Nanoscaled Oxygen Carrier-Driven Chemical Looping for Carbon Neutrality: Opportunities and Challenges

Abstract: Conspectus Climate change poses unprecedented challenges, demanding efforts toward innovative solutions. Amid these efforts, chemical looping stands out as a promising strategy, attracting attention for its CO2 capture prowess and versatile applications. The chemical looping approach involves fragmenting a single reaction, often a redox reaction, into multiple subreactions facilitated by a carrier, frequently a metal oxide. This innovative method enables diverse chemical transformations while inherently segreg… Show more

“…In the 1970s, the CO 2 acceptor gasification process made significant progress, and this innovative approach involved using a gasifier equipped with CaO to convert coal into syngas. Not only did this facilitate the in situ removal of CO 2 , but it also enhanced hydrogen production through the water-gas shift reaction [7]. Thermochemical studies on the splitting of H 2 O and CO 2 began to gain momentum in the 1980s, initiating a series of investigations into different thermochemical cycles.…”

Advances and Challenges in Oxygen Carriers for Chemical Looping Partial Oxidation of Methane

“…In the 1970s, the CO 2 acceptor gasification process made significant progress, and this innovative approach involved using a gasifier equipped with CaO to convert coal into syngas. Not only did this facilitate the in situ removal of CO 2 , but it also enhanced hydrogen production through the water-gas shift reaction [7]. Thermochemical studies on the splitting of H 2 O and CO 2 began to gain momentum in the 1980s, initiating a series of investigations into different thermochemical cycles.…”

Advances and Challenges in Oxygen Carriers for Chemical Looping Partial Oxidation of Methane

“…Chemical looping is a system involving redox reactions in two or more steps, facilitated by an oxygen carrier, and has been successfully applied for applications such as syngas and H 2 production. [21][22][23][24][25][26][27][28][29][30] Instead of co-feeding air with methanol, in the chemical looping approach, methanol reacts with the lattice oxygen of the carrier to form formaldehyde. The carrier provides the active site as well as the oxygen for executing the reaction.…”

Chemical looping methanol oxidation using supported vanadium phosphorous oxide carriers for formaldehyde production

A nickel-modified perovskite-supported iron oxide oxygen carrier for chemical looping dry reforming of methane for syngas production