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  • 通讯作者

    21.Zonggang Qiu, Jiyuan Guo, * Qun Wang, Han Wang and Xiangxiang Tan,Reversible hydrogen storage and release
    mechanism of a B2N monolayer: a first-principles insight. Phys. Chem. Chem. Phys., 2024,26, 22240-22251.

    https://doi.org/10.1039/D4CP02159B3区,Impact Factor 2.9

    20. Qun Wang, Jiyuan Guo *, Zonggang Qiu, Xiangxiang Tan, Han Wang,Unveiling reversible hydrogen storage mechanism for the 2D penta-SiCN material, International journal o f hydrogen energy 77 ( 2024 ) 486-494.


    https://doi.org/10.1016/j.ijhydene.2024.06.222. 【2区,Impact Factor 7.2】

    19.XiangTan , Jiyuan Guo *, Han Wang, Zonggang Qiu, Qun Wang, Huabing Shu, Pristine and defective 2D SiCN substrates as anode materials for sodium-ion batteries,Journal of Energy Storage 93 (2024) 112331.

    https://doi.org/10.1016/j.est.2024.1123312区,Impact Factor9.4

    18.Han Wang , Zonggang Qiu , Jiyuan Guo *, Huabing Shu , Qin Wei,Unravelling the anchoring effects of Hd-Graphene for lithium‑sulfur batteries: A first-principles calculation,Journal of Energy Storage 90 (2024) 111842.

    https://doi.org/10.1016/j.est.2024.1118422区,Impact Factor9.4

    17.Renhao Xu, Zonggang Qiu, Jiyuan Guo *,Theoretical evaluation of gas sensing and capturing characteristics on the
    point defective diboron dinitride monolayer,Journal of Physics and Chemistry of Solids 184 (2024) 111695

    https://doi.org/10.1016/j.jpcs.2023.1116953区,Impact Factor4.0

    16.Han Wang, Fan Kong, Zonggang Qiu, Jiyuan Guo, * Huabing Shu and Qin Wei,Theoretical prediction of 2D biphenylene as a potential anchoring material for lithium–sulfur batteries,Phys. Chem. Chem. Phys., 2023, 25, 25240

    https://doi.org/10.1039/D3CP02863A3区,Impact Factor 3.3

    15.,,,,,,Computational evaluation of lithium functionalized Penta-BN2 as promising reversible hydrogen storage, International journal o f hydrogen energy 48 ( 2023 ) 36051-36062

    https://doi.org/10.1016/j.ijhydene.2023.05.319  2区,Impact Factor 7.139 

    14. ,,,,,Potential application of two-dimensional PC6 monolayer as an anode material in alkali metal-ion (Li, Na, K) batteries,Thin Solid Films 769 (2023) 139734.

    https://doi.org/10.1016/j.tsf.2023.139734   3区,Impact Factor 2.358

    13.

    12.Author links open overlay panelFanKong,LeiChen,MinruiYang,YingWang,HuabingShu,JunDai,Theoretical probing the anchoring properties of BNP2monolayer for lithium-sulfur batteries,Applied Surface Science 594 (2022)   153393.    https://doi.org/10.1016/j.apsusc.2022.153393   1区,Impact Factor 6.707 

    11.

    https://doi.org/10.1016/j.jallcom.2021.163538   【2区,Impact Factor 5.316 

    9.Lei Chen,a, Penta-BCN monolayer with high specific capacity and mobility as a compelling anode material for rechargeable batteries,Phys. Chem. Chem. Phys., 2021, ,23, 17693 - 17702,DOI: 10.1039/D1CP03017E

    2区,Impact Factor 3.676 

    https://pubs.rsc.org/en/content/articlelanding/2021/cp/d1cp03017e/unauth

    8.Author links open overlay panelLeiChen,WenlingDu,,HuabingShu,YingWang,JunDai,Modelling of monolayer penta-PtN2 as an anode material for Li/Na-ion storage,Materials Chemistry and Physics, 262(2021)124312   DOI: 10.1016/j.matchemphys.2021.124312

    【3区,Impact Factor 3.408

    https://www.sciencedirect.com/science/article/abs/pii/S025405842100095X?dgcid=rss_sd_all

    7.W.L. Du, L. Chen, , H.B. Shu,Novel borophosphene as a high capacity anode material for Li-ion storage,Journal of Solid State Chemistry 296 (2021) 121950.

    【3区,Impact Factor 2.726

    https://www.sciencedirect.com/science/article/abs/pii/S0022459620307817

    6.Multidimensional B4N as novel anode materials for lithium ion batteries, Phys. Chem. Chem. Phys., 2020,22, 19913-19922. DOI: 10.1039/D0CP02668A

    2区,Impact Factor 3.676 

    https://pubs.rsc.org/en/content/articlelanding/2020/cp/d0cp02668a/unauth#!divAbstract

    5.Binwei Tian, Wenling Du, Lei Chen,Jiyuan Guo*, Huabing Shu, Ying Wang, Jun Dai,Probing pristine and defective NiB6 monolayer as promising anode materials for Li/Na/K ion batteriesApplied Surface Science 527 (2020) 146580

    【2区,Impact Factor 6.182】

    https://www.sciencedirect.com/science/article/abs/pii/S0169433220313374

    4.Binwei Tian, Taohua Huang,Jiyuan Guo *, Huabing Shu, Ying Wang, Jun Dai,Performance effects of doping engineering on graphene-like C3N as an anode material for alkali metal ion batteries,Materials Science in Semiconductor Processing 109 (2020) 104946.

    【3区,Impact Factor 3.085】

    https://www.sciencedirect.com/science/article/abs/pii/S1369800119313964

    3.Binwei Tian, Taohua Huang, Jiyuan Guo, Huabing Shu, Ying Wang, Jun Dai,Gas adsorption on the pristine monolayer GeP3: A first-principles calculation,Vacuum 164 (2019) 181–185.

    【3区,Impact Factor 2.906】

    https://www.sciencedirect.com/science/article/abs/pii/S0042207X18323923

    2.Taohua Huang, Binwei Tian, Jiyuan Guo, Huabin Shu, Ying Wang, Jun DaiSemiconducting borophene as a promising anode material for Li-ion and Na-ion batteriesMaterials Science in Semiconductor Processing, 89 (2019) 250–255.

    【3区,Impact Factor 3.085】

    https://www.sciencedirect.com/science/article/abs/pii/S1369800118313209

    1.黄桃花,郭纪源,孙晨立,陈雷,锑烯表面碱金属原子吸附和扩散行为研究.人工晶体学报,47(2018)635-641.

    http://www.cnki.com.cn/Article/CJFDTotal-RGJT201803030.htm


    第一作者发表论文

    1.Guo J.Y.,Li C.S.,Xiao C.M.,Effect of Geometrical Confinement on Depletion Interactions in Colloidal Suspensions[J]. Chin.Phys.Lett.,22(2005),1267-1269.

    2.Guo J.Y.,Huang L.X.,Xiao C.M.,Effects of unsymmetrical geometric confinements on depletion interactions in colloidal suspensions[J].Chin. Phys. Soc.15(7),(2006)0001-7.

    3.Guo J.Y.,Chen Z.S.,Huang L.X.,Xiao C.M.,Effects of Geometrical Confinement on Depletion Force in Colloidal System[J].Chinese Journal of Chemical Physics,18(6),2005,993-996.

    4.Guo J.Y.,Xiao C.M.,Grand Canonical Ensemble Monte Carlo Simulation of Depletion Interactions in Colloidal Suspensions[J]. Chin.Phys.Lett.,25 (2008) 314-316.

    5.Guo J.Y., Xu C.X., Wu P., Gu B.X, Structure evolution of Zn cluster on Si (001) substrate for ZnO nanostructure growth [J]. J. Crystal Growth, 312(2010)3609–3612.

    6.Guo J. Y., Xu C. X., Gu B. X., Sheng F. Y. Structure evolution of Zn cluster on graphene for ZnO nanostructure growth [J].J. Appl. Phys. 109(2011) 024307(1-4).

    7.Guo J. Y., Xu C. X., Shi Z. L., Dai J., Li Z. H., and Sheng F. Y. Heteroepitaxial structure of Zn atoms deposit on graphene, Si (001) and graphene/Si (001) substrates for ZnO nanostructure growth [J]. J. Crystal Growth, 336(2011)32-39.

    8.Guo J. Y., Xu C. X., Yang C., Dai J., Li Z. H.Influence of carbon nanotube on the structure evolution of Ni–Cu alloy nanorod [J]. Eur. Phys. J. D 61(2011) 621-625.

    9.Guo J. Y., Xu C. X.Comparative investigation on decorating carbon nanotubes with different transition metals [J]. Appl. Phys. A 102 (2011) 333–337.

    10.Guo J.Y., Xu C.X., Hu A.M., Shi Z. L., Sheng F.Y., Dai J., Li Z.H., Welding of gold nanowires with different joining procedures [J]. J. Nanopart. Res, 14(2012)666.

    11.Guo J. Y.,Xu C. X., Sheng F. Y., Shi Z. L., Dai J., Li Z.H., Hu X. Simulation on initial growth stages of graphene on Pt (111) surface [J]. J. Appl. Phys. 111(2012)044318.

    12.Guo J.Y., Xu C.X., Hu A.M., Sheng F.Y., Shi Z. L., Dai J., Li Z.H. Sintering dynamics and thermal stability for the different arranged styles of Ag clusters [J].J. Phys.Chem.Solids,73 (2012) 1350.

    13.Guo J.Y., Xu C.X., Sheng F.Y., Jin Z.L, Shi Z. L., Dai J., Li Z.H. Morphology and Structure of Nickel Cluster in the Heterojunction between Carbon Nanotube and Metal [J].Quantum Matter 2(2013181-186


    合作发表

    [10].Wang, Y (Wang, Ying); Cheng, Q (Cheng, Quan); Guo, JY (Guo, Jiyuan); Wang, W (Wang, Wei)Sonic horizon dynamics for quantum systems with cubic-quintic-septic nonlinearityAIP ADVANCES,9( 2019)

    [9].Fu, X (Fu, Xi); Guo, JY (Guo, Jiyuan); Li, LM (Li, Liming); Dai, TN (Dai, Tianao),Structural and electronic properties of predicting two-dimensional BC2P and BC3P3 monolayers by the global optimization method,CHEMICAL PHYSICS LETTERS,726(2019)69-76

    [8].Shu, HB (Shu, Huabing); Guo, JY (Guo, Jiyuan); Niu, XH (Niu, Xianghong),Electronic, photocatalytic, and optical properties of two-dimensional boron pnictides,JOURNAL OF MATERIALS SCIENCE,54(2019)2278-2288.

    [7].Fu, X (Fu, Xi); Guo, JY (Guo, Jiyuan); Li, LM (Li, Liming),Computational prediction of two-dimensional monolayer B6C2P2 by the global optimization method,32(2018)30

    [6].Shu, HB (Shu, Huabing); Guo, JY (Guo, Jiyuan),Electronic and optical properties of phosphorene-like arsenic phosphorus: a many-body study,MATERIALS RESEARCH EXPRESS,5(2018)3

    [5].Li, Q (Li, Qiang); Zhao, YH (Zhao, Yinghe); Guo, JY (Guo, Jiyuan); Zhou, QH (Zhou, Qionghua); Chen, Q (Chen, Qian); Wang, JL (Wang, Jinlan),On-surface synthesis: a promising strategy toward the encapsulation of air unstable ultra-thin 2D materials,NANOSCALE,10(2018)3799-3804.

    [4].Zhu, GY (Zhu, Gangyi); Li, JP (Li, Jiaping); Li, JT (Li, Jitao); Guo, JY (Guo, Jiyuan); Dai, J (Dai, Jun); Xu, CX (Xu, Chunxiang); Wang, YJ (Wang, Yongjin),Single-mode ultraviolet whispering gallery mode lasing from a floating GaN microdisk,43(2018)647-650.

    [3].Shu, HB (Shu, Huabing); Li, YH (Li, Yunhai); Niu, XH (Niu, Xianghong); Guo, JY (Guo, JiYuan),Electronic structures and optical properties of arsenene and antimonene under strain and an electric field,JOURNAL OF MATERIALS CHEMISTRY C6(2018)83-90.

    [2].Li, SF (Li, Shifeng); Wang, Y (Wang, Ying); Zhou, Y (Zhou, Yu); Guo, JY (Guo, Jiyuan); Gao, GJ (Gao, Guojun); Zhang, YM (Zhang, Yamei),Soliton dynamics for one dimensional quantum system incorporating higher-order dispersion effect and nonlinear interactions,CHINESE JOURNAL OF PHYSICS,55(2017)2436-2440

    [1].Shu, HB (Shu, Huabing); Tong, YL (Tong, Yilong); Guo, JY (Guo, Jiyuan),Novel electronic and optical properties of ultrathin silicene/arsenene heterostructures and electric field effects,PHYSICAL CHEMISTRY CHEMICAL PHYSICS 19(2017)10644-10650



    2016以前

    1.Xiao C .M., Guo J. Y., Hu P.,Geometrical confinements and depletion interactions[J].Phys.Rev.E 73,(2006)061403.

    2.Xiao C .M., Guo J. Y.,Li C.S.,Depletion forces in colloidal system under geometrical confinements[J].Europhys. Lett., 73 (3)(2006) 443–449

    3.Xiao C .M., Guo J. Y., Hu P.,A Monte Carlo Study of Influences on Depletion Force from Another Large Sphene in Colloidal Suspensions[J]. Chin.Phys.Lett. 23(4)(2006)1038-1041.

    4.Hu A.M, Guo J. Y., Alarifi H., Patane G., Zhou Y., Compagnini G. and Xu C. X. Low temperature sintering of Ag nanoparticles for flexible electronics Packaging[J]. Appl. Phys.Lett. 97(2010)153117.

    5.Sheng F.Y., Xu C.X., Guo J. Y., Zhu G.Y, Chen Q., Structural, electronic and infrared spectral properties of ZnO hexagonal nanodisks with different saturate conditions[J].Science of Advanced Materials,3(2011)709-718.

    6.Dai J., Xu C. X., Wu P., Guo J. Y., Li Z. H., and Shi Z. L. Exciton and electron-hole plasma lasing in ZnO dodecagonal whispering-gallery-mode microcavities at room temperature[J]. Appl. Phys.Lett. 97 (2010) 011101.

    7.Dai J., Xu C.X., Shi Z.L., Ding R., Guo J.Y., Li Z.H., Gu B.X., Wu P. Three-photon absorption induced whispering gallery mode lasing in ZnO twin-rods microstructure[J]. Opt. Mater. 33(2011) 288-291.

    8.Dai J., Xu C. X., Sun L. X., Chen Z. H., Guo J. Y. and Li Z. H., Multiphoton absorption-induced optical whispering-gallery modes in ZnO microcavities at room temperature[J]. J. Phys. D: Appl.Phys. 44(2011) 025404.

    9.Dai J., Xu C. X., Gao M., Liu Z., Shi Z. L., Xu X. Y., Guo J. Y., Li Z. H., Structure evolution and optical properties of the hierarchical ZnO micro/nanorods fabricated by two-step growth method[J]. CrystEngComm, 14(2012) 2180-2185.

    10.Xu, X.Y, Jin, Z.L, Xu, C.X, Guo, J.Y, Shi, Z.L, Pan, J., Hu, J.G, DEFECT-ORIGIN AND STABILITY OF VISIBLE EMISSION IN ZnO NANOPILLARS, Functional Materials Letters, 5(3), (2012 )1240001.

    11.Sheng F.Y, Xu C.X.,Jin Z.L.,Guo J.Y.,Fang S.J.,Shi Z.L, Wang J.L.Simulation on Field Enhanced Electron Transfer between the Interface of ZnO−Ag Nanocomposite[J].J. Phys. Chem. C  2013117 (36), pp 18627–18633

    12.Hu A., Peng P., Alarifi H., Zhang X.Y., Guo J. Y., Zhou Y.,Duley W. W.,Femtosecond laser welded nanostructures and plasmonic devices[J]JOURNAL OF LASER APPLICATIONS,2012,24(4)042001

    13.Dai, J., Xu C.X.,Guo J.Y., Xu X.Y., Zhu G.Y., Lin Y.,Brush-like SnO2/ZnO hierarchical nanostructure: Synthesis, characterization and application in UV photoresponse[J]. AIP ADVANCES 2013,3(6),062108

    14.Jun Dai, Xu C. X., Gao M., Liu Z., Shi Z. L., Xu X. Y., Guo J. Y., Li Z. H., Structure evolution and optical properties of the hierarchical ZnO micro/nanorods fabricated by two-step growth method[J]. CrystEngComm, 14(2012) 2180-2185.

    15..Sheng F.Y, Xu C.X.,Jin Z.L.,Guo J.Y.,Fang S.J.,Shi Z.L, Wang J.L.Simulation on Field Enhanced Electron Transfer between the Interface of ZnO−Ag Nanocomposite[J].J. Phys. Chem. C  2013117 (36), pp 18627–18633

    16.Jun Dai, Chunxiang Xu, Xiaoyong Xu, Jiyuan Guo, Jitao Li,Gangyi Zhu, and Yi LinSingle ZnO Microrod Ultraviolet Photodetector with HighPhotocurrent GainACS Appl. Mater. Interfaces 2013, 5, 9344−9348

    17.Jun Dai, Chunxiang Xu, Jitao Li, Yi Lin, Jiyuan Guo, and Gangyi Zhu,Photoluminescence and Two-Photon Lasing of ZnO:Sn Microdisks,J. Phys. Chem. C 2014, 118, 14542−14547

    18.Jun Dai; Junfeng Lu; Fang Wang; Jiyuan Guo; Ning Gu; Chunxiang Xu,Optical and Exciton Dynamical Properties of a Screw-Dislocation-Driven ZnO:Sn Microstructure, ACS Appl. Mater. Interfaces, 2015,7(23), 12655-12662 .

    19. Jun Dai; Pengxia Zhou; Junfeng Lu; Hongge Zheng; Jiyuan Guo; Fang Wang; Ning Gu; Chunxiang Xu,The excitonic photoluminescence mechanism and lasing action in band-gap-tunable CdS1−xSex nanostructures,Nanoscale, 2016,8, 804-811

    20. Wang, Y (Wang, Ying); Li, SH (Li, Shaohong); Guo, JY (Guo, Jiyuan); Zhou, Y (Zhou, Yu); Zhou, QC (Zhou, Qingchun); Zhou, SY (Zhou, Shuyu); Zhang, YS (Zhang, Yongsheng),Exact soliton solution for the fourth-order nonlinear Schrodinger equation with generalized cubic-quintic nonlinearity,MATHEMATICAL METHODS IN THE APPLIED SCIENCES3920165770-5774