A review on strategies to LDH-based materials to improve adsorption capacity and photoreduction efficiency for CO2

The novelty of the work: This review introduces briefly the use of LDH materials as adsorbents and photocatalysts for the CO2. [Display omitted] •This review provides a brief introduction to recent strategies to improve adsorption capacity and photoreduction efficiency for CO2 by LDHs based material...

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Published inCoordination chemistry reviews Vol. 386; pp. 154 - 182
Main Authors Yang, Zhong-zhu, Wei, Jing-jing, Zeng, Guang-ming, Zhang, Hua-qing, Tan, Xiao-fei, Ma, Chi, Li, Xue-cheng, Li, Zi-hao, Zhang, Chang
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.05.2019
Subjects
Capture
Carbon dioxide
LDH
Photoreduction
Strategies
LDHs
BC
SEWGS
APS
FBA
Carbon dioxide
TPD
Capture
LDH
DFT
FTIR
LDO
r-GO
PFR
CB
C-LDHs
PSA
PBR
UV
GO
VB
HMS
POM
TGA
IEP
Strategies
Photoreduction
CNF
MWCNT
OCN
OCNT
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Summary:The novelty of the work: This review introduces briefly the use of LDH materials as adsorbents and photocatalysts for the CO2. [Display omitted] •This review provides a brief introduction to recent strategies to improve adsorption capacity and photoreduction efficiency for CO2 by LDHs based materials.•Perspectives and challenges in this field of adsorption and photoreduction of CO2 by LDHs are presented. There has been increasing demand for the fixation of CO2 because the increasing atmospheric concentration of CO2 causes the global warming. Layered double hydroxides (LDHs), known as hydrotalcite-like compounds or ionic lamellar compounds, have attracted increasing research interest because of their promising applications as CO2 adsorbents and photocatalysts. The development of LDH-based materials used as CO2 adsorbents and photocatalysts has been separately reviewed in previous papers. However, few of these reviews include the typical synthesis and modification strategies of LDHs to improve their adsorption capacities and photoreduction efficiencies for CO2. Therefore, in this review we summarized some recent progress made in this field. The co-precipitation method is a simple and rapid method for fabricating the desired LDHs directly, and this synthesis method is readily scaled up for industrial production. A few methods have been used for LDHs modification, including doping LDHs with alkali metal, controlling particle characteristics, and fabrication of junctions. It is evident from the literature survey presented herein that modified LDH-based materials have exhibited good potential for the adsorption and photoreduction of CO2. The unresolved issues and possible improvements of LDHs are also highlighted.
ISSN:0010-8545
1873-3840
DOI:10.1016/j.ccr.2019.01.018