Chemical characterization and function of soil organic nitrogen in prairie agroecosystems

草原农业生态系统土壤有机氮的化学特征及功能

• 批准号: 203182-2011
• 负责人: Walley, Frances
• 金额: $ 2.4万
• 依托单位: University of Saskatchewan
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2015
• 资助国家: 加拿大
• 起止时间: 2015-01-01 至 2016-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=569892
• 关键词: Chemical; characterization; function; soil; organic

My program focuses on soil N and N-cycling. Of particular interest has been the examination of soil organic N (SON) fractions with the goal of understanding how various organic N pools contribute to bioavailable N, both from an agricultural sustainability perspective (i.e., soil quality and soil fertility) and from an environmental perspective (i.e., environmental losses). The proposed research builds on existing work in which we use synchrotron-based N and C K-edge X-ray absorption near-edge structure (N- and C-XANES) to examine SON in bulk soil, and soil chemical and physical fractions. The long-term objective is to characterize the molecular composition of key chemical and physical SON pools, with the goal of identifying measureable bioavailable SON pools and examining their implications for ecological functions within agricultural ecosystems. The short-term objectives of the proposed research are: 1) to examine and characterize the occurrence and nature of unique SON compounds as affected by agricultural management practices and define relationships between the structure of these compounds and N bioavailability; and 2) to examine the speciation of SON in stable soil micro- and macro-aggregates, with the goal of elucidating potential mechanisms by which N (and C) is stabilized and protected in these physical fractions. Although others have used synchrotron radiation to examine soil and environmental samples, limited attention has been paid to SON largely due to the low levels of N typically present in soils, together with relatively low detection limits. Ongoing improvements to detections limits have opened new avenues for exploration of SON. Our work represents some of the earliest applications of N-XANES to soil and environmental samples, and we are well positioned to further advance this highly novel analytical technique as a defendable approach to examining SON at the molecular level, to resolve some of the controversy existing in the literature regarding the nature of SON, and to ascertain mechanisms by which SON is stabilized in soil chemical and physical (i.e., soil aggregates) fractions.

我的项目重点是土壤氮和氮循环。特别感兴趣的是土壤有机氮（SON）组分的检查，目的是了解各种有机氮库如何有助于生物有效氮，无论是从农业可持续性的角度（即，土壤质量和土壤肥力）和从环境角度（即，环境损失）。拟议的研究建立在现有的工作中，我们使用同步加速器为基础的N和C K边X射线吸收近边结构（N-和C-XANES）检查SON在散装土壤，土壤化学和物理组分。 长期目标是表征关键化学和物理SON池的分子组成，目标是确定可测量的生物可利用SON池，并研究其对农业生态系统内生态功能的影响。短期目标是：1）研究和表征受农业管理措施影响的独特SON化合物的发生和性质，并确定这些化合物的结构与N生物有效性之间的关系;以及2）检测SON在稳定的土壤微团聚体和大团聚体中的形态，目的是阐明N（和C）在这些物理级分中被稳定和保护的潜在机制。虽然其他人已经使用同步辐射检查土壤和环境样品，有限的关注已经支付给SON主要是由于低水平的N通常存在于土壤中，连同相对较低的检测限。对检测极限的持续改进为SON的探索开辟了新的途径。我们的工作代表了N-XANES在土壤和环境样品中的一些最早应用，并且我们处于有利地位，以进一步推进这种高度新颖的分析技术，作为在分子水平上检查SON的可行方法，以解决文献中存在的关于SON性质的一些争议，并确定SON在土壤化学和物理中稳定的机制（即，土壤团聚体）组分。