张东波 - 北京师范大学 - 物理与天文学院

个人简介

主要从事电子结构、声子物理、和输运理论与计算研究。在国际学术期刊上发表论文60余篇（包含部分合作工作），其中包括Physical Review Letters 6篇、National Science Review 1篇、Nano Letters 2篇、Acs Nano1篇等，在美国APS march meeting（2019）和The 21st Asian Workshop on First-Principles Electronic Structure Calculations（2018）做邀请报告。从事科研工作以来，通过纯计算研究，提出低维材料弯曲力学的量子力学解释，解决了“Yakobson paradox”；证实石墨烯的均匀赝磁场；提出在极性半导体转角双层中存在Bloch平带。近期研究主要关注二维系统中的声子的规范场物理和激子物理，并从事电偶极矩计算新理论的发展。主持自然科学基金面上项目3项，主持国家海外高层次人才青年项目1项，指导“博士后创新人才计划”1项、作为骨干成员参与科技部重点研发计划 1 项、中国工程物理研究院挑战计划1项。教育经历 2005.09∼2010.11：美国明尼苏达大学，博士 1998.09∼2005.06：北京科技大学，学士&硕士工作经历 2022 年 11 月至今，北京师范大学物理学系，教授 2018 年 4 月—2022年10月，北京师范大学核科学与技术学院，教授 2014 年 4 月— 2018 年 3 月，北京计算科学研究中心，特聘研究员

研究领域

半导体物理、电子结构、晶格动力学、激子、输运理论及计算运用课题组开发的计算方法，结合第一性原理计算，开展低维材料的量子力学模拟。课题组的计算方法，包括广义布洛赫能带方法、广义伯恩卡曼边界条件声子方法、声子准粒子方法、紧束缚格林久保热导率计算方法、基于晶格反演的紧束缚排斥势计算方法等。近期研究主要关注低维体系声子、电子、激子物理以及偶极理论与计算。

近期论文

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1. Li, Jian-Gao; Guo, Di; Li, Yun-Mei; Chang, Kai * ; Zhang, Dong-Bo * , Phonon Landau Quantization and Enhanced Lifetime in Deformed Graphene, Nano Letters 24, 11847–11852 (2024) 2. Y.-X. Wang, J.-G. Li, G. Seifert, K. Chang * and D.-B. Zhang * , Giant Flexoelectricity in Bent Semiconductor Thinfilm, Nano Letters 24, 411-416 (2024) 3. X.-J. Zhao, Yang Yang, D.-B. Zhang * and Su-Huai Wei * , Formationof Bloch Flat Bands in Polar Twisted Bilayers without Magic Angles, PhysicalReview Letters, 124 , 086401 (2020). 4. Dong-BoZhang * , Xing-Ju Zhao,Gotthard Seifert, Kaifai Tse, and Junyi Zhu * , Shear-Driven Separation of n-type and p-typeDopants in Single Crystalline Nanowires, National Science Review 6, 532 (2019) 5. Y. Lu, T. Sun, Ping Zhang, P. Zhang, Dong-Bo Zhang, * and R. M. Wentzcovitch, Pre-melting hcp to bcc Transition in Beryllium, Physical Review Letters 118 ,145702 (2017). 6. Dong-BoZhang , T. Sun and R.M. Wentzcovitch, Phonon Quasiparticles andAnharmonic Free Energy in Complex Systems, PhysicalReview Letters 112 , 058501 (2014). 7. Dong-BoZhang , G. Seifert and Kai Chang, Strain-Induced Pseudo-MagneticFields in Twisted Graphene Nanoribbons, PhysicalReview Letters, 112 , 096805 (2014). 8. Dong-BoZhang , E. Akatyeva, and T. Dumitrica, Bending Ultra-Thin Grapheneat the Margins of Continuum Mechanics, PhysicalReview Letters 106 , 255503 (2011). 9. Dong-BoZhang , T. Dumitrica and G. Seifert, Helical Nanotube Structuresof MoS 2 with Intrinsic Twisting: An Objective Molecular DynamicsStudy, Physical Review Letters 104 , 065502 (2010). 10. Li, Jian-Gao; Guo, Di; Li, Yun-Mei; Chang, Kai * ; Zhang, Dong-Bo * , Phonon Landau Quantization and Enhanced Lifetime in Deformed Graphene, Nano Letters 11847–11852 (2024) 11. Y.-X. Wang, J.-G. Li, G. Seifert, Kai Chang * and D.-B. Zhang * , Giant Flexoelectricity in Bent Semiconductor Thinfilm, Nano Letters 24, 411-416 (2024) 12. J.-G. Li, J.-K. Tang, H.-Q. Song, G. Seifert, D.-B.Zhang * ,Programmable Repulsive Potential for Tight-Binding from Chen-Möbius Inversion Theorem, SCIENCE CHINA Physics, Mechanics & Astronomy, 67, No. 1: 217011 (2024) 13. D.-B. Zhang * , J.-G. Li, Y.-H.Ren and T. Sun * ,Green-Kubo Formalism for Thermal Conductivity with Slater-Koster Tight-Binding, Physical Review B 108, 104307 (2023). 14. J.-K Tang, Y.-X. Wang, K. Chang * , and D.-B.Zhang * ,Polarization due to emergent polarity in elemental semiconductor thinfilms underbending, J. Phys.: Condens. Matter 51, 015501 (2023). 15. 王娅巽 , 郭迪 , 李建高 , 张东波 * . 低维材料物性的非均匀应变调控 . 物理学报 , 2022, 71(12) 【邀请综述】【当期优秀论文】 16. Zhen Zhang, Dong-Bo Zhang , Tao Sun, and Renata M. Wentzcovitch, The PhononQuasiparticle Approach for Anharmonic Properties of Solids, Journal of Physics:Conference Series 2207 012042 (2022). 17. Zhen Zhang, Dong-Bo Zhang , Kotaro Onga, Akira Hasegawa, Kenji Ohta, Kei Hirose, and Renata M. Wentzcovitch, Thermal conductivity ofCaSiO3 perovskite at lower mantle conditions, Physical Review B, 104,184101 (2021) 18. Ni Ma, Fan Li, Jian-Gao Li, XinLiu, Dong-Bo Zhang , Yan-Yan Li, Ling Chen, and Li-Ming Wu, Mixed-Valence CsCu4Se3: Large Phonon Anharmonicity Drivenby the Hierarchy of the Rigid [(Cu+)4(Se2 − )2](Se − ) Double Anti-CaF2 Layer and the Soft Cs+ Sublattice , Journal of American Chemistry Society, 143, 18490–18501 (2021). 19. Jun Chen, Jiangao Li, Ling Sun, Zhong Lin, Zhengguang Hu, Hongtao Zhang,Xiaoling Wu, Dong-Bo Zhang , Guoan Cheng, Ruiting Zheng, Tunable oxygen defect density and location for enhancement of energy Storage, Journal of Energy Chemistry 59 736–747(2021). 20. Xing-Ju Zhao, Yang Yang, Dong-BoZhang * and Su-Huai Wei * , Flat bands in twisted bilayers of polar two-dimensionalsemiconductors, Physical Review Materials 5, 014007 (2021). 21. Yong Lu * , Fa-wei Zheng, Yu Yang, Ping Zhang, and Dong-BoZhang * , Dynamic stabilizationand heat transport characteristics of monolayer SnSe at finite temperature: Astudy by phonon quasiparticle approach , Physical Review B 103, 014304 (2021). 22. 张东波 * ；魏苏淮 * ，广义布洛赫方法的应用 : 低维材料物性的非均匀应变调控，科学通报 66 (2021）[邀请综述] 23. Zhao Liu and Dong-Bo Zhang * , Type-II BandAlignment in Single Crystalline TiO2 Nanowires under Twisting , ElectronicStructure 2, 044001 (2020) [Invited paper for the special issue of EmergingLeaders 2020]. 24. Zhao Liu, Xue-Wen Fu, and Dong-Bo Zhang * , Strain gradient induced spatially indirect excitonsin single crystalline ZnO nanowires , Nanoscale 12, 19083 (2020). 25. J.-L.Shi, Y. Wang, X.-J. Zhao, Y.-Z. Zhang, S. Yuan, S.-H. Wei * and D.-B. Zhang * , StrainInduced Spin-splitting and Half-metallicity in Antiferromagnetic BilayerSilicene under Bending, Physical Chemistry Chemical Physics, 22,11567 (2020). 26. J-.L. Shi, X.-J. Zhao, G. Seifert, S.-H.Wei * ,and D.-B. Zhang * , Unconventional deformation potential andhalf metallicity in zigzag nanoribbons of 2D-Xenes, Physical ChemistryChemical Physics, 22, 7294 (2020). 27. X.-J. Zhao, Yang Yang, Dong-Bo Zhang * and Su-Huai Wei * , Formationof Bloch Flat Bands in Polar Twisted Bilayers without Magic Angles, PhysicalReview Letters, 124, 086401 (2020). 28. Zhao Liu, Chi-Yung Yam, Shiwu Gao * , Tao Sun, and Dong-BoZhang * , Lattice Dynamics of DeformedQuasi-One Dimensional Crystals under Generalized Born-von Karman Boundary Conditions,New Journal Physics 22, 023004 (2020). 29. X.-J. Zhao, G. Seifert, J. Zhu * and D.-B. Zhang * , Twist-inducedpreferential distribution of dopants in single-crystalline Si nanowires , PhysicalReview B 100, 174202 (2019) 30. Zhen Zhang, Dong-Bo Zhang * , Tao Sun, and Renata M. Wentzcovitch * , phq : a Fortran code to computephonon quasiparticle properties and dispersions , Computer Physics Communications243, 110 (2019). 31. Yong Lu * , Fa-wei Zheng, Yu Wang, PingZhang, and Dong-Bo Zhang * , Phase Stabilities of Cmcm and Pnma SnSe Studiedby Phonon Quasiparticle Approach, PhysicalReview B 100, 054304 (2019). 32. Zhao Liu, Dong-Bo Zhang * , Gotthard Seifert, YingLiu and Kai Chang * , Interfacial Landau levelsin Bent Graphene Racetracks, PhysicalReview B 99, 165416 (2019) 33. Hong-Quan Song, Zhao Liu and Dong-Bo Zhang * ,Interlayer Vibration of Twisted Bilayer Graphene: A First-Principles Study, PhysicsLetters A 383, 2628 (2019) 34. Dong-BoZhang * , Xing-Ju Zhao,Gotthard Seifert, Kaifai Tse, and Junyi Zhu * , Shear-Driven Separation of n-type and p-typeDopants in Single Crystalline Nanowires, National Science Review6, 532 (2019) See also “ A new strategy offabricating p-n junction in single crystalline Si nanowires, twisting ” at https://www.eurekalert.org/pub_releases/2019-03/scp-ans032019.php “PN 结的长生之道 ” at https://sciencesources.eurekalert.org/pub_releases_ml/2019-03/scp-u032019.php . 35. Yong Lu, Tao Sun, and Dong-Bo Zhang * ,Lattice Anharmonicity, Phonon Dispersion, and Thermal Conductivity of PbTeStudied by the Phonon Quasiparticle Approach, Physical Review B97, 174304 (2018). 36. Dong-BoZhang , P. B. Allen, T. Sun and R. M. Wentzcovitch, Thermal Conductivity of MgSiO 3 with Sublattice Mean Free Path, PhysicalReview B [Rapid Communication], 96,100302 (2017). 37. Yue Ling, Gotthard Seifert, Kai Changand Dong-Bo Zhang , * Effective Zeeman Splitting in BentGraphene/Hexagonal Boron Nitride Lateral Heterojunctions: A New Mechanismtowards Half-Metallicity, PhysicalReview B [Rapid Communication], 96, 201403 (2017). 38. Dong-BoZhang * and Su-Huai Wei * , Realizing Half-Metallicity in Zigzag GrapheneNanoribbon by Bending: A Mechanism Studied by Generalized Bloch Theorem, npj Computational Materials 3, 32 (2017). 39. N. Ghaderi, Dong-Bo Zhang , H. Zhang, J. Xian, R. Wentzcovitch, and T. Sun, LatticeThermal Conductivity of MgSiO 3 Perovskite from First Principles, Scientific Reports, 7, 5417(2017). 40. Y. Lu, T. Sun, Ping Zhang, P. Zhang, Dong-Bo Zhang , * and R. M. Wentzcovitch, Pre-melting hcp to bcc Transition in Beryllium, Physical Review Letters 118,145702 (2017). 41. Y. Lu, F. Zheng, P. Zhang, X. Shao, and Dong-Bo Zhang , Temperature and isotopeeffects on the thermoelectric properties in SnTe, Journal of Physics: Condensed Matter, 29, 175701 (2017). 42. Jiang Zeng, Wei Chen, Ping Cui, Dong-Bo Zhang , * and Zhenyu Zhang * , Enhanced Half-Metallicity inOrientationally Misaligned Graphene/Hexagonal BoronNitride Lateral Heterojunctions,Physical Review B 94, 235425 (2016). 43. Hong-Man Ma, Jing Wang, Hui-Yan Zhao, Dong-Bo Zhang , Ying Liu, Structural predictionfor scandium carbide monolayer sheet, ChemicalPhysics Letters 660 238 (2016). 44. Dong Zhang, Dong-Bo Zhang * , Fuhua Yang, Hai-QingLin, Hongqi Xu and Kai Chang *, Interface engineeringof electronic properties of graphene/boron nitride lateral heterostructures, 2D Materials 2, 041001 (2015). 45. Hui-Yan Zhao, Jing Wang, Xiu-Jie Su, Dong-Bo Zhang , and Ying Liu, IceCarbons,Journal of Physical Chemistry C 118, 27502 (2014). 46. Dong-BoZhang , T. Sun and R.M. Wentzcovitch, Phonon Quasiparticles andAnharmonic Free Energy in Complex Systems, PhysicalReview Letters 112, 058501 (2014). 47. Dong-BoZhang , G. Seifert and Kai Chang, Strain-Induced Pseudo-MagneticFields in Twisted Graphene Nanoribbons, PhysicalReview Letters, 112, 096805 (2014). 48. Sun, Tao, Dong-Bo Zhang , and Renata M. Wentzcovitch. 2014. Dynamic stabilizationof cubic CaSiO 3 perovskite at high temperatures and pressures fromab initio molecular dynamics, Physical Review B89, 094109 (2014). 49. Dong-BoZhang and T. Dumitrica, Role of effective tensile strain inelectromechanical response of helical graphene nanoribbons with open and closedarmchair edges, Physical Review B 85, 035445 (2012). 50. L. Hale, Dong-Bo Zhan g, X. Zhou, J.A. Zimmerman, N.R. Moody, T. Dumitrica, R.Ballarini, and W.W. Gerberich, Dislocation Morphology and Nucleation Within MDCompressed Si Nanospheres, Computational MaterialsScience 54, 280 (2012). 51. A. Mittal, Dong-Bo Zhang , C. Teresi, A. Mkhoyan, and T. Dumitrica, Routes toidentification of intrinsic twist in helical MoS2 nanotubes by electron di_ractionand annular dark-field scanning transmission electron microscopy imaging, Physical Review B 84, 153401 (2011). 52. Dong-BoZhang , E. Akatyeva, and T. Dumitrica, Single Walled BN and ZnONanotubes with Intrinsic Twist: An Objective Molecular Dynamics Study, Physical Review B 106, 255503 (2011). 53. Dong-BoZhang , E. Akatyeva, and T. Dumitrica, Bending Ultra-Thin Grapheneat the Margins of Continuum Mechanics, PhysicalReview Letters 106, 255503 (2011). 54. Dong-BoZhang and T. Dumitrica, An Effective Tensional Strain View onthe Bandgap Tunability of Helical Graphene Nanoribbons with Open and Closed Edges,Small 7, 1023 (2011). 55. Dong-BoZhang and T. Dumitrica, The Role of Peierls-Like Distortionsin the Modification of Electronic Bandgaps of Graphene Nanoribbons UnderStrain, Journal of Chemical Physics, 134, 196101 (2011). 56. D. Teich, T. Lorenz, J. Joswig, G.Seifert, Dong-Bo Zhang and T. Dumitrica,Intrinsic Twist in Helical TiS2 Nanotubes Studied with Objective MolecularDynamics, Journal of Physical Chemistry C115, 6392 (2011). 57. I. Nikiforov, Dong-Bo Zhang and T. Dumitrica, Screw Dislocations in 58. Dong-BoZhang and T. Dumitrica, Effective Strain in Helical RippledCarbon Nanotubes: A Unifying Concept for Understanding Electromechanical Response, ACS Nano, 4, 6966 (2010). 59. Dong-BoZhang , T. Dumitrica and G. Seifert, Helical Nanotube Structuresof MoS 2 with Intrinsic Twisting: An Objective Molecular DynamicsStudy, Physical Review Letters 104, 065502 (2010). 60. I. Nikiforov, Dong-Bo Zhang , R.D. James, and T. Dumitrica, Wavelike rippling inmultiwalled carbon nanotubes under pure bending, Applied Physics Letters 96,123107 (2010). 61. Dong-BoZhang and T. Dumitrica, Modulating the optical and electronicproperties of highly symmetric Si quantum dots, Nanotechnology 20, 445401(2009). 62. Dong-BoZhang , R.D. James, and T. Dumitrica, Electromechanical characterizationof carbon nanotubes in torsion via symmetry adapted tight-binding objectivemolecular dynamics, Physical Review B80, 115418 (2009). 63. Dong-BoZhang , R.D. James, and T. Dumitrica, Dislocation onset andnearly axial glide in carbon nanotubes under torsion, Journal of Chemical Physics [Communication] 130, 071101 (2009). 64. Dong-BoZhang and T. Dumitrica, Elasticity of Ideal Single-WalledCarbon Nanotubes via Symmetry-Adapted Tight-Binding Objective Modeling, Applied Physics Letters 93, 031919 (2008). 65. Dong-BoZhang , M. Hua, and T. Dumitrica, Stability of Polycrystallineand Wurtzite Si Nanowires via Symmetry-Adapted Tight-Binding ObjectiveMolecular Dynamics, Journal of ChemicalPhysics 128, 084104 (2008). 66. S.G. Hao, Dong-Bo Zhang , and T. Dumitrica, Effect of Small Shape Changes onthe Optical Response of Highly Symmetric Silicon Quantum Dots, Physical Review B [Rapid Comm.] 76, 081305 (2007). 67. Dong-BoZhang * , J. Shen, andN.-X. Chen, First principles study of the carbon-(silicon-) doped La 13 clusters, Journal of Chemical Physics122, 114305 (2005). 68. Dong-BoZhang * , J. Shen, andN.-X. Chen, Continuation calculations of boron-(aluminum-, titanium-, andnickel-) doped La 13 clusters, Journalof Chemical Physics 123, 154313(2005). 69. Dong-BoZhang * and J. Shen,First principles study of the stability and electronic structure of theicosahedral La 13 , La −1 13 , and La +1 13 clusters, Journal of Chemical Physics120, 5081 (2004). 70. Dong-BoZhan g * and J. Shen, Groundstate, growth, and electronic properties of small lanthanum clusters, Journal of Chemical Physics 120, 5104 (2004).