Wang, Liming;Lee, Xuhui;Wang, Wei;Wang, Xufeng;Wei, Zhongwang;Fu, Congsheng;Gao, Yunqiu;Lu, Ling;Song, Weimin;Su, Peixi;Lin, Guanghui

Source: Journal of Atmospheric and Oceanic Technology:;2017:;volume( 034 ):;issue: 011::page 2475

Author:

Wang, Liming;Lee, Xuhui;Wang, Wei;Wang, Xufeng;Wei, Zhongwang;Fu, Congsheng;Gao, Yunqiu;Lu, Ling;Song, Weimin;Su, Peixi;Lin, Guanghui

DOI: 10.1175/JTECH-D-17-0085.1

Publisher: American Meteorological Society

Abstract: AbstractOpen-path eddy covariance systems are widely used for measuring the CO2 flux between land and atmosphere. A common problem is that they often yield negative fluxes or physiologically unreasonable CO2 uptake fluxes in the nongrowing season under cold conditions. In this study, a meta-analysis was performed on the eddy flux data from 64 FLUXNET sites and the relationship between the observed CO2 flux and the sensible heat flux was analyzed. In theory, these two fluxes should be independent of each other in cold conditions (air temperature lower than 0°C) when photosynthesis is suppressed. However, the results show that a significant and negative linear relationship existed between these two fluxes at 37 of the sites. The mean linear slope value is ?0.008 ± 0.001 µmol m?2 s?1 per W m?2 among the 64 sites analyzed. The slope value was not significantly different among the three gas analyzer models (LI-7500, LI-7500A, IRGASON/EC150) used at these sites, indicating that self-heating may not be the only reason for the apparent wintertime net CO2 uptake. These results suggest a systematic bias toward larger carbon uptakes in the FLUXNET sites that deploy open-path eddy covariance systems.

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contributor author	Wang, Liming;Lee, Xuhui;Wang, Wei;Wang, Xufeng;Wei, Zhongwang;Fu, Congsheng;Gao, Yunqiu;Lu, Ling;Song, Weimin;Su, Peixi;Lin, Guanghui
date accessioned	2018-01-03T11:00:01Z
date available	2018-01-03T11:00:01Z
date copyright	10/5/2017 12:00:00 AM
date issued	2017
identifier other	jtech-d-17-0085.1.pdf
identifier uri	http://138.201.223.254:8080/yetl1/handle/yetl/4245861
description abstract	AbstractOpen-path eddy covariance systems are widely used for measuring the CO2 flux between land and atmosphere. A common problem is that they often yield negative fluxes or physiologically unreasonable CO2 uptake fluxes in the nongrowing season under cold conditions. In this study, a meta-analysis was performed on the eddy flux data from 64 FLUXNET sites and the relationship between the observed CO2 flux and the sensible heat flux was analyzed. In theory, these two fluxes should be independent of each other in cold conditions (air temperature lower than 0°C) when photosynthesis is suppressed. However, the results show that a significant and negative linear relationship existed between these two fluxes at 37 of the sites. The mean linear slope value is ?0.008 ± 0.001 µmol m?2 s?1 per W m?2 among the 64 sites analyzed. The slope value was not significantly different among the three gas analyzer models (LI-7500, LI-7500A, IRGASON/EC150) used at these sites, indicating that self-heating may not be the only reason for the apparent wintertime net CO2 uptake. These results suggest a systematic bias toward larger carbon uptakes in the FLUXNET sites that deploy open-path eddy covariance systems.
publisher	American Meteorological Society
type	Journal Paper
journal volume	34
journal issue	11
journal title	Journal of Atmospheric and Oceanic Technology
identifier doi	10.1175/JTECH-D-17-0085.1
journal fristpage	2475
journal lastpage	2487
tree	Journal of Atmospheric and Oceanic Technology:;2017:;volume( 034 ):;issue: 011
contenttype	Fulltext

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