Cement treatment,such as cement-mixing columns,is commonly used for deep soft soil improvement to increase the bearing capacity and reduce settlement.However,cement production entails high energy consumption and carbo...Cement treatment,such as cement-mixing columns,is commonly used for deep soft soil improvement to increase the bearing capacity and reduce settlement.However,cement production entails high energy consumption and carbon and pollutant emissions.CO_(2)capture and mineralization represent promising solutions to these issues.This study proposes a sustainable alternative:a novel CO_(2)-carbonated MgO-mixing column that integrates CO_(2)mineralization with soil reinforcement.This approach involves in situ mixing of MgO with deep soil to form columns,which are then carbonated and solidified by injecting captured CO_(2)through gas-permeable pipe piles,achieving both carbon reduction and soil improvement.In this study,CO_(2)-carbonated MgO-mixing columns were comprehensively evaluated to investigate variations in strength,deformation,pH,and CO_(2)sequestration with depth.Two rapid and cost-effective methods to assess its mechanical properties,uniformity,and CO_(2)sequestration capacity are proposed.The results show that the carbonated MgO-treated soil has good strength along the depth direction,with an average unconfined compressive strength(UCS)of 1.02 MPa and a lower pH than that of cement-mixing columns.It also achieves notable CO_(2)sequestration,ranging from 4.88%to 13.10%(average 8.31%),and exhibits good uniformity,as shown by electrical resistivity tests.Needle penetration and electrical resistivity tests could be used to effectively predict the UCS,deformation modulus,and CO_(2)sequestration.XRD,FTIR,SEM,and TG-DTG analyses reveal distinct microstructural differences at various depths,with unhydrated MgO,magnesite,and dypingite/hydromagnesite present in shallow columns,and brucite,nesquehonite,and dypingite/hydromagnesite present in deep columns.These products bind soil particles and fill pores,enhancing the strength of the MgO-mixing column.展开更多
基金funded by the National Natural Science Foundation of China(Grant No.42277146)the Postgraduate Research&Practice Innovation Program of Jiangsu Province(Grant No.KYCX22_0273)the Transportation Science and Technology Project of Jiangsu Province of China(Grant No.HTSQ(B)2021-249).
文摘Cement treatment,such as cement-mixing columns,is commonly used for deep soft soil improvement to increase the bearing capacity and reduce settlement.However,cement production entails high energy consumption and carbon and pollutant emissions.CO_(2)capture and mineralization represent promising solutions to these issues.This study proposes a sustainable alternative:a novel CO_(2)-carbonated MgO-mixing column that integrates CO_(2)mineralization with soil reinforcement.This approach involves in situ mixing of MgO with deep soil to form columns,which are then carbonated and solidified by injecting captured CO_(2)through gas-permeable pipe piles,achieving both carbon reduction and soil improvement.In this study,CO_(2)-carbonated MgO-mixing columns were comprehensively evaluated to investigate variations in strength,deformation,pH,and CO_(2)sequestration with depth.Two rapid and cost-effective methods to assess its mechanical properties,uniformity,and CO_(2)sequestration capacity are proposed.The results show that the carbonated MgO-treated soil has good strength along the depth direction,with an average unconfined compressive strength(UCS)of 1.02 MPa and a lower pH than that of cement-mixing columns.It also achieves notable CO_(2)sequestration,ranging from 4.88%to 13.10%(average 8.31%),and exhibits good uniformity,as shown by electrical resistivity tests.Needle penetration and electrical resistivity tests could be used to effectively predict the UCS,deformation modulus,and CO_(2)sequestration.XRD,FTIR,SEM,and TG-DTG analyses reveal distinct microstructural differences at various depths,with unhydrated MgO,magnesite,and dypingite/hydromagnesite present in shallow columns,and brucite,nesquehonite,and dypingite/hydromagnesite present in deep columns.These products bind soil particles and fill pores,enhancing the strength of the MgO-mixing column.
