Prof. Haiming Guo's main research interests include fabrication and characterization of low-dimensional nanomaterials, physics on functional molecular and nanoscale devices, development and applications on nanostenciling technique, as well as scanning probe microscopy methods and its applications. His recent achievements include investigating the magnetic properties of individual atoms/molecules at surfaces, fabricating and in-situ characterizing the self-assembling molecular thin films on metal surfaces, exploring electronic transport properties in low-dimensional nanosystems with a UHV four probe STM, and also developing an ultra-high vacuum micro clean room, designing and executing nanoscale devices by nanostenciling with a combination of other nanofabrication techniques, from which realizing the electrical interconnections from nanoscale to macro scale.

      He is referee for PRL、NanoLett.、Adv. Mater.、APL、Nanoscale、NJP and Surf. Sci. et al. He was invited to write five chapters in academic books, and has published more than 60 scientific papers.

2001-2004      Ph.D.  Institute of Physics, CAS
1995-1998      M.S. Northwestern Polytechnical University
1991-1995      B.S. Beijing University of Aeronautics and Astronautics (BUAA)

2007-present    Nanoscale Physics and Devices Laboratory,

Institute of Physics, CAS
2007.12-2008.4  Visiting Scientists, Center for Nano Science, University of Munich (LMU)

Walther-Meissner-Institute, Bavarian Academy of Sciences, Germany

2004-2006      Postdoc,  CEMES-CNRS, France

Main Publications：

[1] J. D. Ren^#, H. M. Guo^# *, J. B. Pan^#, Y. F. Zhang, Y. F. Zhang, X. Wu, S. X. Du, M. Ouyang and H. J. Gao, Inter-atomic Spin Coupling in ManganeseClusters Registered on Graphene, Phy. Rev. Lett. 119, 176806 (2017)

[2] X. Lin, J. C. Lu, Y. Shao, Y. Y. Zhang, X. Wu, J. B. Pan, L. Gao, W. Zhou, H. M. Guo, Y. L.Wang, S. X. Du, S. T. Pantelides and H.-J. Gao et al, Intrinsically patterned two-dimensional materials for selective adsorption of molecules and nanoclusters, Nat. Mater. 16, 717 (2017)

[3] T. Liang, G. He, X. Wu, J. D. Ren, H. X. Guo, Y. H. Kong, H. D. Iwai, D. Fujita, H. J. Gao, H. M. Guo*, Y. C. Liu* and M. S. Xu*, Permeation through graphene ripples, 2D Materials. 4, 025010 (2017).

[4] Y. Q. Wang^#, X. Wu^#, Y. L. Wang, Y. Shao, T. Lei, J. O. Wang, S. Y. Zhu, H. M. Guo, L. X. Zhao, G. F. Chen, S. M. Nie, H. M. Weng, K. Ibrahim, X. Dai, Z. Fang, and H. J. Gao*, Spontaneous Formation of a Superconductor–Topological Insulator–Normal Metal Layered Heterostructure. Adv. Mater. 28, 5013 (2016)

[5] Y. Q. Wang, X. Wu, Y. F. Ge, Y. L. Wang, H. M. Guo, Y. Shao, T. Lei, C. Liu, J. O. Wang, S. Y. Zhu, Z. L. Liu, W. Guo, K. Ibrahim, Y. G. Yao, and H. J. Gao, Tunable Electronic Structures in Wrinkled 2D Transition-Metal-Trichalcogenide (TMT) HfTe3 Films, Adv. Electron. Mater. 2, 1600324 (2016)

[6] J. D. Ren, X. Wu, H. M. Guo*, J. B. Pan, H. G. Luo, S. X. Du, and H. J. Gao, Lateral manipulation and interplay of local Kondo resonances in a two-impurity Kondo system, Appl. Phys. Lett 107, 071604 (2015)

[7] J. D. Ren^#, H. M. Guo^#, J. B. Pan^#, Y. Y. Zhang^#, X. Wu, H. G. Luo, S. X. Du, S. T. Pantelides, and H. J. Gao, Kondo Effect of Cobalt Adatoms on a Graphene Monolayer Controlled by Substrate-Induced Ripples. Nano Lett. 14, 4011 (2014)

[8] C. R.Woods, L. Britnell, A. Eckmann, R. S. Ma, J. C. Lu, H. M. Guo, X. Lin, G. L. Yu, Y. Cao, R. V. Gorbachev, A. V. Kretinin, J. Park, L. A. Ponomarenko, M. I. Katsnelson, Yu. N. Gornostyrev, K.Watanabe, T. Taniguchi, C. Casiraghi, H-J. Gao, A. K. Geim and K. S. Novoselov, Commensurate–incommensurate transition in graphene on hexagonal boron nitride. Nat. Phys. 10, 451 (2014)

[9] Q. Zou, M. Liu, G. Q. Wang, H. L. Lu, T. Z. Yang, H. M. Guo*, C. R. Ma, X. Xu, M. H. Zhang, J. C. Jiang, E. I. Meletis, Y. Lin, H. J. Gao, and C. L. Chen, Step Terrace Tuned Anisotropic Transport Properties of Highly Epitaxial LaBaCo₂O_5.5+δ Thin Films on Vicinal SrTiO3 Substrates ACS App. Mater. Interf. 6, 6704 (2014)

[10] H. M. Guo, Y. L. Wang, S. X. Du and H. J. Gao, High-resolution scanning tunneling microscopy imaging of Si(111)-7×7 structure and intrinsic molecular states. J. Phys. Condens. Matter, 26, 394001 (2014)

[11] H. B. Wang, S. Y. Bao, J. Liu, G. Collins, C. R. Ma, M. Liu, C. L. Chen, C. Dong, M.-H. Whangbo, H. M. Guo and H. J. Gao, Ultrafast chemical dynamic behavior in highly epitaxial LaBaCo2O5+d thin films. J. Mater. Chem. C. 2, 5660 (2014)

[12] M. Liu^#, Q. Zou^#, C. R. Ma, G. Collins, S B Mi, C L Jia, H. M. Guo, H. J. Gao, and C. L. Chen, Strain-Induced Anisotropic Transport Properties of LaBaCo2O5.5+delta Thin Films on NdGaO3 Substrates. ACS App. Mater. Interf. 6, 8526 (2014)

[13] Q. Zou, B. D. Belle, L. Z. Zhang, W. D. Xiao, K. Yang, L. W. Liu,G. Q. Wang, X. M. Fei, Y. Huang, R. S. Ma, Y. Lu, P. H. Tan, H. M. Guo*, S. X. Du, and H.-J. Gao*, Modulation of Fermi velocities of Dirac electrons in single layer graphene by moiré superlattice. Appl. Phys. Lett. 103, 113106 (2013)

[14] D. Y. Zhong, L. F. Chi, H. M. Guo, D. X. Shi and H. Fuchs, Molecular Cloisonné: Multicomponent Organic Alternating Nanostructures at Vicinal Surfaces with Tunable Length Scales, Small 8, 535 (2012)

[15] J. H. Mao, L. Huang, Y. Pan, M. Gao, J. F. He, H. T. Zhou, H. M. Guo, A. H. Castro Neto, and H. J. Gao et al, Silicon layer intercalation of centimeter-scale, epitaxially grown monolayer graphene on Ru(0001). Appl. Phys. Lett. 100, 093101 (2012)(Cover story)

[16] G. Li, H. T. Zhou, L. D. Pan, Y. Zhang, J. H. Mao, Q. Zou, H. M. Guo, Y. L. Wang, S. X. Du, and H.-J. Gao, Self-assembly of C60 monolayer on epitaxially grown, nanostructured graphene on Ru(0001) surface. Appl. Phys. Lett. 100, 013304 (2012)

[17] Z. W. Shi, H. L. Lu, L. C. Zhang, R. Yang, Y. Wang, D. H. Liu, H. M. Guo, D. X. Shi, H. J. Gao, E. G. Wang and G. Y. Zhang. Studies of Graphene-Based Nanoelectromechanical Switches. Nano Res. 5, 82 (2012)

[18] Y. L. Wang, Z. H. Cheng, Z. T. Deng, H. M. Guo, S. X. Du, and H. J. Gao, Modifying the STM Tip for the ‘Ultimate’ Imaging of the Si(111)-7×7 Surface and Metal-supported Molecules. Chimia 66, 31 (2012)（邀请综述文章）

[19] L. Z. Zhang, Z. H. Cheng, Q. Huan, X. H. He, X. Lin, L. Gao, Z. T. Deng, N. Jiang, Q. Liu, S. X. Du, H. M. Guo, and H. J. Gao, Site- and Configuration-Selective Anchoring of Iron_Phthalocyanine on the Step Edges of Au(111) Surface, J. Phys. Chem. C. 115, 10791 (2011)

[20] Z. H. Cheng, S. X. Du, W. Guo, L. Gao, Z. T. Deng, N. Jiang, H. M. Guo, H. Tang, and H. -J. Gao, Direct Imaging of Molecular Orbitals of Metal Phthalocyanines on Metal Surfaces with an O2-Functionalized Tip of a Scanning Tunneling Microscope, Nano Res. 4, 523–530, (2011)

[21] M. Gao, Y. Pan, L. Huang, H. Hu, L. Z. Zhang, H. M. Guo, S. X. Du, and H.-J. Gao. “Epitaxial growth and structural property of graphene on Pt(111)”, Appl. Phys. Lett. 98, 033101 (2011)

[22] H. G. Zhang, J. T. Sun, L. Z. Zhang, Y. Pan, Q. Liu, J. H. Mao, H. T. Zhou, H. M. Guo, S. X. Du, F. Guinea, and H.-J. Gao, Assembly of iron phthalocyanine and pentacene molecules on a graphene monolayer grown on Ru(0001)，Phys. Rev. B 84, 245436 (2011)

[23] H. L. Lu, C. D. Zhang, H. M. Guo, H. -J. Gao, M. Liu, J. Liu, G. Collins, and C. L. Chen. "Surface-Step-Terrace-Induced Anomalous Transport Properties in Highly Epitaxial La0.67Ca0.33MnO3 Thin Films".  ACS Appl. Mater. & Interf. 2, 2496 (2010)

[24] H. G. Zhang, H. Hu, Y. Pan, J. H. Mao, M. Gao, H. M. Guo, S. X. Du, T. Greber, H.-J. Gao “Graphene based quantum dots”. J. Phys.: Condens. Matter, 22, 302001 (2010)

[25] Z. C. Zong, M. Z. Zhang, H. L. Lu, D. Xu, S. M. Wang, H. F. Tian, C. Liu, H. M. Guo, H. J. Gao, and G. T. Zou, “Synthesis of PbTe/Pb quasi-one-dimensional nanostructure material arrays by electrodeposition.” Appl. Phys. Lett. 96, 143113 (2010).

[26] Z. T. Deng, H. M. Guo, W. Guo, L. Gao, Z. H. Cheng, D. X. Shi, and H.-J. Gao, “Structural Properties of Tetra-tert-butyl Zinc(II) Phthalocyanine Isomers on a Au(111) Surface”, J. Phys. Chem. C 113, 11223–11227(2009)

[27] Y. L. Wang, H. M. Guo, Z. H. Qin, H. F. Ma, and H. J. Gao. Toward a Detailed Understanding of Si(111)-7×7 Surface and Adsorbed Ge Nanostructures: Fabrications, Structures,and Calculations. Journal of Nanomaterials, ID 874213, 1-18 (2008)

[28] L. Cai, M. Feng, H. M. Guo, W. Ji, S. X. Du, L. F. Chi, H. Fuchs, H. J. Gao. Reversible and Reproducible Conductance Transition in a Polyimide Thin Film, J. Phys. Chem. C.112, 17038 (2008)

[29] X. Y. Zhang, Y. Q. Wen, H. M. Guo, L. Jiang, H. J. Gao and Y. L. Song et al. Molecularly Controlled Modulation of Conductance on Azobenzene Monolayer-Modified Dilicon Surfaces, J. Phys. Chem. C 112, 8288 (2008)

[30] H. M. Guo, D. Martrou, T. Zambelli, E.Dujardin and S. Gauthier, Development of UHV dynamic nanostencil for surface patterning. Rev. Sci. Instrum.79, 103904 (2008)

[31] H. M. Guo, D. Martrou, T. Zambelli, E.Dujardin and S. Gauthier. Nanostenciling for fabrication and interconnection of nanopatterns and microelectrodes. Appl. Phys. Lett. 90, 093113 (2007)

[32] Z. H. Cheng, L. Gao, Z. T. Deng, D. X. Shi, S. X. Du, H. M. Guo and H. J. Gao. Adsorption behavior of iron phthalocyanine on Au(111) surface at submonolayer coverage, J. Phys. Chem. C 111, 9240 (2007)

[33] J. Polesel-Maris, H. M. Guo, T. Zambelli and S. Gauthier, Mapping Van der Waals Forces with Frequency Modulation Dynamic Force Microscopy. Nanotechnology 17: 4204 (2006)

[34] Wang Y L, Gao H J, Guo H M, Wang S W, Pantelides S T, Bonding Configurations and Collective Patterns of Ge Atoms Adsorbed on Si(111)-7×7. Phys. Rev. Lett. 94:106101 (2005)

[35] Wang Y L, Gao H J, Guo H M, Liu H W, H J, Batyrev I G, McMahon W E, Zhang S B, Tip Size Effect on the Appearance of a STM Image for Complex Surfaces: Theory versus Experiment for Si(111)-7×7. Phys. Rev. B, 70: 073312 (2004)

[36] Guo H M, Wang Y L, Liu H W, Ma H F, Qin Z H, and Gao H J, Formation of Ge Nanoclusters on Si(111)-7×7 Surface at High Temperature. Surface Science, 561: 227 (2004)

[37] Guo H M, Liu H W, Wang Y L, Wang W Q, Gong Y, Gao H J, Surface Structures of DL-Valine and L-Alanine Crystals Observed by Atomic Force Microscopy at a Molecular Resolution. Surface Science, 552: 70 (2004)

[38] Guo H M, Liu H W, Wang Y L, Gao H J, Shang H X, Liu Z W, Xie H M, Dai F L, Nanometre Moire Fringes in Scanning Tunneling Microscopy of Surface Lattices. Nanotechnology 15: 991 (2004)

[39] Guo H M, Liu H W, Wang Y L, Xie H M, Dai F L, Gao H J, Moire Fringes of HOPG and Mica in Scanning Probe Microscopy. Acta Physica Sinica 52 : 2512 (2003)

[40] Liu H W, Guo H M, Wang Y L, Wang Y T, Wei L, Self-assembled Stripes on the Anodic Aluminum Oxide by Atomic Force Microscope Observation. Appl. Surf. Sci. 219: 282  (2003)

[41] Liu H W, Guo H M, Lin X, Yan L, Zhang Y P, Yang H Q, Pang S J, Gao H J, Self-assembly of ordered Ge and Si nano-structure on silicon surfaces. (2003) Advanced Nanomaterials and Nanodevices, pp592-610. IOP Publishing Ltd., London,

[42] Liu H W, Yang H Q, Guo H M, Wang Y L, Lin X, Pang S J, Gao H J, Pattern formation of Si on the Dimer Vacancy array by self-assembly. Nanotechnology 13: 729 (2002)

[43] Xie H M, Shang H X, Liu Z W, Guo H M, Gao H J, Phase shifting nano-moire with Scanning tunneling microscope. Optics and Lasers in Engineering，41: 755 (2004)

Academic Books and Chapters

[1]  H. M. Guo, Y. L. Wang, M. Feng L. Gao, and H. J. Gao,

“Probing Single Molecule Motors on Solid Surface” in << Atomic Scale Interconnection Machines, Advances in Single Atoms and Molecule Machines>>, Chapter 17.

    Ed. C. Joachim, Springer-Verlag Berlin Heidelberg (2012)

[2]  H. M. Guo, Y. L. Wang, and H. J. Gao,

“Scanning Tunneling Microscopy of the Si(111)-7×7 Surface and Adsorbed Ge Nanostructures” in <<Applied Scanning Probe Methods XII: Characterization>>, Chapter 17.

     Eds. B. Bhushan and H. Fuchs, Springer-Verlag, Berlin Heidelberg (2009)

[3]  Y. L. Wang, H. M. Guo, H. J. Gao,

“Graphene on Crystalline Metal Surfaces”, in Book <<Surface and Interface Science>>. Chapter 4

Eds. by Klaus Wandelt, Wiely VCH (2013).

[4]  D. Martrou, L. Guiraud, E. Dujardin, S. Gauthier, J. Maris, M. Venegas, H. Guo and T. Leoni et al,

“The DUF Project: A UHV Factory for Multi-Interconnection of a Molecule Logic Gates on Insulating Substrate” in << Atomic Scale Interconnection Machines, Advances in Single Atoms and Molecule Machines>>, Chapter 4.

Ed. C. Joachim, Springer-Verlag Berlin Heidelberg (2012)

[5]  Y. L. Wang, Q. Liu, H. G. Zhang, H. M. Guo, and H. J. Gao,

“Molecular Rotors Observed by Scanning Tunneling Microscopy” in <<Three-Dimensional Nanoarchitectures>>, Chapter 11.

Eds. W. L. Zhou and Z. L. Wang, Springer NY Heidelberg London (2011)