This work comprehensively reviews the recent advances for chemical-loo** reforming of
CH 4 (CLR) technology, which breaks down the traditional CH 4 reforming process …

Chemical‐loo** technology provides a versatile platform to convert methane in a clean
and efficient manner, achieving CO2 capture and generation of syngas/pure H2 without …

As a promising approach for carbon dioxide capture, chemical loo** combustion has been
extensively investigated for more than two decades. However, the chemical loo** strategy …

A series of bimetallic Fe-Ni/MgAl2O4 catalysts with Fe/Ni ratios between 0 and 1.5 have
been examined for methane dry reforming at 923–1073 K, atmospheric pressure, and a …

Efficient CO2 transformation from a waste product to a carbon source for chemicals and fuels
will require reaction conditions that effect its reduction. We developed a “super-dry” CH4 …

By employing metal oxides as oxygen carriers, chemical loo** demonstrates its
effectiveness in transferring oxygen between reduction and oxidation environments to …

Effective integration of CO 2 capture and its conversion is an attractive strategy to reduce the
anthropogenic CO 2 emissions meanwhile achieve the potential revenue of CO 2 molecule …

Chemical loo** dry reforming of methane (CLDRM) is performed by exposing a Ni/CeO 2
solid to CH 4 and CO 2 in a cyclic way. The solid acts as an oxygen vector producing syngas …

Modulating the oxygen-metal interface that enables efficient and selective C–H activation
remains challenging. Herein, we present a novel MoC x O y oxygen carrier for syngas …

Rational design of perovskite-type redox catalysts is still challenging due to the limited
understanding of the correlation between structural distortion and lattice oxygen activity …