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Analysis of dry matter, nitrogen and calcium incorporation dynamics in Honey sweet maize (Zea mays L. convar. saccharata Koern) hybrids
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2023-12-31
https://doi.org/10.12666/ags2sw61
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Copyright (c) 2023 Zsuzsanna Bakos, Abakir Abdalla Rania Alrasheed, Árpád Illés, János Nagy
This work is licensed under a Creative Commons Attribution 4.0 International License.
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Bakos, Z., Alrasheed, A. A. R., Illés, Á., & Nagy, J. (2023). Analysis of dry matter, nitrogen and calcium incorporation dynamics in Honey sweet maize (Zea mays L. convar. saccharata Koern) hybrids. Növénytermelés, 72(4), 21-35. https://doi.org/10.12666/ags2sw61
Abstract
The cultivation of sweet maize is of great importance in Hungary. Hungary is the largest producer on the European continent and the second largest exporter in the world after the United States. The average annual production of Hungarian sweet maize, which is in demand all over the world, reaches 500,000 tonnes as a result of the properly selected precision cultivation technology. Yields of sweet maize are above average in precision farming, with nearly 70% of the area irrigated.
An important factor in the exceptional nature of the drought of 2022 was the lack of rainfall in the previous winter half-year, which was not sufficient to replenish the deeper layers of the soil. April was still average in terms of rainfall, but thereafter a very significant rainfall deficit developed. A total of 66 mm of rain fell in the three summer months. The water shortage and its adverse effects were exacerbated by significantly higher than normal temperatures between May and August. The water deficit was compensated for during the growing season by precision drip irrigation, with 344 mm of water being applied. In particular, the summer months were much warmer than the long-term average, with positive temperature differences of 3.4 °C, 2.4 °C and 2.9 °C respectively. The best indicator of sweet maize yields is dry matter incorporation dynamics.
Based on the results measured during the phenophase, it was found that the growing season can be divided into three dominant intervals. The Honey maize hybrid produced 18% dry matter in the first stage, from emergence to the juvenile stage, and an additional 4% from the juvenile stage to silking. The intensive stage of dry matter incorporation lasted from silking to the R3 phenophase (harvest), with a total of 72%. Continuous knowledge of the grain moisture content of sweet maize is an important indicator for operational efficiency. Our research showed that, at the R3 phenophase, the moisture contents of plant parts were closely correlated, with the grain moisture content being the highest. Our research results demonstrated that dry matter gain from silking to the R3 (harvest) phase is very intensive, with a total heat requirement of 840 HU for the examined hybrid.
An important factor in the exceptional nature of the drought of 2022 was the lack of rainfall in the previous winter half-year, which was not sufficient to replenish the deeper layers of the soil. April was still average in terms of rainfall, but thereafter a very significant rainfall deficit developed. A total of 66 mm of rain fell in the three summer months. The water shortage and its adverse effects were exacerbated by significantly higher than normal temperatures between May and August. The water deficit was compensated for during the growing season by precision drip irrigation, with 344 mm of water being applied. In particular, the summer months were much warmer than the long-term average, with positive temperature differences of 3.4 °C, 2.4 °C and 2.9 °C respectively. The best indicator of sweet maize yields is dry matter incorporation dynamics.
Based on the results measured during the phenophase, it was found that the growing season can be divided into three dominant intervals. The Honey maize hybrid produced 18% dry matter in the first stage, from emergence to the juvenile stage, and an additional 4% from the juvenile stage to silking. The intensive stage of dry matter incorporation lasted from silking to the R3 phenophase (harvest), with a total of 72%. Continuous knowledge of the grain moisture content of sweet maize is an important indicator for operational efficiency. Our research showed that, at the R3 phenophase, the moisture contents of plant parts were closely correlated, with the grain moisture content being the highest. Our research results demonstrated that dry matter gain from silking to the R3 (harvest) phase is very intensive, with a total heat requirement of 840 HU for the examined hybrid.
