Improving the use of soil testing in production agriculture may result in increased nutrient use efficiency and profitability. Three studies were conducted in Iowa with this general goal. One study assessed the impact of soil sample drying on K extraction and developed field correlations of an ammonium-acetate K test (AA) based on field-moist samples for corn and soybean. Potassium extracted with AA from dried samples was higher than K extracted from moist samples. The difference increased with increasing drying temperature, was inversely related to the soil K level, and varied among soil series. The moist AA test correlated better with yield response to fertilization than the common test based on dried samples. Critical concentration ranges defined by Cate-Nelson and linear-plateau models across 64 site-years of data for corn (mg K kg-1, 15 cm depth) were 144-201 and 62-76 for dry and moist tests. Ranges for soybean across 57 site-years were 121-214 and 52-90 mg K kg-1, respectively.; A second study compared the efficacy of AA, Mehlich-3, and sodium tetraphenylboron soil K extractants in determining soil K availability for corn and soybean. Mehlich-3 and AA extracted similar amounts of K. Sodium tetraphenylboron extracted K was significantly higher, differences increased with increasing soil K, and decreased as the Ca and Mg to K ratio increased. Mehlich-3 and AA showed similarly poor predictability of crop response to K. The sodium tetraphenylboron test did not improve consistently the predictability of crop response to K. Critical concentration ranges (mg K kg-1, 15 cm depth) for corn across 63 site-years were 133-216, 128-199, and 421-641 for AA, Mehlich-3, and sodium tetraphenylboron tests. Ranges for soybean across 54 site-years were 122-191, 114-185, and 473-556 mg K kg-1, respectively.; A third study examined spatial variability of soil fertility properties (soil-test P, K, Mg, and pH) using geostatistics and compared inverse distance weighting, ordinary kriging, and universal kriging for data interpolation and mapping. Soil-test variability and its spatial structure varied across nutrients and fields. Universal kriging was the least accurate interpolation method. The results indicated that the sampling density required for effective use of variable-rate technology differs across fields.
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机译:在生产农业中改进土壤测试的使用可能会导致养分利用效率和利润的增加。为此,在爱荷华州进行了三项研究。一项研究评估了土壤样品干燥对钾提取的影响,并基于玉米和大豆的田间潮湿样品,开发了乙酸铵钾试验(AA)的田间相关性。用AA从干燥样品中提取的钾含量高于从潮湿样品中提取的钾含量。差异随干燥温度的升高而增加,与土壤钾水平成反比,并且在土壤系列之间变化。与基于干燥样品的普通测试相比,潮湿的AA测试与施肥的产量响应相关性更好。 Cate-Nelson和线性高原模型在64个站点-年数据中得出的临界浓度范围(mg K kg-1,15 cm深度)用于干湿试验为144-201和62-76。在57个站点年中,大豆的范围分别为121-214和52-90 mg K kg-1。第二项研究比较了AA,Mehlich-3和四苯基硼酸钠土壤K萃取剂在确定玉米和大豆的土壤K利用率方面的功效。 Mehlich-3和AA提取的K相似。四苯基硼钠提取的K显着更高,差异随着土壤K的增加而增加,并且随着Ca和Mg与K的比例增加而减小。 Mehlich-3和AA表现出的作物对钾素响应的可预测性相类似地较差。四苯硼钠试验不能始终如一地提高作物对钾素的响应可预测性。63个玉米的临界浓度范围(mg K kg-1,15 cm深度) AA,Mehlich-3和四苯基硼酸钠的测试年数分别为133-216、128-199和421-641。在54个站点年中,大豆的范围分别为122-191、114-185和473-556 mg K kg-1。第三项研究使用地统计学方法研究了土壤肥力特性的空间变异性(土壤测试P,K,Mg和pH),并比较了反向距离权重,普通克里格法和通用克里格法进行数据插值和制图。土壤测试变异性及其空间结构因养分和田地而异。通用克里金法是最不准确的插值方法。结果表明,不同领域有效使用可变速率技术所需的采样密度有所不同。
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