Sea level variations in the South China Sea inferred from satellite gravity, altimetry, and oceanographic data

Sea level variations (SLVs) can be divided into two major components: the steric SLV and the mass-induced SLV. These two components of SLV in the South China Sea (SCS) are studied by using satellite altimetry, GRACE (Gravity Recovery and Climate Experiment) satellite gravity, and oceanographic data...

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Published inScience China. Earth sciences Vol. 55; no. 10; pp. 1696 - 1701
Main Authors Feng, Wei, Zhong, Min, Xu, HouZe
Format Journal Article
LanguageEnglish
Published Heidelberg SP Science China Press 01.10.2012
Springer Nature B.V
Subjects
Altimeters
Altimetry
Amplitudes
China
Earth and Environmental Science
Earth Sciences
Geographical distribution
Geophysics
GRACE
GRACE (experiment)
Gravitation
Marine
Physical oceanography
Research Paper
Satellite altimetry
Satellites
Sea level
Sea level rise
Water exchange
中国南海
卫星测高
卫星重力
年际时间尺度
海平面变化
海洋学
空间位阻效应
ISEW, South China Sea
sea level variation
ECCO
GRACE
altimetry
the South China Sea
Online AccessGet full text
ISSN1674-7313
1869-1897
DOI10.1007/s11430-012-4394-3

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Summary:Sea level variations (SLVs) can be divided into two major components: the steric SLV and the mass-induced SLV. These two components of SLV in the South China Sea (SCS) are studied by using satellite altimetry, GRACE (Gravity Recovery and Climate Experiment) satellite gravity, and oceanographic data on annual and inter-annual timescales. On the annual timescale, the geographic distribution of mass-induced SLV's amplitude jointly estimated from altimetry and the ECCO (Estimation of the Circulation and Climate of the Ocean) model agrees very well with that from GRACE. GRACE observes obvious seasonal mass-induced SLV in the SCS with annual amplitude of 2.7±0.4 cm, which is consistent with the annual amplitude of 2.7±0.3 cm estimated from the steric-corrected altimetry. On the inter-annual timescales, the mean SLV in the SCS shows a large os- cillation, which is mainly caused by the steric effect. The trend of mean SLV inferred from altimetry in the SCS is 5.5±0.7 mm/yr for the period of 1993-2009, which is significantly higher than the global sea level rise rate of 3.3±0.4 mm/yr in the same period. There is no obvious trend signal in the mass-induced SLV detected from GRACE that indicates the water exchange between the SCS and its adjacent seas and land is in balance within the study period.
Bibliography:altimetry, GRACE, ECCO, the South China Sea, sea level variation
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Sea level variations (SLVs) can be divided into two major components: the steric SLV and the mass-induced SLV. These two components of SLV in the South China Sea (SCS) are studied by using satellite altimetry, GRACE (Gravity Recovery and Climate Experiment) satellite gravity, and oceanographic data on annual and inter-annual timescales. On the annual timescale, the geographic distribution of mass-induced SLV's amplitude jointly estimated from altimetry and the ECCO (Estimation of the Circulation and Climate of the Ocean) model agrees very well with that from GRACE. GRACE observes obvious seasonal mass-induced SLV in the SCS with annual amplitude of 2.7±0.4 cm, which is consistent with the annual amplitude of 2.7±0.3 cm estimated from the steric-corrected altimetry. On the inter-annual timescales, the mean SLV in the SCS shows a large os- cillation, which is mainly caused by the steric effect. The trend of mean SLV inferred from altimetry in the SCS is 5.5±0.7 mm/yr for the period of 1993-2009, which is significantly higher than the global sea level rise rate of 3.3±0.4 mm/yr in the same period. There is no obvious trend signal in the mass-induced SLV detected from GRACE that indicates the water exchange between the SCS and its adjacent seas and land is in balance within the study period.
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ISSN:1674-7313
1869-1897
DOI:10.1007/s11430-012-4394-3