Rapid Construction of LTO/CuO Heterojunctions by Active Screen Plasma for Excellent Lithium-Ion Storage

Abstract: The lower intrinsic capacity and electron/ion transfer rate of Li 4 Ti 5 O 12 limit its application and commercialization in high-specific-energy batteries. In this work, Li 4 Ti 5 O 12 /CuO heterojunctions are constructed by depositing CuO ultrafine nanoparticles on Li 4 Ti 5 O 12 nanosheets using a controllable and high-efficiency active screen plasma (ASP) technique. It is found that the rich interface and built-in electric field provided by the heterojunction enhance the electron conductivity and ionic con… Show more

“…31,32 In addition, the energy exchange caused by the bombardment of high-energy particles allows behavior such as heterojunctions to be achieved at lower threshold temperatures. 33 Du et al constructed a defect-rich twodimensional p−n heterojunction by in situ plasma modification. The heterostructured Zn−N 2 cell exhibited ultrahigh power output and energy density in 0.1 M HCl solution (240 mA•h•g −1 ).…”

“…A power density of up to 109.8 mW cm –2 with no less than 300 stable cycles is presented at the negative electrode in an all-solid-state zinc–air battery . If the bombardment energy is higher than the atomic binding energy of the material surface, it can cause atoms to spill out of the material surface and create structural defects such as vacancies. , In addition, the energy exchange caused by the bombardment of high-energy particles allows behavior such as heterojunctions to be achieved at lower threshold temperatures . Du et al constructed a defect-rich two-dimensional p–n heterojunction by in situ plasma modification.…”

Plasma-Induced Defect Engineering in TiNb₂O₇ for Boosting Lithium-Ion Diffusion

“…31,32 In addition, the energy exchange caused by the bombardment of high-energy particles allows behavior such as heterojunctions to be achieved at lower threshold temperatures. 33 Du et al constructed a defect-rich twodimensional p−n heterojunction by in situ plasma modification. The heterostructured Zn−N 2 cell exhibited ultrahigh power output and energy density in 0.1 M HCl solution (240 mA•h•g −1 ).…”

“…A power density of up to 109.8 mW cm –2 with no less than 300 stable cycles is presented at the negative electrode in an all-solid-state zinc–air battery . If the bombardment energy is higher than the atomic binding energy of the material surface, it can cause atoms to spill out of the material surface and create structural defects such as vacancies. , In addition, the energy exchange caused by the bombardment of high-energy particles allows behavior such as heterojunctions to be achieved at lower threshold temperatures . Du et al constructed a defect-rich two-dimensional p–n heterojunction by in situ plasma modification.…”

Plasma-Induced Defect Engineering in TiNb₂O₇ for Boosting Lithium-Ion Diffusion

γ-Graphyne adjusted diffusion–capacitance behavior of lithium titanate for boosting high-rate and wide-temperature lithium storage

Boosting the zinc-ion storage ability of MnO2 cathode by depositing oxygen-deficient CuOx layer