The Shanghai laser electron gamma source(SLEGS)is a powerful tool for exploring photonuclear physics,such as giant dipole resonance(GDR)and pygmy dipole resonance,which are the main mechanisms of collective nuclear mo...The Shanghai laser electron gamma source(SLEGS)is a powerful tool for exploring photonuclear physics,such as giant dipole resonance(GDR)and pygmy dipole resonance,which are the main mechanisms of collective nuclear motion.The goal of the SLEGS neutron time-of-flight(TOF)spectrometer is to measure GDR and specific nuclear structures in the energy region above the neutron threshold.The SLEGS TOF spectrometer was designed to hold 20 sets of EJ301 and LaBr3 detectors.Geant4 was used to simulate the efficiency of each detector and the entire spectrometer,which provides a reference for the selection of detectors and layout of the SLEGS TOF spectrometer.Under the events of 208Pb,implementations of coincidence and time-of-flight technology for complex experiments are available;thus,and neutron decay events can be separated.The performance of SLEGS TOF spectrometer was systematically evaluated using offline experiments,in which the time resolution reached approximately 0.9 ns.展开更多
The Shanghai Laser Electron Gamma Source(SLEGS)is a powerful gamma source that provides MeV gamma-ray beams for nuclear science and technology.It was developed as one of the 16 beamline stations in the Phase Ⅱ Projec...The Shanghai Laser Electron Gamma Source(SLEGS)is a powerful gamma source that provides MeV gamma-ray beams for nuclear science and technology.It was developed as one of the 16 beamline stations in the Phase Ⅱ Project of the Shanghai Synchrotron Radiation Facility.The slant-scattering mode is for the first time systematically employed in laser Compton scattering at SLEGS to produce energy-tunable quasi-monoenergetic gamma-ray beams.The SLEGS officially completed its commissioning from July to December 2021.Gamma rays in the energy range of 0.25-21.7 MeV with a flux of 2.1×10^(4)-1.2×10^(7) photons/s and an energy spread of 2-15% were produced during the test.This paper reports the results from commissioning the SLEGS beamline.展开更多
Metal-organic frameworks(MOFs)and their pyrolytic derivates,displaying diverse chemical compositions and microstructures,pro-vide the infinite potential for preparing high-performance microwave absorption materials(MA...Metal-organic frameworks(MOFs)and their pyrolytic derivates,displaying diverse chemical compositions and microstructures,pro-vide the infinite potential for preparing high-performance microwave absorption materials(MAMs)and have attracted extensive at-tention.In this review,we systematically reviewed the recent progress of MOF-based MAMs,including three types of MOF-based MAMs(MOF-derived metal/carbon nanocomposites,MOF-based hybridization materials and conductive MOF).Besides that,the microwave absorption properties and their related physical and chemical appearance were also analyzed.On behalf of synergistic effects between microstructures,dielectric components and magnetic response,the MOF-based MAMs show excellent microwave absorption performance,which is superior to that of traditional single metal,metal alloy and pure carbon-based MAMs.Further-more,the novel conductive MOF with tunable electrical conductivity shows great potential in MAMs due to the fact that it can dra-matically simplify the synthesis process.展开更多
Comprehensive Summary Advanced microwave absorbing materials(MAMs)are urgently required to eliminate and attenuate microwaves to address the ubiquitous microwave radiations and interference.In this contribution,we rep...Comprehensive Summary Advanced microwave absorbing materials(MAMs)are urgently required to eliminate and attenuate microwaves to address the ubiquitous microwave radiations and interference.In this contribution,we report the microwave absorption application of a two-dimensional(2D)semiconductive metal-organic framework(MOF),i.e.,CuHT(HT=4-hydroxythiophenol),without any pyrolysis at high temperature.展开更多
Developing transition metal oxides(TMOs)with high energy,power,and long cycle lifetime for elec-tric energy storage devices remains a critical challenge to date.Herein,we demonstrate a facile method that enables in-si...Developing transition metal oxides(TMOs)with high energy,power,and long cycle lifetime for elec-tric energy storage devices remains a critical challenge to date.Herein,we demonstrate a facile method that enables in-situ transformation of nickel cobalt oxide nanowire arrays(NiCoO NWA)into hierarchical nanowire-nanosheet arrays(ac-NiCoO NWSA)for enhanced energy storage properties.More specifically,the method leads to formation of atomically thin nanosheets(only 2.0 nm)and creates abundant an-tisite defects and oxygen vacancies.Owing to these merits,the as-prepared ac-NiCoO NWSA electrode exhibits over five-fold higher specific capacity,superior rate capability(up to 100 A/g),and excellent cy-cling stability of 10,000 cycles at 50 A/g in alkaline electrolyte compared to pristine NiCoO NWA.Density functional theory(DFT)simulations elucidate the electrochemical activity enhancement mechanism of the TMOs.Moreover,our method triggers similar structural reconstruction phenomenon on other TMOs including ZnCo-,CoMn-and ZnNiCo-oxides,proving the universality of the method.Our findings provide a general method towards simultaneously manipulating the micro-morphologies and defects of TMOs for advanced energy storage devices.展开更多
基金supported by the National Natural Science Foundation of China (Nos.12275338,12005280,11905274 and 11875311)the Key Laboratory of Nuclear Data foundation (JCKY2022201C152)+1 种基金National key research and development program (No.2022YFA1602404)the Strategic Priority Research Program of the CAS (No.XDB34030000).
文摘The Shanghai laser electron gamma source(SLEGS)is a powerful tool for exploring photonuclear physics,such as giant dipole resonance(GDR)and pygmy dipole resonance,which are the main mechanisms of collective nuclear motion.The goal of the SLEGS neutron time-of-flight(TOF)spectrometer is to measure GDR and specific nuclear structures in the energy region above the neutron threshold.The SLEGS TOF spectrometer was designed to hold 20 sets of EJ301 and LaBr3 detectors.Geant4 was used to simulate the efficiency of each detector and the entire spectrometer,which provides a reference for the selection of detectors and layout of the SLEGS TOF spectrometer.Under the events of 208Pb,implementations of coincidence and time-of-flight technology for complex experiments are available;thus,and neutron decay events can be separated.The performance of SLEGS TOF spectrometer was systematically evaluated using offline experiments,in which the time resolution reached approximately 0.9 ns.
基金supported by the National Natural Science Foundation of China(Nos.11875311,11905274,12005280)the Chinese Academy of Sciences President’s International Fellowship Initiative(No.2021VMA0025).
文摘The Shanghai Laser Electron Gamma Source(SLEGS)is a powerful gamma source that provides MeV gamma-ray beams for nuclear science and technology.It was developed as one of the 16 beamline stations in the Phase Ⅱ Project of the Shanghai Synchrotron Radiation Facility.The slant-scattering mode is for the first time systematically employed in laser Compton scattering at SLEGS to produce energy-tunable quasi-monoenergetic gamma-ray beams.The SLEGS officially completed its commissioning from July to December 2021.Gamma rays in the energy range of 0.25-21.7 MeV with a flux of 2.1×10^(4)-1.2×10^(7) photons/s and an energy spread of 2-15% were produced during the test.This paper reports the results from commissioning the SLEGS beamline.
基金supported by the National Natural Science Foundation of China(22071195,21875190,21975204)the Natural Science Foundation of Shaanxi Province of China(2022JQ-110)and the Guangdong Basic and Applied Basic Research Foundation(2021A1515110169)。
文摘Metal-organic frameworks(MOFs)and their pyrolytic derivates,displaying diverse chemical compositions and microstructures,pro-vide the infinite potential for preparing high-performance microwave absorption materials(MAMs)and have attracted extensive at-tention.In this review,we systematically reviewed the recent progress of MOF-based MAMs,including three types of MOF-based MAMs(MOF-derived metal/carbon nanocomposites,MOF-based hybridization materials and conductive MOF).Besides that,the microwave absorption properties and their related physical and chemical appearance were also analyzed.On behalf of synergistic effects between microstructures,dielectric components and magnetic response,the MOF-based MAMs show excellent microwave absorption performance,which is superior to that of traditional single metal,metal alloy and pure carbon-based MAMs.Further-more,the novel conductive MOF with tunable electrical conductivity shows great potential in MAMs due to the fact that it can dra-matically simplify the synthesis process.
基金This work was financially supported by the National Natural Science Foundation of China(21875190)Polymer Electromagnetic Functional Materials Innovation Team of Shaanxi Sanqin Scholars,the Natural Science Basic Research Plan in Shaanxi Province of Distinguished Young Scholar(2018JC-008)China Postdoctoral Science Foundation(2018M643724).
基金supported by the National Science Fund for Distinguished Young Scholars(No.52025034)the National Natural Science Foundation of China(Nos.22071195,21805227,21875190,21905229)+2 种基金the Fundamental Research Funds for the Central Universities(No.3102017jc01001)the Natural Science Foundation of Shaanxi Province of China(Nos.2019JQ627,2020JQ135,2020JQ133)the Youth Innovation Team of Shaanxi Universities and Innovation Team of Shaanxi Sanqin Scholars.
文摘Comprehensive Summary Advanced microwave absorbing materials(MAMs)are urgently required to eliminate and attenuate microwaves to address the ubiquitous microwave radiations and interference.In this contribution,we report the microwave absorption application of a two-dimensional(2D)semiconductive metal-organic framework(MOF),i.e.,CuHT(HT=4-hydroxythiophenol),without any pyrolysis at high temperature.
基金supported by National Natural Science Foundation of China (Nos. 21905229, 22071195 and 21805227)China Postdoctoral Science Foundation (No. 2020M683557)+2 种基金Fundamental Research Funds for the Central Universities (No. 3102017jc01001)the postgraduate research scholarship at Queensland University of Technology (QUT-PRA scholarship)the Youth Innovation Team of Shaanxi Universities
文摘Developing transition metal oxides(TMOs)with high energy,power,and long cycle lifetime for elec-tric energy storage devices remains a critical challenge to date.Herein,we demonstrate a facile method that enables in-situ transformation of nickel cobalt oxide nanowire arrays(NiCoO NWA)into hierarchical nanowire-nanosheet arrays(ac-NiCoO NWSA)for enhanced energy storage properties.More specifically,the method leads to formation of atomically thin nanosheets(only 2.0 nm)and creates abundant an-tisite defects and oxygen vacancies.Owing to these merits,the as-prepared ac-NiCoO NWSA electrode exhibits over five-fold higher specific capacity,superior rate capability(up to 100 A/g),and excellent cy-cling stability of 10,000 cycles at 50 A/g in alkaline electrolyte compared to pristine NiCoO NWA.Density functional theory(DFT)simulations elucidate the electrochemical activity enhancement mechanism of the TMOs.Moreover,our method triggers similar structural reconstruction phenomenon on other TMOs including ZnCo-,CoMn-and ZnNiCo-oxides,proving the universality of the method.Our findings provide a general method towards simultaneously manipulating the micro-morphologies and defects of TMOs for advanced energy storage devices.
