Firstly, the Earth's gravitational field from the past Challenging Minisatellite Payload (CHAMP) mission is determined using the energy conservation principle, the combined error model of the cumulative geoid heigh...Firstly, the Earth's gravitational field from the past Challenging Minisatellite Payload (CHAMP) mission is determined using the energy conservation principle, the combined error model of the cumulative geoid height influenced by three instrument errors from the current Gravity Recovery and Climate Experiment (GRACE) and future GRACE Follow-On missions is established based on the semi-analytical method, and the Earth's gravitational field from the executed Gravity Field and Steady-State Ocean Circulation Explorer (GOCE) mission is recovered by the space-time-wise approach. Secondly, the cumulative geoid height errors are 1.727 × 10^-1 m, 1.839 × 10^-1 m and 9.025 × 10^ -2 m at degrees 70,120 and 250 from the implemented three-stage satellite gravity missions consisting of CHAMP, GRACE and GOCE, which preferably accord with those from the existing earth gravity field models involving EIGEN-CHAMP03S, EICEN-GRACE02S and GO_CONS GCF 2 DIR R1. The cumulative geoid height error is 6.847 × 10 ^-2 m at degree 250 from the future GRACE Follow-On mission. Finally, the complementarity among the four-stage satellite gravity missions including CHAMP, GRACE, GOCE and GRACE Follow-On is demonstrated contrastively.展开更多
Semiconductor based photocatalysis that harvests renewable solar energy to produce green hydrogen has attracted widespread attention[1],known for its environmental friendliness,low opera-tional costs,and scalability.E...Semiconductor based photocatalysis that harvests renewable solar energy to produce green hydrogen has attracted widespread attention[1],known for its environmental friendliness,low opera-tional costs,and scalability.Extensive experimental and theoretical explorations have significantly advanced the development of pho-tocatalysts for overall water splitting at laboratory scale[2],by band structure engineering[3],heterostructure construction[4],active site design[5],and even micro-/macro-texture modulation[6,7].Preliminary demonstration and verification of its large-scale application have been accomplished using SrTiO_(3) as photocatalyst[8].However,this technology yet faces the great challenges in practical application,with solar-to-hydrogen conversion efficiency still lower than 2%,suffering from the thermodynamically and kinetically constrained water splitting reactions[9].Although some well documented strategies(e.g.,light concentration,exter-nal heat,and concentrated electrolytes)could overcome these pho-tocatalytic limitations to some extent[10],the introduced harsh reaction conditions would significantly compromise the durability of photocatalysts[11].For example,to realize the practical applica-tion of photocatalytic recycling and upgrading of plastic wastes into solar hydrogen,strong alkaline solutions containing mono-meric constituents should serve as feedstocks for photo-reforming[12],with photocatalysts exposed to the harsh alkaline condition and then suffering from degradation and inactivation.展开更多
基金supported by the Main Direction Program of Knowledge Innovation of Chinese Academy of Sciences for Distinguished Young Scholar(KZCX2-EW-QN114)the National Natural Science Foundation of China(41004006,41131067,11173049 and 41274041)+7 种基金the Merit-based Scientific Research Foundation of the State Ministry of Human Resources and Social Security of China for Returned Overseas Chinese Scholars(Z01101)the Open Research Fund Program of the Key Laboratory of Geospace Environment and Geodesy,Ministry of Education,China(11-01-02)the Open Research Fund Program of the Key Laboratory of Geo-Informatics of National Administration of Surveying,Mapping and Geoinformation of China(201322)the Open Research Fund Program of the State Key Laboratory of Geoinformation Engineering,China(SKLGIE2013-M-1-5)the Main Direction Program of Institute of Geodesy and Geophysics,Chinese Academy of Sciences(Y309451045)the Research Fund Program of State Key Laboratory of Geodesy and Earth's Dynamics,China(Y309491050)the Research Fund of the National Civilian Space Infrastructure Project(Y419341034)the Research Fund of the Lu Jiaxi Young Talent and the Youth Innovation Promotion Association of Chinese Academy of Science(Y305171017)
文摘Firstly, the Earth's gravitational field from the past Challenging Minisatellite Payload (CHAMP) mission is determined using the energy conservation principle, the combined error model of the cumulative geoid height influenced by three instrument errors from the current Gravity Recovery and Climate Experiment (GRACE) and future GRACE Follow-On missions is established based on the semi-analytical method, and the Earth's gravitational field from the executed Gravity Field and Steady-State Ocean Circulation Explorer (GOCE) mission is recovered by the space-time-wise approach. Secondly, the cumulative geoid height errors are 1.727 × 10^-1 m, 1.839 × 10^-1 m and 9.025 × 10^ -2 m at degrees 70,120 and 250 from the implemented three-stage satellite gravity missions consisting of CHAMP, GRACE and GOCE, which preferably accord with those from the existing earth gravity field models involving EIGEN-CHAMP03S, EICEN-GRACE02S and GO_CONS GCF 2 DIR R1. The cumulative geoid height error is 6.847 × 10 ^-2 m at degree 250 from the future GRACE Follow-On mission. Finally, the complementarity among the four-stage satellite gravity missions including CHAMP, GRACE, GOCE and GRACE Follow-On is demonstrated contrastively.
基金supported by the National Natural Science Foun-dation of China(22432003,52225606,and 523B2070).
文摘Semiconductor based photocatalysis that harvests renewable solar energy to produce green hydrogen has attracted widespread attention[1],known for its environmental friendliness,low opera-tional costs,and scalability.Extensive experimental and theoretical explorations have significantly advanced the development of pho-tocatalysts for overall water splitting at laboratory scale[2],by band structure engineering[3],heterostructure construction[4],active site design[5],and even micro-/macro-texture modulation[6,7].Preliminary demonstration and verification of its large-scale application have been accomplished using SrTiO_(3) as photocatalyst[8].However,this technology yet faces the great challenges in practical application,with solar-to-hydrogen conversion efficiency still lower than 2%,suffering from the thermodynamically and kinetically constrained water splitting reactions[9].Although some well documented strategies(e.g.,light concentration,exter-nal heat,and concentrated electrolytes)could overcome these pho-tocatalytic limitations to some extent[10],the introduced harsh reaction conditions would significantly compromise the durability of photocatalysts[11].For example,to realize the practical applica-tion of photocatalytic recycling and upgrading of plastic wastes into solar hydrogen,strong alkaline solutions containing mono-meric constituents should serve as feedstocks for photo-reforming[12],with photocatalysts exposed to the harsh alkaline condition and then suffering from degradation and inactivation.
