High‐Pressure Induction and Quantitative Regulation of Oxygen Vacancy Defects in Lithium Titanate

Abstract: Inspired by the functional properties of ion defect induction and charge compensation in defect engineering, these methods are expected to be an effective strategy to solve the constraints of Li4Ti5O12 (LTO) inherent conductivity and diffusion dynamics, and further improve battery rate performance. The oxygen vacancy (OV) content in LTO can be controlled quantitatively by high‐pressure induction using the high‐pressure and high‐temperature (HPHT) method. In addition, the relationship between the electrochemica… Show more

“…External pressure implementation has been conducive to exploration of new matters, , development of novel functionalities, , and realization of unprecedented performances. , Although external physical pressure, which is at the macroscale, has been utilized in a wide range of research areas, it not only requires a large platform, expensive facilities, and tedious operation, but it is also apt to cause particle agglomeration, form crystallographic defects, and thus affect unambiguous data interpretation. In a parallel manner, chemical pressure is at the nanoscale and is generated by selective doping of certain substances, such as metal cations , or nonmetal anions with different ionic radius or charges from those to be replaced, into expected positions of crystal lattices .…”

Luminescence-Monitored Progressive Chemical Pressure Implementation Realized through Successive Y³⁺ and Mg²⁺ Doping into Ca_10.5(PO₄)₇:Eu²⁺

“…External pressure implementation has been conducive to exploration of new matters, , development of novel functionalities, , and realization of unprecedented performances. , Although external physical pressure, which is at the macroscale, has been utilized in a wide range of research areas, it not only requires a large platform, expensive facilities, and tedious operation, but it is also apt to cause particle agglomeration, form crystallographic defects, and thus affect unambiguous data interpretation. In a parallel manner, chemical pressure is at the nanoscale and is generated by selective doping of certain substances, such as metal cations , or nonmetal anions with different ionic radius or charges from those to be replaced, into expected positions of crystal lattices .…”

Luminescence-Monitored Progressive Chemical Pressure Implementation Realized through Successive Y³⁺ and Mg²⁺ Doping into Ca_10.5(PO₄)₇:Eu²⁺

“…treated natural graphite in a CO 2 atmosphere to obtain graphite anodes with inherent lattice defects, exhibiting good rate performance . Prior to this, our team utilized HPHT technology to synthesize lithium titanate materials with oxygen vacancy defects, significantly improving rate and cycling performance. , However, there have been no literature reports on the rapid preparation of artificial graphite through catalytic pyrolysis under pressure.…”

Ultrafast Catalytic Pyrolysis and Induction of High-Rate Artificial Defect Graphite under High Pressure

Defective heterojunctions in CO2 photoreduction: Enabling ultrafast interfacial charge transfer and selective methanation