Assessment of planting soil temperature and GDD impacts on silage corn (Zea mays L.) biomass

IF 2.7 3区 农林科学 Q1 AGRICULTURE, DAIRY & ANIMAL SCIENCE
Moonju Kim, Jiyung Kim, Mu-Hwan Jo, Kyungil Sung, Kun-Jun Han
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引用次数: 0

Abstract

The annual forage crop production system, enclosing silage corn (Zea mays L.) and following cool-season annual forage, can enhance forage production efficiency where available land is limited for pasture production. In this forage production system, successful silage corn cultivation has a significant value due to the great yield of highly digestible forage. However, some untimely planting or harvesting of corn due to changing weather often reduces biomass and feeding values. Therefore, a study was conducted to quantify the corn silage biomass reductions by the deviations from optimum planting soil temperature and optimum growing degree day. The approximations of maximum corn production were estimated based on field trial data conducted between 1978 and 2018 with early, medium, and late-maturity corn groups. Based on weather data, the recorded planting dates and harvest dates were converted into the corresponding trials’ soil temperatures at planting (STP) and the growing degree days (GDD). The silage corn biomass data were regressed against STP and GDD using a quadratic function. The maximum biomass point was modeled in a convex upward quadratic yield curve and the optimum STP and GDD were defined as those values at the maximum biomass for each maturity group. Optimized STP was at 16.6, 16.2, and 15.6°C for early, medium, and late maturity corn groups, respectively, while optimized GDD at harvest was at 1424, 1363, and 1542 °C. The biomass reductions demonstrated quadratic functions by the departures of STP or GDD. The 5% reductions were anticipated when STP departed from the optimum temperature by 2.2, 2.4, and 1.4°C for early, medium, and late maturity corns, respectively; the same degree of reductions were estimated when the GDD departed by 200, 180, and 130°C in the same order of the maturity groups. This result indicates that biomass reductions of late-maturity corn were more sensitive to the departures of STP or GDD than the early-maturity corn. Therefore, early maturing cultivars are more stable in biomass production in a silage corn–winter annual forage crop production system to enhance forage-based livestock production efficiency.
种植土壤温度和GDD对青贮玉米生物量影响的评价
一年生饲料作物生产体系,包括青贮玉米(<italic>Zea may </italic>L.)和后续冷季一年生牧草,可以在草场生产用地有限的地区提高牧草生产效率。在这一饲料生产体系中,青贮玉米的成功栽培具有重要的价值,因为青贮玉米的高消化率饲料产量很大。然而,由于天气变化,一些玉米的不及时种植或收获往往会减少生物量和饲料价值。因此,本研究通过最佳种植土壤温度和最佳生长度数的偏差来量化玉米青贮生物量的减少。根据1978年至2018年对早熟、中熟和晚熟玉米组进行的田间试验数据,估计了玉米最大产量的近似值。根据气象数据,将记录的种植日期和收获日期转换为相应试验的种植时土壤温度(STP)和生长度日(GDD)。青贮玉米生物量数据采用二次函数对STP和GDD进行回归。最大生物量点以凸向上的二次型产量曲线建模,最佳STP和GDD定义为各成熟度组最大生物量处的值。早熟、中熟和晚熟玉米组最佳STP温度分别为16.6、16.2和15.6°C,收获时最佳GDD温度分别为1424、1363和1542°C。随着STP和GDD的偏离,生物量的减少表现为二次函数。当早熟、中熟和晚熟玉米的STP分别偏离最适温度2.2、2.4和1.4°C时,预计会降低5%;当GDD以相同的成熟度组顺序偏离200、180和130°C时,估计的减少程度相同。结果表明,与早熟玉米相比,晚熟玉米生物量减少对STP和GDD的偏离更为敏感。因此,在青贮玉米-冬季一年生饲料作物生产体系中,早熟品种的生物量产量更稳定,可提高饲料型牲畜的生产效率。
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来源期刊
Journal of Animal Science and Technology
Journal of Animal Science and Technology Agricultural and Biological Sciences-Food Science
CiteScore
4.50
自引率
8.70%
发文量
96
审稿时长
7 weeks
期刊介绍: Journal of Animal Science and Technology (J. Anim. Sci. Technol. or JAST) is a peer-reviewed, open access journal publishing original research, review articles and notes in all fields of animal science. Topics covered by the journal include: genetics and breeding, physiology, nutrition of monogastric animals, nutrition of ruminants, animal products (milk, meat, eggs and their by-products) and their processing, grasslands and roughages, livestock environment, animal biotechnology, animal behavior and welfare. Articles generally report research involving beef cattle, dairy cattle, pigs, companion animals, goats, horses, and sheep. However, studies involving other farm animals, aquatic and wildlife species, and laboratory animal species that address fundamental questions related to livestock and companion animal biology will also be considered for publication. The Journal of Animal Science and Technology (J. Anim. Technol. or JAST) has been the official journal of The Korean Society of Animal Science and Technology (KSAST) since 2000, formerly known as The Korean Journal of Animal Sciences (launched in 1956).
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