Enhanced Li-ion diffusion and electrochemical performance in strained-manganese–iron oxide core–shell nanoparticles

Abstract: Efforts to improve energy storage depend greatly on the development of efficient electrode materials. Recently, strain has been employed as an alternate approach to improve ion mobility. While lattice strain has been well-researched in catalytic applications, its effects on electrochemical energy storage are largely limited to computational studies due to complexities associated with strain control in nanomaterials as well as loss of strain due to the phase change of the active material during charging–dischar… Show more

“…All Spinels share a common structure but their properties can be tuned by changing their stoichiometry, cation distribution, strain engineering, and by introducing point defects. [1][2][3][4] Moreover, spinel compounds made of earth-abundant elements (Mn, Fe, Ni, etc.) are leading candidates for energy applications.…”

Electronic Structure Study of Various Transition Metal Oxide Spinels Reveals a Possible Design Strategy for Charge Transport Pathways

“…All Spinels share a common structure but their properties can be tuned by changing their stoichiometry, cation distribution, strain engineering, and by introducing point defects. [1][2][3][4] Moreover, spinel compounds made of earth-abundant elements (Mn, Fe, Ni, etc.) are leading candidates for energy applications.…”

Electronic Structure Study of Various Transition Metal Oxide Spinels Reveals a Possible Design Strategy for Charge Transport Pathways

High capacity and excellent cyclic performances of Mn2O3/Mn3O4/C materials as li-ion battery anode

Current understanding of ceria surfaces for CO2 reduction in SOECs and future prospects – A review