一种新型多年生谷物的根系动态变化与年龄有关

Grassland Research Pub Date : 2024-02-08 DOI:10.1002/glr2.12068

Stella Woeltjen, J. Gutknecht, J. Jungers

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摘要

与一年生春小麦（Triticum aestivum L.）相比，多年生谷物中间小麦草（IWG; Thinopyrum intermedium [Host] Barkworth and Dewey）的常备根生物量存量更大。然而，以往的研究并未将根的生长与根的分解分开，这为我们了解根如何随着时间的推移对土壤有机碳（C）累积或其他土壤性质做出贡献提供了重大空白。我们使用成对的顺序取芯法和根系生长取芯法测量了 1 年生 IWG（IWG-1）、2 年生 IWG（IWG-2）和一年生春小麦 0 至 15 厘米土壤深度的立根量、新根生成量、根系分解量以及分解的根系 C 和 N。IWG-1 的总生根量是 IWG-2 的 1.7 倍。相反，IWG-1 和 IWG-2 的根系分解量几乎翻了一番，从 1.39 kg m-3 增加到 2.43 kg m-3。在 IWG 中，随着林分年龄的增长，根系产量减少，根系分解量增加，这表明随着 IWG 林分年龄的增长，生长策略的改变可能会减少根系衍生的 C 对稳定土壤 C 池的贡献。

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Age‐related changes in root dynamics of a novel perennial grain crop

Standing root biomass stocks are larger in the perennial grain intermediate wheatgrass (IWG; Thinopyrum intermedium [Host] Barkworth and Dewey) than annual spring wheat (Triticum aestivum L.). However, previous studies have not separated root growth from root decomposition, which presents a significant gap in our understanding of how roots can contribute to soil organic carbon (C) accrual or other soil properties through time.We used paired sequential coring and root ingrowth cores to measure standing root stock, new root production, root decomposition, and decomposed root C and N from 0 to 15 cm soil depth of 1‐year‐old IWG (IWG‐1), 2‐year‐old IWG (IWG‐2), and annual spring wheat.Standing root stock was 3.2–6.5 and 6.3–9.9 times higher in IWG‐1 and IWG‐2 than wheat. Total root production was 1.7 times greater in IWG‐1 than IWG‐2. Conversely, root decomposition almost doubled from 1.39 to 2.43 kg m−3 between IWG‐1 and IWG‐2.In IWG, decreased root production and increased root decomposition with stand age suggest a change in growth strategy that could reduce the contribution of root‐derived C to stabilized soil C pools as IWG stands age.

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