Hydrogen is an attractive energy carrier due to its potentially high energy efficiency and low
generation of pollutants, which can be used for transportation and stationary power …

Hydrogen production from thermochemical conversion has been considered the most
promising technology for the use of biomass, and some novel methods are also being …

To clarify the discrepancies between oxygen vacancies (VO) types and concentrations, we
designed two types of VO by substituting Mn 4+ in akhtenskite-type MnO 2 with low-valence …

Chemical-loo** reforming of methane (CLRM) offers an effective approach for
coproducing syngas and pure hydrogen. In this work, CeO 2 nano particles (2–3 nm) are …

Conducting catalytic methane decomposition over Fe catalysts is a green and economic
route to produce H 2 without CO/CO 2 contamination. Fused 65 wt% and impregnated 20 …

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 …

Chemical loo** technology enables achievement of the simultaneous feedstock
conversion and product separation without additional processes via circulating solid …

This review aims to give more understanding of the selection and development of oxygen
carrier materials for chemical loo**. Chemical loo**, a rising star in chemical …

Since CO 2 hydrogenation into higher hydrocarbons is an attractive approach to mitigate
greenhouse effect and to reduce reliance on fossil feedstock, this reaction has been …

Chemical-loo** steam methane reforming (CL-SMR) is a novel process for the co-
production of pure hydrogen and syngas (synthesis gas) without purification processes …