Acumulação diferencial de nutrientes por cinco cultivares de milho (Zea mays L.): I - acumulação de macronutrientes

Andrade, A.G. de; Haag, H.P.; Oliveira, G.D. de; Sarruge, J.R.

doi:10.1590/S0071-12761975000100011

Resumos

No presente trabalho, os autores apresentam os resultados de um ensaio de campo empregando os cultivares Agroceres 256, Agroceres 504, Centralmex, H-7974 e Piranão no sentido de aquilatar diferenças no crescimento, produção e acumulação e exportação de nutrientes. O ensaio foi conduzido num regossol de fertilidade mediana, exceto em relação ao K que é baixo, situado no Município de Piracicaba, SP. O delineamento experimental utilizado foi de blocos ao acaso com 4 repetições. Foram seguidas as práticas culturais comuns, e a adubação constituiu de 83 g da fórmula 30-120-70 por metro linear por ocasião do plantio e 33 g por metro linear da fórmula 50-0-4, em cobertura 22 dias após a germinação. Plantas foram coletadas a partir dos 20 dias após a germinação, em intervalos de 20 dias até os 120 dias. As plantas foram divididas em "colmo + folhas", pendão e espiga e analisadas para N, P, K, Ca, Mg e S. Concluíram os autores que diferenças entre cultivares na acumulação de matéria seca na parte vegetativa não se traduzem, necessariamente, por um aumento de peso da matéria seca na espiga. Os cultivares atingem o máximo da quantidade de nutrientes nas seguintes épocas, em dias: N (89-100); P (101-120); K (58-66); Ca (74-94); Mg (100-120); S (93-95). Verificaram, ainda, que as quantidades máximas extraídas em mg/planta são: N (3169-3878); P (541-642); K (3850-4693); Ca (582-782); Mg (654-943); S (444-799). Finalmente, a exportação de nutrientes nas espigas por hectare (50.000 plantas) colhidas é: N (111-143 kg); P (22-30 kg); Ca (0,7-1,1 kg); Mg (10-12kg); S(9-13kg).

The objective of the present work was to examine the differences in growth, yield, accumulation and transport of nutrients between the cultivars Agroceres 256, Agroceres 504, Centralmex, H-7974 and Piranão. The experiment was carried out in the municipality of Piracicaba, State of São Paulo, Brazil. The soil type was a sandy oxisol of medium fertility, expect for K which was low. The experimental set-up was a randon block design with four replications. Common cultivation practices were followed, and the fertilizer used consisted of 83 g of a formula: 30-120-70, per meter length at planting, and 33 g of the formula: 50-0-45 per meter length as dressing 22 days after germination. The plant population density was 50,000 per hectare. Plants were collected for analysis at 20 days after germination, and there after at intervals of 20 days up to 120 days. The plants were divided into "stems + leaves", tassels, and ears for chemical analysis of N, P, K, Ca, Mg and S. Conclusions: Growth - The cultivars produce maximum quantities of dry matter of 327 to 381 g per plant at the age of 100 to 106 days. - Differences between cultivars in terms of dry matter accumulation in the vegetative parts of the plant is not necessarily relate to the dry weight of the ear. Accumulation of nutrients - There are no differences in the quantity of N, P and K taken-up by the cultivars, although during the period of rapid growth some differences may appear. - Differences in the accumulation of Ca, Mg and S are detected when the quantities of these nutrients approach the maximum. The cultivar H-7974 presented the highest quantities of Ca and Mg where as Agroceres 504 was richest in S. - The maximum level of nutrients are attained in the following period in days: N (89-100); P (101 -120); K (58-66); Ca (75-94); Mg (100-120) and S (93-95). - The maximum quantities taken-up in mg/plant are:N (3,169-3,878);P (541-642); K (3,850-4,693); Ca (582-782); Mg (654-943); S (444-799). Yield - No differences were found between cultivars for grain production. Transport of nutrients - The re were no differences in the amounts of nutrients in the grain between cultivars. - The transport of nutrients into the ears of the different cultivars are the following order (per hectare harvested, 50,000 plants): N (111-143 kg); P (22-30 kg); K (30-45 kg); Ca (0.7-1.1 kg); Mg (10-12 kg) and S (9-13 kg).

Acumulação diferencial de nutrientes por cinco cultivares de milho (Zea mays L.). I - acumulação de macronutrientes^* * Parte da dissertação apresentada pelo primeiro autor para obtenção do grau de MESTRE pela E.S.A. "Luiz de Queiroz", USP. Suporte financeiro da EMBRAPA, Brasília-DF.

Differential accumulation of nutrients by five cultivars of corn (Zea mays L.). I - macronutrients accumulation

A.G. de Andrade^I; H.P. Haag^II; G.D. de Oliveira^II; J.R. Sarruge^II

^IUniversidade Federal Rural de Pernambuco, Recife-PE

^IIE.S.A. "Luiz de Queiroz", USP - Depto. de Química, Piracicaba-SP

RESUMO

No presente trabalho, os autores apresentam os resultados de um ensaio de campo empregando os cultivares Agroceres 256, Agroceres 504, Centralmex, H-7974 e Piranão no sentido de aquilatar diferenças no crescimento, produção e acumulação e exportação de nutrientes. O ensaio foi conduzido num regossol de fertilidade mediana, exceto em relação ao K que é baixo, situado no Município de Piracicaba, SP. O delineamento experimental utilizado foi de blocos ao acaso com 4 repetições. Foram seguidas as práticas culturais comuns, e a adubação constituiu de 83 g da fórmula 30-120-70 por metro linear por ocasião do plantio e 33 g por metro linear da fórmula 50-0-4, em cobertura 22 dias após a germinação. Plantas foram coletadas a partir dos 20 dias após a germinação, em intervalos de 20 dias até os 120 dias. As plantas foram divididas em "colmo + folhas", pendão e espiga e analisadas para N, P, K, Ca, Mg e S. Concluíram os autores que diferenças entre cultivares na acumulação de matéria seca na parte vegetativa não se traduzem, necessariamente, por um aumento de peso da matéria seca na espiga. Os cultivares atingem o máximo da quantidade de nutrientes nas seguintes épocas, em dias: N (89-100); P (101-120); K (58-66); Ca (74-94); Mg (100-120); S (93-95). Verificaram, ainda, que as quantidades máximas extraídas em mg/planta são: N (3169-3878); P (541-642); K (3850-4693); Ca (582-782); Mg (654-943); S (444-799). Finalmente, a exportação de nutrientes nas espigas por hectare (50.000 plantas) colhidas é: N (111-143 kg); P (22-30 kg); Ca (0,7-1,1 kg); Mg (10-12kg); S(9-13kg).

SUMMARY

The objective of the present work was to examine the differences in growth, yield, accumulation and transport of nutrients between the cultivars Agroceres 256, Agroceres 504, Centralmex, H-7974 and Piranão. The experiment was carried out in the municipality of Piracicaba, State of São Paulo, Brazil. The soil type was a sandy oxisol of medium fertility, expect for K which was low. The experimental set-up was a randon block design with four replications. Common cultivation practices were followed, and the fertilizer used consisted of 83 g of a formula: 30-120-70, per meter length at planting, and 33 g of the formula: 50-0-45 per meter length as dressing 22 days after germination. The plant population density was 50,000 per hectare. Plants were collected for analysis at 20 days after germination, and there after at intervals of 20 days up to 120 days. The plants were divided into "stems + leaves", tassels, and ears for chemical analysis of N, P, K, Ca, Mg and S.

Conclusions:

Growth

- The cultivars produce maximum quantities of dry matter of 327 to 381 g per plant at the age of 100 to 106 days.

- Differences between cultivars in terms of dry matter accumulation in the vegetative parts of the plant is not necessarily relate to the dry weight of the ear.

Accumulation of nutrients

- There are no differences in the quantity of N, P and K taken-up by the cultivars, although during the period of rapid growth some differences may appear.

- Differences in the accumulation of Ca, Mg and S are detected when the quantities of these nutrients approach the maximum. The cultivar H-7974 presented the highest quantities of Ca and Mg where as Agroceres 504 was richest in S.

- The maximum level of nutrients are attained in the following period in days: N (89-100); P (101 -120); K (58-66); Ca (75-94); Mg (100-120) and S (93-95).

- The maximum quantities taken-up in mg/plant are:N (3,169-3,878);P (541-642); K (3,850-4,693); Ca (582-782); Mg (654-943); S (444-799).

Yield

- No differences were found between cultivars for grain production. Transport of nutrients

- The re were no differences in the amounts of nutrients in the grain between cultivars.

- The transport of nutrients into the ears of the different cultivars are the following order (per hectare harvested, 50,000 plants): N (111-143 kg); P (22-30 kg); K (30-45 kg); Ca (0.7-1.1 kg); Mg (10-12 kg) and S (9-13 kg).

Texto completo disponível apenas em PDF.

Full text available only in PDF format.

LITERATURA CITADA

Entregue para publicação em 22/7/1975.

ADELANA, B.O. & MILBOURN, G.M., 1972. The growth of maize. II. Dry matter partition in three maize hybrids. J. Agric. Sci., 78:73-78.
ASHBURN, E.L., 1971. The yield and uptake of nutrients by selected corn genotypes as influenced by nitrogen fertilization. Dissert. Abst. Intern. B, 32:33.
BAKER, E.E., BRADFORD, B.R. & THOMAS, W.I., 1966. Leaf analysis of corntool for predicting soil fertility needs. Better Crops Plant Food., 50:36-40.
BAKER, D.E., BRADFORD, B.R. & THOMAS, W.I., 1967. Accumulation of Ca, Sr., Mg, P and Zn by genotypes of corn (Zea mays L.), under different soil fertility levels. Isotopes in Plant Nutrition and Physiology. Proc. Symp. FAO/IAEA, Vienna, 1966.
BARBER, S.A., 1968. Mechanism of potassium absorption by plants. IN:Kilmer, V.J. et al. (eds.). The role of potassium in agriculture. American Society of Agronomy, Inc.; Madison, Wis., p. 293-310.
BARRIGA BEZANILLA, G.P., 1971. A eficiência de alguns cultivares de milho (Zea mays L.) na produção de grãos. Piracicaba, SP. 84 pp. Dissertação (mestre). ESALQ.
BENNET, W.F., STANFORD, G. & DUMENIL, L., 1953. Nitrogen, phosphorus and potassium content of the corn leaf and grain as related to nitrogen fertilization and yield. Soil Sci. Soc. Amer. Proc., 17 252-258.
BRADFORD, R.R., BAKER, D.E. & THOMAS, W.I., 1966. Effect of soil treatments on chemical element accumulation of four corn hybrids. Agron. J., 58:614-617.
CLARK, R.B. & BROWN, J.C., 1974a. Internal root control of iron uptake and utilization in maize genotypes. Plant and Soil, 40: 667-677.
CIMMYT, 1972. Informe Anual. El Batan, México.
DEPARDON-MAUVISSEAU, B., 1952. Besoins en elements fertilisants des mais hybrides. C.R. Ac. Agr., 38:143-145.
DUNCAN, W.G., 1967. Corn yield to meet the challenge. IN: Maximum crop yield - the challenge. American Society of Agronomy (publicação especial nş 9), Madison, Wis., p. 51-56.
DYNARD, T.B., TANNER, J.W. & DUNCAN, W.G., 1971. Duration of grain filling period and its relation to grain yield in corn (Zea mays L.). Crop Sci., 11:45-48.
EPSTEIN, E., 1972. Mineral nutrition of plants: principles and perspectives. John Wiley and Sons. Inc., New York, London. 412 pp.
EPSTEIN, E. & JEFFERIES, R.L., 1964. The genetic basis of seletive ion transport in plants. Ann. Rev. Plant Physiol, 15:169-184.
FERRARI, G. & RENOSTO, F., 1972. Comparative studies on active transport by excised roots of imbred and hybrid maize. J. Agri. Sci., 79:105-108.
FOY, CD. & BARBER, S.A., 1958. Magnesium absorption and utilization by two imbred lines of corn. Soil Sci. Soc. Amer. Proc, 22:57-62.
GALLO, J.R., HIROCE, R. & DE MIRANDA, L.T., 1968. A análise foliar na nutrição do milho. I. Correlação entre análise de folhas e produção. Bragantia, 27:177-186.
GALVÃO, J.D., 1973. Comportamento do milho Piranão (braquítico - 2) e de milhos de porte normal em diferentes níveis de nitrogênio e populações de plantas. Piracicaba, SP. 106 pp. Tese (doutor) - ESALQ.
GOODSELL, S.F., 1968. Potassium levels in mature seeds of normal and opaque - 2 maize. Crop Sci., 8:281-282.
GORSLINE, G.W., RAGLAND, J.L. & THOMAS, W.I., 1961. Evidence for inheritance of differential accumulation of calcium, magnesium and potassium by maize. Crop Sci., 1:155-156.
GORSLINE, G.W., THOMAS, W.I. & BAKER, D.E., 1964. Inheritance of P, K, Mg, Cu, B, Zn, Mn, Al, Fe concentration by corn (Zea mays L.) leaves and grain. Crop Sci., 4: 207-210.
HANWAY, D.G., 1967. Irrigation. IN: Pierre, W.H. et al. (eds.). Advances in corn production: principles and practices. The Iowa State University Press. AMES, Iowa., p. 155-175.
HANWAY, J.J., 1962a. Corn growth and composition in relation to soil fertility. I. Growth of different plant parts and relation between leaf weight and grain yield. Agron. J., 54:145-148.
HANWAY, J.J., 1962b. Corn growth and composition in relation to soil fertility. II. Uptake of N, P and K and their distribution in different plant parts during the growing season. Agron. J., 54: 217-222.
HANWAY, J.J. & RUSSEL, W.A., 1969. Dry-matter accumulation in corn plants: comparisons among single-cross hybrids. Agron. J., 61:947-951.
JENNE, E.A., RHOADES, H.F., YIEN, C.H. & HOWE, O.W., 1958. Change in nutrient element accumulation by corn with depletion of soil moisture. Agron. J., 50:71-74.
JONES, W.J., Jr. & HUSTON, H.A., 1914. Composition of maize at various stages of its growth. Indiana Agr. Expt. Sta. Bull. 175.
KOLLER, O.L. & MUNSTOCK, C.M,, 1972. Distribuição da matéria seca, na planta durante o período de formação dos grãos, em seis cultivares de milho. Anais da IX Reunião Brasileira de Milho. Recife, p. 150-158.
KRUG, C.A., 1966. O milho no mundo. IN: Cultura e adubação do milho. Instituto Brasileiro de Potassa (ed.). São Paulo, SP, p. 11-19.
LEITE, D.R. & PATERNIANI, E., 1973. Comportamento de milho (Zea mays L.) braquítico-2 em diferentes densidades de plantio. Relatório Científico do Instituto de Genética - E.S.A. "Luiz de Queiroz", Piracicaba, 7:74-82.
LIEBHARDT, W.C, 1968. Effect of potassium on carbohidrate metabolism and translocation. IN: Kilmer, V.J. et al. (eds.). The role potassium in agriculture. American Society of Agronomy, Inc., Madison, Wis., p. 147-164.
LOUÉ, A., 1963. Estudo comparativo das exigências minerais de algumas variedades de milho híbrido. Fertilité, 20:22-32.
MALA VOLTA, E., HAAG, H.P., MELLO, F.A.F. & BRASIL SOBRş, M.O.C, 1974. Nutrição mineral e adubação de plantas cultivadas. Liv. Pioneira editora, São Paulo. 727 pp.
MENGEL, K., 1968. Exchangeable cations of plant roots and potassium absorption by the plant. IN: Kilmer, V.J. et al. (eds.). The role of potassium in agriculture. American Society of Agronomy, Inc. Madison, Wis., p. 311-320.
MIRANDA, L.T., 1966. Híbridos e variedades. IN: Cultura e adubação do milho. Instituto Brasileiro da Potassa (ed.). São Paulo, p. 153-173.
NELSON, L.B., 1956. The mineral nutrition of corn as related to its growth and culture. Adv. Agron., 8:321-375.
NELSON, W.L., 1968. Plant factors affecting potassium availability and uptake. IN: Kilmer, V.J. et al. (eds.). The role of potassium in agriculture. American Society of Agronomy, Inc. Madison, Wis., p. 355-384.
NEPTUNE, A.M.L., 1966. Estudos sobre adubação e diagnose foliar do milho (Zea mays L.). Piracicaba, SP. 167 pp. Tese (cátedra) - ESALQ.
OLSON, R.A. & LUCAS, R.E., 1967. Fertility requirement: secundary and micronutrients. IN: Pierre, W.H. et al. (eds.). Advances in corn production: principles and practices. The Iowa State University Press. Ames, Iowa., p. 285-330.
PATERNIANI, E., 1973. Origem e comportamento do milho Piranão. Relatório Científico do Instituto de Genética - E.S.A. "Luiz de Queiroz", Piracicaba, 7:148-160.
PEASLEE, D.E., RAGLAND, J.L. & DUNCAN, W.G., 1971. Grain filling period of corn as influenced by phosphorus, potassium and the time of planting. Agron. J., 63: 561-563.
PESEK, J., 1968. Potassium nutrition of soybeans and corn. IN: Kilmer, V.J. et al. (eds.). The role of potassium in agriculture. American Society of Agronomy, Inc. Madison, Wis., p. 447--468.
RANZANI, G., 1956. Levantamento da carta de solo da Secção Técnica "Química Agrícola" da Escola Superior de Agricultura "Luiz de Queiroz". Piracicaba, SP. Tese (livre-docente) -ESALQ.
ROBERTSON, W.K., THOMPSON, L. & HAMMOND, L.C., 1968. Yield and nutrient removal by corn (Zea mays L.) for grain as influenced by fertilizer, plant population, and hybrid. Soil Sci. Amer. Proc, 32:245-249.
SARRUGE, J.R. & HAAG, H.P., 1974. Análises químicas em plantas. Piracicaba, SP. Departamento de Química, ESALQ (publicação especial).
SAYRE, J.D., 1948. Mineral accumulation in corn. Plant Physiol., 23: 267-281.
SAYRE, J.D., 1955. Mineral nutrition of corn. IN: Sprague, G.F. (ed.). Corn and corn improvement. Academic Press, Inc., New York, N.Y., p. 293-314.
SOUBIES, L. & GADET, R., 1953. L'exportation d'element fertilisants par le mais. C.R. Ac. Agr., 39:176-178.
TAVARES, F.C. & ZINSLY, J.R., 1972. Componentes da produção relacionados à heterose em híbridos intervarietais de milho (Zea mays L.). Relatório Científico do Instituto de Genética da E.S.A. "Luiz de Queiroz", Piracicaba, 6:96-116.
TREGUBEMCO, M.J. & NEPOMNACIS, V.I., 1971. The water consumption of brachytic maize hybrids in relation to their yields. APUD: Plant Breeding Abst., vol. 41, nş 2, p. 340.
VIETS, F.G., 1962. Fertilizers and the efficient use of water. Adv. Agron., 14:223-264.
VOSE, P.B., 1963. Varietal differences in plant nutrition. Herb. Abst., 33:1-13.
VEINMANN, H., 1956. Studies on the chemical composition and nutrient uptake of maize. Rhod. Agr. J., 53:168-181.

*

Parte da dissertação apresentada pelo primeiro autor para obtenção do grau de MESTRE pela E.S.A. "Luiz de Queiroz", USP. Suporte financeiro da EMBRAPA, Brasília-DF.

Datas de Publicação

Publicação nesta coleção
30 Maio 2012
Data do Fascículo
1975

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] ADELANA, B.O. & MILBOURN, G.M., 1972. The growth of maize. II. Dry matter partition in three maize hybrids. J. Agric. Sci., 78:73-78.

[2] ASHBURN, E.L., 1971. The yield and uptake of nutrients by selected corn genotypes as influenced by nitrogen fertilization. Dissert. Abst. Intern. B, 32:33.

[3] BAKER, E.E., BRADFORD, B.R. & THOMAS, W.I., 1966. Leaf analysis of corntool for predicting soil fertility needs. Better Crops Plant Food., 50:36-40.

[4] BAKER, D.E., BRADFORD, B.R. & THOMAS, W.I., 1967. Accumulation of Ca, Sr., Mg, P and Zn by genotypes of corn (Zea mays L.), under different soil fertility levels. Isotopes in Plant Nutrition and Physiology. Proc. Symp. FAO/IAEA, Vienna, 1966.

[5] BARBER, S.A., 1968. Mechanism of potassium absorption by plants. IN:Kilmer, V.J. et al. (eds.). The role of potassium in agriculture. American Society of Agronomy, Inc.; Madison, Wis., p. 293-310.

[6] BARRIGA BEZANILLA, G.P., 1971. A eficiência de alguns cultivares de milho (Zea mays L.) na produção de grãos. Piracicaba, SP. 84 pp. Dissertação (mestre). ESALQ.

[7] BENNET, W.F., STANFORD, G. & DUMENIL, L., 1953. Nitrogen, phosphorus and potassium content of the corn leaf and grain as related to nitrogen fertilization and yield. Soil Sci. Soc. Amer. Proc., 17 252-258.

[8] BRADFORD, R.R., BAKER, D.E. & THOMAS, W.I., 1966. Effect of soil treatments on chemical element accumulation of four corn hybrids. Agron. J., 58:614-617.

[9] CLARK, R.B. & BROWN, J.C., 1974a. Internal root control of iron uptake and utilization in maize genotypes. Plant and Soil, 40: 667-677.

[10] CIMMYT, 1972. Informe Anual. El Batan, México.

[11] DEPARDON-MAUVISSEAU, B., 1952. Besoins en elements fertilisants des mais hybrides. C.R. Ac. Agr., 38:143-145.

[12] DUNCAN, W.G., 1967. Corn yield to meet the challenge. IN: Maximum crop yield - the challenge. American Society of Agronomy (publicação especial nş 9), Madison, Wis., p. 51-56.

[13] DYNARD, T.B., TANNER, J.W. & DUNCAN, W.G., 1971. Duration of grain filling period and its relation to grain yield in corn (Zea mays L.). Crop Sci., 11:45-48.

[14] EPSTEIN, E., 1972. Mineral nutrition of plants: principles and perspectives. John Wiley and Sons. Inc., New York, London. 412 pp.

[15] EPSTEIN, E. & JEFFERIES, R.L., 1964. The genetic basis of seletive ion transport in plants. Ann. Rev. Plant Physiol, 15:169-184.

[16] FERRARI, G. & RENOSTO, F., 1972. Comparative studies on active transport by excised roots of imbred and hybrid maize. J. Agri. Sci., 79:105-108.

[17] FOY, CD. & BARBER, S.A., 1958. Magnesium absorption and utilization by two imbred lines of corn. Soil Sci. Soc. Amer. Proc, 22:57-62.

[18] GALLO, J.R., HIROCE, R. & DE MIRANDA, L.T., 1968. A análise foliar na nutrição do milho. I. Correlação entre análise de folhas e produção. Bragantia, 27:177-186.

[19] GALVÃO, J.D., 1973. Comportamento do milho Piranão (braquítico - 2) e de milhos de porte normal em diferentes níveis de nitrogênio e populações de plantas. Piracicaba, SP. 106 pp. Tese (doutor) - ESALQ.

[20] GOODSELL, S.F., 1968. Potassium levels in mature seeds of normal and opaque - 2 maize. Crop Sci., 8:281-282.

[21] GORSLINE, G.W., RAGLAND, J.L. & THOMAS, W.I., 1961. Evidence for inheritance of differential accumulation of calcium, magnesium and potassium by maize. Crop Sci., 1:155-156.

[22] GORSLINE, G.W., THOMAS, W.I. & BAKER, D.E., 1964. Inheritance of P, K, Mg, Cu, B, Zn, Mn, Al, Fe concentration by corn (Zea mays L.) leaves and grain. Crop Sci., 4: 207-210.

[23] HANWAY, D.G., 1967. Irrigation. IN: Pierre, W.H. et al. (eds.). Advances in corn production: principles and practices. The Iowa State University Press. AMES, Iowa., p. 155-175.

[24] HANWAY, J.J., 1962a. Corn growth and composition in relation to soil fertility. I. Growth of different plant parts and relation between leaf weight and grain yield. Agron. J., 54:145-148.

[25] HANWAY, J.J., 1962b. Corn growth and composition in relation to soil fertility. II. Uptake of N, P and K and their distribution in different plant parts during the growing season. Agron. J., 54: 217-222.

[26] HANWAY, J.J. & RUSSEL, W.A., 1969. Dry-matter accumulation in corn plants: comparisons among single-cross hybrids. Agron. J., 61:947-951.

[27] JENNE, E.A., RHOADES, H.F., YIEN, C.H. & HOWE, O.W., 1958. Change in nutrient element accumulation by corn with depletion of soil moisture. Agron. J., 50:71-74.

[28] JONES, W.J., Jr. & HUSTON, H.A., 1914. Composition of maize at various stages of its growth. Indiana Agr. Expt. Sta. Bull. 175.

[29] KOLLER, O.L. & MUNSTOCK, C.M,, 1972. Distribuição da matéria seca, na planta durante o período de formação dos grãos, em seis cultivares de milho. Anais da IX Reunião Brasileira de Milho. Recife, p. 150-158.

[30] KRUG, C.A., 1966. O milho no mundo. IN: Cultura e adubação do milho. Instituto Brasileiro de Potassa (ed.). São Paulo, SP, p. 11-19.

[31] LEITE, D.R. & PATERNIANI, E., 1973. Comportamento de milho (Zea mays L.) braquítico-2 em diferentes densidades de plantio. Relatório Científico do Instituto de Genética - E.S.A. "Luiz de Queiroz", Piracicaba, 7:74-82.

[32] LIEBHARDT, W.C, 1968. Effect of potassium on carbohidrate metabolism and translocation. IN: Kilmer, V.J. et al. (eds.). The role potassium in agriculture. American Society of Agronomy, Inc., Madison, Wis., p. 147-164.

[33] LOUÉ, A., 1963. Estudo comparativo das exigências minerais de algumas variedades de milho híbrido. Fertilité, 20:22-32.

[34] MALA VOLTA, E., HAAG, H.P., MELLO, F.A.F. & BRASIL SOBRş, M.O.C, 1974. Nutrição mineral e adubação de plantas cultivadas. Liv. Pioneira editora, São Paulo. 727 pp.

[35] MENGEL, K., 1968. Exchangeable cations of plant roots and potassium absorption by the plant. IN: Kilmer, V.J. et al. (eds.). The role of potassium in agriculture. American Society of Agronomy, Inc. Madison, Wis., p. 311-320.

[36] MIRANDA, L.T., 1966. Híbridos e variedades. IN: Cultura e adubação do milho. Instituto Brasileiro da Potassa (ed.). São Paulo, p. 153-173.

[37] NELSON, L.B., 1956. The mineral nutrition of corn as related to its growth and culture. Adv. Agron., 8:321-375.

[38] NELSON, W.L., 1968. Plant factors affecting potassium availability and uptake. IN: Kilmer, V.J. et al. (eds.). The role of potassium in agriculture. American Society of Agronomy, Inc. Madison, Wis., p. 355-384.

[39] NEPTUNE, A.M.L., 1966. Estudos sobre adubação e diagnose foliar do milho (Zea mays L.). Piracicaba, SP. 167 pp. Tese (cátedra) - ESALQ.

[40] OLSON, R.A. & LUCAS, R.E., 1967. Fertility requirement: secundary and micronutrients. IN: Pierre, W.H. et al. (eds.). Advances in corn production: principles and practices. The Iowa State University Press. Ames, Iowa., p. 285-330.

[41] PATERNIANI, E., 1973. Origem e comportamento do milho Piranão. Relatório Científico do Instituto de Genética - E.S.A. "Luiz de Queiroz", Piracicaba, 7:148-160.

[42] PEASLEE, D.E., RAGLAND, J.L. & DUNCAN, W.G., 1971. Grain filling period of corn as influenced by phosphorus, potassium and the time of planting. Agron. J., 63: 561-563.

[43] PESEK, J., 1968. Potassium nutrition of soybeans and corn. IN: Kilmer, V.J. et al. (eds.). The role of potassium in agriculture. American Society of Agronomy, Inc. Madison, Wis., p. 447--468.

[44] RANZANI, G., 1956. Levantamento da carta de solo da Secção Técnica "Química Agrícola" da Escola Superior de Agricultura "Luiz de Queiroz". Piracicaba, SP. Tese (livre-docente) -ESALQ.

[45] ROBERTSON, W.K., THOMPSON, L. & HAMMOND, L.C., 1968. Yield and nutrient removal by corn (Zea mays L.) for grain as influenced by fertilizer, plant population, and hybrid. Soil Sci. Amer. Proc, 32:245-249.

[46] SARRUGE, J.R. & HAAG, H.P., 1974. Análises químicas em plantas. Piracicaba, SP. Departamento de Química, ESALQ (publicação especial).

[47] SAYRE, J.D., 1948. Mineral accumulation in corn. Plant Physiol., 23: 267-281.

[48] SAYRE, J.D., 1955. Mineral nutrition of corn. IN: Sprague, G.F. (ed.). Corn and corn improvement. Academic Press, Inc., New York, N.Y., p. 293-314.

[49] SOUBIES, L. & GADET, R., 1953. L'exportation d'element fertilisants par le mais. C.R. Ac. Agr., 39:176-178.

[50] TAVARES, F.C. & ZINSLY, J.R., 1972. Componentes da produção relacionados à heterose em híbridos intervarietais de milho (Zea mays L.). Relatório Científico do Instituto de Genética da E.S.A. "Luiz de Queiroz", Piracicaba, 6:96-116.

[51] TREGUBEMCO, M.J. & NEPOMNACIS, V.I., 1971. The water consumption of brachytic maize hybrids in relation to their yields. APUD: Plant Breeding Abst., vol. 41, nş 2, p. 340.

[52] VIETS, F.G., 1962. Fertilizers and the efficient use of water. Adv. Agron., 14:223-264.

[53] VOSE, P.B., 1963. Varietal differences in plant nutrition. Herb. Abst., 33:1-13.

[54] VEINMANN, H., 1956. Studies on the chemical composition and nutrient uptake of maize. Rhod. Agr. J., 53:168-181.

Brasil

Brasil

Acumulação diferencial de nutrientes por cinco cultivares de milho (Zea mays L.): I - acumulação de macronutrientes

Differential accumulation of nutrients by five cultivars of corn (Zea mays L.): I - macronutrients accumulation

Resumos

Datas de Publicação