0 INTRODUCTION The carbon buried in marine sediments in the form of organic carbon or carbonate minerals represents the largest pathway for carbon removal from Earth's surface environments(Sun and Turchyn,2014).Mi...0 INTRODUCTION The carbon buried in marine sediments in the form of organic carbon or carbonate minerals represents the largest pathway for carbon removal from Earth's surface environments(Sun and Turchyn,2014).Microbial sulfate reduction(MSR)is a fundamental biogeochemical process occurring in marine sediments,where sulfate-reducing bacteria(SRB)reduce sulfate(SO42-)to sulfide(S2-)using organic matter or methane as electron donors(Jorgensen,2021).展开更多
Marine sediments are the most significant reservoir of organic carbon(OC)in Earth′s surface system.Iron,a crucial component of the marine biogeochemical cycle,has a considerable impact on marine ecology and carbon cy...Marine sediments are the most significant reservoir of organic carbon(OC)in Earth′s surface system.Iron,a crucial component of the marine biogeochemical cycle,has a considerable impact on marine ecology and carbon cycling.Understanding the effect of iron on the preservation of OC in marine sediments is essential for comprehending biogeochemical processes of carbon and climate change.This review summarizes the methods for characterizing the content and structure of iron-bound OC and explores the influencing mechanism of iron on OC preservation in marine sediments from two aspects:the selective preservation of OC by reactive iron minerals(iron oxides and iron sulfides)and iron redox processes.The selective preservation of sedimentary OC is influenced by different types of reactive iron minerals,OC reactivity,and functional groups.The iron redox process has dual effects on the preservation and degradation of OC.By considering sedimentary records of iron-bound OC across diverse marine environments,the role of iron in long-term preservation of OC and its significance for carbon sequestration are illustrated.Future research should focus on identifying effective methods for extracting reactive iron,the effect of diverse functional groups and marine sedimentary environments on the selective preservation of OC,and the mediation of microorganisms.Such work will help elucidate the influencing mechanisms of iron on the long-term burial and preservation of OC and explore its potential application in marine carbon sequestration to maximize its role in achieving carbon neutrality.展开更多
According to the IPCC Sixth Assessment Report,the global sea level is rising rapidly and rose up to 3.7 mm/a during 2006–2018,which seriously threatens the lives of people in coastal areas.Therefore,it is important t...According to the IPCC Sixth Assessment Report,the global sea level is rising rapidly and rose up to 3.7 mm/a during 2006–2018,which seriously threatens the lives of people in coastal areas.Therefore,it is important to scientifically assess the mode of sealevel change in a global warming context.However,our ability to predict sea-level rise and its impact on coastal zones is hampered by limited instrumental observations.展开更多
基金supported by the National Key Research and Development Program of China(No.2022YFE0136300)the National Natural Science Foundation of China(Nos.42276060,42076031)+1 种基金the Natural Science Foundation of Shandong Province(No.ZR2021YQ26)the Taishan Scholars Program of Shandong Province(No.tsqn201909057).
文摘0 INTRODUCTION The carbon buried in marine sediments in the form of organic carbon or carbonate minerals represents the largest pathway for carbon removal from Earth's surface environments(Sun and Turchyn,2014).Microbial sulfate reduction(MSR)is a fundamental biogeochemical process occurring in marine sediments,where sulfate-reducing bacteria(SRB)reduce sulfate(SO42-)to sulfide(S2-)using organic matter or methane as electron donors(Jorgensen,2021).
基金supported by the Fundamental Research Funds for the Central Universities(Grant No.202241001)the Natural Nature Science Foundation of China(Grant Nos.42076074,42006041&42076034)the Taishan Scholar Program(Grant No.TSQN20182117).
文摘Marine sediments are the most significant reservoir of organic carbon(OC)in Earth′s surface system.Iron,a crucial component of the marine biogeochemical cycle,has a considerable impact on marine ecology and carbon cycling.Understanding the effect of iron on the preservation of OC in marine sediments is essential for comprehending biogeochemical processes of carbon and climate change.This review summarizes the methods for characterizing the content and structure of iron-bound OC and explores the influencing mechanism of iron on OC preservation in marine sediments from two aspects:the selective preservation of OC by reactive iron minerals(iron oxides and iron sulfides)and iron redox processes.The selective preservation of sedimentary OC is influenced by different types of reactive iron minerals,OC reactivity,and functional groups.The iron redox process has dual effects on the preservation and degradation of OC.By considering sedimentary records of iron-bound OC across diverse marine environments,the role of iron in long-term preservation of OC and its significance for carbon sequestration are illustrated.Future research should focus on identifying effective methods for extracting reactive iron,the effect of diverse functional groups and marine sedimentary environments on the selective preservation of OC,and the mediation of microorganisms.Such work will help elucidate the influencing mechanisms of iron on the long-term burial and preservation of OC and explore its potential application in marine carbon sequestration to maximize its role in achieving carbon neutrality.
基金supported by the National Natural Science Foundation of China(42276060 and 41876068)the Natural Science Foundation of Shandong Province(ZR2021YQ26)。
文摘According to the IPCC Sixth Assessment Report,the global sea level is rising rapidly and rose up to 3.7 mm/a during 2006–2018,which seriously threatens the lives of people in coastal areas.Therefore,it is important to scientifically assess the mode of sealevel change in a global warming context.However,our ability to predict sea-level rise and its impact on coastal zones is hampered by limited instrumental observations.
