张东波教授

通信地址：北京市新街口外大街19号 北京师范大学核科学与技术学院
邮 编：100875
E-mail：dbzhang@bnu.edu.cn

---

张东波，2010年毕业于美国明尼苏达大学，获博士学位。2014年入选海外高层次人才计划。2018年初，在北京师范大学核科学与技术学院任职教授。他的主要研究领域是计算凝聚态物理，并近期侧重于核材料相关体系的理论研究。他曾发展出广义布洛赫方法、第一性原理声子准粒子方法、以及量子力学格林-久保方法等。
五篇代表性论文 [*通讯作者]
? X.-J. Zhao, Yang Yang, Dong-Bo Zhang* and S.-H. Wei*, Formation of Bloch Flat Bands in Polar Twisted Bilayers without Magic Angles, Physical Review Letters, 124, 086401 (2020).
? Dong-Bo Zhang*, X.-J. Zhao, G. Seifert, K. Tse, and J. Zhu*, Shear-Driven Separation of n-type and p-type Dopants in Single Crystalline Nanowires, National Science Review 6, 532 (2019)
? 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).
? Dong-Bo Zhang, T. Sun and R.M. Wentzcovitch, Phonon Quasiparticles and Anharmonic Free Energy in Complex Systems, Physical Review Letters 112, 058501 (2014).
? Dong-Bo Zhang, G. Seifert and Kai Chang, Strain-Induced Pseudo-Magnetic Fields in Twisted Graphene Nanoribbons, Physical Review Letters 112, 096805 (2014).
其它五篇重要论文 [*通讯作者]
? Dong-Bo Zhang, T. Dumitrica and G. Seifert, Helical Nanotube Structures of MoS₂ with Intrinsic Twisting: An Objective Molecular Dynamics Study, Physical Review Letters 104, 065502 (2010).
? Dong-Bo Zhang, E. Akatyeva, and T. Dumitrica, Bending Ultra-Thin Graphene at the Margins of Continuum Mechanics, Physical Review Letters 106, 255503 (2011).
? Dong-Bo Zhang and T. Dumitrica, Effective Strain in Helical Rippled Carbon Nanotubes: A Unifying Concept for Understanding Electromechanical Response, ACS Nano, 4, 6966 (2010).
? Dong-Bo Zhang, P. B. Allen, T. Sun and R. M. Wentzcovitch, Thermal Conductivity of MgSiO₃ with Sublattice Mean Free Path, Physical Review B (RC), 96, 100302 (2017).
? Dong-Bo Zhang* and Su-Huai Wei*, Realizing Half-Metallicity in Zigzag Graphene Nanoribbon by Bending: A Mechanism Studied by Generalized Bloch Theorem, npj Computational Materials 3, 32 (2017).
研究领域
? 计算凝聚态物理，计算材料学
? 材料结构、电、声子及输运性质计算
? 核材料、复合材料、低维材料
计算方法与计算软件
1. 广义布洛赫能带计算方法
2. 第一性原理声子准粒子计算方法
3. 量子力学Green-Kubo热导率计算方法
4. 固态材料Slater-Koster紧束缚排斥项参数的可程序化计算方法
5. 晶格失配下复合晶体体系电子、声子计算方法
荣誉和奖励
? 2002年，北京市优秀毕业生
? 2014年，海外高层次人才计划
?2017年，研究课题“晶格失配复合材料电子能带计算方法及应用”获得“博士后创新人才计划”支持（2017-2019，赵兴举博士后）
课题经费/基金
? 2014—2017，海外高层次人才计划（ 300万人民币）
? 2017—2020，基金委面上项目“低维材料电子性质的应变调控：自洽密度泛函紧束缚广义布洛赫方法”（负责）
? 2017—2022，科技部重点专项“低维固态极性结构中量子态调控及其原型器件研究”（参与）
? 2017—2019，赵兴举，博士后创新人才计划（60万）（指导老师）
? 2018—2023，北京师范大学引进人才启动经费，“极端条件下主要核材料的热力学及热输运计算研究”（300万，负责）
? 2019—2023，基金委面上项目“固态材料晶格热导率计算：基于Slater-Koster原子轨道表象的量子力学格林-久保方法”（负责）
课题组成员
? 博士后：赵兴举（郑州大学）
? 博士生：刘钊（2016—）、史金磊（2017—）
? 硕士生：李建高（2018—）、王雅巽（2019—）何超（2019—）
? 本科生：唐锦琨（2018—）等
? 访问学生：张桢（美国哥伦比亚大学，2018年1月—9月）
毕业学生/出站博士后/访问人员
? 赵荟艳（博士后，出站时间2015），河北师范大学物理学院副教授
? 鲁勇（博士后，出站时间2016），北京化工大学物理系讲师
? 任迎辉（博士后，出站时间2017），台湾
? 刘卯鑫（博士后，出站时间2018），北京邮电大学讲师
? 宋宏权（访问人员），周口师范学院副教授
? 李进春（博士后，出站时间2018），北京
访问教授
? Renata. M. Wentzcovitch（2016年9月29日—12月2日），Professor,Columbia University Department of Applied Physics and Applied Mathematics.
? Gotthard Seifert（2015年11月1日—6日），Professor, Theoretische Chemie, Technische Universitaet Dresden, Germany
其他
? APS，AIP，ACS，IOP等系列杂志审稿人。
论文目录
期刊论文
[*]通讯作者
1. Xing-Ju Zhao, Dong-Bo Zhang* and Su-Huai Wei*, Graphene Membrane as Molecular Filters (in preparation, 2019)
2. Jin-Lei Shi, Xing-Ju Zhao, Dong-Bo Zhang*, Pure Bending in Two Dimensions Towards Robust Flexible Electronics (in preparation, 2019).
3. J-.L. Shi, X.-J. Zhao, G. Seifert, S.-H. Wei, D.-B. Zhang, Unusual deformation potential and half-metallicity in Maxene nanoribbons, Physical Chemistry Chemical Physics (under review)
4. Zhao Liu, Dong-Bo Zhang*, Xu-Wen Fu*, Dapeng Yu, and Wanlin Guo*, Indirect Exciton in Bent ZnO Nanowire (under review, 2019)
5. X.-J. Zhao, Yang Yang, Dong-Bo Zhang* and Su-Huai Wei*, Formation of Bloch Flat Bands in Polar Twisted Bilayers without Magic Angles, Physical Review Letters, 124, 086401 (2020)
6. Zhao Liu, Chi-Yung Yam, Shiwu Gao*, Tao Sun, and Dong-Bo Zhang*, Lattice Dynamics of Deformed Quasi-One Dimensional Crystals under Generalized Born-von Karman Boundary Conditions, New Journal Physics 22, 023004 (2020).
7. X.-J. Zhao, G. Seifert, J. Zhu* and D.-B. Zhang*, Twist-induced preferential distribution of dopants in single-crystalline Si nanowires, Phys. Rev. B 100, 174202 (2019)
8. Zhen Zhang, Dong-Bo Zhang*, Tao Sun, and Renata M. Wentzcovitch*, phq: a Fortran code to compute phonon quasiparticle properties and dispersions, Computer Physics Communications 243, 110 (2019).
9. Yong Lu*, Fa-wei Zheng, Yu Wang, Ping Zhang, and Dong-Bo Zhang*, Phase Stabilities of Cmcm and Pnma SnSe Studied by Phonon Quasiparticle Approach, Physical Review B 100, 054304 (2019).
10. Zhao Liu, Dong-Bo Zhang*, Gotthard Seifert, Ying Liu and Kai Chang*, Interfacial Landau levels in Bent Graphene Racetracks, Physical Review B 99, 165416 (2019)
11. Hong-Quan Song, Zhao Liu and Dong-Bo Zhang*, Interlayer Vibration of Twisted Bilayer Graphene: A First-Principles Study, Physics Letters A 383, 2628 (2019)
12. Dong-Bo Zhang*, Xing-Ju Zhao, Gotthard Seifert, Kaifai Tse, and Junyi Zhu*, Shear-Driven Separation of n-type and p-type Dopants in Single Crystalline Nanowires, National Science Review 6, 532 (2019) See also “A new strategy of fabricating 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.
13. Yong Lu, Tao Sun, and Dong-Bo Zhang*, Lattice Anharmonicity, Phonon Dispersion, and Thermal Conductivity of PbTe Studied by the Phonon Quasiparticle Approach, Physical Review B 97, 174304 (2018).
14. Dong-Bo Zhang, P. B. Allen, T. Sun and R. M. Wentzcovitch, Thermal Conductivity of MgSiO₃ with Sublattice Mean Free Path, Physical Review B [Rapid Communication], 96, 100302 (2017).
15.Yue Ling, Gotthard Seifert, Kai Chang and Dong-Bo Zhang,* Effective Zeeman Splitting in Bent Graphene/Hexagonal Boron Nitride Lateral Heterojunctions: A New Mechanism towards Half-Metallicity, Physical Review B [Rapid Communication], 96, 201403 (2017).
16. Dong-Bo Zhang* and Su-Huai Wei*, Realizing Half-Metallicity in Zigzag Graphene Nanoribbon by Bending: A Mechanism Studied by Generalized Bloch Theorem, npj Computational Materials 3, 32 (2017).
17. N. Ghaderi, Dong-Bo Zhang, H. Zhang, J. Xian, R. Wentzcovitch, and T. Sun, Lattice Thermal Conductivity of MgSiO₃ Perovskite from First Principles, Scientific Reports, 7, 5417(2017).
18. 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).
19. Y. Lu, F. Zheng, P. Zhang, X. Shao, and Dong-Bo Zhang, Temperature and isotope effects on the thermoelectric properties in SnTe, Journal of Physics: Condensed Matter, 29, 175701 (2017).
20. Jiang Zeng, Wei Chen, Ping Cui, Dong-Bo Zhang,* and Zhenyu Zhang*, Enhanced Half-Metallicity in Orientationally Misaligned Graphene/Hexagonal BoronNitride Lateral Heterojunctions, Physical Review B 94, 235425 (2016).
21. Hong-Man Ma, Jing Wang, Hui-Yan Zhao, Dong-Bo Zhang, Ying Liu, Structural prediction for scandium carbide monolayer sheet, Chemical Physics Letters 660 238 (2016).
22. Dong Zhang, Dong-Bo Zhang*, Fuhua Yang, Hai-Qing Lin, Hongqi Xu and Kai Chang*, Interface engineering of electronic properties of graphene/boron nitride lateral heterostructures, 2D Materials 2, 041001 (2015).
23. Hui-Yan Zhao, Jing Wang, Xiu-Jie Su, Dong-Bo Zhang, and Ying Liu, Ice Carbons, Journal of Physical Chemistry C 118, 27502 (2014).
24. Dong-Bo Zhang, T. Sun and R.M. Wentzcovitch, Phonon Quasiparticles and Anharmonic Free Energy in Complex Systems, Physical Review Letters 112, 058501 (2014).
25. Dong-Bo Zhang, G. Seifert and Kai Chang, Strain-Induced Pseudo-Magnetic Fields in Twisted Graphene Nanoribbons, Physical Review Letters, 112, 096805 (2014).
26. Sun, Tao, Dong-Bo Zhang, and Renata M. Wentzcovitch. 2014. Dynamic stabilization of cubic CaSiO₃ perovskite at high temperatures and pressures from ab initio molecular dynamics, Physical Review B 89, 094109 (2014).
27. Dong-Bo Zhang and T. Dumitrica, Role of effective tensile strain in electromechanical response of helical graphene nanoribbons with open and closed armchair edges, Physical Review B 85, 035445 (2012).
28. L. Hale, Dong-Bo Zhang, X. Zhou, J.A. Zimmerman, N.R. Moody, T. Dumitrica, R. Ballarini, and W.W. Gerberich, Dislocation Morphology and Nucleation Within MD Compressed Si Nanospheres, Computational Materials Science 54, 280 (2012).
29. A. Mittal, Dong-Bo Zhang, C. Teresi, A. Mkhoyan, and T. Dumitrica, Routes to identification of intrinsic twist in helical MoS2 nanotubes by electron di_raction and annular dark-field scanning transmission electron microscopy imaging, Physical Review B 84, 153401 (2011).
30. Dong-Bo Zhang, E. Akatyeva, and T. Dumitrica, Single Walled BN and ZnO Nanotubes with Intrinsic Twist: An Objective Molecular Dynamics Study, Physical Review B 106, 255503 (2011).
31. Dong-Bo Zhang, E. Akatyeva, and T. Dumitrica, Bending Ultra-Thin Graphene at the Margins of Continuum Mechanics, Physical Review Letters 106, 255503 (2011).
32. Dong-Bo Zhang and T. Dumitrica, An Effective Tensional Strain View on the Bandgap Tunability of Helical Graphene Nanoribbons with Open and Closed Edges, Small 7, 1023 (2011).
33. Dong-Bo Zhang and T. Dumitrica, The Role of Peierls-Like Distortions in the Modification of Electronic Bandgaps of Graphene Nanoribbons Under Strain, Journal of Chemical Physics, 134, 196101 (2011).
34. D. Teich, T. Lorenz, J. Joswig, G. Seifert, Dong-Bo Zhang and T. Dumitrica, Intrinsic Twist in Helical TiS2 Nanotubes Studied with Objective Molecular Dynamics, Journal of Physical Chemistry C 115, 6392 (2011).
35. I. Nikiforov, Dong-Bo Zhang and T. Dumitrica, Screw Dislocations in <100>Silicon Nanowires: An Objective Molecular Dynamics Study, Journal of Physicl Chemistry Letters, 2, 2544 (2011).
36. Dong-Bo Zhang and T. Dumitrica, Effective Strain in Helical Rippled Carbon Nanotubes: A Unifying Concept for Understanding Electromechanical Response, ACS Nano, 4, 6966 (2010).
37. Dong-Bo Zhang, T. Dumitrica and G. Seifert, Helical Nanotube Structures of MoS₂ with Intrinsic Twisting: An Objective Molecular Dynamics Study, Physical Review Letters 104, 065502 (2010).
38. I. Nikiforov, Dong-Bo Zhang, R.D. James, and T. Dumitrica, Wavelike rippling in multiwalled carbon nanotubes under pure bending, Applied Physics Letters 96, 123107 (2010).
39. Dong-Bo Zhang and T. Dumitrica, Modulating the optical and electronic properties of highly symmetric Si quantum dots, Nanotechnology 20, 445401 (2009).
40. Dong-Bo Zhang, R.D. James, and T. Dumitrica, Electromechanical characterization of carbon nanotubes in torsion via symmetry adapted tight-binding objective molecular dynamics, Physical Review B 80, 115418 (2009).
41. Dong-Bo Zhang and T. Dumitrica, Elasticity of Ideal Single-Walled Carbon Nanotubes via Symmetry-Adapted Tight-Binding Objective Modeling, Applied Physics Letters 93, 031919 (2008).
42. Dong-Bo Zhang, R.D. James, and T. Dumitrica, Dislocation onset and nearly axial glide in carbon nanotubes under torsion, Journal of Chemical Physics [Communication] 130, 071101 (2009).
43. Dong-Bo Zhang, M. Hua, and T. Dumitrica, Stability of Polycrystalline and Wurtzite Si Nanowires via Symmetry-Adapted Tight-Binding Objective Molecular Dynamics, Journal of Chemical Physics 128, 084104 (2008).
44. S.G. Hao, Dong-Bo Zhang, and T. Dumitrica, Effect of Small Shape Changes on the Optical Response of Highly Symmetric Silicon Quantum Dots, Physical Review B [Rapid Comm.] 76, 081305 (2007).
45. Dong-Bo Zhang* and J. Shen, Ground state, growth, and electronic properties of small lanthanum clusters, Journal of Chemical Physics 120, 5104 (2004).
46. Dong-Bo Zhang*, J. Shen, and N.-X. Chen, Continuation calculations of boron- (aluminum-, titanium-, and nickel-) doped La₁₃ clusters, Journal of Chemical Physics 123, 154313 (2005).
47. Dong-Bo Zhang* and J. Shen, First principles study of the stability and electronic structure of the icosahedral La₁₃, La^?1₁₃ , and La⁺¹₁₃ clusters, Journal of Chemical Physics 120, 5081 (2004).
48. Dong-Bo Zhang*, J. Shen, and N.-X. Chen, First principles study of the carbon- (silicon-) doped La₁₃ clusters, Journal of Chemical Physics 122, 114305 (2005).