Patterns of water-extractable soil organic matter in the US Great Plains: Insights from the Haas Soil Archive

IF 1.5 Q3 AGRONOMY Agrosystems, Geosciences & Environment Pub Date : 2025-03-31 DOI:10.1002/agg2.70060

Jonathan J. Halvorson, Angela M. Hansen, Catherine E. Stewart, Mark A. Liebig

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Abstract

Novel approaches that are fast and sensitive are needed to evaluate soil change and integrate soil ecosystem properties. Carbon (C) and nitrogen (N) extracted from soil with water are associated with plant nutrients and microbial activity but information about change over time in the US Great Plains is sparse. We used cool (20°C) and hot (80°C) water extracts from historic (1947) and contemporary (2018) soil samples collected at Moccasin, MT; Akron, CO; and Big Spring, TX; to examine changes to labile C and N and optical properties after 71 years of dryland cropping. Concentrations of C and N extracted with cool water decreased between 1947 and 2018 in surface (0–15.2 cm) samples from Moccasin, by 52% and 35%, and Big Spring, by 37% and 32%, but remained unchanged at Akron. Conversely, net (hot−cool) extractable C did not change at Moccasin or Big Spring but increased at Akron by 26%. Net extractable N decreased at Moccasin by 22% but did not change elsewhere. Sequential principal component analysis and stepwise discriminant analysis identified three important optical properties. Values of SUVA₂₅₄ (where SUVA₂₅₄ is the specific ultraviolet absorbance at 254 nm) in extracts did not change at Moccasin between 1947 and 2018 but increased at Akron, indicating increased aromaticity. Conversely, SUVA₂₅₄ decreased at Big Spring. Values for Sag_350–400 (where Sag_350–400 is the slope from a nonlinear fit of an exponential function to the absorption spectrum over the wavelength range from 350 to 400 nm), inversely related to extract molecular weight and aromaticity, decreased at Moccasin but not elsewhere. The proportion of recalcitrant to labile compounds, C:T (where C:T is the ratio of fluorescence intensity from Peak C [ex340/em440] to Peak T [ex275/em340]), increased in extracts from all sites but especially at Akron. Together, these methods provided insights into soil change while conserving samples.

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美国大平原水可提取土壤有机质的模式：来自哈斯土壤档案的见解

需要快速、灵敏地评价土壤变化和综合土壤生态系统特性的新方法。随水从土壤中提取的碳(C)和氮(N)与植物养分和微生物活动有关，但关于美国大平原随时间变化的信息很少。我们使用低温（20°C）和高温（80°C）水提取物，提取自历史（1947年）和当代（2018年）在MT Moccasin采集的土壤样本；阿克伦有限公司;德克萨斯州的大泉；研究71年旱地种植后，土壤活性碳、氮和光学特性的变化。1947年至2018年间，在Moccasin和Big Spring的地表（0-15.2 cm）样品中，冷水提取的C和N浓度分别下降了52%和35%，下降了37%和32%，但在Akron保持不变。相反，在Moccasin和Big Spring，净（热-冷）可提取碳含量没有变化，但在Akron增加了26%。Moccasin的净可提取氮减少了22%，但其他地方没有变化。序贯主成分分析和逐步判别分析确定了三个重要的光学特性。1947 - 2018年间，Moccasin萃取物中SUVA254（其中SUVA254为254 nm的特定紫外吸光度）的值没有变化，但在Akron萃取物中增加，表明芳香性增加。相反，在大泉，SUVA254减少。Sag350-400的值（其中Sag350-400是指数函数的非线性拟合到350 - 400 nm波长范围内的吸收光谱的斜率）与萃取物的分子量和芳香性呈负相关，在Moccasin下降，但在其他地方没有。顽固性和不稳定化合物的比例C:T（其中C:T是C峰[ex340/em440]与T峰[ex275/em340]的荧光强度之比）在所有位点的提取物中都有所增加，但在Akron位点尤为明显。总之，这些方法在保存样品的同时提供了对土壤变化的见解。

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