汤朝晖

TANG ZHAO HUI

职称/学术兼职

工业科学研究院PI、中组部“千人计划"、教授、博导、加州理工学院高级研究员

 

职位

联系方式

Jautang@yahoo.com

主要研究方向

  • 4D electron microscopy of photoinduced carrier dynamics, structural dynamics, phase transitions in metallic, semiconductor and carbon-based nanomaterials.
  • Nanoscience and Nanotechnology: Photoluminescence of Semiconductor and Metallic Nanoparticles; Confocal/AFM Single Molecule Spectroscopy; Quantum Dot Lasers; Quantum Dot Single-Photon Sources; Plasmonics;
  • Photophysics & Photochemistry: Femtosecond-Laser Induced Ultrafast Phenomena; Time-Resolved Electron/X-ray Diffraction of Nanomaterials; Photo-Induced Electron
    Transfer in Natural and Artificial Photosynthesis; Photovoltaics;
  • Nonlinear Fiber Optics Lightwave System and DWDM Transmission System Designs; Information Theory of Shannon Channel Capacity;        

教育工作经历

Education:

  • University of California, Berkeley; Ph.D. Physics, 1981, “Study of correlated motion by multiple quantum nuclear magnetic resonance spectroscopy”. Thesis adviser: Prof. Alex Pines
  • National Tsinghua University, Taiwan; M.S. Physics, 1976
  • National Taiwan University, Taiwan; B.S. Physics, 1974

Work Experience:

  • Distinguished Professor, Institute of Technological Sciences, Wuhan University, Wuhan, China (2017-present)
  • Senior Scientist, Dept. Chemistry, Caltech (2014-2017)
  • Research Fellow (2007 -2014)  Research Center for Applied Sciences, Academia Sinica, Taipei, Taiwan
  • Associate Director (2007-2010), Research Center for Applied Sciences, Academia Sinica, Taipei, Taiwan
  • Adjunct Professor, Institute of Photonics, National Chiao Tung University, Hsinchu, Taiwan (2007 -2014)
  • Senior Scientist, California Institute of Technology, Pasadena, California (2003-2007)
  • Senior Engineer, Opvista, California (2001-2002)
  • Member of Technical Staff, Bell Laboratories, New Jersey (1998-2001)
  • Physicist, Argonne National Laboratory, Illinois (1981-1998)

论文发表和专利

H-index: 30, accumulated citations > 2400

 

High Impact Factor (IF > 7) Publications

(Science, Nature, Nature Comm., Nano Lett., ACS Nano, PNAS, PRL, JACS)

  1. X. W. Fu, B. Chen, Jau Tang*, M. Th. Hassan, A. H. Zewail, Science 355, 994 (2017), “Imaging rotational dynamics of a nanoparticle in liquid by 4D electron microscopy”. (SCI IF = 34.66 )
  2. X. W. Fu*, B. Chen, Jau Tang*, A. H. Zewail, Science Advances 3, e1701160  (2017),

“Photoinduced nanobubbe-driven superfast diffusion of nanoparticles imaged by 4D electron microscopy”.

  1. M. Kaplan, B.K. Yoo, J. Tang*, D. Baltimore, G. J. Jensen*, A. H. Zewail, , Angewandte Chemie 56, 11498  (2017),

“Photon-induced near field electron microscopy of eukaryotic cells” . (SCI IF=11.99)

  1. E. Najafi, T. D. Scarborough, Jau Tang, A. H. Zewail , Science  347, 164 (2015),

“4D imaging of carrier interface dynamics in p-n junctions.

  1. B-K Yoo, O. H. Kwon, H. Liu, Jau Tang, A. H. Zewail, Nature Communications  6, No. 8639 (2015), “Observing in space and time the ephemeral nucleation of liquid-to-crystal phase transitions” (SCI IF =   11.33)
  2. H. Liu, O. H. Kwon, Jau Tang, A. H. Zewail. Nano Lett. 14, 946 (2014), ”4D Imaging and Diffraction Dynamics of Single-Particle Phase Transition in Heterogeneous Ensembles” (SCI IF = 13.78  )
  3. P. Yu, X. M. Wen, Y.-C. Lee, W.-C. Lee, C.-C. Kang* and J. Tang*, J. Phys. Chem. Lett. 4, 3596−3601 (2013),, “"Photoinduced Ultrafast Charge Separation in Plexcitonic CdSe/Au and CdSe/Pt Nanorods".  (SCI  IF = 8.54)
  4. P. Lee, W.‐C. Li, B.‐J. Chen, C.‐W. Yang, C.C. Chang, I. Botiz, G. Reiter, T. L. Lin, J. Tang, A. C.M. Yang, ACS Nano 7, 6659 (2013),
    “Massive Enhancement of Photoluminescence through Dewetting”. ". (SCI  IF = 11.421)
  5. C. T. Yuan, Y. G. Wang, K. Y. Huang, T. Y. Chen, P. Yu, J. Tang, A. Sitt, U. Banin, and O. Millo, ACS Nano 6, 176 (2012), "Single-Particle Studies of Band Alignment Effects on Electron Transfer Dynamics from Semiconductor Hetero-Nanostructures to Single-Walled Carbon Nanotubes". (SCI  IF = 11.421).
  6. J. Chen, W. K. Chen, J. Tang, P, M. Rentzepis, PNAS 108, no. 47, 18887 ( (2011),
    "Time Resolved X-ray Diffraction Studies on Ultrafast Melting, contraction and Wave Propagation in Au(111) thin crystal film induced by fs laser pulses". (SCI IF = 9.771).
  7. C. T. Yuan, P. Yu, H. C. Ko, J. Huang, and J. Tang, ACS Nano 3, 3051 (2009),
    "High Performance Nonblinking Single-Photon Sources".  (SCI  IF = 11.421).
  8. J. Tang and R. A. Marcus, Phys. Rev. Lett. 95, 107401 (2005),  “Diffusion-controlled Electron Transfer Processes and Power-law Statistics of Fluorescence Intermittency of  Nanoparticles”. (SCI IF = 7.621)
  9. V. A. Lobastov, J. Weissenrieder, J. Tang and A. H. Zewail, Nano Lett. 7, 2552 (2007),

“Ultrafast Electron Microscopy of Nanostructured Materials: 4D Imaging and Diffraction during Phase Transitions.”  (SCI IF = 13.198)

  1. J. Tang and J. R. Norris, Nature 333, 216 (1988),

"Padé Approximation and the Linear Prediction Method".  (SCI IF = 36.101)

  1. K. Hasharoni, H. Levanon, J. Tang, M. K. Bowman, J. R. Norris, D. Gust, T. A. Moore, and A. L. Moore, JCAS 112, 6477 (1990), "Singlet Photochemistry in Model Photosynthesis: Identification of Charge Separated Intermediates by Fourier Transform & CW EPR Spectroscopies". (SCI IF = 9.019)
  2. J. R. Norris, M. K. Bowman, D. E. Budil, J. Tang, C. A. Wraight, and G. L. Closs, Proc. Natl. Acad. Sci. U.S.A. 79, 5532 (1982), "Magnetic Characterization of the Primary State of Bacterial Photosynthesis". (SCI IF = 9.771)


 

Publications on 4D electron microscopy

  1. X. W. Fu, B. Chen, Jau Tang*, M. Th. Hassan, A. H. Zewail, Science 355, 994 (2017), “Imaging rotational dynamics of a nanoparticle in liquid by 4D electron microscopy”. (SCI IF = 34.66 )
  2. B. Chen*, X.W. Fu, Jau Tang*, M. Lysevych, H. H. Tan, C. Jagadish, A. H. Zewail. , PNAS.  (submitted), “Eutectic  dynamics and control of gold-encapped gallium arsenide nanowires imaged by 4D electron microscopy”.  “
  3. X. W. Fu*, B. Chen, Jau Tang*, A. H. Zewail, Science Advances  3, e1701160 (2017),
  4. “Photoinduced nanobubbe-driven superfast diffusion of nanoparticles imaged by 4D electron microscopy”.
  5. M. Kaplan, B.K. Yoo, J. Tang*, D. Baltimore, G. J. Jensen*, A. H. Zewail, Angewandte Chemie 56, 11498  ( 2017),
  6. ““Photon-induced near field electron microscopy of eukaryotic cells”
  7.  J. Cho*, T. Y. Hwang, E. Najari, H. Li, J. S. Baskin, Jau Tang*, A. H. Zewail,, Science Advances (to be submitted), “Observing dynamical crater-shaped charge distribution in monolayer graphene by 4D electron microscopy”.
  8. E. Najafi1, T. D. Scarborough, Jau Tang, A. H. Zewail, Science 347, 164 (2015), ”4D imaging of carrier interface dynamics in p-n junctions”.  
  9. B-K Yoo, O. H. Kwon, H. Liu, Jau Tang, A. H. Zewail, Nature Communications  6, No. 8639 (2015), “Observing in space and time the ephemeral nucleation of liquid-to-crystal phase transitions”.
  10. H. Liu, O. H. Kwon, Jau Tang, A. H. Zewail , Nano Lett. 14, 946 (2014),“4D Imaging and Diffraction Dynamics of Single-Particle Phase Transition in Heterogeneous Ensembles”,.
  11. J. Tang, J. Chem. Phys. 128, 164702 (2008),  “Coherent Phonon Excitation and Linear Thermal Expansion in Structural Dynamics and Ultrafast Electron Diffraction of Laser-Heated Metals”.
  12. V. A. Lobastov, J. Weissenrieder, J. Tang and A. H. Zewail, Nano Lett.  7, 2552 (2007),  “Ultrafast Electron Microscopy of Nanostructured Materials: 4D Imaging and Diffraction during Phase Transitions.“
  13. J. Tang, D. S. Yang and A. H. Zewail, J. Phys. Chem. C  111, 8957 (2007). “Time-resolved Ultrafast Electron Crystallography. III  Theoretical Modeling of Structural Dynamics”.

    Complete Publication List

    H Index = 30

    Accumulated citations > 2500

     

    197) X. W. Fu, B. Chen, Jau Tang*,, M. Th. Hassan, A. H. Zewail, Science 355, 994 (2017),

    “Imaging rotational dynamics of a nanoparticle in liquid by 4D electron microscopy”,

    196) B. Chen*, X.W. Fu, Jau Tang*, M. Lysevych, H. H. Tan, C. Jagadish, A. H. Zewail. , PNAS  (submitted),

    “Eutectic  dynamics and control of gold-encapped gallium arsenide nanowires imaged by 4D electron microscopy”.  “

    195) X. W. Fu*, B. Chen, Jau Tang*, A. H. Zewail, Science Advances  (2017),

    “Nanobubbe-driven superfast Brownian dynamics of photoexcited gold nanoparticles using 4D electron microscopy”.

    194) M. Kaplan, B.K. Yoo, J. Tang*, D. Baltimore, G. J. Jensen*, A. H. Zewail, Angewandte Chemie 3, e1701160 (2017),

    “Cellular PINEM imaging of ligand-induced receptor conformational changes by 4D electron microscopy”.”.

     

    193) B. Chen*, B-K Yoo, J. Tang*, M. Lysevych, H. H. Tan, C. Jagadish, A. H. Zewail. Nature Nanophotonics. (in preparation), 

     “Imaging photoinduced charge separation in gold encapped core-shell quantum wires by PINEM ”,

     

    192) J. Cho*, T. Y. Hwang, E. Najari, H. Li, J. S. Baskin, Jau Tang*, A. H. Zewail, Science Advances  (to be submitted),

    “Observing dynamical crater-shaped charge distribution in monolayer graphene by 4D electron microscopy”,

     

    191) E. Najafi1, T. D. Scarborough, Jau Tang, A. H. Zewail, Science 347, 164 (2015),

    ,”4D imaging of carrier interface dynamics in p-n junctions”.  

    190) B-K Yoo, O. H. Kwon, H. Liu, Jau Tang, A. H. Zewail, Nature Communications  6, No. 8639 (2015),

    “Observing in space and time the ephemeral nucleation of liquid-to-crystal phase transitions,

    189)H. Liu, O. H. Kwon, Jau Tang, A. H. Zewail , Nano Lett. 14, 946 (2014),

    “4D Imaging and Diffraction Dynamics of Single-Particle Phase Transition in Heterogeneous Ensembles”,.

     

    188) X. M. Wen, P. Yu, X. Ma, Y.-R. Toh and J. Tang, Chem. Comm. (in press, 2014),

    “On the Upconversion Fluorescence in Carbon Nanodots and Graphene Quantum Dots".

     

    187) H. H. Liu, O. H. Kwon, J. Tang and A. H. Zewail, Nano Lett. 7, 2552 (2014),

    “4D Imaging and Diffraction Dynamics of Single-Particle Phase Transition in Heterogeneous Ensembles”.

     

    186) X. Ma, X. M. Wen*, Y.-R. Toh, K.-Y. Huang, J. Tang and P. Yu*, Nanotechnology 25, 445 (2014),

     "Dynamic study on the atomically precise size transformation process of gold nanoclusters" ..

     

    185) X. M. Wen*, P. Yu*, Y.-R. Toh, Y.-C. Lee, K. Y. Huang, S. Huang, S. Shrestha, G. Conibeer and J. Tang*, J. Mater. Chem. C2, 3826  (2014),

    "Ultrafast Directional Electron Transfer in Nanocomposite of Graphene Oxide/Au Nanocluster with Graphene Oxide As a Donor"

     

    184) X. M. Wen*, P. Zhang, T. Smith, R. J. Anthony, U. R. Kortshagen, P. Yu, Y.-R. Toh, J. Tang, Y. Feng, S. Shrestha, G. Conibeer, M. Green and S. Huang*, Phys. Rev. Lett.,

    "The Origin of Photoluminescence and Correlation with Surface State in Colloidal Silicon Nanocrystals" (submitted).

     

    183) P. Yu*, X. M. Wen*, Y.-R. Toh, X. Q. Ma, and J. Tang*, Nano Comm. Int., "Dynamics, Structures and Applications of Metallic Nanoclusters" ( invited review article).

     

    182) P. Yu*, X. M. Wen, Y.-R. Toh, Y.-C. Lee, K.-Y. Huang, S. Huang, S. Shrestha, G. Conibeer and J. Tang*, J. Mater. Chem. C2 2894 (2014).

      "Efficient Electron Transfer in Carbon Nanodot-Graphene Oxide,

     

    181) P. Yu, X. M. Wen, Y.-C. Lee, W.-C. Lee, C.-C. Kang* and J. Tang*, J. Phys. Chem. Lett. 4, 3596−3601 (2013),

    "Photoinduced Ultrafast Charge Separation in Plexcitonic CdSe/Au and CdSe/Pt Nanorods".

     

    180) C. T. Yuan, Y. C. Wang, H. W. Cheng, H. S. Wang, M. Y. Kuo, M. H. Shih, J. Tang*, J. Phys. Chem. C 117, 12762 (2013),

     "Modification of Fluorescence Properties in Single Colloidal Quantum Dots by Coupling to Plasmonic Gap Modes".

     

    179) H. W. Cheng, Y. C. Chang, C. T. Yuan, S. N. Tang, C. S. Chang, J. Tang, F. R. Chen, R. L. Pan, F. G. Tseng*, J. Phys. Chem. C 117, 13239 (2013),

    "Simple and Fast Method To Fabricate Single-Nanoparticle-Terminated Atomic Force Microscope Tips".

     

    178) H. W. Cheng, Y. C. Chang, S. N. Tang, C. T. Yuan, J. Tang, F. G. Tseng, Nanoscale Res. Lett. 8, 482 (2013),

    "Characterization of single 1.8-nm Au nanoparticle attachments on AFM tips for single sub-4-nm object pickup".

     

    177) C. T. Yuan, C. A. Lin, T. N. Lin, W. H. Chang, J. L. Shen, H. W. Cheng, and J. Tang*, J. Chem. Phys. (in press, 2013,

     “Probing Electronic Triplet States of Fluorescent Gold Nanoclusters at the Single-Molecule Levels”.

     

    176) X. M. Wen, P. Yu, , J. Tang* and V. Podzorov, J. Phys. Chem. C 117, 17741–17747 (2013), “Singlet and Triplet Carrier Dynamics in Rubrene Single crystal”.

     

    175) X. M. Wen*, P. Yu, Y.-R. Toh, X. Q. Ma, S. J. Huang and J. Tang*, Nanoscale 5, 10251-10257 (2013), "Fluorescence Origin and Spectral Broadening Mechanism in Atomically Precise Au8 Nanoclusters".

     

    174) P. Yu*, X. M. Wen, Y.-R. Toh, Y.-C. Lee and J. Tang*, RSC Adv. 3, 19609-19616 (2013),"Optical Properties of Gold Particle-Cluster Core-Satellite Nanoassemblies".

     

    173) M. Y. Ng, P. Yu, J. Tang*, Y. C. Chang*, J. Phys. Chem. C 117, 13697–13707 (2013), "Sound Wave Propagation Anisotropy in Silver Nanoprisms: Characterization of Photoinduced Multiple Modes Using the Symmetric Molecular Dynamics Method".

     

    172) J. Tang, A. Oguz-Er, J. Chen and P. M. Rentzepis, J. App. Phys. (submitted),
    "Acoustic blast waves in a bilayer metallic film induced by femtosecond pulsed laser: A time-resolved X-ray diffraction study".

    171) H. W. Cheng, C. T. Yuan, J. S. Wang,T. N. Lin, J. L. Shen,Y. J. Hung,F. G. Tseng, and J. Tang, JPC C (in press),
    "A Trade-off between Pure Single-Photon Emission and Blinking Suppression in Single Colloidal Quantum Dots".

    170) P. Yu, X.M. Wen, Y.R. Toh, Y.C. Lee, X.Q. Ma and.J. Tang, Nanoscale (in press, 2013),
    "Optical Properties of Gold Particle-Cluster Core-Satellite Nanoassemblies".

    169) P. Lee, W.‐C. Li, B.‐J. Chen, C.‐W. Yang, C.C. Chang, I. Botiz, G. Reiter, T. L. Lin, J. Tang, A. C.M. Yang, ACS Nano (in press, 2013),
    Massive Enhancement of Photoluminescence through Dewetting”.

    168) C. T. Yuan, Y. C. Wang, H. W. Cheng, H. S. Wang, M. Y. Kuo, M. H. Shih, and J. Tang, JPC C 117 (24) 12762 (2013),
    "Concurrent Enhancement of Exciton and Bi-exciton Quantum Yields of Single Colloidal Quantum Dots by Coupling to Plasmonic Gap Modes".)

    167) M. Y. Ng, P. Yu, J. Tang*, Y. C. Chang*, J. Phys. Chem. C 117, 13697–13707 (2013), "Sound Wave Propagation Anisotropy in Silver Nanoprisms: Characterization of Photoinduced Multiple Modes Using the Symmetric Molecular Dynamics Method".

    166) X.M. Wen, P. Yu, Y.R. Toh, X.T. Hao, and Jau Tang, Adv. Opt. Materials 1 173 (2013),
    "Intrinsic and Extrinsic Fluorescence in Carbon Nanodots: Ultrafast Time-Resolved Fluorescence and Carrier Dynamics".

    165) P. Yu, X. M. Wen, Y. C. Lee, W. Y. Hsu, C. C. Kang, and J. Tang Chem. Phys. Chem. (submitted), 
    "Ultrafast Carrier Dynamics in Plexcitonic CdSe/Au and CdSe/Pt Nanorodss".

    164) H. W. Cheng, Y. C. Chang, C. T. Yuan, S. N. Tang, C. S. Chang, J. Tang, F. R. Chen, R. L. Pan, F. G. Tseng, JPC C (2013),
    "Simple and Fast Method to Fabricate Single-Nanoparticle-Terminated AFM Tips/

    163) A. Oguz Er, J. Chen, J. Tang, and P. M. Rentzepis, APL 102. 051915 (2013),
    "Laser Induced Acoustic Phonon Propagation in Cu/Ag(111) by Time-resolved X-ray Diffraction".

    162) Y. R. Toh, P. Yu, X. M. Wen and J. Tang, Journal of Colloid and Interface Science 402, 86(2013),
    "The Enhancement of Electron-Phonon Coupling in Glutathione-protected Au25 Clusters".

    161) Y.R. Toh, P. Yu, J. Tang and T. S. Hsieh, Nanoscale Res. Lett. 8 103 (2013),
    "Induced pH-Dependent Shift by Local Surface Plasmon Resonance in Functionalized Gold Nanorods”

    160) C. R. Tsai, M. S. Chen, T. S. Hsieh, Y. R. Toh, J. Huang, H. C. Ko, P. Yu and J. Tang, J. of Mater. Chem. B (submitted),
    "Cellular Uptake and Localization of Gold NanocubesCellular Uptake and Localization of Gold Nanocubes".

    159) C. T. Yuan, J. Huang and J. Tang, Appl. Phys. Lett. (submitted),
    "Influence of External Electron Donors and Acceptors on Fluorescence Blinking of Single CdSe/ZnS Quantum Dots".

    158) P. Yu, X.M. Wen, Y.R. Toh, J. Huang and J. Tang, Particle & Particle Systems Characterization 30 467 (2013),
    "Metallophilic bond induced quenching of delay fluorescence in Au25@BSA nanoclusters".

    157) X. M. Wen, P. Yu, Y. R. Toh and J. Tang, JPC C 117, 3621 (2013),
    "The Quantum Confined Stark Effects in BSA Protected Au8 and Au25 Gold Nanoclusters".            

    156) P. Yu, X.M. Wen, Y.R. Toh and J. Tang, JPC C 116, 25552 (2013),
    "Temperature Dependent Fluorescence in Carbon Dots.”

    155)  J. Tang, Y. G. Wang, S. M. Cheng, P. Yu, K. Y. Huang and C. T. Yuan, Proc. SPIE, 8462, 8462OK-1 (2012),
    "Applications of Single-Walled Carbon Nanotubes and Type-II Quantum Dots in Photovoltaics and Passive Mode-Locking Saturable Absorbers". 

    154) X.M. Wen, P. Yu, Y.R. Toh, Y.C. Lee, A.C. Hsu, and J. Tang, APL 101, 163107 (2012),
    "Near infrared enhanced carbon quantum dots by thermally assisted grown. ”. H. M. 153) Cheng, K. Y. Huang, P. Yu, A. C. Hsu, J. H. Huang and J. Tang , PCCP 14, 13539 (2012), 
    "High-efficiency cascade CdS/CdSe quantum dot-sensitized solar cells based on hierarchical tetrapod-like ZnO nanoparticles”.

    152) X. M. Wen, A. Sitt, P. Yu, H. C. Ko, Y. R. Toh and J. Tang, J. Nanopart. Res. 14 1278 (2012),
    "Studies of photostability of dot-in-rod CdSe/CdS nanoparticles".X. M. Wen, P. Yu,

    151) Y. R. Toh and J. Tang, JPC C 116,19032(2012),
    "Fluorescence Dynamics in BSA-Protected Au25 Nanoclusters".

     150) X. M. Wen, P. Yu, Y. R. Toh and J. Tang, JPC C 116, 11830 (2012),
    "Structure-Correlated Dual Fluorescent Bands of BSA- Protected Au25 Nanoclusters".

    149) L.D. Tuyen, J.H. Lin, C,Y. Wu, P.T. Tai, J. Tang, L.Q. Minh, H.C. Kan, and C.C. Hsu, Opt. Exp. 20, 15418(2012),
    "Pumping-power-dependent photoluminescence angular distribution from an opal photonic crystal composed of monodisperse Eu3+/SiO2 core/shell nanospheres".

    148) Y. C. Wang, C. T. Yuan, M. Y. Kuo, M. C. Wu, J. Tang, and M. H. Shih, Appl. Phys. Lett. 100, 253110 (2012),
    "Enhancement of the Purcell Effect for Colloidal CdSe/ZnS Quantum Dots Coupled to Silver Nanowires by a Metallic Tip".

    147) J. Huang, P. Yu, C. T. Yuan, H. C. Ko, J. Tang and T. S. Hsieh, J. Nanophotonics Lett. 6, 069502 (2012),
    "Single-Particle Studies of the Plasmonic Fluorescence in Gold Nanocubes

    146) S. Y. Cheng, Y. G. Wang, J. Tang, L. Zhang, L. Sun, X. C. Lin, and J. M. Li, Optik 123 1279 (2012),
    "Semiconductor Type Single Wall Carbon Nanotube Absorber for Passive Mode-Locked Nd: WO4 Laser

    145) P. Yu, P. T. Tai, C. T. Yuan and J. Tang, AAPPS Bulletin (Assoc. Asia Pacific Physicical Societies), 22, 9 (2012) (invited paper),
    "Coheretn phonon excitation and plasmonic effects of silver nanoprisms as studied by transient optical absorption and confocal microscopy".

    144) A. Oguz-Er, J. Chen, J. Tang, and P. M. Rentzepis, Appl. Phys. Lett. 100, 151910 (2012),
    "Coherent Acoustic Wave Oscillations and Melting on Ag(111) Surface by Time Resolved X-ray Diffraction".

    143) Y. G. Wang, H. R. Chen, X. M. Wen, W. F. Hsieh and J. Tang, Opt. Commun. 285, 1891 (2012),
    "Wall paper single-walled carbon nanotubes absorber for passively mode-locked Nd:
    GdVO4 laser

    142) Y. G. Wang, S. Y. Chenga, P. T. Tai, J. Tang, Optik 123, 348 (2012),
    “Saturable absorber at 940 nm using single wall carbon nanotubes deposited by vertical evaporation technique”.

    141) S. Y. Cheng, Y. G. Wang, P. Yu, Y. J. Cheng, J. Tang, H. R. Chen, and W. F. Hsieh, Laser Phys. 22, 54, (2012),
    "Fabrication of Aligned Single Wall Carbon Nanotube Absorbers for High Power Passive ModeLocked Nd:GdVO4 Laser".

    140) H. Y. Ahn, C. C. Yu, P. Yu, J. Tang, Y. L. Hong, and S. J. Gwo, Opt. Exp. 20 769 (2012),
    "Carrier dynamics of InN nanorod arrays".

    139)P. Yu, X. M. Wen, Y. R. Toh and J. Tang, JPC C 116, 6567 (2012),
    "Temperature dependent fluorescence in Au10 nanoclusters". 

    138) X. M. Wen, A. Sitt, P. Yu, Y. R. Toh and J. Tang, Phys. Chem. Chem. Phys. 14, 3505 (2012),
    "Temperature dependent spectral properties of type-I and quasi type-II CdSe/CdS dot-in-rod nanocrystals".C. T. Yuan, Y. G. Wang, K. Y. Huang,

    137) T. Y. Chen, P. Yu, J. Tang, A. Sitt, U. Banin, and O. Millo, ACS Nano 6, 176 (2012),
    "Single-Particle Studies of Band Alignment Effects on Electron Transfer Dynamics from Semiconductor Hetero-Nanostructures to Single-Walled Carbon Nanotubes

    136) J. Chen, W. K. Chen, J. Tang*, P, M. Rentzepis, PNAS 108, no. 47, 18887 (2011),
    "Time Resolved structural dynamics of thin metal films heated with femtosecond optical pulses".

     

    135) Y. G. Wang, H. R. Chen, X. M. Wen, W. F. Hsieh and J. Tang*, Nanotechnology 22, 455203, 2011),

    "A highly efficient graphene oxide absorber for Q-switched Nd:GdVO(4) lasers".

     

    134) Y. C. Wang, C. T. Yuan, Y. C. Yang, M. C. Wu, J. Tang* and M. H. Shih*, Nano Rev. 2, 7275 (2011),
    "High efficient silicon nanodisk laser with colloidal CdSe/ZnS QDs".

     

    133) Q. Yang, D. Liu, J. Liu*, Y. G. Wang, J. Tang, L.H. Zheng,L.B. Su, J. Xu, Opt. Eng. 50, 114202 (2011),
    " Efficient diode-pumped Yb:LuYSiO5 laser mode locked by single-walled carbon nanotube absorber"

     

    132) H. C. Ko, C. T. Yuan, S. H. Lin, and J. Tang , J. Phys. Chem. C , 13977 (2011),

    "Observation of Inverted Regime Electron Transfer in CdSe/ZnS QDs from pH-Sensitive Single-Particle and Ensemble Fluorescence Measurements".

     

    131) C. T. Yuan, Y. C. Wang, Y. C. Yang, M. C. Wu, J. Tang and M. H. Shih, App. Phys. Lett. 99, 053116 (2011),

    "Modification of Spontaneous Emission Rates in Single Colloidal CdSe/ZnS QDs by a Submicron-sized Dielectric Disks".

    (selected by Virtual Journal of Nanoscale Science & Technology, August 15, 2011 issue)

     

    130) S. D. Pan, Y. G. Wang and J. Tang, Laser Phys. 21, 867 (2011),

    "Diode Pumped Passively Q Switched and Q Switch Mode Locked Nd:YVO4 Laser Using Single Wall Carbon Nanotube Based Saturable Absorber1".

     

    129) P. T. Tai, P. Yu and J. Tang, J. Chem. Phys. 134, 184506 (2011),

    "Effects of Shape-Induced Anisotropic Electronic Stresses on Multimode Coherent Acoustic Phonons of Metallic Nanoprisms by a Femtosecond Laser Pulse".

    (selected for the June 2011 issue of Virtual Journal of Ultrafast Science)

     

    128)Y.G. Wang, S. Z. Qu, J. Liu, P. Yu, J. Y. Tai, Y. J. Hung and J. Tang, Laser Phys. 21, 1 (2011),

    "Fabrication and Characterization of Double-Wall Carbon Nanotube Absorber for Passive Mode-Locked Nd: GdVO4 Laser".

     

    127)  L. Zhang, Y. G. Wang, H. J. Yu, L. Sun, L. Guo, W. Hou1, J. Tang, X. C. Lin, J. M. Li, Laser Phys. 21, 454 (2011),
    "880 nm LD Pumped Passive Q-switched and Mode-Locked Nd:YVO4 Laser using a Single-Walled Carbon Nanotube Saturable Absorber".

     

    126) H.R. Chen, Y.G. Wang, C.Y. Tsai, K.H. Lin, T.Y. Chang, J. Tang and W.F. Hsieh, Opt. Lett. 36, 1284 (2011),

    "High-Power Passively Mode-Locked Nd:GdVO4 Laser using Single-Walled Carbon

    Nanotubes as Saturable Absorber".

     

    125) H.C. Ko, C. T. Yuan and J. Tang, Nano Rev. 2, 1 (2011),

    "Probing and Controlling Fluorescence Blinking in Single Semiconductor Nanoparticles".

     

    124) P. T. Tai, Y. G. Wang, and J. Tang, Opt. Commun. 284, 1303 (2011),
    "Single-Wall Carbon Nanotube-Poly (vinylalcohol) Absorber Deposited by Vertical Evaporation Method".

     

    123)  P. Yu, J. Huang, C. T. Yuan and J. Tang, Nanoscale Res. Lett. 6, 46 (2011),
    "Observation of Coalescence Process of Silver Nanospheres during Shape Transformation to Nanoprisms".

     

    122) J. Tang and P. T. Tai, Scientific American, Chinese Edition (科學人雜誌) Sept. 103 (3), 86 (2010, Invited paper),
    "The Nanoworld in Femotoseconds", "飛秒下的奈米世界".

     

    121) H. C. Ko, C. T. Yuan, P. Yu, J. Huang and J. Tang, Proceeding of SPIE, 7758 OU 1-12 (2010),
    "Environmental Effects on Photoinduced Electron Transfer and Fluorescence Blinking of Single Semiconducting Nanocrystals in Various Matrices".

     

    120)  戴伯澤, 於平, 湯朝暉, "脈衝雷射引發奈米金屬粒子的超快結構動力學 (Ultrafast Structural Dynamics of Metallic Nanoparticles Induced by Femtosecond Laser Pulses)", ROC 物理雙月刊 May 2010, 32 (3), 4 (invited paper).

     

    119) P. Yu, C. T. Yuan, H. C. Ko, J. Huang and J. Tang, SPIE Proceeding 7608 76082I-1 (2010),
    "Blinking Suppression and Anti-Bunching of Quantum Dots as Single-Photon Sources".

     

    118) P. T. Tai, P. Yu and J. Tang, Chem. Phys. 374 126 (2010),
    "2-D Modeling of Dual-Mode Acoustic Phonon Excitation of a Triangular Nanoplate".

     

    117) H. C. Ko, C. T. Yuan, J. Huang, S. H. Lin, and J. Tang , JCCS 57, No. 3, 1 (invited paper, 2010),
    "Blocked Electron Transfer and Suppressed Blinking of Single CdSe/ZnS Quantum Dots in Agarose Gel".

     

    116) P. Yu, J. Huang, C. T. Yuan and J. Tang, JCCS 57, No. 3B, 1 (invited paper, 2010),
    "Synthesis of Silver Nanoprisms and Nanodiscs and applications in fluorescence blinking suppression".

     

    115) P. T. Tai, P. Yu and J. Tang , Chem. Phys. Lett. (in press, 2010),
    "Selective Acoustic Phonon Mode Excitation of Multi-mode Silver Nanoprisms".

     

    114) J. Tang , Nano Reviews 1, 5031 (2010),
    "Random On-Off Telegraphic Signaling in Single Nanoparticles and Molecules".

     

    113) H. C. Ko, C. T. Yuan, S. H. Lin, and J. Tang , Appl. Phys. Lett. 96, 012104 (2010),
    "Suppressed Blinking of Single Quantum Dots Confined in Agarose Gel".

     

    112) G. W.  Shu, C. C. Lin, H. P. Chang, J. L. Shen, C. A. J. Lin, C. H. Lee, W. H. Chang, W. H. Chan, H. H. Wang, C. T. Yuan and J. Tang, Appl. Phys. Lett. (in press),

    “Recombination Dynamics of Photoluminescence in Thiol-Protected Gold Nanoclusters”.

     

    111) D. H. Lee, C. T. Yuan, M. Tachiya and J. Tang , Appl. Phys. Lett.  95, 163101 (2009),
    "Influence of bin time and excitation intensity on fluorescence lifetime distribution and blinking statistics of single quantum dots".

     

    110) C. T. Yuan, P. Yu, H. C. Ko, J. Huang, and J. Tang, ACS Nano 3, 3051 (2009),
    "Antibunching Single-Photon Emission and Blinking Suppression of CdSe/ZnS Quantum Dots".".

     

    109) P. T. Tai, P. Yu and J. Tang , J. Phys. Chem. C 113, 15014 (2009),
    "Determination of the electronic Grüneisen parameter from the photo-excited coherent acoustic vibrational phonon modes and their laser fluence dependence".

     

    108) J. Tang , D. H. Lee, Y. C. Yeh and C. T. Yuan, J. Chem. Phys.131, 064506 (2009),
    "Short-time power-law blinking statistics of single quantum dots and a test of the diffusion-controlled electron transfer model".

    (selected for the Aug. 31, 2009 issue of Virtual Journal of Nanoscale Science & Technology)

     

    107) J. Tang, P. Yu, P. T. Tai and S. H. Lin, SPIE Proceeding 7214 72140F-1 (2009),
    "Photoinduced ultrafast structural dynamics of nanomaterials".

     

    106) C. T. Yuan, P. Yu and J. Tang , Appl. Phys. Lett. 94, 243108 (2009),
    "Blinking Suppression of Colloidal CdSe/ZnS Quantum Dots by Coupling to Silver Nanoprisms"

     

    105) P. T. Tai and J. Tang, J. of Scientific Conference Proceedings 1, 1 (2009),
    "Coherent Acoustic Phonon Excitation in Nanoprisms by a Femtosecond Impulse".

     

    104) C. T. Yuan, C. Chou, J. Tang, C. A. Lin, W. H. Chang, J. L. Shen, and D. S. Chuu, Opt. Exp. 17, .16111 (2009),
    "Single fluorescent gold nanoclusters".

     

     103) Y. C. Yeh, C. T. Yuan, C. C. Kang, P. T. Chou and J. Tang, Appl. Phys. Lett. 93,, 223110 (2008)

     ,"Influences of light intensity on fluorescence lifetime of nanorods and quantum dots".
     

    102) P. Yu, J. Tang and S. H. Lin, J. Phys. Chem. C 112, 17133 (2008),

    “Photoinduced Structural Dynamics in Laser-Heated Nanomaterials of Various Shapes and Sizes”.

     

    101) J. Tang, Y-C. Yeh and P-T. Tai, Chem. Phys. Lett. 463, 134 (2008),

    “Fluctuating Reaction Rate and Non-Exponential Blinking Statistics in Single-Enzyme Kinetics”.

     

    100) D. H. Lee and J. Tang, J. Phys. Chem. C 112, 15665 (2008),

    “Unusually large exponent for the inverse power-law blinking of single chromophores”

     

    99) J. Tang, J. Chem. Phys. 129, 084709 (2008),

    “The Effects of Anomalous Diffusion on Power-law Blinking Statistics of CdSe Nanorods”.

     

    98) J. Tang, Chem. Phys. Lett. 458, 363 (2008),

    “Exploring Fluorescence Intermittency in Enzyme Reactions of Single Lipase Molecules”.

     

    97) J. Tang, J. Chem. Phys. 128, 164702 (2008),

    “Coherent Phonon Excitation and Linear Thermal Expansion in

    Structural Dynamics and Ultrafast Electron Diffraction of Laser-Heated Metals”.

     

    (selected for the May 2008 issue of Virtual Journal of Ultrafast Science)

     

     

    96) J. Tang, App. Phys. Lett. 92, 011901 (2008),

    “Nano-Scale Heat Transfer in a Thin Aluminum Film and Femtosecond Time-Resolved Electron Diffraction”.

    (selected for the Jan. 14, 2008 issue of Virtual Journal of Nanoscale Science & Technology)

     

    (selected for the Feb. 7, 2008 issue of Virtual Journal of Ultrafast Science)

     

     

    95) J. Tang, J. Phys. Chem. A  111, 9336 (2007) (invited paper),

    Size Effects and the Breakdown of the Power-Law Blinking Statistics of CdSe Nanorods”.

     

    94) J. Tang, J. Chem. Phys. 127, 111105 (2007),

    “Fluorescence intermittency of silicon nanocrystals and other quantum dots: a unified two-dimensional diffusion-controlled reaction model”.

     

    93) V. A. Lobastov, J. Weissenrieder, J. Tang and A. H. Zewail, Nano Lett.  7, 2552 (2007),

    “Ultrafast Electron Microscopy of Nanostructured Materials: 4D Imaging and Diffraction during Phase Transitions.“

     

    92) J. Tang, D. S. Yang and A. H. Zewail, J. Phys. Chem. C  111, 8957 (2007).

    “Time-resolved Ultrafast Electron Crystallography. III  Theoretical Modeling of Structural Dynamics”.

     

    91) C. W. Chen and J. Tang, Chem. Phys. 331. 245 (2007),

     “Half- and Full-integer Power-law Behavior in Distance Fluctuations: Langevin Dynamics in One- and Two-dimensional Systems”.

     

    90) J. Tang and S. H. Lin, Phys. Rev. E  73, 061108 (2006).

    “Distance versus Energy Fluctuations and Electron Transfer in Single Protein Molecules”.

    (selected for the July 1, 2006 issue of Virtual Journal of Biological Physics Research)

     

    89) J. Tang  and R. A. Marcus, J. Chem. Phys.       125, 044703 (2006),                            “Determination of Energetics and Kinetics from Single-particle Intermittency and Ensemble-averaged Fluorescence Intensity Decay of Quantum Dots”.

     

    88) J. Tang and R. A. Marcus, Phys. Rev. E  73, 022102 (2006),

    “Chain Dynamics and Power-law Distance Fluctuations of Single-molecule Systems”.

    (selected for the Mar. 1, 2006 issue of Virtual Journal of Biological Physics Research)

     

    87) J. Tang and R. A. Marcus, J. Chinese Chemical Soc. 53. pp. 1-13 (2006),

     “Photoinduced Spectral Diffusion and Electron Transfer in Fluorescence Intermittency of Quantum Dots”,

     

    86) J. Tang, J. Lightwave Tech. 24, 2070-2075 (2006),

    “A Comparison Study of Shannon Channel Capacity of Various Nonlinear Optical Fibers”,

    85) J. Tang and R. A. Marcus, J. Chem. Phys., 123, 204511 (2005),                           “Single Particle vs. Ensemble Average: From Power-law Intermittency of a Single Particle to Stretched Exponential Fluorescence Decay of an Ensemble”.

    (selected for the Dec. 12, 2005 issue of Virtual Journal of Nanoscale Science & Technology)

     

    84) J. Tang and R. A. Marcus, Phys. Rev. Lett. 95, 107401 (2005),               “Diffusion-controlled Electron Transfer Processes and Power-law Statistics of Fluorescence Intermittency of  Nanoparticles”.

    (selected for the Sept. 12, 2005 issue of Virtual Journal of Nanoscale Science & Technology)

     

    83) J. Tang and R. A. Marcus, J. Chem. Phys. 123, 054704 (2005),                            “Mechanisms for Fluorescence Blinking in Semiconductor Nanocrystal Quantum Dots”.

    (selected for the Aug. 22, 2005 issue of Virtual Journal of Nanoscale Science & Technology)

    82) J. Tang, M. T. Lin and S. H. Lin, J. Chem. Phys. 119, 7188-7196 (2003),          “Effects of Duschinsky Mode-mixing Mechanism on Electron Transfer and its Temperature Dependence”.

    81) J. Tang, J. Lightwave Technology, vol. 20, 1095-1101 (2002),                                           “The Channel Capacity of a Multispan DWDM System Employing Dispersive Nonlinear Optical Fibers and An Ideal Coherent Optical Receiver”.

    80) J. Tang, J. Lightwave Technology, vol. 19, 1110-1115 (2001),                                           “The multispan effects of Kerr Nonlinearity and Amplifier Noises on Shannon Channel Capacity of Dispersion-free Nonlinear Optical Fiber Transmission – II. An Exact Closed-form Treatment”.

    79) J. Tang, J. Lightwave Technology, vol. 19, 1104-1109 (2001),                                           “The Shannon Channel Capacity of Dispersion-free Nonlinear Optical Fiber Transmission – I. An Exact Closed-form Formula for Arbitrary Operating Power”.

    78) G. Link, T. Berthold, M. Bechtold, J.-U. Weidner, E. Ohmes, J. Tang, O. Poluektov, L. Utschig, S. Schlesselman, M. C. Thurnauer and G. Kothe, J. Am. Chem. Soc., 123, 4211-4222 (2001),                                                                                                                                   “Structure of the P+700A-1 Radical Pair Intermediate in Photosystem I by High Time Resolution Multifrequency Electron Paramagnetic Resonance - Analysis of Quantum Beat Oscillations”.

     

    77) O. G. Poluektov, L. M. Utschig, J. Tang, A. A. Dubinski, S. Schlesselman, and M. C. Thurnauer, Appl. Magn. Reson., 21, 311-323 (2001),                                                            “High-Frequency Approach to the Electron Spin-Polarization Effects Observed in the Photosynthetic Reaction Centers”.

    76) T. Berthold, M. Bechtold, U. Heinen, G. Link, O. Poluektov, L. Utschig, J. Tang, M. C. Thurnauer and G. Kothe, J. Phys. Chem. B 103, 10733-10736 (1999),                                        “Magnetic Field Induced Orientation of Photosynthetic Reaction Centers as Revealed by Time-Resolved W-Band EPR Of Spin-Correlated Radical Pairs”.

    t75) J. Tang, L. M. Utschig, O. Poluektov and M. C. Thurnauer, J. Phys. Chem. B 103, 5145-5150 (1999),                                                                                                            “Transient W-Band EPR Study of Sequential Electron Transfer in Photosynthetic Bacterial Reaction Centers”.

    74) J. Tang, Chem. Phys. Lett. 290, 49  (1998),

    “Structural Implications of Transient X-,, K- and W-band EPR Spectra of Deuterated and Protonated Reaction Centers of Rhodobacter sphaeroides R-26".

     

    73) H. Hara, J. Tang, A. Kawamori, S. Itoh, and M. Iwaki, Appl. Magn. Reson. 14, 367 (1998)

    “Anomalous Pulse-angle and Phase Dependence of Hahn’s Electron Spin Echo and Multiple-Quantum Echoes of Spin Correlated Radical Pair P700+A- in Photosystem I”.

     

    72) J. Tang and S. H. Lin, J. Chem. Phys. 107, 3485 (1997),

    “Quantum Tunneling versus Thermally Activated Electron Transfer in Ohmic and non-Ohmic Heat Baths”.

     

    71) L. M. Utschig, J. Tang, S. R. Greenfield, P. D. Laible, and M. C. Thurnauer, Biochem. 36, 8548 (1997),

    “Influence of Iron-removal Procedures on Sequential Electron Transfer in Photosynthetic Bacterial Reaction Centers Studied by Transient EPR Spectroscopy”.

     

    70) J. Tang, M. C. Thurnauer, A. Kubo, H. Hara and A. Kawamori, J. Chem. Phys. 106, 7471 (1997),

    “Anomalous Pulse-angle and Phase Dependence of Hahn’s Electron Spin Echo and Multiple-quantum Echoes in a Photoinduced Spin-correlated Radical Pair”.

     

    69) J. Tang, J. R. Norris and H. Shirakawa,  J. Phys. Chem. Solid 58, 475(1997),

    "EPR Lineshape Analysis of One-Dimensional Soliton Diffusion  in Trans-Polyacetylene”.

     

    68) J. Tang, Phys. Lett. A 229, 33 (1996),

    “Coherent States and Squeezed States of Massless and Massive Relativistic Harmonic Oscillators”.

     

    67) J. Tang and S. H. Lin, Chem. Phys. Lett.  254, 6 (1996),

    "Nonexponential Decays and Oscillations in Electron Transfer Reactions".

     

    66) J. Tang, J. Chem. Phys. 104, 9408 (1996),

    “Electron Transfer Reactions in a Non-Debye Medium with Frequency-Dependent Friction”.

     

    65) J. Tang, S. Bondeson, and M. C. Thurnauer, Chem. Phys. Lett. 253, 293 (1996),

    “Effects of Sequential Electron Transfer on Electron Spin Polarization Transient EPR Spectra at High Fields”.

     

    64) J. Tang, Phys. Lett. A 210, 33 (1996),

    "The Generalized Heisenberg Commutation Relations and Uncertainty Inequality for Relativistic Quantum Harmonic Oscillators".

     

    63) J. Tang, S. N. Dikshit and J. R. Norris, J. Chem. Phys. 103, 2873 (1995),

    "ESR Line Shapes for One- and Two-Dimensional Random Walk Processes".

     

    62) J. Tang, M. C. Thurnauer, and J. R. Norris, Appl. Mag. Reson. 9, 23 (1995),

    "Abnormal Electron Spin Echo and Multiple-Quantum Coherence in a Spin-Correlated Radical Pair System".

     

    61) A. L. Morris, S. W. Snyder, Y. Zhang, J. Tang, M. C. Thurnauer, P. L. Dutton, D. E. Robertson, M. R. Gunner, J. Phys. Chem.  99, 3854 (1995),

    "An Electron Spin Polarization Model Applied to Sequential Electron Transfer in Iron-Containing Photosynthetic Bacterial Reaction Centers with Different Quinones as QA".

     

    60) J. Tang and J. R. Norris, Chem. Phys. Lett. 233, 192 (1995),

    "Multiple-Quantum EPR Coherence in a Spin-Correlated Radical Pair System".

     

    59) J. R. Norris, S. Dirkshit, J. Tang and D. M. Tiede, Abs. Am. Chem. Soc. 210, 141-PHYS (1995),

    “Electron Transfer in Integral Membrane-Proteins”.

     

    58) J. Tang, Chem. Phys. 189, 427 (1994),

    "Resonance Effects on Superexchange and Sequential Electron-Transfer  Reactions due to Energy-Level Crossing".

     

    57) J. Tang and J. R. Norris,  J. Chem. Phys. 101, 5615 (1994),

    "On Superexchange Electron-Transfer Reactions Involving Three Paraboloidal Potential Surfaces  in a Two-Dimensional Reaction Coordinate".

     

    56) J. Tang, Chem. Phys. 188,  143 (1994),

    "Electron-Transfer Reactions Involving Non-linear Spin-Boson Interactions".

     

    55) J. Tang, Chem. Phys. Lett. 227, 170 (1994),

    "On Tunneling Mechanism in Electron Transfer: a View from the Feynman's Path

    Integral Approach".

    54) J. Tang, Chem. Phys. 184, 38 (1994),

    "Sequential and Superexchange Electron-Transfer Reactions in a Three-Component System".

     

    53) J. Tang, M. C. Thurnauer and J. R. Norris,  Chem. Phys. Lett.  219,  283 (1994),

    "Electron Spin Echo Envelope Modulation due to Exchange and Dipolar  Interactions in a Spin-Correlated Radical Pair".

     

    52) J. Tang,  Chem. Phys. Lett.  217, 55 (1994),

    "On Superexchange Electron-Transfer Reactions in a Three-Component System:

    the Spin-Boson Model for Photosynthesis".

     

    51) J. Tang,  Chem. Phys., 179, 105 (1994),

    "The Effects of Anharmonicity on Electron-Transfer Reactions".

     

    50) J. Tang, J. Chem. Phys. 99, 5828 (1993),

    "The Effects of Quantum Modes on the Energy Gap Law for Eletron-Transfer Reactions".

     

    49)  J. Tang and J. R. Norris, Chem. Phys. 175, 337 (1993),

    "On Superexchange Electron-Transfer Coupling for a Three-Component System".

     

    48) J. Tang, Z. Wang and J. R. Norris, J. Chem. Phys. 99, 979 (1993),

    "The General Treatment of Superexchange versus Sequential Electron Transfer in a Three-Component System".

     

    47) J. Tang, J. Chem. Phys. 98, 6263 (1993),

    "Effects of a Fluctuating Electronic Coupling Matrix Element on Electron Transfer Rate".

     

    46)  Z. Wang, T. J. DiMagno, C-K. Chan, M. Popov, J. Tang, D. Hanson, M. Schiffer, G. Fleming and J. R. Norris, in Photochemical and Photoelectrochemical Conversion and Storage of Solar Energy, Z. W. Tian and Y. Cao, Eds., International Academic Publishers, Beijing, pp. 1-10. (1993),

    "Model Photoreaction Centers via Genetic Engineering".

     

    45) J. R. Norris, J. Tang,  C. K. Chan, T. J. Dimagno, Z. Wang and G. R. Fleming, FASEB J. 6, A277 (1992),

    “Coherence in Photosynthesis – from Experiment to Theory”.

     

    44) Z. Wang, J. Tang and J. R. Norris, J. Chem. Phys. 97, 7251 (1992),

    "The General Treatment of Dynamic Solvent Effects in Electron Transfer at High Temperature".

     

    43) Z. Wang, J. Tang and J. R. Norris, J. Magn. Reson. 97, 322 (1992),

    "The Time Development of the Magnetic Moment of Correlated Radical Pairs".

     

    42) J. R. Norris, M. K. Bowman, L. Chen, J. Tang, M. C. Thurnauer, G. S. Knapp and P. A. Montano, Rev. Sci. Instrum. 63, 1172-1175 (l992),

    "A Shutter Design for Time Domain Studies Using Synchrotron Radiation at the Advanced Photon Source".

     

    41) G. Kothe, S. Weber, R. Bittle, J. R. Norris, S. W. Snyder, J. Tang, M. C. Thurnauer, A. L. Morris, R. R. Rustandi and Z. Wang, in "Spin Chemistry", Ed., Y. J. I'Haya, Published by The Oji International Conference on Spin Chemistry, pp420-434 (l99l),

    "The Role of Spin Chemistry in the Primary Events of Photosynthesis",

     

    40) J. Isoya, H. Kanda, J. R. Norris, J. Tang and M. K. Bowman, Phys. Rev. B4, 3905 (1990),

    "FT- and CW-EPR Studies of Nickel in Synthetic Diamond: Site and Spin Multiplicity".

     

    39) K. Hasharoni, H. Levanon, J. Tang, M. K. Bowman, J. R. Norris, D. Gust, T. A. Moore, and A. L. Moore, JCAS 112, 6477 (1990),

    "Singlet Photochemistry in Model Photosynthesis: Identification of Charge Separated Intermediates by Fourier Transform & CW EPR Spectroscopies".

     

    38) J. R. Norris, A. L. Morris, M. C. Thurnauer and J. Tang, J. Chem. Phys. 92, 4239 (1990),

    "A General Model of Electron Spin Polarization Arising from the Interactions within Radical Pairs".

     

    37) J. Tang and J. R. Norris, Int. J. of Quantum Chemistry, 16, 45-55, (1989),

    "Phase Refinement from a Partially Known Structure Using Linear Prediction Filtering".

     

    36) Y. Zeng, J. Tang, C. A. Bush, and J. R. Norris, J. Magn. Reson. 83, 473 (1989),

    "Enhanced Spectral Resolution in 2D NMR Signal Analysis Using Linear Prediction Extrapolation and Apodization".

     

    35) J. Tang and J. R. Norris, J. Magn. Reson. 79, 190 (1988),

    "LP-ZOOM, A Linear Prediction Method for Local Spectral Analysis of NMR Signals".

     

    34) J. Tang and J. R. Norris, Nature 333, 216 (1988),

    "Padé Approximation and the Linear Prediction Method".

     

    33) J. Tang and J. R. Norris, J. Magn. Reson. 78, 23 (1988),

    "Linear Prediction Z-Transform (LPZ) Method, Padé Rational  Approximation and the Burg Maximum Entropy Extrapolation".

     

    32) J. Tang and J. R. Norris, Nucl. Instr. and Meth. in Phys. Res. A273, 338 (1988),

    "Deconvolution of Kinetic Decays and Fitting of Multiple Exponential Decay Curves by the Linear Prediction Method".

     

    31) D. M. Tiede, D. E. Budil, J. Tang, O. El-Kabbani, J. R. Norris, C. H. Chang and M. Schiffer in "The Photosynthetic Bacterial Reaction Centers: Structure and Dynamics", ed. J. Breton and A. Vermeglio, NATO ASI Series, Series A: LIfe Sciences, Vol. 149, Plenum Publishing Co., (1988),

    "Symmetery Breaking Structures Involved in the Docking of Cytochrome c and Primary Electron Transfer in Reaction Centers of Rhodobacter sphaeroides".

     

    30) D. M. Tiede, C.H. Chang, O. El-Kabbani, J. Tang, M. Wasielewski, J. R. Norris and M. Schiffer, Biophys. J., 53, A413 (1988),

    "Structures Involved in the Docking of Cytochrome c and Electron Transfer in Reaction Centers of Rhodobacter sphaeroides".

     

    29) J. Isoya, H. Nagasawa, H. shirakawa, M. K. Bowman, C. P. Lin, J. Tang and J. R. Norris, Synthetic Metals 17, 215-220 (1987),

    “Electron-spin Echo Study of Iodine Doped Transpolyacetylene”.

     

    28) L.D. Kispert, J. Joseph, J. Tang, M.K. Bowman, G.H. Van Brakel, and J.R. Norris, Synthetic Metals 17, 617 (1987),

    "Temperature Dependent Electron Spin Echo Studies of Polarons in Donor‑ and Acceptor‑doped Poly(p‑Phenylene): Structural Studies".

     

    27) J. Tang, J. F. Wang and A. Pines, Sci. Sin. A. 30, 157 (1987),

    "Study of Correlation of Two Methyl-Groups by Multiple-Quantum NMR".

     

    26) J. Tang and J.R. Norris, in "Electronic Magnetic Resonance of the Solid State" (ed. J.A. Weil), Canadian Institute of Chemistry (1987),

    "Linear Prediction Spectral Analysis with Improved Resolution and Sensitivity".

     

    25) C. H. Chang, D. Tiede, J. Tang, J. R. Norris and M. Schiffer, in "Progress in Photosynthesis Research" Vol. 1 (ed., J. Briggins), Dordrecht, Netherlands, Nijhoff (1987), (Proceedings of the VII International Photosynthesis Congress, Providence, Rhode Island, August 10-15, 1986),

    "Crystallographic Studies of the Photosynthetic Reaction Center from Rsphaeroides".

     

    24) J. R. Norris, D. E. Budil, D. M. Tiede, J. Tang, S. Kolaczkowski, C. H. Chang and M. Schiffer, in "Progress in Photosynthesis Research" Vol. 1 (ed., J. Briggins), Dordrecht, Netherlands, Nijhoff (1987), (Proceedings of  the VII International Photosynthesis Congress, Providence, Rhode Island, August 10-15, 1986),

    "Relating Structure to Function in Bacterial Photoreaction Centers".

     

    23) C.H. Chang, D.Tiede, J. Tang, U. Smith, J.R. Norris, and M. Schiffer, FEBS Lett. 205, 82 (1986),

    "Structure of Rhodopseudomonas sphaeroides R‑26 Reaction Center".

     

    22) J. Tang and J. R. Norris, Chem. Phys. Lett. 131, 252 (1986),

    "Spectral Analysis using Linear Prediction Z-Transform and Autoregression".

     

    21) J. Tang and J. R. Norris, J. Magn. Reson. 69, 180 (1986),

    "Two‑dimensional LPZ Spectral Analysis with Improved Resolution and Sensitivity".

     

    20) J. Tang and J. R. Norris, J. Chem. Phys. 84, 5210 (1986),

    "LPZ Spectral Analysis Using Linear Prediction and the Z‑Transform".

     

    19) J. Tang, C. P. Lin, and J. R. Norris, J. Chem. Phys. 83, 4917 (1986),

    "Analysis of Electron Spin Stimulated Echo Modulation in Randomly Oriented Solids: 15N Modulation of Bacteriochlorophyll a Radical Cation."

     

    18) D. E. Budil, J. Tang and J. R. Norris, Biophys. J. 49, A585 (1986),

    “Microwave-Power And Temperature-Dependence Of The Reaction Yield-Detected Magnetic-Resonance Spectrum Of The Primary Radical Pair Of Bacterial Photosynthesis”.

     

    17) J. Isoya, H. Nagasawa, H. Shirakawa, M. K. Bowman, C. P. Lin, J. Tang, and J. R. Norris, NIPPON KAGAKU KAISHI 3, 416-419 (1986),

    “Electron-spin Echo Study of Polyacetylene”.

     

    16) J. Isoya, H. Nagasawa, H. Shirakawa, M. K. Bowman, C. P. Lin, J. Tang, and J. R. Norris, Mole. Cryst. Liq. Cryst. 117, 463 (1985),

    "Electron Spin Echo Study of Polyacetylene”.

     

    15) J. Tang, C. P. Lin, M. K. Bowman, and J. R. Norris, J. Magn. Reson. 62, 167 (1985),

    "An Alternative to Fourier Transform Spectral Analysis with Improved Resolution".

     

    14) J. R. Norris, D. E. Budil, S. V. Kolaczkowski, J. Tang and M. K. Bowman, Advances of Chemical Physics Series, 42, (1984) M. E. Michel‑Beyerle, Ed., Spring‑Verlag, Berlin,"Phot­oin­duced ­Charge Separation in Bacterial Reaction Centers Investigated by Triplets and Radical Pairs".

     

    13) L. D. Kispert, J. Joseph, M. K. Bowman, G. H. van Brakel, J. Tang, and J. R. Norris, Mole. Cryst. Liq. Cryst. 107, 81 (1984),

    "Electron Spin Echo Studies of Donor-doped Poly(o-Phenylene) and its Origomers".

     

    12) J. R. Norris, C. Boch, M. K. Bowman, and M. R. Wasielewski, Abs. Am. Chem. Soc. 185, 97-PHYS (1983),

    “Time Resolved Optically Detected Magnetic Resonance Studies of Primary Radical Pairs”.

     

    11) M. R. Wasielewski, C. H. Boch, M. K. Bowman, J. H. Tang and J. R. Norris, Biophys. J. 41, A120 (1983),

    “Nanosecond Time Resolved Magnetic Resonance of the Primary Radical Pair State PF of Bacterial Photosynthesis”.

     

    10) J. Tang, C. P. Lin, M. K. Bowman, J. R. Norris, J. Isoya and H. Shirakawa, Phys. Rev. B 28, 2845 (1983),

       "Time‑domain Analysis of ESR Measurements of Polyacetylene and Soliton Diffusion".

     

      9) C. Ye, J. Tang, and A. Pines, Chinese J. Microwave and Radio Frequency Spectroscopy 1, 11 (1983),

            "Multiple Quantum NMR Spectroscopy". 

     

    8)    8) J. Tang and J. R. Norris, Chem. Phys. Lett. 94, 77 (1983),

       "Theoretical Calculations of Microwave Effects on the Triplet Yield in Photosynthetic Reaction Centers".

     

    7)    7)J. Tang and J. R. Norris, Chem. Phys. Lett. 92, 136 (1982),

       "Theoretical Calculations of Kinetics of the Radical Pair PF State in the Bacterial Photosynthesis”.

     

      6) J. R. Norris, M. K. Bowman, D. E. Budil, J. Tang, C. A. Wraight, and G. L. Closs, Proc. Natl. Acad. Sci. U.S.A. 79, 5532 (1982),

            "Magnetic Characterization of the Primary State of Bacterial Photosynthesis".

     

    5)    5) J. Tang, L. Sterna, and A. Pines, J. Magn. Reson. 41, 389 (1980),

            "Anisotropic Spin‑lattice Relaxation of Deuterated Hexamethylbenzene".

     

    4)    4) J. Tang and A. Pines, J. Chem. Phys. 73, 2512 (1980),

       "Multiple Quantum NMR Study of Correlated Motion of Two Coupled Methyl Groups".

     

    3)    3) J. Tang, A. Pines, and S. Emid, J. Chem. Phys. 73, 172 (1980),

           "Spin‑lattice Relaxation of Reorienting or Tunneling Deuterated Methyl Groups".

     

    2)    2) J. Tang and A. Pines, J. Chem. Phys. 72, 3290 (1980),

           "Multiple Quantum NMR and Relaxation of an Oriented Methyl Group".

     

      1) A. Pines, D.Wemmer, J. Tang, and S. Sinton, Bull. Amer. Phys. Soc. 23, 21 (1978),

    "     "The 5‑ and 6‑Quantum NMR Spectra of Oriented Benzene".

所获荣誉

2010 APS Fellow – American Physical Society, Citation: For his contributions in elucidating the structure and the radical-pair mechanism of photosynthetic systems, photoinduced charge transfer and blinking in single nanocrystals, as well as in developing multi-quantum NMR and linear prediction filtering techniques, and for his work on nonblinking and less toxic nanostructures for biophotonics.

Distinguished Scholar – Foundation for the Advancement of Outstanding Scholarship Taiwan, 2007-2011.

R&D 100 Award – top 100 innovations in US, R&D Research and Development Magazine, September (1988) for the contributions on linear prediction method in magnetic resonance.

Argonne Director’s Award – laboratory wide award by the Director of Argonne National Laboratory (1986) for my contribution to solving the x-ray structure of photosynthetic reaction center Rhodopseudomonas sphaeroides. This paper has received 500 Scientific citations till 2007

Two Argonne Pacesetter Awards - distinguished achievement award, 1986