Determining Economic Optimum Soil Sampling Density for Potassium Fertilizer Management in Soybean: A Case Study in the U.S. Mid-South

Research on World Agricultural Economy Pub Date : 2023-12-29 DOI:10.36956/rwae.v4i4.985

Bayarbat Badarch, Michael P. Popp, Aurelie M. Poncet, Shelby T. Rider, N. Slaton

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Abstract

Determining the number of samples to collect in a field to develop soil-test K (STK) maps that are sufficiently accurate for profit-maximizing fertilizer rate prescription maps is complex. The decision also hinges on the application method—variable rate or uniform rate (VRT vs. URT). Using a 400 m2 fishnet grid on a 26.3-ha irrigated soybean field, the authors compared sampling densities ranging from 5 to 60 samples or 5.3 ha/sample to 0.40 ha/sample. Subsequently, the authors simulated yields based on STK maps generated with that range of samples taken to generate i) associated profit-maximizing fertilizer-K rates (K*) that varied by grid with VRT, or ii) a single fertilizer rate based on field-average STK with URT, to compare revenue less fertilizer cost (NR) across VRT, URT, and sampling strategy. With more information, NR increased at a diminishing rate as crop needs could be better matched to fertilizer needs with greater detail in STK maps with VRT. Also, fertilizer use with URT was higher than VRT given the field-specific distribution of STK. Regardless of the sampling strategy, NR was higher for VRT than URT, however, that benefit was smaller than the upcharges for VRT equipment. Marginal benefits from added soil sampling were smaller than their marginal cost leading to an optimal least-cost, 5-sample strategy and URT. Changing one of the 5 sampling locations, however, revealed unreliable field average STK estimates. Since soil samples inform about several macronutrients, splitting soil sampling charges across K and P profitably justified sampling near every 1.5 ha with URT.

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确定大豆钾肥管理的最佳经济土壤采样密度：美国中南部案例研究

要绘制出足够精确的土壤测试钾（STK）图，以实现利润最大化的施肥量处方图，确定在田间采集样本的数量非常复杂。这一决定还取决于施肥方法--变量施肥还是均匀施肥（VRT 与 URT）。作者在一块 26.3 公顷的灌溉大豆田中使用 400 平方米的鱼网网格，比较了 5 到 60 个样本或 5.3 公顷/样本到 0.40 公顷/样本的取样密度。随后，作者根据取样范围内的 STK 图模拟产量，以生成 i) 相关的利润最大化肥料-K 率 (K*)，该肥料-K 率随 VRT 的网格变化而变化；或 ii) 基于田间平均 STK 的单一肥料率，该肥料率随 URT 的变化而变化，以比较不同 VRT、URT 和取样策略下的收入减去肥料成本 (NR)。随着信息量的增加，NR 的增加速度也在减慢，因为使用 VRT 时，作物需求与 STK 地图中更详细的肥料需求可以更好地匹配。此外，鉴于 STK 在田间的具体分布情况，URT 的肥料用量要高于 VRT。无论采用哪种取样策略，VRT 的 NR 均高于 URT，但这一收益小于 VRT 设备的费用。增加土壤取样的边际收益小于其边际成本，因此采用成本最低的 5 个取样策略和 URT 是最优的。然而，改变 5 个取样点中的一个后，发现田间平均 STK 估算值并不可靠。由于土壤样本可提供多种宏量营养元素的信息，因此将 K 和 P 的土壤取样费用分开计算，每 1.5 公顷附近取样一次，并采用 URT，就能获利。

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来源期刊

Research on World Agricultural Economy

CiteScore

0.70

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0.00%

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