Tuning the dehydrogenation performance of dibenzyl toluene as liquid organic hydrogen carriers

“…Since many substances can undergo a reversible hydrogenation reaction, the definition of an LOHC depends on the existence of a liquid state under normal conditions [10]. Due to their physical resemblance to conventional liquid fuels, LOHCs hold the potential for easy use and transport within existing infrastructures [11][12][13][14][15]. Aromatic and heterocyclic compounds possess the advantages of high hydrogen storage density, reversible hydrogen absorption and release, the absence of CO 2 as a by-product during dehydrogenation, and compatibility with industrial equipment, making them the most extensively researched and closest to practical application among LOHCs [15,16].…”

Application and Analysis of Liquid Organic Hydrogen Carrier (LOHC) Technology in Practical Projects

“…Since many substances can undergo a reversible hydrogenation reaction, the definition of an LOHC depends on the existence of a liquid state under normal conditions [10]. Due to their physical resemblance to conventional liquid fuels, LOHCs hold the potential for easy use and transport within existing infrastructures [11][12][13][14][15]. Aromatic and heterocyclic compounds possess the advantages of high hydrogen storage density, reversible hydrogen absorption and release, the absence of CO 2 as a by-product during dehydrogenation, and compatibility with industrial equipment, making them the most extensively researched and closest to practical application among LOHCs [15,16].…”

Application and Analysis of Liquid Organic Hydrogen Carrier (LOHC) Technology in Practical Projects

Computation-Based Development of Carrier Materials and Catalysts for Liquid Organic Hydrogen Carrier Systems

Research progress on carbon-based catalysts for catalytic dehydrogenation of liquid organic hydrogen carriers