更新时间：2016-03-11 11:16:00点击次数：5359次字号：T|T
教授，博士生导师，国家“****”青年拔尖人才，国家优秀青年基金获得者，享受国务院政府特殊津贴专家
相关介绍
主要经历
2006年6月，中国科学院高能物理研究所，博士学位
2006年6月-2008年5月，中国科学院理论物理研究所，博士后
2008年5月-现在，东北大学，教授
2011年1月-现在，北京大学高能物理中心，李政道青年学者
个人简介
张鑫，东北大学教授、博士生导师，东北大学第八届学术委员会委员。多年来一直致力于引力与宇宙学的研究，在暗能量与暗物质、暴胀宇宙学、中微子物理、量子引力理论等方面取得一系列研究成果，在Nature Communications、Physical Review D、Physics Letters B等国际主流学术期刊发表研究论文100余篇，被国际同行学者引用4400多次，H指数34。研究工作受到国际同行的高度关注，被众多国际顶尖学者正面引用和评价，引用者包括George Smoot（2006年诺贝尔奖获得者）、Adam Riess（2011年诺贝尔奖获得者）、Joseph Silk（英国皇家学会会员）、John Barrow（英国皇家学会会员）、Alexei A. Starobinsky（俄罗斯科学院院士）、普朗克合作组、大亚湾合作组等。研究成果获得辽宁省政府自然科学奖二等奖（第一完成人）。入选国家“****”青年拔尖人才，并获得国家优秀青年基金资助。获得国务院政府特殊津贴。此外还曾入选教育部新世纪优秀人才支持计划和辽宁省百千万人才工程（百层次）。指导的本科生曾获得“挑战杯”竞赛全国一等奖，指导的研究生多次获得辽宁省优秀硕士学位论文。目前指导博士生6人，硕士生3人。
入选人才计划
国家“****”青年拔尖人才支持计划
国家优秀青年科学基金
教育部新世纪优秀人才支持计划
辽宁省百千万人才工程-百层次
东北大学高层次人才培养计划-英才学者



主持项目
国家自然科学基金项目：
国家自然科学基金-优秀青年基金项目，“暗能量与修改引力”，2016-2018；
国家自然科学基金-面上项目，“相互作用暗能量若干问题的研究”，2012-2015；
国家自然科学基金-面上项目，“暗能量和极早期宇宙的理论研究”，2010-2012；
国家自然科学基金-青年基金项目，“暴胀宇宙学与暗能量相关问题的研究”，2008-2010。
人才计划项目：
国家“****”（高层次人才特殊支持计划）青年拔尖人才支持计划项目，2016-2018；
教育部新世纪优秀人才支持计划项目，2010-2012。
省部级项目：
教育部基本科研业务费项目，“宇宙学前沿若干问题的研究”，2011-2012；
教育部基本科研业务费项目，“暗能量宇宙学若干问题的研究”，2013-2014；
教育部基本科研业务费项目，“相互作用暗能量与大尺度结构”，2015-2016；
教育部基本科研业务费项目，“早期宇宙基本物理问题的研究”，2015；
辽宁省百千万人才工程项目，“暗能量与修改引力的研究”，2016-2017。



指导学生
辽宁省优秀硕士学位论文，2010，刘向来
辽宁省优秀硕士学位论文，2013，李云鹤
辽宁省优秀硕士学位论文，2016，郭瑞芸
全国“挑战杯”竞赛，一等奖，2011，马京哲
辽宁省“挑战杯”竞赛，特等奖，2011，马京哲
辽宁省“挑战杯”竞赛，特等奖，2013，李云鹤
辽宁省“挑战杯”竞赛，特等奖，2013，傅天赋
国家奖学金（博士生），2015，耿佳佳
国家奖学金（博士生），2015，李云鹤
国家奖学金（博士生），2017，赵明明
东北大学校长奖章（首届），2015，李云鹤

获奖情况
省部级科技奖励：
辽宁省政府自然科学奖二等奖，“全息暗能量的研究”，2011年，第一完成人
其他获奖及荣誉：
沈阳市优秀科技工作者
沈阳市优秀研究生导师
沈阳市优秀教师
沈阳市优秀共产党员
沈阳市五四奖章
江河奖教金
东北大学教学成果一等奖
国际SCI期刊《SCIENCE CHINAPhysics, Mechanics & Astronomy》期刊贡献奖
国际SCI期刊《Research in Astronomy and Astrophysics》杰出审稿人奖
社会兼职
中国引力与相对论天体物理学会，理事
学术期刊《SCIENCE CHINAPhysics, Mechanics & Astronomy》编委（SCI，Q1区期刊）



学术论文

[114]Lu Feng, Yun-He Li, Fei Yu, Jing-Fei Zhang, Xin Zhang*.Exploring interacting holographic dark energy in a perturbed universe with parameterized post-Friedmann approach.e-Print:arXiv:1807.03022[astro-ph.CO] |PDF
[113] Jia-Jia Geng, Rui-Yun Guo, Anzhong Wang, Jing-Fei Zhang, Xin Zhang*.Prospect for cosmological parameter estimation using future Hubble parameter measurements.e-Print:arXiv:1806.10735[astro-ph.CO] |PDF
[112] Xuan-Neng Zhang, Ling-Feng Wang, Jing-Fei Zhang, Xin Zhang*.Improving cosmological parameter estimation with the future gravitational-wave standard siren observation from the Einstein Telescope.e-Print:arXiv:1804.08379[astro-ph.CO] |PDF
[111] Rui-Yun Guo, Jing-Fei Zhang, Xin Zhang*.Exploring neutrino mass and mass hierarchy in the scenario of vacuum energy interacting with cold dark matter.e-Print:arXiv:1803.06910[astro-ph.CO] |PDF
[110] Ling-Feng Wang, Xuan-Neng Zhang, Jing-Fei Zhang, Xin Zhang*. Impacts of gravitational-wave standard siren observation of the Einstein Telescope on weighing neutrinos in cosmology. Physics Letters B 782 (2018) 87-93.e-Print:arXiv:1802.04720[astro-ph.CO] |PDF
[109] Rui-Yun Guo, Lei Zhang, Jing-Fei Zhang, Xin Zhang*. Constraints on brane inflation after Planck 2015: Impacts of the latest local measurement of the Hubble constant.e-Print:arXiv:1801.02187[astro-ph.CO] |PDF
[108] Lu Feng, Jing-Fei Zhang, Xin Zhang*. Search for sterile neutrinos in a universe of vacuum energy interacting with cold dark matter.e-Print:arXiv:1712.03148[astro-ph.CO] |PDF
[107] Jue Zhang, Xin Zhang*. Gravitational clustering of cosmic relic neutrinos in the Milky Way. Nature Communications 9 (2018) 1833.
[106] Hai-Li Li, Jing-Fei Zhang, Lu Feng, Xin Zhang*. Reexploration of interacting holographic dark energy model: cases of interaction term excluding the Hubble parameter.European Physical Journal C 77 (2017) 907.
[105] Juan-Juan Guo, Jing-Fei Zhang, Yun-He Li, Dong-Ze He, Xin Zhang*. Probing the sign-changeable interaction between dark energy and dark matter with current observations.Science China-Physics, Mechanics & Astronomy 61 (2018) 030011.
[104] Ming-Ming Zhao, Jing-Fei Zhang, Xin Zhang*. Measuring growth index in a universe with massive neutrinos: A revisit of the general relativity test with the latest observations. Physics Letters B 779 (2018) 473-478.
[103]Shulei Ni, Hong Li, Taotao Qiu, Wei Zheng, Xin Zhang. Probing signatures of bounce inflation with current observations. (2017) submitted.
[102] Lu Feng, Jing-Fei Zhang, Xin Zhang*. Searching for sterile neutrinos in dynamical dark energy cosmologies.Science China-Physics, Mechanics & Astronomy 61 (2018) 050411.
[101] Rui-Yun Guo, Xin Zhang*. Constraints on inflation revisited: an analysis including the latest local measurement of the Hubble constant. European Physical Journal C 77 (2017) 882.
[100] Ming-Ming Zhao, Dong-Ze He, Jing-Fei Zhang, Xin Zhang*. Search for sterile neutrinos in holographic dark energy cosmology: Reconciling Planck observation with the local measurement of the Hubble constant. Physical Review D 96 (2017) 043520.
[99] Lu Feng, Jing-Fei Zhang, Xin Zhang*. A search for sterile neutrinos with the latest cosmological observations. European Physical Journal C 77 (2017) 418.
[98] Jing-Lei Cui, Hai-Li Li, Xin Zhang*. No evidence for the evolution of mass density power-law indexγfrom strong gravitational lensing observation. Science China Physics, Mechanics & Astronomy 60 (2017) 080411.
[97] Rui-Yun Guo, Yun-He Li, Jing-Fei Zhang, Xin Zhang*. Weighing neutrinos in the scenario of vacuum energy interacting with cold dark matter: application of the parameterized post-Friedmann approach. Journal of Cosmology and Astroparticle Physics 1705 (2017) 040.
[96] Ming-Ming Zhao, Yun-He Li, Jing-Fei Zhang, Xin Zhang*. Constraining neutrino mass and extra relativistic degrees of freedom in dynamical dark energy models using Planck 2015 data in combination with low-redshift cosmological probes: basic extensions toΛCDM cosmology. Monthly Notices of the Royal Astronomical Society 469 (2017) 1713.
[95] Xin Zhang*. Weighing neutrinos in dynamical dark energy models. Science China Physics, Mechanics & Astronomy 60 (2017) 060431.
[94] Xin Zhang*. Impact of the latest measurement of Hubble constant on constraining inflation models. Science China Physics, Mechanics & Astronomy 60 (2017) 060421.
[93] Xin Zhang*. Probing the interaction between dark energy and dark matter with the parametrized post-Friedmann approach. Science China Physics, Mechanics & Astronomy 60 (2017) 050431.
[92] Dong-Ze He, Jing-Fei Zhang, Xin Zhang. Redshift drift constraints on holographic dark energy. Science China Physics, Mechanics & Astronomy 60 (2017) 039511.
[91] Sai Wang, Yi-Fan Wang, Dong-Mei Xia, Xin Zhang. Impacts of dark energy on weighing neutrinos: Mass hierarchies considered. Physical Review D 94 (2016) 083519.
[90] Yue-Yao Xu, Xin Zhang*. Comparison of dark energy models after Planck 2015. European Physical Journal C 76 (2016) 588.
[89] Lu Feng, Xin Zhang*. Revisit of the interacting holographic dark energy model after Planck 2015. Journal of Cosmology and Astroparticle Physics 1608 (2016) 072.
[88] Xin Zhang*. Impacts of dark energy on weighing neutrinos after Planck 2015. Physical Review D 93 (2016) 083011.
[87] Yun-He Li, Jing-Fei Zhang, Xin Zhang*. Testing models of vacuum energy interacting with cold dark matter. Physical Review D 93 (2016) 023002.
[86] Rui-Yun Guo, Xin Zhang*. Constraining dark energy with Hubble parameter measurements: an analysis including future redshift-drift observations. European Physical Journal C 76 (2016) 163.
[85] Shuang Wang, Jia-Jia Geng, Yi-Liang Hu, Xin Zhang*. Revisit of constraints on holographic dark energy: SNLS3 dataset with the effects of time-varyingβand different light-curve fitters. Science China Physics, Mechanics & Astronomy 58 (2015) 019801.
[84] Jia-Jia Geng, Rui-Yun Guo, Dong-Ze He, Jing-Fei Zhang, Xin Zhang*. Redshift drift constraints on f(T) gravity. Frontiers of Physics 10 (2015) 109501.
[83] Jing-Lei Cui, Yue-Yao Xu, Jing-Fei Zhang, Xin Zhang*. Strong gravitational lensing constraints on holographic dark energy. Science China Physics, Mechanics & Astronomy 58 (2015) 110402.
[82] Fei Yu, Jing-Lei Cui, Jing-Fei Zhang, Xin Zhang*. Statefinder hierarchy exploration of the extended Ricci dark energy. European Physical Journal C 75 (2015) 274.
[81]Jing-Lei Cui, Lu Yin, Ling-Feng Wang, Yun-He Li, Xin Zhang*. A closer look at interacting dark energy with statefinder hierarchy and growth rate of structure，Journal of Cosmology and Astroparticle Physics 09 (2015) 024.
[80] Yun-He Li, Jing-Fei Zhang, Xin Zhang*. Probing f(R) cosmology with sterile neutrinos via measurements of scale-dependent growth rate of structure. Physics Letters B 744 (2015) 213-217.
[79] Jia-Jia Geng, Yun-He Li, Jing-Fei Zhang, Xin Zhang*. Redshift drift exploration for interacting dark energy.European Physical Journal C 75 (2015) 356.
[78] Jing-Fei Zhang, Ming-Ming Zhao, Yun-He Li, Xin Zhang*. Neutrinos in the holographic dark energy model: constraints from latest measurements of expansion history and growth of structure. Journal of Cosmology and Astroparticle Physics 04 (2015) 038 .
[77] Jing-Fei Zhang, Yun-He Li, Xin Zhang*. Sterile neutrinos help reconcile the observational results of primordial gravitational waves from Planck and BICEP2. Physics Letters B 740 (2015) 359-363.
[76] Wei-Jiang Gong, Ying Zhao, Zhen Gao, Guangyu Yi, Xin Zhang. Odd-Even Effect of the Persistent Current in a Quantum Dot Ring with Embedded Majorana Bound States. Journal of the Physical Society of Japan 84 (2015) 024707.
[75] Jia-Jia Geng, Jing-Fei Zhang, Xin Zhang*. Parameter estimation with Sandage-Loeb test. Journal of Cosmology and Astroparticle Physics 12 (2014) 018.
[74] Yun-He Li, Jing-Fei Zhang, Xin Zhang*. Exploring the full parameter space for an interacting dark energy model with recent observations including redshift-space distortions: Application of the parametrized post-Friedmann approach. Physical Review D 90 (2014) 123007.
[73] Jing-Fei Zhang, Ming-Ming Zhao, Jing-Lei Cui, Xin Zhang*. Revisiting the holographic dark energy in a non-flat universe: alternative model and cosmological parameter constraints. European Physical Journal C 74 (2014) 3178.
[72] Jing-Fei Zhang, Jia-Jia Geng, Xin Zhang*. Neutrinos and dark energy after Planck and BICEP2: data consistency tests and cosmological parameter constraints. Journal of Cosmology and Astroparticle Physics 10 (2014) 044.
[71] Shuang Wang, Yong-Zhen Wang, Jia-Jia Geng, Xin Zhang*. Effects of time-varyingβin SNLS3 on constraining interacting dark energy models. European Physical Journal C 74 (2014) 3148.
[70] Jing-Fei Zhang, Jing-Lei Cui, Xin Zhang*. Diagnosing holographic dark energy models with statefinder hierarchy. European Physical Journal C 74 (2014) 3100.
[69] Jing-Fei Zhang, Yun-He Li, Xin Zhang*. Measuring growth index in a universe with sterile neutrinos. Physics Letters B 739 (2014) 102-105.
[68]Shuang Wang, Yong-Zhen Wang,Xin Zhang*.Effects of a time-varying color-luminosity parameterβon the cosmological constraints of modified gravity models. Communications in Theoretical Physics 62 (2014) 927-936.
[67]Yun-He Li,Jing-Fei Zhang,Xin Zhang*.Tilt of primordial gravitational wave spectrum in a universe with sterile neutrinos. Science China Physics, Mechanics & Astronomy 57 (2014) 1455-1459.
[66]Jia-Jia Geng,Jing-Fei Zhang, Xin Zhang*.Quantifying the impact of future Sandage-Loeb test data on dark energy constraints. Journal of Cosmology and Astroparticle Physics 1407 (2014) 006.
[65]Yun-He Li,Jing-Fei Zhang,Xin Zhang*.Parametrized post-Friedmann framework for interacting dark energy. Physical Review D 90 (2014) 063005.
[64] Jing-Fei Zhang, Yun-He Li,Xin Zhang*. Cosmological constraints on neutrinos after BICEP2. European Physical Journal C 74 (2014) 2954.
[63] Yun-He Li, Xin Zhang*. Large-scale stable interacting dark energy model: Cosmological perturbations and observational constraints. Physical Review D 89 (2014) 083009.
[62] Shuang Wang, Yun-He Li, Xin Zhang*. Exploring the evolution of color-luminosity parameterβand its effects on parameter estimation. Physical Review D 89 (2014) 063524.
[61] Chao-Qiang Geng,Lu-Hsing Tsai,Xin Zhang.Dark radiation from a unified dark fluid model. Progress of Theoretical and Experimental Physics 2014 (2014) 6, 063E01.
[60] Jing-Fei Zhang, Li-Ang Zhao, Xin Zhang*. Revisiting the interacting model of new agegraphic dark energy. Science China Physics, Mechanics & Astronomy 57 (2014) 387-392.
[59] Miao Li, Xiao-Dong Li, Yin-Zhe Ma, Xin Zhang, Zhenhui Zhang. Planck constraints on holographic dark energy. Journal of Cosmology and Astroparticle Physics 1309 (2013) 021.
[58] Nan Li, Xin Zhang*. Reexamination of inflation in noncommutative space-time after Planck results. Physical Review D 88 (2013) 023508.
[57] Yin-Zhe Ma, Qing-Guo Huang, Xin Zhang. Confronting brane inflation with Planck and pre-Planck data. Physical Review D 87 (2013) 103516.
[56] Yun-He Li, Shuang Wang, Xiao-Dong Li, Xin Zhang*. Holographic dark energy in a universe with spatial curvature and massive neutrinos: a full Markov Chain Monte Carlo exploration. Journal of Cosmology and Astroparticle Physics 1302 (2013) 033.
[55] Jing-Fei Zhang, Yun-He Li, Xin Zhang*. A global fit study on the new agegraphic dark energy model. European Physical Journal C 73 (2013) 2280.
[54] Yun-He Li, Jing-Fei Zhang, Xin Zhang*. New initial condition of the new agegraphic dark energy model. Chinese Physics B 22(2013) 039501.
[53] Jing-Fei Zhang, Yang-Yang Li, Ying Liu, Sheng Zou, Xin Zhang*. HolographicΛ(t)CDM model in a non-flat universe. European Physical Journal C 72 (2012) 2077.
[52] Zhen-Hui Zhang, Song Li, Xiao-Dong Li, Xin Zhang, Miao Li. Revisit of the interaction between holographic dark energy and dark matter. Journal of Cosmology and Astroparticle Physics 1206 (2012) 009.
[51] Xiao-Dong Li, Shuang Wang, Qing-Guo Huang, Xin Zhang*, Miao Li. Dark energy and fate of the universe. Science China Physics, Mechanics & Astronomy 55 (2012) 1330-1334.
[50] Hong Li, Xin Zhang*. Constraining dynamical dark energy with a divergence-free parametrization in the presence of spatial curvature and massive neutrinos. Physics Letters B 713 (2012) 160-164.
[49] Tian-Fu Fu, Jing-Fei Zhang, Jin-Qian Chen, Xin Zhang*. Holographic Ricci dark energy: interacting model and cosmological constraints. European Physical Journal C 72 (2012) 1932.
[48] Hong Li, Xin Zhang*. Probing the dynamics of dark energy with divergence-free parametrizations: A global fit study. Physics Letters B 703 (2011) 119-123.
[47] Yun-He Li, Xin Zhang*. Running coupling: does the coupling between dark energy and dark matter change sign during the cosmological evolution? European Physical Journal C 71 (2011) 1700.
[46] Jing-Zhe Ma, Xin Zhang*. Probing the dynamics of dark energy with novel parametrizations. Physics Letters B 699 (2011) 233-238.
[45] Yun-He Li, Jing-Zhe Ma, Jing-Lei Cui, Zhuo Wang, Xin Zhang*. Interacting model of new agegraphic dark energy: observational constraints and age problem. Science China - Physics, Mechanics & Astronomy 54 (2011) 1367-1377.
[44] Miao Li, Xiao-Dong Li, Xin Zhang*. Comparison of dark energy models: A perspective from the latest observational data. Chinese Science Bulletin 55 (2010) 3741.
[43] Xin Zhang*. Heal the world: Avoiding the cosmic doomsday in the holographic dark energy model. Physics Letters B 683 (2010) 81-87.
[42]Jingfei Zhang, Li Zhang, Xin Zhang*. Sandage-Loeb test for the new agegraphic and Ricci dark energy models. Physics Letters B 691 (2010) 11-17.
[41]Jinglei Cui, Xin Zhang*. Cosmic age problem revisited in the holographic dark energy model. Physics Letters B 690 (2010) 233-238.
[40] Xiang-Lai Liu, Jingfei Zhang, Xin Zhang*. Theoretical limits on agegraphic quintessence from weak gravity conjecture. Physics Letters B 689 (2010) 139-144.
[39] Miao Li, Xiao-Dong Li, Xin Zhang*. Comparison of dark energy models: A perspective from the latest observational data. Science China - Physics, Mechanics & Astronomy 53 (2010) 1631-1645.
[38]Li Zhang, Jinglei Cui, Jingfei Zhang, Xin Zhang*. Interacting model of new agegraphic dark energy: Cosmological evolution and statefinder diagnostic. International Journal of Modern Physics D 19 (2010) 21-35.
[37]Jinglei Cui, Li Zhang, Jingfei Zhang, Xin Zhang*. New agegraphic dark energy as a rolling tachyon. Chinese Physics B 19 (2010) 019802.
[36]Miao Li, Xiao-Dong Li, Shuang Wang, Yi Wang, Xin Zhang*. Probing interaction and spatial curvature in the holographic dark energy model. Journal of Cosmology and Astroparticle Physics 0912 (2009) 014
[35] Wan-Lei Guo, Xin Zhang. Constraints on dark matter annihilation cross section in the brane-world and quintessence scenarios. Physical Review D 79 (2009) 115023.
[34]Miao Li, Xiao-Dong Li, Shuang Wang, Xin Zhang. Holographic dark energy models: a comparison from the latest observational data. Journal of Cosmology and Astroparticle Physics 0906 (2009) 036.
[33]Xin Zhang*. Holographic Ricci dark energy: Current observational constraints, quintom feature, and the reconstruction of scalar-field dark energy. Physical Review D 79 (2009) 103509.
[32] Yin-Zhe Ma, Xin Zhang*. Brane inflation revisited after WMAP five-year results. Journal of Cosmology and Astroparticle Physics 0903 (2009) 006.
[31]Xin Zhang*. Can the universe fragment into many independent causal patches at turnaround in cyclic cosmology? European Physical Journal C 59 (2009) 755-759.
[30]Xin Zhang*. Can black holes be torn up by phantom dark energy in cyclic cosmology? European Physical Journal C 60 (2009) 661-667.
[29] Xin Zhang, Jingfei Zhang, Jinglei Cui, Li Zhang. Chaplygin inflation in loop quantum cosmology. Modern Physics Letters A 24 (2009) 1763-1773.
[28]Chao-Jun Feng, Xin Zhang*. Holographic Ricci dark energy in Randall-Sundrumbraneworld: Avoidance of big rip and steady state future. Physics Letters B 680 (2009) 399-403.
[27]Xiang-Lai Liu, Xin Zhang*. New agegraphic dark energy in Brans-Dicke theory. Communications in Theoretical Physics 52 (2009) 761-768.
[26]Yin-Zhe Ma, Xin Zhang*. Possible theoretical limits on holographic quintessence from weak gravity conjecture. Physics Letters B 661 (2008) 239-245.
[25]Jingfei Zhang, Xin Zhang*, Hongya Liu. Statefinder diagnosis for the interacting model of holographic dark energy. Physics Letters B 659 (2008) 26-33.
[24]Jingfei Zhang, Xin Zhang*, Hongya Liu. Agegraphic dark energy as a quintessence. European Physical Journal C 54 (2008) 253-258.
[23]Jingfei Zhang, Xin Zhang*, Hongya Liu. Reconstructing generalized ghost condensate model with dynamical dark energy parametrizations and observational datasets. Modern Physics Letters A 23 (2008) 139-152.
[22]Jingfei Zhang, Xin Zhang*, Hongya Liu. Holographic dark energy in a cyclic universe. European Physical Journal C 52 (2007) 693-699.
[21]Jingfei Zhang, Xin Zhang, Hongya Liu. Holographic tachyon model. Physics Letters B 651 (2007) 84-88.
[20]Xin Zhang*, Yi Ling. Inflationary universe in loop quantum cosmology. Journal of Cosmology and Astroparticle Physics 0708 (2007) 012.
[19]Xin Zhang*, Feng-Quan Wu. Constraints on holographic dark energy from latest supernovae, galaxy clustering, and cosmic microwave background anisotropy observations. Physical Review D 76 (2007) 023502.
[18]Xin Zhang*. Reconstructing holographic quintessence. Physics Letters B 648 (2007) 1-7.
[17]M. R. Setare, Jingfei Zhang, Xin Zhang*. Statefinder diagnosis in a non-flat universe and the holographic model of dark energy. Journal of Cosmology and Astroparticle Physics 0703 (2007) 007.
[16]Xin Zhang*. Dynamical vacuum energy, holographic quintom, and the reconstruction of scalar-field dark energy. Physical Review D 74 (2006) 103505.
[15]Xin Zhang*. A note on noncommutative brane inflation. Journal of Cosmology and Astroparticle Physics 0612 (2006) 002.
[14]Xin Zhang*, Feng-Quan Wu. Noncommutative chaotic inflation and WMAP three year results. Physics Letters B 638 (2006) 396-400.
[13]Xin Zhang*, Feng-Quan Wu, Jingfei Zhang. New generalized Chaplygin gas as a scheme for unification of dark energy and dark matter. Journal of Cosmology and Astroparticle Physics 0601 (2006) 003.
[12]Zhe Chang, Feng-Quan Wu, Xin Zhang*. Constraints on holographic dark energy from X-ray gas mass fraction of galaxy clusters. Physics Letters B 633 (2006) 14-18.
[11]Xin Zhang*, Feng-Quan Wu. Constraints on holographic dark energy from type Ia supernova observations. Physical Review D 72 (2005) 043524.
[10] Xin Zhang*. Statefinder diagnostic for coupled quintessence. Physics Letters B 611 (2005) 1-7.
[9]Xin Zhang*. Coupled quintessence in a power-law case and the cosmic coincidence problem. Modern Physics Letters A 20 (2005) 2575.
[8] Xin Zhang*. Statefinder diagnostic for holographic dark energy model. International Journal of Modern Physics D 14 (2005) 1597-1606.
[7]Xin Zhang*. An interacting two-fluid scenario for quintom dark energy. Communications in Theoretical Physics 44 (2005) 762-768.
[6] Xin Zhang*. Statefinder parameters for coupled quintessence scenario in a power law case. Communications in Theoretical Physics 44 (2005) 573-576.
[5] Xin Zhang*. Black hole evaporation based upon a q-deformation description. International Journal of Modern Physics A 20 (2005) 6039-6049.
[4] Xin Zhang*, Feng Pan. Transitional description of diatomic molecules in U(4) vibron model. Communications in Theoretical Physics 41 (2004) 29-36.
[3] Xin Zhang*, Feng Pan. Exact solutions of sl-boson system in U(2l+1)-O(2l+2) transitional region. Chinese Physics C 26 (2002) 1228-1237.
[2] Feng Pan, Xin Zhang, J. P. Draayer. Possible deviations from the O(4) limit of the vibron model in diatomic molecules. Physics Letters A 316 (2003) 84-90.
[1] Feng Pan, Xin Zhang, J. P. Draayer. Algebraic solutions of an sl-boson system in the U(2l+1)<-->O(2l+2) transitional region. Journal of Physics A 35 (2002) 7173-7185.