通过对流层监测仪器（TROPOMI）和平流层大气探测卫星（SMAP）确定的农田土壤每日一氧化氮排放量。

Daily Cropland Soil NO Emissions Identified by TROPOMI and SMAP.

作者信息

Huber Daniel E, Steiner Allison L, Kort Eric A

机构信息

Department of Climate and Space Sciences and Engineering University of Michigan Ann Arbor MI USA.

出版信息

Geophys Res Lett. 2020 Nov 28;47(22):e2020GL089949. doi: 10.1029/2020GL089949. Epub 2020 Nov 13.

DOI:10.1029/2020GL089949

PMID:33380760

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7757188/

Abstract

We use TROPOMI (TROPOspheric Monitoring Instrument) tropospheric nitrogen dioxide (NO) measurements to identify cropland soil nitrogen oxide (NO = NO + NO) emissions at daily to seasonal scales in the U.S. Southern Mississippi River Valley. Evaluating 1.5 years of TROPOMI observations with a box model, we observe seasonality in local NO enhancements and estimate maximum cropland soil NO emissions (15-34 ng N m s) early in growing season (May-June). We observe soil NO pulsing in response to daily decreases in volumetric soil moisture (VSM) as measured by the Soil Moisture Active Passive (SMAP) satellite. Daily NO enhancements reach up to 0.8 × 10 molecules cm 4-8 days after precipitation when VSM decreases to ~30%, reflecting emissions behavior distinct from previously defined soil NO pulse events. This demonstrates that TROPOMI NO observations, combined with observations of underlying process controls (e.g., soil moisture), can constrain soil NO processes from space.

摘要

我们利用对流层监测仪器（TROPOMI）对流层二氧化氮（NO）测量数据，在美国密西西比河谷南部每日至季节尺度上识别农田土壤氮氧化物（NO = NO + NO）排放。通过箱式模型评估1.5年的TROPOMI观测数据，我们观测到当地NO增强的季节性变化，并估计在生长季节早期（5月至6月）农田土壤NO排放最大值为（15 - 34纳克氮/米²/秒）。我们观测到土壤NO随土壤湿度主动被动探测（SMAP）卫星测量的土壤体积含水量（VSM）每日下降而出现脉冲现象。当VSM降至约30%时，降水后4 - 8天每日NO增强可达0.8×10¹³分子/厘米³，这反映出与先前定义的土壤NO脉冲事件不同的排放行为。这表明TROPOMI NO观测数据与潜在过程控制（如土壤湿度）观测数据相结合，能够从太空约束土壤NO过程。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6f81/7757188/95732a0444dd/GRL-47-e2020GL089949-g001.jpg

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通过对流层监测仪器（TROPOMI）和平流层大气探测卫星（SMAP）确定的农田土壤每日一氧化氮排放量。

Daily Cropland Soil NO Emissions Identified by TROPOMI and SMAP.

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