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Dr. Zhao's Research
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Invited Talks Guo-meng Zhao 1. Giant Oxygen-Isotope Shift of the Ferromagnetic Transition
Temperature in the Colossal Magnetoresistive La1-xCaxMnO3+y:
Evidence for Jahn-Teller Polarons The XIII International Symposium on Electronics and Vibrations in Solid and Finite Systems Berlin, August 24-29, 1996. 2. Oxygen Isotope Effects in the Manganites and Cuprates:
Evidence for Polaronic Charge Carriers Symposium
on Rare Earth Manganites, ETH-Hönggerberg, Feb. 4, 1997. 3. Oxygen Isotope Effects in the Manganites and Cuprates:
Evidence for Polaronic Charge Carriers Physics Institute, Chinese Academy of Sciences, Feb. 22,
1997. 4. Oxygen Isotope Effects in the Manganites and Cuprates:
Evidence for Polaronic Charge Carriers The 5th International Conference on
Materials and Mechanisms of Superconductivity and High-Temperature
Superconductors, Beijing, February 28 - March 4, 1997. 5. Isotope Effects in the Manganites: Evidence for Polaronic
Charge Carriers The
American Physical Society, March Meetings, Kansas City, March 17-21, 1997. 6.
Oxygen Isotope Effects in
the Magnetoresistive Manganites and Superconductive Cuprates: Evidence for
Polaronic Charge Carriers Electron-Phonon
Interaction and Phase Transition, Erice, June 9-15, 1997. 7. Giant Oxygen Isotope Effects in the CMR Manganites Dynamical
Properties of Solids (DYPROSO XXVI), Davos, Switzerland, September 21-26, 1997. 8. Polaron Problems in the Perovskite Oxides Physics
Institute, Chinese Academy of Sciences, Nov. 4, 1997. 9. Polaronic Charge Carriers and Their Condensation in the
Cuprate Superconductors Polarons:
Condensation, Pairing, Magnetism, Erice, June 9-17, 1998. 10. Oxygen Isotope Effects in Manganites: Evidence for
(Bi)polaronic Charge Carriers Physics
of Manganites Workshop, Michigan State University, July 26-29, 1998. 11. Experimental Constraints on the Physics of the Cuprate
Superconductors Symposium
on polarons and their condensation, University of Zurich, Nov.
10-11, 1999. 12. Experimental Constraints on the Physics of Cuprates and Manganites Symposium
on Itinerant and Localized States in HTSC, Klosters, Switzerland, March
31-April 10, 2000. 13. Unconventional Isotope Effects in Manganites and Cuprates Department
of Physics, Montana State University, USA, April 17, 2000. 14. Experimental Constraints on the Physics of Cuprates and
Manganites Department
of Physics, University of Geneve, Switzerland, May 23, 2000. 15. Experimental Constraints on the Physics of Cuprates and
Manganites Second
International Summer School on Strongly Correlated Systems, Debrecen, Hungary,
Sept. 4-9, 2000. 16. Experimental Constraints on the Physics of Cuprates Department
of Physics/TcSUH, University of Houston, USA, Jan. 21, 2001. 17. Unconvetional Isotope Effects in the High-Temperature
Cuprate Superconductors and Colossal Magnetoresistive Manganites Department
of Physics, University of South Carolina, USA, Jan. 25, 2001. 18. Unconvetional Isotope Effects in the High-Temperature
Cuprate Superconductors and Colossal Magnetoresistive Manganites Department
of Physics, National Tsing Hua University, Taiwan, March 2001. 19. Unconvetional Isotope Effects in the High-Temperature
Cuprate Superconductors and Colossal Magnetoresistive Manganites Physics
Institute, Academia Sinica, Taipei, Taiwan, March 2001. 20. Unconvetional Isotope Effects in the High-Temperature
Cuprate Superconductors and Colossal Magnetoresistive Manganites Department
of Physics, Texas A&M University, USA, March 2001. 21. Unconvetional Isotope Effects in Cuprates: The Role of
Electron-Phonon Coupling in the Physics of Cuprates Department
of Applied Physics, Stanford University, USA, Oct. 24, 2001. 22. The Role of Electron-Phonon Coupling and Pairing Symmetry
in the High-Tc Cuprates Department
of Physics, Brown University, USA, Jan. 25, 2002. 23. Strong Electron-Phonon Coupling in Cuprates, Manganites
and Carbon Nanotubes Department
of Physics, Oklahoma State University, USA, Feb. 14, 2002. 24. Strong Electron-Phonon Coupling in Cuprates, Manganites
and Carbon Nanotubes Department of Physics, University of Akron, USA, Feb. 19, 2002. 25. The Role of Electron-Phonon Coupling and the Pairing Symmetry in High-Temperature Superconductors Department of Physics, California State University, Long Beach, Nov. 25, 2002. 26. The Role of Electron-Phonon Coupling and the Pairing Symmetry in High Temperature Superconductors Department of Physics, California State University, Los Angeles, Feb. 13, 2003. Nato sponsored Advanced Research Workshop on ¡§Molecular Nanowires and Other Quantum Objects¡¨, Bled, Slovenia, September 7-10, 2003. 29. The Role of Electron-Phonon Coupling and the Pairing Symmetry in High-Temperature Superconductors 30. The Pairing Interactions and the Gap Symmetry in High-Temperature Cuprate Superconductors 31. The Pairing Interactions and the Gap Symmetry in High-Temperature Cuprate Superconductors 32. Physics of Manganites 33. The Pairing Interactions and the Gap Symmetry in High-Temperature Cuprate Superconductors 34. The Pairing Interactions and the Gap Symmetry in High-Temperature Cuprate Superconductors Department of Physics, Loughorough University, UK, September 24, 2004. 35. Pairing Interactions and Pairing Mechanism in High-Temperature Cuprate Superconductors The Second CSULA-USC-UCI Mini-Workshop on Applications of Numerical Techniques to Condensed Matter Physics, CSULA, October 29, 2004. 36. Pairing Interactions and Pairing Mechanism in High-Temperature Cuprate Superconductors NingBo University, China, March 20, 2005. 37. Magnetic and Electrical Evidence for Room-Temperature Superconductivity in Carbon Nanotubes Department of Chemistry and Biochemistry, UCLA, Nov. 28, 2005. 38. Bose-Einstein Condensation and High-Temperature Superconductivity CSULA, Science Series Lecture, March 2, 2005. 39.
Evidence for
Room Temperature Superconductivity in Multi-Walled Carbon Nanotubes CSULA, Science Series Lecture, Feb. 8, 2006. |