Optimising the acid–base ratio of Mg–Al layered double oxides to enhance CO<sub>2</sub> capture performance: the critical role of calcination conditions

Leung, D. W. Justin; Laney, Katherine R.; Kenyon, Philip; Rees, Nicholas H.; Buffet, Jean-Charles; Chen, Chunping; O'Hare, Dermot

doi:10.1039/d4dt00270a

Dalton Trans.

2024

DOI: 10.1039/d4dt00270a

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Optimising the acid–base ratio of Mg–Al layered double oxides to enhance CO₂ capture performance: the critical role of calcination conditions

D. W. Justin Leung,

Katherine R. Laney,

Philip Kenyon

et al.

Abstract: We investigated the impact of calcination conditions of layered double hydroxide on the formation of layered double oxides and its relationship with CO2 capture.

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Mg_2−xCa_xAl layered double hydroxide-derived mixed metal oxide porous hexagonal nanoplatelets for CO₂ sorption

Bhojaraj,

Nethravathi,

Rajamathi

2024

Dalton Trans.

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Mg_2−xCa_xAl layered double hydroxide-derived mixed metal oxide porous hexagonal nanoplatelets for CO₂ sorption

Bhojaraj,

Nethravathi,

Rajamathi

2024

Dalton Trans.

View full text Add to dashboard Cite

show abstract

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Optimising the acid–base ratio of Mg–Al layered double oxides to enhance CO₂ capture performance: the critical role of calcination conditions

Abstract: We investigated the impact of calcination conditions of layered double hydroxide on the formation of layered double oxides and its relationship with CO2 capture.

Cited by 1 publication

References 29 publications

Mg_2−xCa_xAl layered double hydroxide-derived mixed metal oxide porous hexagonal nanoplatelets for CO₂ sorption

Mg_2−xCa_xAl layered double hydroxide-derived mixed metal oxide porous hexagonal nanoplatelets for CO₂ sorption

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Optimising the acid–base ratio of Mg–Al layered double oxides to enhance CO2 capture performance: the critical role of calcination conditions

Abstract: We investigated the impact of calcination conditions of layered double hydroxide on the formation of layered double oxides and its relationship with CO2 capture.

Cited by 1 publication

References 29 publications

Mg2−xCaxAl layered double hydroxide-derived mixed metal oxide porous hexagonal nanoplatelets for CO2 sorption

Mg2−xCaxAl layered double hydroxide-derived mixed metal oxide porous hexagonal nanoplatelets for CO2 sorption

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Optimising the acid–base ratio of Mg–Al layered double oxides to enhance CO₂ capture performance: the critical role of calcination conditions

Mg_2−xCa_xAl layered double hydroxide-derived mixed metal oxide porous hexagonal nanoplatelets for CO₂ sorption

Mg_2−xCa_xAl layered double hydroxide-derived mixed metal oxide porous hexagonal nanoplatelets for CO₂ sorption