氮输入量最能预测俄勒冈州威拉米特山谷农田的硝酸盐淋失情况。

Nitrogen inputs best predict farm field nitrate leaching in the Willamette Valley, Oregon.

作者信息

Compton J E, Pearlstein S L, Erban L, Coulombe R A, Hatteberg B, Henning A, Brooks J R, Selker J E

机构信息

US Environmental Protection Agency, Office of Research and Development, Center for Public Health and Environmental Assessment, Pacific Ecological Systems Division, 200 SW 35 St., Corvallis OR 97333, USA.

Oak Ridge Institute for Science and Education postdoctoral participant based at US EPA.

出版信息

Nutr Cycl Agroecosyst. 2021 May 19;120:223-242. doi: 10.1007/s10705-021-10145-6.

DOI:10.1007/s10705-021-10145-6

PMID:34335077

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8318121/

Abstract

Nitrate leaching is an important yet difficult to manage contribution to groundwater and surface water contamination in agricultural areas. We examine 14 farm fields over a four year period (2014-2017) in the southern Willamette Valley, providing 53 sets of annual, field-level agricultural performance metrics related to nitrogen (N), including fertilizer inputs, crop harvest outputs, N use efficiency (NUE), nitrate-N leaching and surplus N. Crop-specific nitrate-N leaching varied widely from 10 kg N hayr in hazelnuts to >200 kg N hayr in peppermint. Averaging across all sites and years, most leaching occurred during fall (60%) and winter (32%). Overall NUE was 57%. We used a graphical approach to explore the relationships between N inputs, surplus, crop N harvest removal and NUE by crop type. The blueberry site had high inputs and surplus, peppermint had high inputs but also high crop N removal and NUE and thus lower surplus, and most wheat crops had high NUE and evidence of using soil N. Annual N surplus was not well correlated with leaching, and leaching varied more by crop type and inputs. Grass seed and hazelnuts, which are dominant crop types in the southern Willamette Valley, were intermediate in terms of NUE, leaching and surplus. Of all performance metrics, N input was most closely aligned with field-level crop N harvest and nitrate leaching, therefore optimizing N inputs may well inform local efforts to reduce groundwater nitrate contamination.

摘要

硝酸盐淋失是农业地区地下水和地表水污染物的一个重要来源，但其管理难度较大。我们在四年期间（2014 - 2017年）对威拉米特河谷南部的14个农田进行了研究，提供了53组与氮（N）相关的年度田间农业绩效指标，包括肥料投入、作物收获产量、氮利用效率（NUE）、硝态氮淋失和剩余氮。不同作物的硝态氮淋失差异很大，从榛子的10千克氮/公顷到薄荷的超过200千克氮/公顷。在所有地点和年份进行平均计算，大部分淋失发生在秋季（60%）和冬季（32%）。总体氮利用效率为57%。我们采用了一种图形化方法来探究氮输入、盈余、作物氮收获去除量以及不同作物类型的氮利用效率之间的关系。蓝莓种植地的投入和盈余较高，薄荷的投入高，但作物氮去除量和氮利用效率也高，因此盈余较低，而大多数小麦作物的氮利用效率较高，且有利用土壤氮的迹象。年度氮盈余与淋失的相关性不强，淋失量因作物类型和投入的不同而有更大差异。草籽和榛子是威拉米特河谷南部的主要作物类型，在氮利用效率、淋失和盈余方面处于中等水平。在所有绩效指标中，氮输入与田间作物氮收获和硝酸盐淋失的相关性最为紧密，因此优化氮输入很可能为当地减少地下水硝酸盐污染的努力提供参考。

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氮输入量最能预测俄勒冈州威拉米特山谷农田的硝酸盐淋失情况。

Nitrogen inputs best predict farm field nitrate leaching in the Willamette Valley, Oregon.

作者信息

Compton J E, Pearlstein S L, Erban L, Coulombe R A, Hatteberg B, Henning A, Brooks J R, Selker J E

机构信息

Oak Ridge Institute for Science and Education postdoctoral participant based at US EPA.

出版信息

Nutr Cycl Agroecosyst. 2021 May 19;120:223-242. doi: 10.1007/s10705-021-10145-6.

DOI:10.1007/s10705-021-10145-6

PMID:34335077

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8318121/

Abstract

摘要

氮输入量最能预测俄勒冈州威拉米特山谷农田的硝酸盐淋失情况。

Nitrogen inputs best predict farm field nitrate leaching in the Willamette Valley, Oregon.

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氮输入量最能预测俄勒冈州威拉米特山谷农田的硝酸盐淋失情况。

Nitrogen inputs best predict farm field nitrate leaching in the Willamette Valley, Oregon.

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