Detecting hotspots of interactions between vegetation greenness and terrestrial water storage using satellite observations

Changes in water availability strongly affect vegetation growth, and vegetation can also modify land water storage by changing the land surface water balance. Here, based on the terrestrial water storage (TWS) data retrieved from the Gravity Recovery and Climate Experiment (GRACE)satellites mission...

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Published inRemote sensing of environment Vol. 231; p. 111259
Main Authors Xie, Xiaoming, He, Bin, Guo, Lanlan, Miao, Chiyuan, Zhang, Yafeng
Format Journal Article
LanguageEnglish
Published New York Elsevier Inc 15.09.2019
Elsevier BV
Subjects
case studies
China
Delayed response
GRACE
GRACE (experiment)
humid zones
Interaction
Investigations
NDVI
normalized difference vegetation index
Normalized difference vegetative index
remote sensing
Satellite observation
Satellites
Strong interactions (field theory)
Surface water
Terrestrial water storage
Vegetation
Vegetation greenness
Vegetation growth
Vegetation index
Water availability
Water balance
Water storage
China
Terrestrial water storage
NDVI
Interaction
GRACE
Vegetation greenness
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Abstract Changes in water availability strongly affect vegetation growth, and vegetation can also modify land water storage by changing the land surface water balance. Here, based on the terrestrial water storage (TWS) data retrieved from the Gravity Recovery and Climate Experiment (GRACE)satellites mission and the normalized difference vegetation index (NDVI) from Jan. 2003 to Dec. 2015, we investigate the interplay between land water and vegetation greenness at a global scale. The results reveal a coherent trend with statistical significance between the terrestrial water storage anomaly (TWSA) and the NDVI in 20.90% of global vegetated lands in contrast to a non-coherent trend of 20.87% in global vegetated lands. Vegetation greenness exhibits a common 0- to 1-month delayed response to the TWSA, and significant positive TWSA-NDVI relationships appear in approximately 43.17% of global vegetated areas. A comparison study suggests that the response of vegetation greenness to the TWSA is more rapid than that to precipitation. Interactions between the TWSA and NDVI are further investigated by using the Granger causality test technique. Globally, a strong interaction between the TWSA and NDVI occurs in over 16.75% of vegetated areas. Simultaneously, vegetation greenness is found to be the Granger cause of the TWSA in over 40.34% of global vegetated areas, indicating widespread impacts of vegetation change on variations in land water storage. A case study in China suggests that vegetation greenness increase is an important reason for the decrease in the TWSA in North and Northwest China, which are traditionally water-limited-growth regions. In two humid regions, Southwest and South China, the influence of the TWSA on vegetation greenness seems to be stronger than that of vegetation greenness on the TWSA. Our study suggests that the GRACE TWS is a useful tool for investigations of interactions between vegetation greenness and land water conditions. •Temporal relationships between the NDVI and TWSA derived from GRACE were examined.•A significant response of the NDVI to TWSA was found over 43.17% of global vegetated areas.•The response of the NDVI to TWSA is more rapid than that to precipitation.•Interactions between the NDVI and TWSA were detected over 16.75% of global vegetated areas.
AbstractList Changes in water availability strongly affect vegetation growth, and vegetation can also modify land water storage by changing the land surface water balance. Here, based on the terrestrial water storage (TWS) data retrieved from the Gravity Recovery and Climate Experiment (GRACE)satellites mission and the normalized difference vegetation index (NDVI) from Jan. 2003 to Dec. 2015, we investigate the interplay between land water and vegetation greenness at a global scale. The results reveal a coherent trend with statistical significance between the terrestrial water storage anomaly (TWSA) and the NDVI in 20.90% of global vegetated lands in contrast to a non-coherent trend of 20.87% in global vegetated lands. Vegetation greenness exhibits a common 0- to 1-month delayed response to the TWSA, and significant positive TWSA-NDVI relationships appear in approximately 43.17% of global vegetated areas. A comparison study suggests that the response of vegetation greenness to the TWSA is more rapid than that to precipitation. Interactions between the TWSA and NDVI are further investigated by using the Granger causality test technique. Globally, a strong interaction between the TWSA and NDVI occurs in over 16.75% of vegetated areas. Simultaneously, vegetation greenness is found to be the Granger cause of the TWSA in over 40.34% of global vegetated areas, indicating widespread impacts of vegetation change on variations in land water storage. A case study in China suggests that vegetation greenness increase is an important reason for the decrease in the TWSA in North and Northwest China, which are traditionally water-limited-growth regions. In two humid regions, Southwest and South China, the influence of the TWSA on vegetation greenness seems to be stronger than that of vegetation greenness on the TWSA. Our study suggests that the GRACE TWS is a useful tool for investigations of interactions between vegetation greenness and land water conditions.
Changes in water availability strongly affect vegetation growth, and vegetation can also modify land water storage by changing the land surface water balance. Here, based on the terrestrial water storage (TWS) data retrieved from the Gravity Recovery and Climate Experiment (GRACE)satellites mission and the normalized difference vegetation index (NDVI) from Jan. 2003 to Dec. 2015, we investigate the interplay between land water and vegetation greenness at a global scale. The results reveal a coherent trend with statistical significance between the terrestrial water storage anomaly (TWSA) and the NDVI in 20.90% of global vegetated lands in contrast to a non-coherent trend of 20.87% in global vegetated lands. Vegetation greenness exhibits a common 0- to 1-month delayed response to the TWSA, and significant positive TWSA-NDVI relationships appear in approximately 43.17% of global vegetated areas. A comparison study suggests that the response of vegetation greenness to the TWSA is more rapid than that to precipitation. Interactions between the TWSA and NDVI are further investigated by using the Granger causality test technique. Globally, a strong interaction between the TWSA and NDVI occurs in over 16.75% of vegetated areas. Simultaneously, vegetation greenness is found to be the Granger cause of the TWSA in over 40.34% of global vegetated areas, indicating widespread impacts of vegetation change on variations in land water storage. A case study in China suggests that vegetation greenness increase is an important reason for the decrease in the TWSA in North and Northwest China, which are traditionally water-limited-growth regions. In two humid regions, Southwest and South China, the influence of the TWSA on vegetation greenness seems to be stronger than that of vegetation greenness on the TWSA. Our study suggests that the GRACE TWS is a useful tool for investigations of interactions between vegetation greenness and land water conditions. •Temporal relationships between the NDVI and TWSA derived from GRACE were examined.•A significant response of the NDVI to TWSA was found over 43.17% of global vegetated areas.•The response of the NDVI to TWSA is more rapid than that to precipitation.•Interactions between the NDVI and TWSA were detected over 16.75% of global vegetated areas.
ArticleNumber 111259
Author He, Bin
Zhang, Yafeng
Guo, Lanlan
Xie, Xiaoming
Miao, Chiyuan
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  givenname: Lanlan
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  organization: State Key Laboratory of Earth Surface Processes and Resource Ecology, Faculty of Geographical Science, Beijing Normal University, Beijing 100875, China
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  givenname: Chiyuan
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  organization: State Key Laboratory of Earth Surface Processes and Resource Ecology, Faculty of Geographical Science, Beijing Normal University, Beijing 100875, China
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  givenname: Yafeng
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  organization: State Key Laboratory of Earth Surface Processes and Resource Ecology, College of Global Change and Earth System Science, Beijing Normal University, Beijing 100875, China
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Vegetation greenness
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Snippet Changes in water availability strongly affect vegetation growth, and vegetation can also modify land water storage by changing the land surface water balance....
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SubjectTerms case studies
China
Delayed response
GRACE
GRACE (experiment)
humid zones
Interaction
Investigations
NDVI
normalized difference vegetation index
Normalized difference vegetative index
remote sensing
Satellite observation
Satellites
Strong interactions (field theory)
Surface water
Terrestrial water storage
Vegetation
Vegetation greenness
Vegetation growth
Vegetation index
Water availability
Water balance
Water storage
Title Detecting hotspots of interactions between vegetation greenness and terrestrial water storage using satellite observations
URI https://dx.doi.org/10.1016/j.rse.2019.111259
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