Absorption and desorption of hydrogen in Ti_1.02Cr_1.1Mn_0.3Fe_0.6RE_0.03: experiments, characterization and analytical interpretation using statistical physics treatment

Abstract: XRD patterns of Ti1.02Cr1.1Mn0.3Fe0.6RE0.03 alloys.

“…Recently, high-entropy alloys are emerging as a new category of hydrogen storage materials, and their hydrogen storage capacity, 20 kinetics, 21 thermodynamics, 22 activation properties, 23 and cycling performance 24 are being investigated. In previous studies, [20][21][22][23][24][25][26][27][28][29][30] high-entropy hydrogen storage alloys are basically divided into two types: Laves phase hydrogen storage alloys [25][26][27][28] and BCC solid solution hydrogen storage alloys. [29][30][31] These two types of alloys have different advantages.…”

Enhanced hydrogen storage properties of ZrTiVAl_1−xFe_x high-entropy alloys by modifying the Fe content

“…Recently, high-entropy alloys are emerging as a new category of hydrogen storage materials, and their hydrogen storage capacity, 20 kinetics, 21 thermodynamics, 22 activation properties, 23 and cycling performance 24 are being investigated. In previous studies, [20][21][22][23][24][25][26][27][28][29][30] high-entropy hydrogen storage alloys are basically divided into two types: Laves phase hydrogen storage alloys [25][26][27][28] and BCC solid solution hydrogen storage alloys. [29][30][31] These two types of alloys have different advantages.…”

Enhanced hydrogen storage properties of ZrTiVAl_1−xFe_x high-entropy alloys by modifying the Fe content

From nickel–metal hydride batteries to advanced engines: A comprehensive review of hydrogen's role in the future energy landscape

Laves type intermetallic compounds as hydrogen storage materials: A review