Abstract

The solid Earth deforms elastically in response to variations of surface atmosphere, hydrology, and ice/glacier mass loads. Continuous geodetic observations by Global Positioning System (CGPS) stations and Gravity Recovery and Climate Experiment (GRACE) record such deformations to estimate seasonal and secular mass changes. In this paper, we present the seasonal variation of the surface mass changes and the crustal vertical deformation in the South China Block (SCB) identified by GPS and GRACE observations with records spanning from 1999 to 2016. We used 33 CGPS stations to construct a time series of coordinate changes, which are decomposed by empirical orthogonal functions (EOFs) in SCB. The average weighted root-mean-square (WRMS) reduction is 38% when we subtract GRACE-modeled vertical displacements from GPS time series. The first common mode shows clear seasonal changes, indicating seasonal surface mass re-distribution in and around the South China Block. The correlation between GRACE and GPS time series is analyzed which provides a reference for further improvement of the seasonal variation of CGPS time series. The results of the GRACE observations inversion are the surface deformations caused by the surface mass change load at a rate of about −0.4 to −0.8 mm/year, which is used to improve the long-term trend of non-tectonic loads of the GPS vertical velocity field to further explain the crustal tectonic movement in the SCB and surroundings.

Highlights

  • The mass surface of the Earth is an elastomer, susceptible to some physical phenomena on the surface of the Earth

  • We present a new vertical crustal deformation in South China and surroundings derived by regional continuous Global Positioning System (GPS) and Gravity Recovery and Climate Experiment (GRACE) observations

  • The uncertainly of GPS velocity were improved by removing common mode errors (CME) from time series

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Summary

Introduction

The mass surface of the Earth is an elastomer, susceptible to some physical phenomena on the surface of the Earth. The atmosphere, hydrology and non-tidal ocean mass redistribution will contribute to a flexible deformation of regional crust [1]. Changes in the mass of water, atmosphere and non-tidal ocean during climate cycles perturb the Earth’s gravity field following Newton’s law of gravitation, and the accompanying loading effects on the Earth surface deform the lithosphere [2]. With the development of space satellite technology, we have some in-depth understanding of Earth’s physical phenomena from surface water resources to deep crust dynamics. Global Positioning System (GPS) and Gravity Recovery and Climate. Experiment (GRACE) technology provide us with a variety of trusted data sources.

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