Silicon-air batteries(SABs),a new type of semiconductor air battery,have a high energy density.However,some side reactions in SABs cause Si anodes to be covered by a passivation layer to prevent continuous discharge,a...Silicon-air batteries(SABs),a new type of semiconductor air battery,have a high energy density.However,some side reactions in SABs cause Si anodes to be covered by a passivation layer to prevent continuous discharge,and the anode utilization rate is low.In this work,reduced graphene oxide(RGO)fabricated via high-temperature annealing or L-ascorbic acid(L.AA)reduction was first used to obtain Si nanowires/RGO-1000(Si NWs/RGO-1000)and Si nanowires/RGO-L.AA(Si NWs/RGO-L.AA)composite anodes for SABs.It was found that RGO suppressed the passivation and self-corrosion reactions and that SABs using Si NWs/RGO-L.AA as the anode can discharge for more than 700 h,breaking the previous performance of SABs,and that the specific capacity was increased by 90.8%compared to bare Si.This work provides a new solution for the design of high specific capacity SABs with nanostructures and anode protective layers.展开更多
Silicon-air(Si-air)batteries have received significant attention owing to their high theoretical energy density and safety profile.However,the actual energy density of the Si-air battery remains significantly lower th...Silicon-air(Si-air)batteries have received significant attention owing to their high theoretical energy density and safety profile.However,the actual energy density of the Si-air battery remains significantly lower than the theoretical value,primarily due to corrosion issues and passivation.This study used various metal-organic framework(MOF)materials,such as MIL-53(Al),MIL-88(Fe),and MIL-101(Cr),to modify Si anodes.The MOFs were fabricated to have different morphologies,particle sizes,and pore sizes by altering their central metal nodes and ligands.This approach aimed to modulate the adsorption behavior of H_(2)O,SiO_(2),and OH^(−),thereby mitigating corrosion and passivation reactions.Under a constant current of 150μA,Si-air batteries with MIL-53(Al)@Si,MIL-88(Fe)@Si,and MIL-101(Cr)@Si as anodes demonstrated lifetimes of 293,412,and 336 h,respectively,surpassing the 276 h observed with pristine silicon anodes.Among these composite anodes,MIL-88(Fe)@Si displayed the best performance due to its superior hydrophobicity and optimal pore size,which enhance OH^(−)migration.This study offers a promising strategy for enhancing Si-air battery performance by developing an anodic protective layer with selective screening properties.展开更多
Germanium(Ge)–air batteries have gained significant attention from researchers owing to their high power density and excellent safety.However,self-corrosion and surface passivation issues of Ge anode limit the develo...Germanium(Ge)–air batteries have gained significant attention from researchers owing to their high power density and excellent safety.However,self-corrosion and surface passivation issues of Ge anode limit the development of high-performance Ge–air batteries.In this study,conductive metal-organic framework(MOF)Ni_(3)(HITP)_(2) material was synthesized by the gas–liquid interface approach.The Ni_(3)(HITP)_(2) material was deposited on the surface of the Ge anode to prevent corrosion and passivation reactions inside the battery.At 16℃,the discharge time of Ge anodes protected with MOFs was extended to 59 h at 195μA cm−2,which was twice that of bare Ge anodes.The positive effect of MOFs on Ge–air batteries at high temperatures was observed for the first time.The Ge@Ni_(3)(HITP)_(2) anodes discharged over 600 h at 65.0μA cm^(−2).The experimental results confirmed that the two-dimensional conductive MOF material effectively suppressed the self-corrosion and passivation on Ge anodes.This work provides new ideas for improving the performance of batteries in extreme environments and a new strategy for anode protection in air batteries.展开更多
Epigallocatechin-3-gallate (EGCG), a naturally occurring compound in green tea, has been widely used as an antioxidant agent. In the present study, model rats with acute spinal cord injury were intraperitoneally inj...Epigallocatechin-3-gallate (EGCG), a naturally occurring compound in green tea, has been widely used as an antioxidant agent. In the present study, model rats with acute spinal cord injury were intraperitoneally injected with 25, 50, and 100 mg/kg EGCG, and spinal cord ultrastructure, oxidative stress reaction, inflammatory factors, and apoptosis-associated gene expression were observed. Results showed that EGCG attenuated neuronal and axonal injury 24 hours post injury. It also decreased serum intedeukin-113, tumor necrosis factor-a, and intercellular adhesion molecule-1 release, and decreased apoptosis-associated gene expression. Furthermore, it increased the level of the superoxide anion (O2-), superoxide dismutase, and B-cell lymphoma/leukemia-2, and reduced malondialdehyde levels. Furthermore, it reduced the expression of the pro-apoptotic protein Bax. Noticeably, EGCG at the 100 mg/kg dosage exhibited similar effects as methylprednisolone sodium succinate, which has been frequently used for clinical acute spinal cord injury. The results demonstrated that EGCG can significantly inhibit inflammation, suppress oxidation, and reduce apoptosis in acute spinal cord injury.展开更多
基金supported by the National Natural Science Foundation of China(No.61904073)Spring City Plan-Special Program for Young Talents(No.K202005007)+4 种基金Yunnan Talents Support Plan for Yong Talents(No.XDYC-QNRC-20220482)Yunnan Local Colleges Applied Basic Research Projects(No.202101BA070001-138)Scientific Research Fund of Yunnan Education Department(No.2023Y0883)Frontier Research Team of Kunming University 2023Key Laboratory of Artificial Microstructures in Yunnan Higher Education。
文摘Silicon-air batteries(SABs),a new type of semiconductor air battery,have a high energy density.However,some side reactions in SABs cause Si anodes to be covered by a passivation layer to prevent continuous discharge,and the anode utilization rate is low.In this work,reduced graphene oxide(RGO)fabricated via high-temperature annealing or L-ascorbic acid(L.AA)reduction was first used to obtain Si nanowires/RGO-1000(Si NWs/RGO-1000)and Si nanowires/RGO-L.AA(Si NWs/RGO-L.AA)composite anodes for SABs.It was found that RGO suppressed the passivation and self-corrosion reactions and that SABs using Si NWs/RGO-L.AA as the anode can discharge for more than 700 h,breaking the previous performance of SABs,and that the specific capacity was increased by 90.8%compared to bare Si.This work provides a new solution for the design of high specific capacity SABs with nanostructures and anode protective layers.
基金financially supported by the National Natural Science Foundation of China (62464010)Spring City Plan-Special Program for Young Talents (K202005007)+3 种基金the Yunnan Talents Support Plan for Yong Talents (XDYC-QNRC-2022-0482)Yunnan Local Colleges Applied Basic Research Projects (202101BA070001-138)Key Laboratory of Artificial Microstructures in Yunnan Higher Educationthe Frontier Research Team of Kunming University 2023
文摘Silicon-air(Si-air)batteries have received significant attention owing to their high theoretical energy density and safety profile.However,the actual energy density of the Si-air battery remains significantly lower than the theoretical value,primarily due to corrosion issues and passivation.This study used various metal-organic framework(MOF)materials,such as MIL-53(Al),MIL-88(Fe),and MIL-101(Cr),to modify Si anodes.The MOFs were fabricated to have different morphologies,particle sizes,and pore sizes by altering their central metal nodes and ligands.This approach aimed to modulate the adsorption behavior of H_(2)O,SiO_(2),and OH^(−),thereby mitigating corrosion and passivation reactions.Under a constant current of 150μA,Si-air batteries with MIL-53(Al)@Si,MIL-88(Fe)@Si,and MIL-101(Cr)@Si as anodes demonstrated lifetimes of 293,412,and 336 h,respectively,surpassing the 276 h observed with pristine silicon anodes.Among these composite anodes,MIL-88(Fe)@Si displayed the best performance due to its superior hydrophobicity and optimal pore size,which enhance OH^(−)migration.This study offers a promising strategy for enhancing Si-air battery performance by developing an anodic protective layer with selective screening properties.
基金National Natural Science Foundation ofChina,Grant/ Award Number: 61904073Spring City Plan-Special Program forYoung Talents,Grant/A ward Number:K202005007+2 种基金Yunnan Talents SupportPlan for Yong Talents,Grant/Award Number: XDYC-QNRC-2022-0482Yunnan Local CollegesApplied Basic Research Projects,Grant/A ward Numbers:202101BA070001-138,2018FH001-016Frontier Research Team of KunmingUniversity 2023。
文摘Germanium(Ge)–air batteries have gained significant attention from researchers owing to their high power density and excellent safety.However,self-corrosion and surface passivation issues of Ge anode limit the development of high-performance Ge–air batteries.In this study,conductive metal-organic framework(MOF)Ni_(3)(HITP)_(2) material was synthesized by the gas–liquid interface approach.The Ni_(3)(HITP)_(2) material was deposited on the surface of the Ge anode to prevent corrosion and passivation reactions inside the battery.At 16℃,the discharge time of Ge anodes protected with MOFs was extended to 59 h at 195μA cm−2,which was twice that of bare Ge anodes.The positive effect of MOFs on Ge–air batteries at high temperatures was observed for the first time.The Ge@Ni_(3)(HITP)_(2) anodes discharged over 600 h at 65.0μA cm^(−2).The experimental results confirmed that the two-dimensional conductive MOF material effectively suppressed the self-corrosion and passivation on Ge anodes.This work provides new ideas for improving the performance of batteries in extreme environments and a new strategy for anode protection in air batteries.
文摘Epigallocatechin-3-gallate (EGCG), a naturally occurring compound in green tea, has been widely used as an antioxidant agent. In the present study, model rats with acute spinal cord injury were intraperitoneally injected with 25, 50, and 100 mg/kg EGCG, and spinal cord ultrastructure, oxidative stress reaction, inflammatory factors, and apoptosis-associated gene expression were observed. Results showed that EGCG attenuated neuronal and axonal injury 24 hours post injury. It also decreased serum intedeukin-113, tumor necrosis factor-a, and intercellular adhesion molecule-1 release, and decreased apoptosis-associated gene expression. Furthermore, it increased the level of the superoxide anion (O2-), superoxide dismutase, and B-cell lymphoma/leukemia-2, and reduced malondialdehyde levels. Furthermore, it reduced the expression of the pro-apoptotic protein Bax. Noticeably, EGCG at the 100 mg/kg dosage exhibited similar effects as methylprednisolone sodium succinate, which has been frequently used for clinical acute spinal cord injury. The results demonstrated that EGCG can significantly inhibit inflammation, suppress oxidation, and reduce apoptosis in acute spinal cord injury.
