes the environmental impact, increases soil fertility and also reduces the use of mineral fertilizers, converting many advantages to the producer. The organomineral fertilizer facilitates the release of nutrients, promotes improvement in the physical, chemical and biological attributes of the soil. The main advantages related to these attributes are: Received: 02/12/16 Accepted: 03/05/17 862 Performance of organomineral… CARDOSO, A. F. et al. Biosci. J., Uberlândia, v. 33, n. 4, p. 861-870, July/Aug. 2017 cation exchange capacity increase, nutrient availability in a slower way and as a consequence less leaching of these, greater aeration, water retention, better soil aggregation, favors the increase of beneficial microbial activity, complexation of heavy metals and maintenance of pH balance (CARDOSO, 2015a; FERREIRA, 2015). There are few results for the use of organomineral fertilizer in potatoes. However, for maize crop, the productivity of the crop was higher in the 600 kg ha-1 dose of the organomineral fertilizer, not differing from the treatments that used 200 kg ha-1 mineral And 300 kg ha-1 organomineral. The same author concludes that organomineral fertilization can replace, in a viable way, the conventional mineral fertilizer to obtain high crop productivity (TIRITAN; SANTOS, 2012). Thus, the objective of this work was to evaluate doses of organomineral fertilizer in comparison with the mineral source of immediate release in potato yield, Agata cultivar, in different crops: winter harvest and harvest of the waters. MATERIAL AND METHODS The work was carried out in areas provided by the agricultural company Wehrmann® in municipality of Cristalina, Goiás, with altitude of 1189 m, (16º 46 '07 "S and 47º 36 '49 "W), soil classified as LATOSSOLO VERMELHO distrófico (LVd), of clayey texture (FERREIRA, 2010a). The climate of the region is considered tropical type Cwb according to Koppen classification. The data of average precipitation, maximum and minimum temperature occurred during the period of the conduction of the experiments are in table 1. Table 1. Average precipitation - P (mm) and maximum temperatures - T max (ºC) and minimum - T min (ºC) in winter and rainy season. Winter Rainy P T mín T máx P T mín T máx May 3,40 14,80 22,66 Oct 0,00 18,00 34,20 Jun 0,00 14,20 21,23 Nov 2,66 19,13 27,46 Jul 0,00 13,00 24,19 Dec 3,10 17,90 29,77 Agu 0,00 14,00 26,40 Jan 5,73 19,09 27,09 Feb 2,11 18,43 27,25 Source: INMET (2015) The experiments was carried out in the winter crop in 2012, in the period between May 26 to October 29 and rainy crop was carried out in 2012/2013 at October 29 to February 16, 2013. The chemical analysis of the soil to characterize the area, performed in the superficial layer of 0-0.20 m depth according to the methodology described by Donagena et al. (2011) presented the following results: P (mg dm-3) = 50; K (mg dm-3) = 161; pH (H2O) = 6.4; Ca 2+ (cmolcdm -3) = 5.4; Mg 2+ (cmolcdm -3) = 1.0; The soil had no aluminum; Base saturation of 77% and cation exchange capacity of 88 mmolc dm -3; H + Al (cmolcdm -3) = 2.0; Organic matter of 3.6 g dm-3. The experimentals design were a randomized complete block design, with five rates of organomineral fertilizer with four replications and a control treatment (chemical mineral fertilizer rate) (Table 2). Table 2. Fertilizer rates (kg ha-1) used in the experiments. Fertilizer Percentage corresponding to mineral fertilizer Rates (kg ha-1) Mineral (3-32-8) 2800,00 Organomineral 40% 1629,0 Organomineral 60% 2444,0 Organomineral 80% 3258,0 Organomineral 100% 4073,0 Organomineral 120% 4888,0 The plots in the winter harvest consisted of 6 lines with 0.8 m between rows and 10 m of length, 863 Performance of organomineral… CARDOSO, A. F. et al. Biosci. J., Uberlândia, v. 33, n. 4, p. 861-870, July/Aug. 2017 totaling 48 m2 per plot. The evaluations were carried out in the two 14.4 m2 central lines, with the edges located on the lines on each side and the initial and final half-meters of each block being neglected. In the harvest of the waters, the experiment contained 28 plots, consisting of 8 rows with 0.8 m between rows and 8m long, totaling 51.2 m2 of area per plot. The evaluations were carried out in the two central lines of 11 m2 scoring the borders located in the two lines on each side and half a meter initial and final of each plot. The rates of organomineral fertilizer were fixed according to recommendations for potato cultivation using mineral fertilizer (SOUZA; LOBATO, 2004). The source of NPK of mineral fertilizer was formulated 3-32-6 with 6.7% of N, 78% of P2O5 and 10.3% of K2O using the sources urea, triple superphosphate and potassium chloride. For the production of organomineral fertilizer was made A chicken bed compost by means of a controlled decomposition aerobic process with an average duration of 20 days. To reduce the composting period, nutrient and microorganism cocktails (fungi and bacteria) were used to accelerate the decomposition process, obtaining, in a few days, the stabilized compound. The mineral sources urea, triple superphosphate and potassium chloride were added to the compound aiming at the balance of nutrients according to the requirement of the potato crop and the ability of the soil to provide the nutrients. Subsequently, the material was homogenized and pelletized (TEIXEIRA, 2013). The organomineral fertilizer pellets have a high hardness (8 kgf cm-2), which means high breaking strength and the prevention of the formation of ununiform particles. The organic matter exerts the physical protection, forms a porous matrix around the nutrients, it prevents the direct contact of soluble nutrients with the soil. As a consequence, it promotes lower losses by fixation and leaching (TEIXEIRA, 2013). The chemical characterization of the organomineral fertilizer used in the experiments is presented in Table 3. Table 3. Chemical parameters of organomineral and mineral fertilizers used (%). Nutrients Mineral (3-32-6) Organomineral (2-22-4) Calcium (Ca) 2,00 1,40 Sulfur (S) 2,00 1,40 Magnesium (Mg) 1,50 1,10 Boron (B) 0,20 0,14 Cupper (Cu) 0,10 0,07 Manganese (Mn) 0,15 0,11 Zinc (Zn) 0,14 0,14 The preparation of the soil area was recommended for the potato crop, by means of a plowing followed by trenching / leveling and later opening of the furrows (FILGUEIRA, 2008). Fertilization was done manually, with incorporation through hoes, in the planting grooves, where the potatoes were planted cv. Agate type 3 (tubers with a diameter of 30 to 40 mm). In the planting grooves of all plots, 30 kg ha-1 of a source of macro and micronutrients composed of 2.7% of Ca; 8.2% of S; 12% of Zn and 6% of B according to the recommendation of Souza and Lobato (2004) for the potato crop. During the two planting seasons, about 30 days after planting, the heap was used to stimulate plant tuberization. In the winter harvest, the fertilization in the cover with 300 kg ha-1 of the formulated 20-00-20 was performed together with the heap. Coverage was not applied in the harvesting of the rainy crop with the purpose of verifying the effect of the slow release of the organomineral fertilizer. The irrigation system used was aspersion by central pivot. The plants received approximately 500 mm of water during the cycle, being close to the volume of water indicated for cultivation, which varies from 450 to 550 mm. After harvest, to obtain productivity at t ha-1, the tubers were weighed and graded. The classification was made according to the diameter of the tubers and in the classes: Special (42-70 mm), Second (33-42 mm), First (28-33 mm), Miscellaneous (up to 28 mm) and discarded (damaged tubers, Non-commercial). The characterization of the commercial productivity was made by the sum of the income of the Special, Second and Diverse classes, which are the classes accepted by the market. The standard for classification used was that used by the potato processing industries (FAEP, 2015). 864 Performance of organomineral… CARDOSO, A. F. et al. Biosci. J., Uberlândia, v. 33, n. 4, p. 861-870, July/Aug. 2017 Data were submitted to analysis of variance. For the comparison of the means of the mineral fertilizer treatment and the treatments with organomineral fertilizer, the Dunnett test, 5% of significance, was applied with the program SPSS for Windows Release 8.0 (1998). Data on treatments with organomineral fertilizer were submitted to polynomial regression analysis using the SISVAR statistical program (FERREIRA, 2000b). RESULTS AND DISCUSSION The efficiency of organo mineral fertilizers in was evaluate through of the yield of tubers in relation that mineral fertilizer at rainy and winter crop Tables 4 and 5. The total productivity of tubers in this harvest at winter crops were no differences between mineral fertilizer rate and organomineral fertilizers rates by Dunnet test (p>0.05) Table 4. In the winter crops the average total productivity was 41.05 t ha-1.Recently, Brazilian producers found a yield of 33.8 t ha-1 in the winter harvest. This value is below that obtained by Cardoso et al. (2015a) of 40.64 t ha-1 in this crop under organomineral fertilization at planting and cover with mineral source (Table 4). Table 4. Total and commercial tubers productivity and classification of Agata potato under winter crop. Averages followed by * differ significantly in relation to control treatment by Dunnet test (p>0.05) The total productivity of tubers in this harvest at rainy crop was significant from the rate of 2443,60 kg ha-1 with (Table 5). Table 2 shows the percentage of organic fertilizer fertilizers in the range of 3258.20 and 4887.30 kg ha-1, corresponding 80% and 120% of the mineral rate. In addition, the special class, at 3258.20 kg ha-1 of organomineral fertilizer, presented higher productivity than the Brazilian average of 27.80 t ha- 1, according to Ibge (2014). The organic matter that compose the organomineral fertilizer may have been essential to stimulate soil microorganisms to release nutrients gradually and have resulted in productivity higher than the Brazilian average in the harvest of the rainy crop. The total average productivity of potato tubers cv. Agata in the rainy crop harvest was 29 t ha-1 in all evaluated rates of organomineral fertilizer, which represents 22% higher than mineral fertilizer (Table 5). This result was higher than the productivity of 26.5 t ha-1 found by potato farmers in the region of Parana state in the harvest of 2015/2016 at rainy crop. Table 5. Total and commercial tubers productivity (t ha-1) and classification under rainy crops. Averages followed by * differ significantly in relation to control treatment by Dunnet test (p>0.05) According to Cardoso et al. (2015 b) there weren´t significant differences in the comparison between mineral and organomineral fertilizer tested in the winter harvest in evaluation of total yield of Rates (kg ha-1) ----Productivity----- (t ha-1) -----------------------Classification------------------ (t ha-1) 2800,00 (mineral) Total Commercial Special Second Diverse No commercial Doll 43,1 41,40 37,40 3,30 0,70 0,80 0,90 1629,10(40%) 41,6 39,7 35,60 3,60 0,50 0,90 1,0 2443,60(60%) 42,6 39,0 35,60 2,90 0,50 0,90 2,7 3258,20(80%) 41,7 39,7 35,60 3,50 0,60 0,90 1,1 4072,70(100%) 42,5 39,5 34,90 4,00 0,60 0,80 2,2 4887,30(120%) 34,8 33,6 31,10 2,20 0,30 0,50 0,7 Rates (kg ha-1) ------Productivity--- (t ha-1) -----------------------Classification------------------ (t ha-1) 2800,00 (mineral) Total Commercial Special Second Diverse No commercial Doll 22,61 21,79 19,31 2,26 0,22 0,73 0,09 1629,10(40%) 27,68 27,31 24,11 2,96 0,24 0,33 0,04 2443,60(60%) 31,74* 31,32* 28,09* 2,98 0,25 0,42 0,17 3258,20(80%) 39,91* 38,95* 35,17* 3,50 0,28 0,76 0,31 4072,70(100%) 34,98* 34,32* 30,80* 3,14 0,38 0,64 0,02 4887,30(120%) 39,42* 38,32* 35,86* 2,11 0,35 0,83 0,27 865 Performance of organomineral… CARDOSO, A. F. et al. Biosci. J., Uberlândia, v. 33, n. 4, p. 861-870, July/Aug. 2017 tubers cv. Atlantic. Already in rainy crop, there was difference in the comparison between the mineral and organomineral. The maximum estimated productivity was 27 t ha-1 at the organomineral rate of 3500 kg ha-1 corresponding to 85.90% of the organomineral fertilizer rate in relation to the mineral. In regions of high altitude the temperature decreases in average of 0,6ºC for each 100 m of elevation (PEREIRA et al., 2007). The Cristalina region has an altitude of 1189 m and this result in favorable conditions for the growth and development of potato in the winter season and explains the differences between yields in the evaluated harvests. The mild temperatures influence in a lower respiratory rate and greater reserve accumulation, less occurrence of pests and disease pressures for the culture and nights with mild temperatures are favorable to thermoperiodicity of the plant, that is, the potato needs a daily variation of 10º C (Nocturnal) and 20º C (diurnal) to achieve high productivity (FILGUEIRA, 2008; PEREIRA et al., 2007). Table 4 shows that there weren`t significant difference in the total and commercial yield of tubers, however, it was observed that the total productivity in the winter crop was 47% higher than the rainy crop and the special class was 48% higher in this crop (Tables 4 and 5). The results suggest that the productivity differential between the winter and the rainy crops may have occurred due to climatic conditions, with emphasis on temperature (Table 1). In the rainy crop occurs greater temperature variation and precipitation, in this condition the productivity of the crop is smaller in relation to the winter crop due to the occurrence of pests and diseases being more favorable to the plant. Nights with higher temperatures favor energy expenditure by increasing the respiratory rate of plants, and thus, the tubers produced in these conditions will be of reduced size and weight due to the less accumulation of photoassimilates produced during the day. The potato is a plant C3 and sensitive to high air temperatures that result in the reduction of photosynthetic rate due to the reduction in the efficiency of photosystem II, increased respiration and reduction of leaf area (FAGUNDES et al., 2010). The potato tubers of the discard and doll class decreased, respectively, 25% and 89% in the rainy crop compared to the winter crop (Tables 4 and 5). It was observed probably due an increase in the quality of the tubers for effect of slow release of the nutrients by the organomineral fertilizer, because in the winter harvest the supply of these essential elements by immediate source in cover could have been fundamental to increase the number of tubers of the class discard and Doll (Tables 4 and 5). Already Aguilar (2015) found yield for tubers of potato cv. Cupid of the class discarded 6.94 t ha-1 in plots treated with mineral fertilizer in the winter crop, not differing with doses of organomineral fertilizer. In the regression analyse for the organomineral rates in the winter season it was observed that there was no significant difference for total, commercial and special class p> 0.05 - Table 6. Table 6. Analysis of variance, cultivar Agata, according to the different rates of organomineral fertilizer, in the winter crop. Productivity Class SV L Total Commercial Special First Diverse Boneca No- commercial Rates 3 0,98ns 0,90ns 0,90ns 0,46ns 0,11ns 0,09ns 0,98ns Block 2 0,27 0,09 0,11 0,44 0,09 0,09 0,08 Residue 6 18,64 18,28 16,73 0,03 0,31 1,01 0,08 C.V 10,16 10,66 11,34 34,39 16,17 64,14 35,89 SV: variation of source; L: degrees of freedom It was observed in Figure 1 that total, commercial productivity and the special class of potato tubers cv. Agata were higher, at constant rates, in the treatments that used higher organomineral fertilizer rates in the rainy crop. These yields were found to be 40,33; 39,20 and 35,98 t ha-1, respectively, and the highest rate yielding this yield was 4887.0 kg ha-1 of the organomineral fertilizer which is equivalent to 120% of the immediate release mineral source. 866 Performance of organomineral… CARDOSO, A. F. et al. Biosci. J., Uberlândia, v. 33, n. 4, p. 861-870, July/Aug. 2017 Figure 1. Total (a), Commercial (b) and Special class (c) (t ha-1) of tubers in function of organomineral rates in rainy crop It was observed that there was no significant difference for first, diverse, doll and no-commercial class yield as a function of the rates of organomineral fertilizer in the winter season for p> 0.05 - Table 7. Table 7. Analysis of variance, cultivar Agata, according to the different rates of organomineral fertilizer, in rainy crop. Class FV L First Diverse Doll No- commercial Rates 3 0,31ns 0,69 ns 0,36 ns 0,31 ns Block 2 0,16 0,50 0,06 0,48 Residue 6 0,64 0,02 1,42 0,11 C.V 27,13 52,63 141,15 58,75 b c 867 Performance of organomineral… CARDOSO, A. F. et al. Biosci. J., Uberlândia, v. 33, n. 4, p. 861-870, July/Aug. 2017 According to Souza et al. (2012), the effect of the slow release of the nutrients of the organomineral fertilizer is due to the conditions of temperature, pressure and humidity used in the transformation of the compound into pellets. Therefore, the mineral phase of this fertilizer will be protected in the porous organic matrix, which prevents losses by leaching of nitrogen and potassium. Moreover, this effect may bring benefits to plants since they can better utilize the nutrients through the release timing throughout the development of the crop (OLIVEIRA, 2014). According to Ferreira (2015), the addition of mineral fertilizer to organic fertilizer reduces the mineralization rate of nutrients, mainly NPK, which can reduce quantities applied per area. In addition, organic matter is essential to potentiate the effect of nutrients and act as a conditioning agent for the decomposing minerals, avoiding physical and chemical incompatibility between the fertilizers that make up the formula. The application of the organomineral fertilizer presents uniformity in the fertilization since the pellets in their composition NPK, micronutrients and organic matter are evenly distributed (AGUILAR, 2016). Santos et al. (2013) applied 3650.00 kg ha-1 of organomineral fertilizer and obtained maximum yield of sunflower achenes of 887 kg ha-1 representing an increase of 33.71% in relation to the non-fertilized treatment. According to the author, this improvement is attributed by the presence of organic matter in the nutrient supply, in the elevation of humidity and improvement of soil structure, increase in the catatonic exchange capacity, formation of humus-clay complex and release of nutrients from the mineral fraction . According to Andraus et al. (2015) the growth and development of radish culture was satisfactory at the rate of 2 t ha-1 for organomineral. The application of this fertilizer provided a larger root diameter at 17 days after sowing. The superiority of this application was related to the slow and continuous supply of nutrients in relation to the conventional sources of immediate release and improvement of the chemical, physical and biological attributes of the soil. (FILGUEIRA, 2008, LUZ et al., 2010). According to Cardoso (2014), the maximum productivity of the special class was 27 t ha-1 which corresponds to 86% of the organomineral rate in the harvest of waters. In the evaluation of the two crops, winter and rainy, the results showed that from 86% of the rate of organomineral fertilizer in relation to the mineral source there was no increase in the yield of the tubers. The organomineral fertilizers present in their composition free amino acids that act as hormonal precursors to the rooting process, besides serving as input vehicle of nutrients, being a source of initial energy and the humic acids contained in the organic fraction of the fertilizer stimulates the activity of the microorganisms Of the soil around the root facilitating the release of nutrients (AGUILAR, 2016; FERREIRA, 2015). The required organomineral fertilizer rate to obtain the same yield with mineral source was obtained by means of the regression equation and it was verified that the organomineral fertilizer was superior presenting rates of 117, 126 and 111% of NDEs - Table 8. It is noticed that to achieve the same total, commercial and special class of tubers of 22.61; 21.79 and 19.31 t ha-1, respectively, of the mineral source of 2800 kg ha-1 requires rates of less than 40% of the organomineral. Therefore, this result allows the immediate release source to be replaced by the organomineral fertilizer, since the agronomic efficiency of this one for total, commercial and special class productivity were higher 17; 26 and 11%, respectively. Table 8. Organomineral fertilizer rates (kg ha-1) to reach the same production of tubers with mineral fertilizer in the harvest of rainy crop - Mineral Equivalent (NDE). According to the company Geociclo (2012) in a study with cane soca of third cut, variety IAC 91 1099, the application of 211.5 kg ha-1 of the organomineral fertilizer produced the same 93.8 t ha -1 of stalk when using the 500 kg ha-1 rate of the mineral source corresponding to 35% of the NDE content in relation to the mineral. The company claims that continuous use of organomineral fertilizer can bring improvement in the chemical and microbiological attributes of the soil over the years. Oliveira (2014) found in the experimental field corn 16.38% higher for the organomineral treatment 4-14-8 compared to the commercial mineral source 4-14-8, since both treatments Productivy Rainy NDE (%) Regression equation Total -485,15 117 y = 0,0033x + 24,211 Commercial -730,64 126 y = 0,0031x + 24,055 Special class -322,18 111 y = 0,0032x + 20,341 868 Performance of organomineral… CARDOSO, A. F. et al. Biosci. J., Uberlândia, v. 33, n. 4, p. 861-870, July/Aug. 2017 received the same amount of NPK. The same author evaluated the differences in yield between treatments and yield of the crop with the use of organomineral fertilizer in three years was 28.75; 33.33 and 38.78% higher than the mineral treatment in the harvests of 2009/2010; 2010/2011 and 2011/2012 respectively. The superiority of organomineral treatment is in the supply of organic matter that is not found in mineral fertilizer. CONCLUSIONS The organomineral is efficient to potato crop at rainy and winter crop. At 4887.0 kg ha-1, which represents 120% higher than the mineral source provided higher quality of tubers. RESUMO: A batata Agata é a principal fonte econômica de alimentos no Brasil. No entanto, a fertilização para esta cultura foi realizada incorretamente, aumentando os custos de produção. Assim, o uso de fertilizante organomineral reduz a quantidade de nutriente aplicado, facilita a liberação de nutrientes mais lentamente e traz melhora nos atributos químicos, físicos e biológicos do solo. O objetivo deste trabalho foi avaliar a eficiência das taxas de fertilizantes organomineral e comparar com a fonte mineral na cultura da batata em diferentes estações. O delineamento experimental foi em blocos ao acaso, com cinco taxas e quatro repetições no inverno. Na safra da estação chuvosa, a experiência consistiu em 5 doses e quatro repetições. Os tratamentos foram 1629,0; 2444,0; 3258,0; 4073,0; 4887,0 kg ha-1 do fertilizante organomineral que é igual a 40; 60; 80; 100 e 120% da dose em relação ao fertilizante mineral de 2800 kg ha-1 da formulação 03-32-06. Não houve diferença significativa do fertilizante organomineral em relação ao mineral na classe total, comercial e especial de tubérculos na safra de inverno. Na colheita da colheita chuvosa, a produtividade total média dos tubérculos de batata a todas as doses de fertilizante organomineral foi de 29 t ha-1, o que representa 22% maior que o fertilizante mineral. O fertilizante organomineral apresentou eficiência agronômica para cultivo de batata e pode substituir as fontes minerais NPK. A taxa organomineral de 4887,0 kg ha-1 gerou maior produção total, classe comercial e classe especial de tubérculos. PALAVRAS-CHAVE: Solanum tuberosum. Adubação orgânica. Tubérculos. REFERENCES AGUILAR, A. S. Resposta da batata cv. Cupido à fertilização organomineral. 2016. 56f. Dissertação (Mestrado em fitotecnia), Universidade Federal de Uberlândia, Uberlândia-MG, 2016. ANDRAUS, M. P.; CARDOSO, A. A.; FERREIRA, E. M.; NASCIMENTO, A. R.; SELEGUINE, A. Fontes e doses de biofertilizante e fertilizante ornanomineral na cultura do rabanete. Enciclopédia biosfera, Goiânia, v. 11, n. 21; p. 2015. CARDOSO, A. D.; ALVARENGA, M. A. R.; MELO, T. L.; VIANA, A. L. S. Produtividade e qualidade de tubérculos de batata em função de doses e parcelamentos de nitrogênio e potássio. 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