PUBLICATIONS LIST OF PROFESSOR GEORGE GRÜNER
1967
1. K. Tompa, F. Tóth, G. Grüner, “Susceptibility of MnO Measured by the NMR Method," Phys. Stat. Sol 22, K11.
2. G. Grüner, K. Tompa, F. Tóth, “NMR Studies of Molecular Motions in Compounds with Three Carbon Rings," Phys. Stat. Sol. 32, K71.
3. A. Jánossy, G. . Grüner, K. Tompa, “PMR Studies of Frozen Acqueous FeCl2 Solutions," J. Chem. Phys. 51, 5189.
4. K. Tompa, F. Tóth, G. Grüner, “NMR Investigation of Dilute Al-Ta Alloys," Solid State Comm. 7, 51.
5. K. Tompa, G. Grüner, A. Jánossy, F. Tóth, “First Order Quadruple Effect in Dilute Copper-Based Cu-Zn Alloys," Solid State Comm. 7, 697.
6. G. Grüner, “Charge Density Oscillations in Dilute Fe-Al Alloys," Solid State Comm. 7, 1421.
1970
7. G Grüner, K. Tompa, C.R. Vassel, “NMR study of metallurgical effects in dilute AlFe alloys". Hungarian Academy of Sciences, Budapest, Hungary. N/A
1971
8. G. Grüner, E. Kovács-Csetényi, K. Tompa, C.R. Vassel, “27Al NMR Spectra in Al-3D-Transition Metal Alloys," Phys. Stat. Sol. 45, 663.
9. G. Grüner, C. Hargitai, “`Temperature Dependence of the Charge Oscillation Around Nearly Magnetic Impurities," Phys. Rev. Lett. 26, 772.
10. G Grüner, I. Vincze, “Hyperfine field distribution & average hyperfine field in dilute Fe-Co alloys.” Hungarian Acad. Sci., Budapest,Hungary, N/A.
11. A. Jánossy, G. Grüner, “Satellite Structure Due to Charge Perturbation Around a Nearly Magnetic Impurity," Solid State Comm. 9, 1503.
12. G. Grüner, B.E. Paton, “LSF effects in Al-3D-Transition Metal Alloys," Technical Report KFKI-49. (N/A}
1
1972
13. G. Grüner, I. Vincze, L. Cser, “Charge and Spin Perturbation Around Nonmagnetic Impurities in Iron," Solid State Comm. 10, 347.
14. F.I. Tóth, K. Tompa, G. Grüner, “Frequency Modulated NMR Spectrometer for Measurement of Internal Magnetic Fields," J. Phys. E 5, 42.
15. G. Grüner, “Temperature Dependence of the Charge Perturbation Around 3-D Transition Metal Impurities in Aluminum," Solid State Comm. 10, 1939.
16. G. Grüner and A. Zawadowski, “Semiphenomenological Model for the Resonances and Charge Neutrality in Dilute Magnetic Alloys," Solid State Clomm. 11, 663.
17. I. Vincze, G. Grüner, “Temperature Dependence of the Hyperfine Field at Iron Atoms Near Three Dimensional Impurities," Phys. Rev. Lett. 28, 178.
18. F. Mezei, G. Grüner, “Theory of Anomalous Charge Oscillation Around Resonant Scattering Impurities," Phys. Rev. Lett. 29, 1465.
19. E. Kovács-Csetényi, F.J. Kedves, L. Gergely, G. Grüner, “High Temperature Impurity Resistivity in AlMn Alloys," J. Phys. F 2, 499.
1973
20. G. Grüner, K. Tompa, “`Detailed 57Fe Continuous NMR Spectra in Fe Based Alloys, "J. Phys. F3, 199.
21. A.M. Stewart, G. Grüner, “Physical Properties Given by the Magnetic Hartree- Fock Solution of Anderson's Model," J. Phys. F3, 843
22. A.D. Caplin, G. Grüner, J.B. Dunlop, “Al10V: An Einstein Solid," Phys. Rev. Lett. 30, 1138.
23. G. Serfózó, E. Kovács-Csetényi, G. Grüner, “Quadrupolar NMR Line broadening in Al- Three Dimensional-Transition Metal Alloys," Solid State Comm. 13, 1315.
1974
24. V. Zlatic, G. Grüner, N. Rivier, “Model Calculation of the Density of States of Dilute Alloys," Solid State Comm. 14, 639.
25. F. Mezei, G. Grüner, “NMR Experimental Test for Existence of the KondoResonance," Proc. LT 13, Vol.2, 444 Plenum Press.
2 26. J.B. Dunlop, G. Grüner, F. Napoli, “Phonon Resistivities of Dilute Transition Metal Compounds," Solid State Comm. 15, 13.
27. G. Grüner, N.F. Mott, “A Model for the Kondo Type Intermetallic Compounds With Small Effective Moments," J. Phys. F 4, L16.
28. J.B. Dunlop, G. Grüner, A.D. Caplin, “Dilute Intermetallic Compounds II: Properties of Aluminum Rich Aluminum-transition Metal Phases," J. Phys. F 4, 2203.
29. A. Zawadowski, G. Grüner, “On the Absence of the Finite Conduction Electron Polarization in Dilute Alloys," J. Phys. F 4, L202.
30. G. Grüner and A. Zawadowski, “Magnetic Impurities in Non-magnetic Metals," Rep. Prog. Phys. 37, 1497-1583.
31. G. Grüner, “Experimental Evidence for Many-body Effects in Dilute Alloys," Advances in Physics, 23, 941.
1975
32. G. Mihály, K. Ritvay-Emandity, and G. Grüner, “High Temperature Resistivity of
Qn (TCNQ)2 and Ad (TCNQ)2," J. Phys. C 8, L361.
33. M. Miljak, A. Jánossy, G. Grüner, “Magnetic Susceptibility of Qn (TCNQ)2, "KFKI reports 38. (1 page) N/A
34. G. Mihály, K. Holczer, K. Pintér, A. Jánossy, G. Grüner, “Magnetic and Electric
Properties of NMeQn (TCNQ)2," Solid State Comm. 17, 1007.
1976
35. K. Holczer, G. Mihály, A. Jánossy, and G. Grüner, “Magnetic and Electric
Properties of Qn (TCNQ)2," Mol. Cryst. Liq. Cryst. 32, 199.
36. J.B. Dunlop and G. Grüner, “One Dimensional Effects in the Intermetallic
Compound Al11Mn4," Solid State Comm. 18, 827.
37. E. Babíc and G. Grüner, “Interaction Effects in Dilute Alloys," Physica 84B, 37.
38. G. Mihály, K. Holczer, G. Grüner, L.D. Kunstelj, “Interchain Interactions and
Phase Transition in NMeQn (TCNQ)2," Solid State Comm. 19, 1091.
39. F. Woynarovich, L. Mihály, G. Grüner, “Coupled Charge Density Waves in Nearly One Dimensional Systems," Solid State Comm. 19, 1189.
40. K. Holczer, G. Mihály, K. Pintér, A. Jánossy, G. Grüner, W.G. Clark, “Phase
Transition in Py (TCNQ)2," Lecture Notes in Physics 65 (Proceedings of the Conf.on Organic Conductors and Semiconductors, 1976), Springer Verlag, p. 507. 3 41. G. Mihály, K. Ritvay-Emandity, G. Grüner, “Interchain Coupling and Disorder in Complex TCNQ Salts With Aromatic Donors," Lecture Notes in Physics 65 (Proceedings of the Conf. on Organic Conductors and Semiconductors, 1976), Springer Verlag, p. 507.
42. G. Mihály, K. Holczer, A. Jánossy, G. Grüner, M. Miljak, “TCNQ Salts With Symmetric and Asymmetric Donors," Lecture Notes in Physics 65 (Proceedings of the Conf. on Organic Conductors and Semiconductors, 1976), Springer Verlag, p. 553.
1977
43. G. Mihály, K. Ritvay-Emandity, A. Jánossy, K. Holczer, G. Grüner, “Single Crystal Conductivity of Bipyridine-TCNQ Salts," Solid State Comm. 21, 1115.
44. G. Mihály, A. Jánossy, G. Grüner, “Dimensionality and Disorder in TTT-I1.6," Solid State Comm. 22, 771.
45. V. Zlatíc, G. Grüner, “Preasymptotic Charge Oscillations Around 3-D Impurities in Aluminum," J. de Phys. Lett. 38, L97.
46. G. Grüner, E. Babíc, “Impurity Interactions in Kondo Systems," Physica 86-88B, 850.
47. G. Mihály, G. Said, G. Grüner, M. Kertész, “2-3 Benzacridinium (TCNQ)2: A Small Bandgap Conductor," Solid State Comm. 24, 97.
48. K. Kamarás, K. Ritvay-Emandity, G. Mihály, G. Grüner, N. Rysava, “Impurity
Effects in the Organic Charge Transfer Salt Qn (TCNQ)2," KFKI-31, (1977), J. Phys. C10, L423.
49. K. Kamarás, K. Ritvay-Emandity, G. Mihály, G. Grüner, “Electronic Spectra of the Organic Charge Transfer Salts TTT-In," Solid State Comm. 24, 93.
50. K. Holczer, G. Grüner, M. Miljak, J. Cooper, “Surface Magnetism in Organic ChargeTransfer Salts," Solid State Comm. 24, 97.
51. M. Miljak, B. Korin, J.R. Cooper, G. Grüner, “Magnetic Susceptibility of theOrganic Metal TTT2I3," Comm. Phys. 2, 193.
52. G. Grüner and A. Zawadowski, “Low Temperature Properties of Kondo Alloys, "Progress in Low Temperature Physics, Vol. 7, Ed. E. Brewer.
53. G. Grüner and M. Minier, “Charge Perturbations Around Impurities in Metals," Advances in Physics, 26, No. 3, 231-284.
4 1978
54. K. Holczer, G. Mihály, A. Jánossy, G. Grüner, M. Kertész, “Complex TCNQ Salts with Asymmetric Donors: Transport Properties," J. Phys. C11, 4707.
55. M. Kürti, G. Mihály, G. Grüner, A. Jánossy, “Nonohmic Electrical Conductivity in Qn (TCNQ)2," KFKI-29. N/A
56. K. Kamarás, G. Grüner, S. Sawatzky, “Optical Absorption in Complex TCNQ Salts," Solid State Comm. 27, 1171.
57. K. Kamarás, G. Mihály, G. Grüner, A. Jánossy, “Highly Conducting Organic
Alloys: TTT2IxBr3-x," Chem. Comm., 974.
58. T. Kemény, Z. Poko, G. Mihály, K. Holczer, G. Grüner, “The Role of Solvent in
Phase Transition of NMeQn (TCNQ)2," Mol. Cryst. Liq. Cryst. 1.
59. M. Miljak, J. Cooper, G. Grüner, “Complex TCNQ Salts with Asymmetric Donors: II. Magnetic Properties," J. Phys. C1.
1979
60. K. Kamarás and G. Grüner, “Optical Properties of the Charge Transfer Salts of Tetra- thiotetracene," Solid State Comm. 30, 277.
61. K. Holczer, G. Grüner, G. Mihály, A. Jánossy, “Defect Dependence of the
Dielectric Permeability of Qn (TCNQ)2," Solid State Comm. 31, 145.
62. G. Mihály, A. Jánossy, J. Kürti, L. Forró, G. Grüner, “Nonohmic Conductivity in
Qn (TCNQ)2," Lecture Notes on Phys. 95, 297 Springer Verlag.
63. G. Grüner, A. Jánossy, K. Holczer, G. Mihály, “Disordered One DimensionalConductors," Lecture Notes on Phys. 96, 246 Springer Verlag
64. K. Holczer, G. Mihály, G. Grüner, A. Jánossy, “Decrease of Electronic Coherence
Length by Impurities in the Quasi-one-dimensional Charge Transfer Salt Qn (TCNQ)2," J. Phys. C 12, 1883.
65. P.M. Chaikin, G. Grüner, I.F. Schegolev, E.B. Yagubskii, “Thermoelectric Power of TTT2I3+δ" Solid State Comm. 32, 1211.
66. E. Chock, G. Grüner, “Thermoelectric Power of Na0.33V2O5," Solid State Comm. 36, 12.
67. L. Zuppiroli, G. Mihály, A. Jánossy, G. Grüner, “Effects of Neutron Irradiation
Induced Defects and Chemical Impurities on the dc Conductivity of TTT2I3," J. Phys. C1.
5 68. G. Grüner and S.K. Khanna, “Configurational Entropy in the Organic Conductor
Qn (TCNQ)2," Solid State Comm. 32, 1233.
69. G. Mihály, A. Jánossy, J. Kürti, L. Forró, and G. Grüner, “Nonlinear Transport in
Qn (TCNQ)2," Phys. Stat. Sol. B94, 287.
1980
70. M. Miljak, B. Korin, J.R. Cooper, K. Holczer, G. Grüner, A. Jánossy, “LowTemperature Magnetic Susceptibility of Some Quasi-one-dimensional Organic Conductors," Journal of Magnetism and Magnetic Materials, 15, 219.
71. F. Devreux, M. Nechtschein, G. Grüner, “Charge Transport in the Organic
Conductor Qn (TCNQ)2," Phys. Rev. Lett. 45, 53.
72. M. Morrow, W.N. Hardy, J.F. Carolan, A.J. Berlinsky, A. Jánossy, K. Holczer, G. Mihály, G. Grüner, S. Huizinga, A. Verwey, G.A. Sawatzky, “Metal Insulator
Transition in MEM (TCNQ)2," Can. J. Phys.
73. J. Sanny, G. Grüner, W.G. Clark, “Observation of Quasi-universal MagneticBehavior in a Random Heisenber Antiferromagnetic Chain: Neutron Irradiated
Quinolinium (TCNQ)2," Solid State Comm. 35, 657.
74. R. Lacoe, G. Grüner, P. Chaikin, “The Thermoelectric Power of MEM (TCNQ)2," Solid State Comm. 36, 599.
75. M. Weger, G. Grüner, W.G. Clark, “Charge Density Wave Noise in NbSe3," Solid State Comm. 35, 243.
76. G. Grüner, J. Sanny, L. Tippie, W.G. Clark, N.P. Ong, “Frequency
DependentConductivity in NbSe3," Phys. Rev. Lett. 45, 935.
77. A.J. Epstein, H.W. Gibson, P.M. Chaikin, G. Grüner, W.G. Clark, “Frequency and Electric Field Dependent Conductivity in Metallic Polyacetilene," Phys. Rev. Lett. 45, 1730.
78. P.M. Chaikin, G. Grüner, E.M. Engler, R.L. Greene, “Study of Nonlinear Electric
Field Effects in (TMSF)2PF6," Phys. Rev. Lett. 45, 1874.
1981
79. S.K. Khanna, G. Grüner, R. Orbach, H. Beyeler, “Thermally Activated Microwave
Conductivity in the Superionic Conductor Hollandite [K1.54Mg0.77Ti7.23O16]," Phys. Rev. Lett. 47, 255.
80. G. Grüner, A. Zawadowski, P.M. Chaikin, “Nonlinear Conductivity and Noise Due to Charge Density Wave Depinning in NbSe3," Phys. Rev. Lett. 46, 511.
6 81. G. Grüner, “Frequency and Field Dependent Transport in Low Dimensional Conductors," Chemical Scripta A, 207.
82. A.H. Thompson, A. Zettl, G. Grüner, “Charge Density Wave Transport in TaS3," Phys. Rev. Lett. 47, 64.
83. G. Grüner, A. Zettl, W.G. Clark, A.H. Thompson, “Observation of Narrow
BandCharge Density Wave Noise in TaS3," Phys. Rev. B 23, 6813.
84. C.M. Jackson, A. Zettl, G. Grüner, A.H. Thompson, “High Frequency
Conductivity in the Charge Density Wave Semiconductor TaS3," Solid State Comm. 39, 531.
85. W.W. Fuller, G. Grüner, P.M. Chaikin, N.P. Ong, “Impurity Effects in NbSe3," Chemica Scripta (Sweden) 17, 135.
86. W.W. Fuller, G. Grüner, P.M. Chaikin, N.P. Ong, “Effect of Radiation Damage on the Charge Density Wave Dynamics of NbSe3," Phys. Rev. B23, 6259.
87. G. Grüner, W.G. Clark, A.M. Portis, “Ac-induced Conductivity in the Charge
Density Wave State in NbSe3," Phys. Rev. B24, 3641.
88. G. Grüner, A. Zettl, W.G. Clark, J. Bardeen, “Field and Frequency Dependence of
Charge Density Wave Conduction in NbSe3," Phys. Rev. B 24, 724
89. A. Zettl, G. Grüner, A.H. Thompson, “On the Nonlinear Charge Density Wave
Conductivity of TaS3," Solid State Comm. 39, 899.
90. S. Alexander, J. Bernasconi, W.R. Schneider, R. Biller, W.G. Clark, G. Grüner, R. Orbach, A. Zettl, “Frequency Dependent Charge Transport in a One Dimensional Disordered Metal," Phys. Rev. B 24, 7474.
91. A.J. Epstein, H.W. Gibson, P.M. Chaikin, W.G. Clark, G. Grüner, “Electric Field Dependent Conductivity of Metallic Polyacetylene," Chemica Scripta 17, 135.
92. S.K. Khanna, W.W. Fuller, G. Grüner, P.M. Chaikin, “Transport Properties of
Tetra- thiotetracene Iodide (TTT2I3-δ) at Low Temperatures," Phys. Rev. B 24.
93. S.K. Khanna, G. Grüner, R. Orbach, M. Beyeler, “Thermally Activated
Conductivity in the Superionic Conductor Hollandite [K1.54Mg0.77Ti7.23}O16]," Phys. Rev. Lett. 47, 255.
94. S. Oostra, B.V. Bodegom, S. Huizinga, G.A. Sawatsky, G. Grüner, T.P. Travers,
“Molecular Motion Induced Order-disorder Transition in MEM (TCNQ)2," Phys. Rev. B 24, 5004.
7
95. Y. Tomkiewicz, N.S. Shiven, T.D. Schultz, K. Thomann, L.R. Delhon, A. Zettl, G. Grüner, T.D. Clarke, “Spin and Charge Excitation in Polyacetilene," Solid State Physics RC 91 89 (No. 40326).
1982
96. G. Grüner, “Charge Density Wave Dynamics in NbSe3 and TaS3," Molecular Crystals and Liquid Crystals 81, 17.
97. M. Weger, G. Grüner, W.G. Clark, “Spectral Purity and Phase Coherence of
Narrow Band Noise in NbSe3," Solid State Comm. 44, 1179.
98. A. Zettl, G. Grüner, “Charge Density Wave Dynamics in TaS3," Phys. Rev. B 25, 2081.
99. A. Zettl, G. Grüner, E.M. Engler, “Dynamical Response of the Spin-density-wave
Mode in Tetramethyltetraselenofulvalene Hexafluorophosphate (TMTSF)2PF6," Phys. Rev. B 25, 1443.
100. A. Zettl, G. Grüner, “Onset of CDW Conduction: Switching and Hysteresis in
NbSe3," Phys. Rev. B 26, 2298.
101. A. Zettl, C.M. Jackson, A. Jánossy, G. Grüner, A. Jacobsen, A.H. Thompson,
“Charge Density Wave Transition and Nonlinear Conductivity in NbSe3," Solid State Comm. 43, 345.
102. J. Bardeen, E. Ben-Jacob, A. Zettl, G. Grüner, “Current Oscillations and Stability of Charge Density Wave Motion in NbSe3," Phys. Rev. Lett. 49.
103. A. Zettl, G. Grüner, A.H. Thompson, “Charge Density Wave Transport in
Orthorhombic TaS3I: Nonlinear Conductivity," Phys. Rev. B 26, 5760.
104. A. Zettl, G. Grüner, “Observation of Shapiro Steps in the Charge Density Wave
State of NbSe3," Solid State Comm. 46, 501.
105. A. Zettl, C.M. Jackson, G. Grüner, “Charge Density Wave Transport in
Orthorhombic TaS3II: Frequency Dependent Conductivity," Phys. Rev. B 26, 5773.
1983
106. G. Grüner, “Charge Density Wave Transport in Linear Chain Compounds," Comments on Solid State Physics 10, 183.
107. C.M. Jackson, A. Zettl, G. Grüner, I.J. DiSalvo, “Frequency Dependent
Conductivity in HfTe5 and ZrTe5," Solid State Comm. 45, 247.
8 108. A. Jánossy, M. Hardiman, G. Grüner, “Ac-dc Coupling Experiments in the Spin
Density Wave State of (TMTSF)2PF6," Solid State Comm. 21, 46.
109. A. Zettl, G. Grüner, “Broad Band Noise Associated With the Current Carrying
Charge Density Wave State in TaS3," Solid State Comm. 46.
110. Pei-Ling Hsieh, C.M. Jackson, G. Grüner, “Disorder Effects in the Linear Chain
(TiS3)," Solid State Comm. 46, 505.
111. M. Maki, M. Kaiser, A. Zettl, G. Grüner, “Charge Density Wave Transport in a
Novel Inorganic Chain Compound, (TaSe4)2I," Solid State Comm. 46, 497.
112. A. Zettl, G. Grüner, “Charge Density Wave Transport in Orthorhombic TaSx: III: Narrow Band `noise'," Phys. Rev. B 28, 2091.
113. M. Weger, W.G. Clark, G. Grüner, “The Relaxation Oscillator Model of the
Narrow Band Noise in NbSe3," J. de Phys. (Paris) Coll. 3, Suppl. 44, C3-1673.
114. R.A. Klemm, J.R. Schrieffer, G. Grüner, “Dynamics of Pinned Charge Density
Waves in NbSe3," J. de Phys. Coll. C 3, Tome 44, June. N/A
115. G. Grüner, A. Zettl, “Long Range Phase Coherence in the Current Carrying Charge Density Wave State," J. de Phys. Coll. C 3, Suppl. 44, 1631.
116. G. Grüner, A. Zettl, “Switching and Hysteresis in NbSe3," J. de Phys. Coll. C 3, Suppl. 44, 1745.
117. D.C. Johnston, J.P. Stokes, Pei-Ling Hsieh, G. Grüner, “Characterization of the
CDW Transition in Orthorhombic TaS3 by Thermoelectric Power and Magnetic Susceptibility Measurements," J. de Phys. Coll. C3, Suppl. 44.
118. G. Mozurkewich, G. Grüner, “Volume Dependence of Current Oscillations in
NbSe3: A Finite Size Effect," Phys. Rev. Lett. 51, 24.
119. G. Mozurkewich, M. Maki, G. Grüner, “Size Dependence of Current Osillations in the Charge Density Wave Compound (TaSe4)2I," Solid State Comm. 48, 453. (3 pages)
120. G. Grüner, “Nonlinear and Frequency-dependent Transport Phenomena in Low- dimensional Conductors," Physica 8D, 1-34.
1984
121. C.M. Jackson, G. Grüner, Z. Fisk, S. von Molnár, “Microwave Conductivity of
SmB6," Phys. Rev. B 29, 4786.
122. G. Grüner, “Charge Density Wave Transport in Linear Chain Compounds," Physica 126B, 400.
9 123. A. Zettl, G. Grüner, “Phase Coherence in the Current Carrying Charge Density
Wave State: ac-dc Coupling Experiments in NbSe3," Phys. Rev. B 29, 755.
124. Wei-yu Wu, A. Jánossy, G. Grüner, “Correlation Between the Static Dielectric Constant and Threshold Electric Field for Sliding Charge Density Wave Conduction," Solid State Comm. 49, 1013.
125. S. Brown, G. Mozurkewich, G. Grüner, “Subharmonic Shapiro Steps, and Devil's Staircase Behavior in Driven Charge Density Wave Systems," Phys. Rev. Lett. 52, 2277.
126. Wei-yu Wu, L. Mihály, G. Mozurkewich, G. Grüner, “Low Frequency Behavior of Pinned CDW Condensates," Phys. Rev. Lett. 52, 2382.
127. L. Mihály, G. Grüner, “The Onset of Current Carrying Charge Density Wave State in TaS3: Switching, Hysteresis, and Oscillation Phenomena," Solid State Comm. 50, 807.
128. J.P. Stokes, A.N. Bloch, A. Jánossy, G. Grüner, “Thermoelectric Aspects of
Charge Density Wave Transport in TaS3," Phys. Rev. Lett. 52, 5.
1985
129. Wei-yu Wu, L. Mihály, G. Mozurkewich, G. Grüner, “Frequency Dependent Conductivity of CDW Compounds," Proceeding of the International Conference on Charge Density Waves in Solids, Lecture Notes in Phys. Vol. 217, Eds. G. Hutiray, J. Solyom.
130. G. Grüner, “Coherent and Incoherent Effects in Charge Density Wave Transport, "Proceedings of the International Conference on Charge Density Waves in Solids, Lecture Notes in Phys. Vol. 217, Eds. G. Hutiray, J. Solyom.
131. D. Reagor, S. Sridhar, M. Maki, G. Grüner, “Frequency Dependent Conductivity in (TaSe4)2I," Phys. Rev. B 32, 8995.
132. D. Reagor, S. Sridhar, G. Grüner, “Inertial Dynamics of CDW Transport in
NbSe3," Proceeding of the International Conference on Charge Density Waves in Solids, Lecture Notes in Phys. Vol. 217, Eds. G. Hutiray, J. Solyom.
133. S.E. Brown, G. Mozurkewich, G. Grüner, “Subharmonic Shapiro Steps, Devil's Staircase and Synchronization in rf-driven CDW Conductors," Proceedings of the International Conference on Charge Density Waves in Solids, Lecture Notes in Physics, Vol. 217, Eds. G. Hutiray, J. Solyom.
134. G. Mozurkewich, P.M. Chaikin, W.G. Clark, G. Grüner, “Low Frequency Elastic Properties of Materials Containing a Sliding CDW," Proceedings of the International Conference on Charge Density Waves in Solids, Lecture Notes in Phys. Vol. 217, Eds. G. Hutiray, J. Solyom.
10 135. L. Mihály, T. Chen, B. Alavi, G. Grüner, “Relaxation of Metastable States in Blue
Bronze K0.3MoO3," Proceedings of the International Conference on Charge Density Waves in Solids, Lecture Notes in Phys. Vol. 217, Eds. G. Hutiray, J. Solyom.
136. D.C. Johnston, M. Maki, G. Grüner, “Influence of Charge Density Wave Fluctuations on the Magnetic Susceptibility of the Quasi One Dimensional Conductor
(TaSe4)2I," Solid State Comm. 53, 5.
137. S.E. Brown, G. Mozurkewich, G. Grüner, “Harmonic and Subharmonic Shapiro
Steps in Orthorhombic TaS3," Solid State Comm. 54, 23.
138. S.E. Brown, A. Jánossy, G. Grüner, “Effect of A Temperature Gradient on the Current Oscillations in Moving Charge Density Waves," Phys. Rev. B 31, 6869.
139. A. Zettl, M. Kaiser, G. Grüner, “Non-equilibrium Transport in NbSe3: Effects of A Temperature Gradient," Solid State Comm. 53, 8.)
140. S. Brown, G. Grüner, “Shapiro Steps in Orthorhombic TaS3," Phys. Rev. B 31, 8302.
141. A.K. Sood, G. Grüner, “Electric Field Dependence of the Ramon Phonon in the
Charge Density Wave State of TaS3," Phys. Rev. B 32, 271.
142. S. Sridhar, D. Reagor, G. Grüner, “Complex Conductivity Measurements Between 26 and 110 GHz Using Complex Impedance Bridges," Rev. Sci. Instum. 56, 1946.
143. H.H.S. Javadi, S. Sridhar, G. Grüner, “Giant Conductivity Resonance in the Spin Density Wave State on An Organic Conductor," Phys. Rev. Lett. 55, 1216.
144. S. Sridhar, D. Reagor, G. Grüner, “Inertial Dynamics of Charge Density Waves in
TaS3 and NbSe3," Phys. Rev. Lett. 55, 1196.
145. G. Mozurkewich, P.M. Chaikin, W.G. Clark, G. Grüner, “Elastic Properties of Linear Charge Density Wave Materials in the Regime of Nonlinear Conduction," Solid State Comm. 56, 421.
1986
146. S.E. Brown, L. Mihály, G. Grüner, “Long Range Remanent Deformations of
Charge Density Waves in TaS3 and NbSe3," Solid State Comm. 58, 231.
147. D. Reagor, G. Grüner, “Frequency Dependent Response of Pinned Charge Density Wave Condensates: Classical versus Quantum Description," Phys. Rev. Lett. 56, 659.
148. S.E. Brown, G. Grüner, L. Mihály, “Interference Phenomena in Charge Density Waves for Nonsinusoidal External Drives," Solid State Comm. 57, 165.
11 149. Wei-yu Wu, L. Mihály, G. Mozurkewich, G. Grüner, “Low Frequency Response of Pinned Charge Density Wave Condensates," Phys. Rev. B 33, 2444.
150. R.E. Thorne, J.R. Tucker, J. Bardeen, S.E. Brown, G. Grüner, “Phase Locking in Charge Density Wave Transport," Phys. Rev. B 33, 7342.
151. W.P. Beyermann, L. Mihály, G. Grüner, “Temperature Gradient Induced Open Circuit Electric Currents in Charge Density Wave Condensates," Phys. Rev. Lett. 56, 1948.
152. S.E. Brown, L. Mihály, G. Grüner, “Interference Effects in the Charge Density
Wave Conductor NbSe3," Physica 23D, 169.
153. D. Reagor, S. Sridhar, G. Grüner, “Inertial Dynamics of Pinned Charge Density
Wave Condensates I. NbSe3," Phys. Rev. B 34, 2212.
154. S. Sridhar, D. Reagor, G. Grüner, “Inertial Dynamics of Pinned Charge Density
Wave Condensates II. Orthorhombic TaS3," Phys. Rev. B 34, 2223.
155. G. Grüner, “Frequency Dependent Response of Pinned CDW Condensates," Physica 143B, 8-13.
156. G. Grüner, “Nonlinear Transport Due to Driven Collective Modes," Physica 23D, 145-154.
1987
157. L. Mihály, M. Crommie, G. Grüner, “The Dynamics of Partially Random Systems: A Computer Simulation," Europhys. Lett. 4, 103.
158. A. Migliori, T. Chen, B. Alavi, and G. Grüner, “Ultrasound Anomaly At Tc in
YBa2Cu3Oy," Solid State Comm. 63, 827.
159. M. Underweise, M. Maki, B. Alavi, G Grüner, “Impurity Pinning Studies in Nb1-x TaxSe3 Alloys," Solid State Comm. 64, 181.
160. W. Beyermann, B. Alavi, G. Grüner, “Surface Impedance Measurements in
La1.8Ba0.2 CuO4-y," Phys. Rev. B 35, 8826.
161. J.R. Cooper, B. Alavi, L-W. Zhou, W.P. Beyermann, G. Grüner, “Thermoelectric
Power of Some High Tc Oxides," Phys. Rev. B 35, 8794.
162. J.R. Cooper, W.P. Beyermann, S.W. Cheong, G. Grüner, S. von Molnár, “Field
Dependent Electrical Conductivity in Disordered Ge1-xAux Alloys," Phys. Rev. B 36, 3913.
163. S.W. Cheong, S.E. Brown, J.R. Cooper, Z. Fisk, R.S. Kwok, D.E. Peterson, J.D. Thompson, G.L. Wells, E. Zirngiebl, R.B. Schwarz, G. Grüner, “Normal State Properties 12 of ABa2Cu3O7-y Compounds (A-Y and Gd): Electron-electron Correlations," Phys. Rev. B 36, 3913.
164. G. Grüner, “The Dynamics of Charge Density Waves in Low Dimensional Conductors and Superconductors," Eds. D. Jerome, L.G. Caron, Plenum Publ. Corp. 347- 368
165. T. Chen, L. Mihály, G. Grüner, “Nonlinear CDW Dynamics: Third Harmonic Generation," Phys. Rev. B 36, 2931.
166. J.R. Cooper, L.W. Zhou, B. Dunn, C.T. Chu, B. Alavi, G. Grüner, “Traces of
Superconductivity in Sintered La2CuO4-y," Solid State Comm. 64, 253.
167. A. Philip, W. Mayr, T.W. Kim, G. Grüner, “Dynamical Charge Density Wave
Response in $(NbSe4)2I," Solid State Comm. 62, 521.
168. L. Mihály, T. Chen, G. Grüner, “Switching, Hysteresis and Time Delay in Charge Density Wave Conduction," Solid State Comm. 61, 751.
1988
169. W.P. Beyermann, G. Grüner, Y. Dalicheouch, M.B. Maple, “Frequency Dependent
Transport Properties of UPt3," Phys. Rev. B 37, 353.
170. T.W. Kim, W.P. Beyermann, D. Reagor, G. Grüner, “Complex Conductivity Measurements at Several Frequencies in the Millimeter Wave Spectral Range," Rev. Sci. Instr. 59, 1219.
171. J.R. Cooper, C.T. Chu, L.W. Zhou, B. Dunn, G. Grüner, “Determination of the Magnetic Field Penetration Depth in Superconducting Yytrium Barium Copper Oxide: Deviations from the BCS Laws," Phys. Rev. B 37, 638.
172. W.P. Beyermann, G. Grüner, Y. Dalicheouch, M.B. Maple, “Relaxation Time
Enhancement in the Heavy Fermion System CePd3," Phys. Rev. Lett. 60, 216.
173. T. Chen, L. Mihály, G. Grüner, “Polarization Divergence in Driven Charge DensityWaves," Phys. Rev. Lett. 60, 464.
174. S.W. Cheong, Z. Fisk, J.O. Willis, S.E. Brown, J.D. Thompson, J.P. Remeika, A.S. Cooper, R.M. Aikin, D. Schiferl, G. Grüner, “Novel Phase Transition in Non- antiferro-magnetically Ordered Crystals of La2CuO4," Solid State Comm. 65, 111
175. S.W. Cheong, J.D. Thompson, Z. Fisk, G. Grüner, “Magnetic Field Dependence of the Three Dimensional Ordering in La2CuO4-δ," Solid State Comm. 66, 1019
176. S.W. Cheong, Z. Fisk, R.S. Kwok, J.P. Remeika, J.D. Thompson, G. Grüner,
“Electronic Anisotropy in Single Crystal La2CuO4," Phys. Rev. B 37, 5916.
13 177. A.M. Awasthi, J.P. Carini, B. Alavi, G. Grüner, “Millimeter Wave Surface
Impedance Measurements of YBa2Cu3O7-δ Ceramic Superconductors," Solid State Comm. 67, 373
178. J.P. Carini, A.M. Awasthi, W. Beyermann, G. Grüner, “Millimeter Wave Surface
Resistance Measurements in Highly Oriented YBa2Cu3O7-δ Thin Films," Phys. Rev. B 37, 9726.
179. T.L. Hylton, A. Kapitulnik, M.R. Beasly, J.P. Carini, L. Drabeck, G. Grüner,
“Weakly Coupled Grain Model of High Frequency Losses in high-Tc Superconducting Thin Films," J. Appl. Phys. Lett. 53, 1343.
180. I.D. Shaltiel, A. Grayevsky, V. Zevin, G. Grüner, “Electron Spin Resonance
Studies of the Charge Density Wave Phase of (TaSe4)2I," Phys. Rev. B 38, 10075.
181. W.P. Beyermann, A.M. Awasthi, J.P. Carini, G. Grüner, “Frequency Dependent Transport in Heavy Fermion Systems," J. of Magnetism and Mag. Mat. 76 & 77, 207- 212.
182. G. Mihály, G. Kriza, G. Grüner, “Heat Transport by Moving Charge Density Waves," Solid State Comm. 68, 993.
183. G. Mihály, T. Chen, G. Grüner, “Reversible and Remanent Charge Density Wave Polarization at Low Temperatures," Phys. Rev. B 38, 12740
184. G. Mihály, P. Beaucheˆ ne, T. Chen, L. Mihály, G. Grüner, “Electronic Anisotropy of Nonlinear Properties in the Low Temperature Sliding Charge Density Wave State of
K0.3MoO3," Phys. Rev. B 37, 6536.
185. S.E. Brown, J.O.Willis, B. Alavi, G. Grüner, “Effect of Substitutional Impurities on the Low Temperature Specific Heat of (TaSe4)2I," Phys. Rev. B 37, 6551.
186. G. Mihály, T. Chen, T.W. Kim, G. Grüner, “Low Temperature Charge Density Wave Dynamics," Phys. Rev. B 38, 3602.
187. G. Grüner, “Competing Interactions: Charge Density Waves and Impurities in `Competing Interactions and Microstructures: Statics and Dynamics'," Eds. R. LeSar, A. Bishop, R. Heffner, Proceedings in Physics, Springer Verlag 202.
188. G. Grüner, “The Dynamics of Charge Density Waves," Rev. Mod. Phys. Vol. 60, 1129.
189. G. Grüner, “Charge Density Waves in Solids," Future Trends in Material Sciences, Ed. J. Keller, 119 (North Scientific).
14 1989
190. T.L. Hylton, M.R. Beasley, A. Kapitulnik, J.P. Carini, L. Drabeck, G. Grüner,
“Surface Impedance Studies of the High- Tc Oxide Superconductors," IEEE Trans. Magnetics Vol. 25, 810.
191. J.P. Carini and G. Grüner, “Superconducting State Properties of the High-Tc Oxides:Penetration Depth and Surface Impedance," Physica Scripta, T25.
192. G. Grüner, “Frequency Dependent Response of Charge and Spin Density Wave Condensates," Synthetic Metals 29, F453-462.
193. D. Reagor and G. Grüner, “Effect of Impurities on the Charge Density Wave
Dynamics in Ta1-xNbxS3 Alloys," Phys. Rev. B 39, 7626.
194. Y.M. Kim, G. Mihály, G. Grüner, “Onset of the Charge Density Wave
Conductionat Low Temperatures in K0.3MoO3," Solid State Comm. 69, 975.
195. L. Drabeck, J.P. Carini, G. Grüner, T. Hylton, K. Char, M.R. Beasley, “Power-law
Temperature Dependence of the Electrodynamic Properties in Oriented YBa2Cu3O7-δ\ and
Y2Ba4Cu8O16-δ Films," Phys. Rev. B 39, 785.
196. G. Kriza, G. Mihály, G. Grüner, “Frequency Dependent Thermoelectric Power in
K0.3 MoO3," Phys. Rev. Lett. 62, 2032.
197. L. Drabeck, J. Carini, G. Grüner, T.L. Hylton, A. Kapitulnik, M.R. Beasley,
“Surface Impedance of High Tc Superconductors," International Microwave Symposium Digest, IEEE MTT-S, 551-554.
198. L. Drabeck, G. Grüner, J.J. Chang, A. Inam, X.D. Wu, L. Nazar, T. Venkatesan, D.
Scalapino, “Millimeter Wave Surface Impedance of YBa2Cu3O7 Thin Films, "Phys. Rev. B 40, 7350.
199. G. Mihály, Y.M. Kim, G. Grüner, “Charge Density Wave Dielectrics: Pinned Fröhlich Mode at Low Temperatures," Europhys. Lett. 9, (5) 483-488.
200. G. Mihály, T.W. Kim, and G. Grüner, “Ac Response of the Charge Density Wave
Mode in K0.3MoO3," Phys. Rev. B 39, 13009.
201. A.M. Awasthi, W.P. Beyermann, J.P. Carini, G. Grüner, “Relaxation Time
Enhancement in the Heavy-fermion Systems CePd3 and UPt3," Phys. Rev. B39, 2377.
202. G. Mihály and G. Grüner, “Phase Coherent Charge Density Wave Response versus Metastable States," Proceedings of the Third European Conference on Low Dimensional Conductors and Superconductors, Dubrovnik, Yugoslavia. N/A
15 203. L.D. Chang, M.J. Moskowitz, R.B. Hammond, M.M. Eddy, W.L. Olson, D.D. Casavant, E.J. Smith, M. Robinson, L. Drabeck, G. Grüner, “Microwave Surface Resistance in T1-based Superconducting Thin Films," Appl. Phys. Lett. 5, 1357.
204. A. Philipp, W. Mayr, T.W. Kim, B. Alavi, M. Maki, G. Grüner, “Dynamics of the
Charge Density Wave Mode in (NbSe4)2I," Phys. Rev. B 39, 7536.
205. T.W. Kim, D. Reagor, G. Grüner, K. Maki, A. Virosztek, “Temperature Dependence of the Charge Density Wave Mass and Relaxation Time," Phys. Rev. B 40, 5372 .
206. R.S. Kwok, G. Grüner, S.E. Brown, “Thermal Conductivity of Potassium Blue Bronze in the Nonohmic Regime," Solid State Comm. 72, 513.
207. D.W. Cooke, E.R Gray, R.J. Houlton, H.H.S. Javadi, M.A. Maez, B.L. Bennett, B. Rusnak, E.A. Meyer, P.N. Arendt, J.G. Beery, D.R. Brown, F.H. Garzon, I.D. Raistrick, A.D. Rollett, B. Bolmaro, N.E. Elliott, N. Klein, G. Müller, S. Orbach, H. Piel, J.Y.
Josefowicz, D.B. Rensch, L. Drabeck, G. Grüner, “Surface Resistance of YBa2Cu3O7
Films Deposited on LaGaO3 Substrates," Physica C 162-164.
208. W.L. Olson, M. Eddy, T. James, R. Hammond, G. Grüner, L. Drabeck, “Preparation of Superconducting Tl-Cu-Ba-Cu Thin Films by Chemical Deposition," Appl. Phys. Lett. 55, 188.
209. G. Grüner, P. Monceau, “Dynamical Properties of Charge Density Waves," Charge Density Waves in Solids, Eds. L.P. Gor'kov, G. Grüner, Elsevier Science Publishers B.V.
210. G. Grüner, “Current Oscillations and Interference Effects in Driven Charge Density Wave Condensates," Progress in Low Temperature Physics, Vol. III., Ed. D.F. Brewer, Elsevier Science Publishers B.V. 195-269.
211. L.P. Gorkov and G. Grüner, “Introduction." Charge Density Waves in Solids, Eds. L.P. Gor'kov and G. Grüner, Elsevier Science Publishers.
212. J. Carini, L. Drabeck, G. Grüner, “The Surface Impedance of High-Tc Superconductors," Modern Phys. Lett. B 3, No. 1.
213. G. Grüner, “Properties and Parameters of the Superconducting Oxides," Physica C162-164, North Holland 8-11.
1990
214. P.C. Canfield, J.D. Thompson, G. Grüner, “Unifying Trends Found for the VNO2N-1 Series by the Application of Hydrostatic Pressure," Phys. Rev. B 40, 4850.
215. R.S. Kwok, G. Grüner, and S.E. Brown, “Fluctuations and Thermodynamics of the Charge Density Wave Transition," Phys. Rev. Lett. 65, 365. 16 216. G. Grüner and W.P. Beyermann, “The Electrodynamics of Correlated Metals," Physica, North Holland Publ. Co. B 163
217. D.W. Cooke, E.R. Gray, H.H.S. Javadi, R.J. Houlton, B. Rusnak, E.A. Meyer, P.N. Arendt, N. Klein, G. Müller, S. Orback, H. Piel, L. Drabeck, G. Grüner, J.Y. Josefowicz, D.B. Rensch, F. Krajenbrink, “Frequency Dependence of the Surface Resistance in High Temperature Superconductors," Solid State Comm. 73, 297.
218. A. Inam, X.D. Wu, L. Nazar, M.S. Hedge, C.T. Rogers, T. Venkatesan, R.W. Simon, K. Daly, H. Padamsee, J. Kirchgessner, D. Moffat, D. Rubin, Q.S. Shu, D. Kalokitis, A. Fathy, V. Pendrick, R. Brown, B. Brycki, E. Belohoubek, L. Drabeck, G. Grüner, R. Hammond, F. Gamble, B.M. Lairson, J.C. Bravman, “Microwave Properties of
Highly Oriented YBa2Cu3O7 Thin Films," Appl. Phys. Lett. 56, 1178.
219. L. Drabeck, K. Holczer, G. Grüner, D.J. Scalapino, “Ohmic and Radiation Losses in superconducting films," J. Appl. Phys. 68, (2) 892.
220. L. Drabeck, K. Holczer, G. Grüner, J.J. Chang, D.J. Scalapino, T. Venkatesan. “An
Experimental Investigation of YBa2Cu3O7 Films at Millimeter Wave Frequencies," J. of Superconductivity 3, 317.
221. P.C. Canfield, J.D. Thompson, G. Grüner, “Pressure-temperature Phase Diagrams for the Low Temperature Ground States of VNO2N-1 Materials," Physica, North Holland B163, 191-193. (3 pages)
222. W.B. Beyermann, A.M. Awasthi, G. Grüner, Y. Dalichaouch, M.B. Maple,
“Dynamical Mass Enhancement in CeAl3," Physica, North Holland B163, 584-586
223. D. Anselmetti, R. Wiesendanger, H.J. Guntherodt, G. Grüner, “Atomic- scaleSurface Investigations of K0.3MoO3 by Scanning Tunneling Microscopy," Europhys. Lett. 12, 241-245. (5 pages)
224. S. Donovan, Y. Kim, B. Alavi, L. Degiorgi, G. Grüner, “The Optical Spectrum of Charge Density Wave Condensates," Solid State Comm. No. 9 75, 721-724. (5 pages).
225. D. Quinlivan, Y. Kim, K. Holczer, G. Grüner, F. Wudl, “Spin Density Wave
Dynamics in (tetramethyltetraselenofulvalene)2PF6, (TMTSF)2PF6," Phys. Rev.Lett. 65, 1816.
226. G. Grüner, “Surface Impedance of High- Tc Superconductors," in Electronic Properties of High-Tc Superconductors and Related Compounds, Eds. H. Kuzmany, M. Mehring, J. Fink, Springer Series in Solid State Sciences 99, Springer Verlag. (5 pages)
1991
227. K.H. Young, McD. Robinson, G.V. Negrete, T. Yamashita, T. Hirai, H. Suzuki, H. Kurosawa, L. Drabeck, G. Grüner, “Microstructure and Microwave Propertiesof YBCO
Thin Films Grown on MgO and SrTiO3 by CVD," J. Mater. Res., Vol. 6, No. 11, 2259. 17
228. L. Drabeck, K. Holczer, G. Grüner, J.J. Chang, D.J. Scalapino, A. Inam, X.D. Wu,
L. Nazar, T. Venkatesan, “Surface Resistance of Laser Deposited YBa2Cu3O7 Films," Phys. Rev. B 42, 10020.
229. K. Holczer, D. Quinlivan, G. Grüner, J.J. Chang, D. Scalapino, F. Wudl, “Temperature Dependence and Anisotropy of the Penetration Depth in K-(BEDT-
TTF)2Cu(NCS)2,"Solid State Comm. 76, 499.
230. O. Klein, K. Holczer, G. Grüner, J.J. Chang, D. Scalapino, F. Wudl, “The
Electrodynamics of the Superconducting State of K-(BEDT-TTF)2Cu(NCS)2," International Conference on Organic Superconductivity, Lake Tahoe, CA, May 20-24, 1990. Organic Superconductors, Eds. V. Kresin, W.A. Little, Planum Press, N.Y.
231. M.M. Eddy, J.Z. Sun, R.D. Hammond, L. Drabeck, I.B. Ferreira, K. Holczer, G. Grüner, “Surface Resistance Studies of Laser Deposited Superconducting
Tl2Ba2CaCu2O8 Films," J. of Appl. Phys. 70, 496.
232. T.W. Kim, S. Donovan, G. Grüner, A. Philipp, “Charge Density Wave Dynamics in (Ta1-xNbxSe4)2I Alloys," Phys. Rev. B 43, 6315. (11 pages)
233. G. Sparn, J.D. Thompson, S.M. Huang, R.B. Kaner, F. Diederich, R.L. Whetten, G. Grüner, K. Holczer, “Pressure Dependence of Superconductivity in Single-phase
K3C60," Science 252, 1829. (3 pages)
234. K. Holczer, O. Klein, G. Grüner, J.D. Thompson, F. Diederich, R.L. Whetten,
“Critical Magnetic Fields in the Superconducting State of K3C60," Phys. Rev. Lett. 67, 271.
235. P.M. Allemand, K.C. Khemani, A. Koch, F. Wudl, K. Holczer, S. Donovan, G.
Grüner, J.D. Thompson, “Organic Molecular Soft Ferromagnetism in a Fullerene C60," Science 253, 301.
236. Y.J.Uemura, A. Keren, L.P. Le, G.M. Luke, B.J. Sternlieb, W.D. Wu, R.L. Whetten, S.M. Huang, S. Lin, R.B. Kaner, F. Diederich, S. Donovan, G. Grüner, K.
Holczer, “Magnetic Field Preparation Depth in K3C60 Measured by Muon Spin Relaxation," Nature 352, 605.
237. G. Grüner, “The Electrodynamics of Spin Density Waves," Synthetic Metals 43, 3, 3767.
238. R.S. Kwok, G. Grüner, S.E. Brown, “Fluctuations and Thermodynamics of the
Charge Density Wave Phase Transition of K0.3MoO3," Synthetic Metals 43, 3, 3845-3848.
239. S. Donovan, K. Holczer, and G. Grüner, “Search for a Collective Mode Resonance in (TMTSF)2NO3," Synthetic Metals 43, 3, 3877-3880.
18 240. O.Klein, K. Holczer, G. Grüner, J.J. Chang, F. Wudl, “Electrodynamics of the
Superconducting State of K-(BEDT-TTF)2Cu(NCS)2," Phys. Rev. Lett. 66, 782.(4 pages)
241. K. Maki, G. Grüner, “Effect of Coulomb Interaction on Spin Density Wave Dynamics,"Phys. Rev. Lett. 66, 782. (4 pages)
242. G. Mihály, Y. Kim, G. Grüner, “Dielectric Relaxation of the Pinned Spin Density
Wave in (TMTSF)2PF6," Phys. Rev. Lett. 66, 2806. (4 pages)
243. K. Holczer, L. Forro, L. Mihály, G. Grüner, “Observation of the Conductivity
Coherence Peak in Superconducting Bi2Sr2CaCuO8 Single Crystal," Phys. Rev. Lett. 67, 152.
244. L. Degiorgi, B. Alavi, G. Mihály, G. Grüner, “Complete Excitation Spectrum of
Charge Density Waves: Optical Experiments on K0.3MoO3," Phys. Rev. B 44, 7808.(12 pages)
245. L. Degiorgi, G. Grüner, “Pinned and Bound Collective Mode State in Charge Density Wave Condensates," Phys. Rev. B 44, 820.
246. Y. Kim, L. Degiorgi, B. Alavi, G. Grüner, “The Complete Frequency Dependent Response of Charge Density Wave Condensates," Synthetic Metals 41-43, 3959. (4 pages)
247. L. Degiorgi and G. Grüner, “Bound Collective Mode State of Charge Density Wave Condensates," Europhysics Lett. 16, 97.
248. A. Philipp, T.W. Kim, M. Maki, G. Grüner, “Linear and Nonlinear ac Response of
(Ta1-xNbxSe4)2I Alloys," Synthetic Metals 41-43, 4041-44.
249. G. Grüner, “High Tc Superconductors at Microwave Frequencies," in Phenomenology and Applications of High Temperature Superconductors," Ed. M. Iniu, et al. Addison-Wesley. (21 pages)
250. P.M. Allemand, K.C. Khemani, A. Koch, F. Wudl, K. Holczer, S. Donovan, G.
Grüner, J.D. Thompson, “Organic Molecular Soft Ferromagnetism in a Fullerene C60," Science 253. (3 pages)
251. G. Grüner and K. Maki, “The Dynamics of Spin Density Waves," Comments Cond.Mat. Phys. 15, No. 3, 145 (18 pages)
252. G. Mihály, Y. Kim, and G. Grüner, “Crossover in Low Temperature Spin Density Wave Transport," Phys. Rev. Lett. 67, 2713.
19 1992
253 W.P. Beyermann, M.F. Hundley, J.D. Thompson, R.N. Diederich, G. Grüner,
“Low Temperature Specific Heat of C60," Phys. Rev. Lett. 68, 2046.(4 pages)
254. W.H. Wong, M.E. Hanson, W.G. Clark, G. Grüner, J.D. Thompson, R.L. Whetten, S.M. Huang, R.B. Kaner, F. Diederich, P. Pettit, J.J. Andre, K. Holczer, “Normal State
Magnetic Properties of K3C60," Europhys. Lett. 18, 1. (1 page)
255. O. Klein, K. Holczer, G. Grüner, “Klein, Holczer, Grüner Reply,"Phys. Rev. Lett. 68, 2407. (1 page)
256. O. Klein, K. Holczer, G. Grüner, G.A. Emelchenko, “Conductivity Coherence
Peak in YBa2Cu3O7," J. Phys. I. France 2, 517. (6 pages)
257. L. Degiorgi and G. Grüner, “Fluctuation Conductivity Above the Charge Density
Wave Transition in K0.3MoO3," J. Phys. I. France 2, 523. (6 pages)
258. S. Donovan, L. Degiorgi and G. Grüner, “Electodynamics of One Dimensional
Metals: Optical Experiments on (TMTSF)2PF6," Europhys. Lett. 19, 5.
259. I.B. Ferreira, A.M. Awasthi, L. Degiorgi, G. Grüner, Y. Dalichaouch, M.B.
Maple,”The Electrodynamics of the Heavy Fermion State of CeAl3," Solid State Comm. 83, 1.
260. L. Degiorgi, G. Grüner, P. Wachter, S.M. Huang, J. Wiley, R.L. Whetten, R.B.
Kaner, K. Holczer, F.N. Diederich, “Electrodynamic Response of Rb3C60," Phys. Rev. B 46, 11250.
261. W.P. Beyermann, J.D. Thompson, M.F. Hundley, G. Grüner, Reply to the
Comment, `Low Temperature Specific Heat of C60," Phys. Rev. Lett. 69, 2737.
262. L. Degiorgi, P. Wachter, G. Grüner, S.M. Huang, J. Wiley, R.B. Kaner, “Optical
Response of the Superconducting K3C60 and Rb3C60," Phys. Rev. Lett. 69, 2987.
263. O. Klein, G. Grüner, S.M. Huang, J.B. Wiley, R.B. Kaner, “Electrical Resistivity of K3C60," Phys. Rev. B 46, 11247.
264. G. Sparn, J.D. Thompson, R.L. Whetten, S.M. Huang, F. Diederich, G. Grüner, K.
Holczer, “Pressure and Field Dependence of Superconductivity in Rb3C60," Phys. Rev.Lett. 68, 1228.
265. S.E. Brown, K. Bartholomew, B. Alavi, G. Grüner, “Electrical Field Dependence of Young's Modulus in the Spin Density Wave State of (TMTSF)2PF6," Phys. Rev. B 46, 10483.
20 266. S.E. Brown, B. Alavi, G. Grüner, K. Bartholomew, “Softening of Young's
Modulus and Collective Spin Density Wave Transport in (TMTSF)2PF6 (where TMTSF is tetramethyltetraselenafulvalene)," Phys. Rev. B 46, 10483.
1993
267. S. Donovan, Y. Kim, L. Degiorgi, and G. Grüner, “Phason Excitations in the SDW
State of (TMTSF)2PF6," J. de Physique I, France 3, 1493-1498.
268. L.P. Le, A. Keren, G.M. Luke, B.J. Sternlieb, W.D. Wu, and Y.J. Uemura, J.H. Brewer, and T.M. Riseman,R.V. Upasani, L.Y. Chiang, W. Kang, and P.M. Chaikin, T.
Csiba and G. Grüner, “Muon-spin-rotation and Relaxation Studies in (TMTSF)2X Compounds," Phys. Rev. B 48, 7284-7296.
269. M. Dressel, S. Bruder, and G. Grüner, K.D. Carlson, H.H. Wang, and J.M. Williams, `Low-temperature Microwave Surface Impedance of the Conventional Organic
Superconductor κ-(BEDT-TTF)2Cu(NCS)2" Phys. Rev.B Rapid Communications 48, 9906-9909.
270. A.M. Awasthi, L. Degiorgi, and G. Grüner, Y. Dalichaouch, and M.P. Maple,
“Complete Optical Spectrum of CeAl3," Phys. Rev. B 48, 10692-10700.
271. M. Dressel, L. Degiorgi, O. Klein, and G. Grüner, “The Electrodynamics of Organic Superconductors," J.Phys. and Chem. of Solids 54, 1411-1426.
272. L. Degiorgi and G. Grüner, “The Electrodynamics of the Charge Density Wave Condensate," Synthetic Metals, 55-57, 2688-2695.
273. O. Klein, S. Donovan, M. Dressel, and G. Grüner, “Microwave Cavity Perturbation Technique: Part I: Principles," International Journal of Infrared and Millimeter Waves, 14, 2423-2457.
274. S. Donovan, O. Klein, M. Dressel, K. Holczer, and G. Grüner, “Microwave Cavity Perturbation Technique: Part II: Experimental Scheme," International Journal of Infrared and Millimeter Waves, 14, 2459-2487.
275. M. Dressel, O. Klein, S. Donovan, and G. Grüner, “Microwave Cavity Perturbation Technique: Part III: Applications," International Journal of Infrared and Millimeter Waves, 14, 2489-2517.
276. L. Degiorgi, E.J. Nicol, G. Grüner, P. Wachter, and R.B. Kaner, “Optical Evidence of the Weak Coupling Pairing Mechanism in the Superconductors K3C60 and Rb3C60," ICMAS-93, Superconducting Materials, Eds. J. Etoumeau, J.B. Torrance, and H. Yamauchi, p. 391. not available
21 1994
277. G. Grüner, “The Dynamics of Spin-density Waves," Reviews of Modern Physics, Vol. 66, No. 1, 1-24.
278. L. Degiorgi, M. Dressel, G. Grüner, P. Wachter, N. Sato, and T. Komatsubara,
“Optical Investigation of the Electrodynamic Response of UPd2Al3," Europhys.Lett., 25, 311-316.
279. S. Donovan, Y. Kim, L. Degiorgi, M. Dressel, G. Grüner, and W. Wonneberger, “Electrodynamics of the Spin-density-wave Ground State: Optical Experiments on
(TMTSF)2 PF6," Phys. Rev. B 49, 3363-3377.
280. L. Degiorgi, E.J. Nicol, O. Klein, G. Grüner, P. Wachter, S.-M. Huang, J. Wiley, and R.B. Kaner,”Optical Properties of the Alkali-metal-doped Superconducting
Fullerenes: K3C60 and Rb3C60," Phys. Rev. B 49, 7012-7025.
281. M. Dressel, G. Grüner, J.P. Pouget, A. Breining, and D. Schweitzer, “Field and Frequency Dependent Transport in the Two-dimensional Organic Conductor κ-(BEDT-
TTF)2I3," J. Phys. I France 4, 579-594.
282. W.H. Wong, M.E. Hanson, W.G. Clark, B. Alavi, and G. Grüner, “Restoring Force and Displacement of the Pinned Spin Density Wave Condensate in (TMTSF)2PG6," Phys. Rev. Lett. 72, 2640-2643.
283. S. Brown and G. Grüner, “Charge and Spin Density Waves," Scientific American, 270, No. 4, 28-34.
284. L. Degiorgi, H.R. Ott, M. Dressel, G. Grüner, and Z. Fisk, “Optical Probing of the
Antiferromagnetic Phase Transitions in the Heavy-electron Compounds U2Zn17 and UCu5," Europhys. Lett., 26 (3), 221-226.
285. L. Degiorgi, G. Grüner, K. Kim, R.H. McKenzie, and P. Wachter, “Optical Probing of Thermal Lattice Fluctuations in Charge-density-wave Condensates," Phys. Rev. B Rapid Communications 49, 14754-14757.
286. B.P. Gorshunov, A.A. Volkov, G.V. Kozlov, L. Degiorgi, A. Blank, T. Csiba, M. Dressel, Y. Kim, A. Schwartz, and G. Grüner, “Charge-density-wave Paraconductivity in
K0.3Mo03," Phys. Rev. Lett. 73, 308-311.
287. M. Dressel, L. Degiorgi, G. Grüner, P. Wachter, N. Sato, T. Komatsubara, and Y.
Uemura, “Optical Investigations of the Electrodynamics of UPd2Al3," Physica B 199 & 200, 173-175.
288. O. Klein, E.J. Nicol, K. Holczer and G. Grüner, “Conductivity Coherence Factors in Conventional Superconductors Nb and Pb," Phys. Rev. B 50, 6307-6316.
22 289. L. Degiorgi, M.B. Hunt, H.R. Ott, M. Dressel, B.J. Feenstra, G. Grüner, Z. Fisk, and P. Canfield, `Optical Evidence of Anderson-Mott Localization in FeSi," Europhys. Lett., 28 (5), 341-346.
290. Y.M. Kim, R. Gaál, B. Alavi, and G. Grüner, “Effect of Impurities on the Low- temperature Nonlinear Spin-density-wave Transport," Phys. Rev. B 50, 13867-13870.
291. M. Dressel, O. Klein, G. Grüner, K.D. Carlson, H.H. Wang, and J.M. Williams,
“The Electrodynamics of the Organic Superconductors κ - (BEDT-TTF)2Cu(NCS)2 and κ - (BEDT-TTF)2Cu [N(CN)2]Br," Phys. Rev. B 50, 13603-13615.
292. L. Degiorgi, E.J. Nicol, G. Grüner, P. Wachter, and R.B. Kaner, “Optical Probing and Eliashberg Calculation of the Superconducting State in K3C60 and Rb3C60," Mol. Cryst. Liq. Cryst. 256, 267. not available
293. L. Degiorgi, H.R. Ott, G. Grüner, M. Dressel, and Z Fisk, “Influence of Magnetic Order on Optical Properties of the Heavy-electron Antiferromagnets in Strongly Correlated Electronic Materials," Eds. K. Bedell,Z. Wang, D. Meltzer, A. Balatsky, and E. Abrahams, Addison-Wesley Publ. Company, p. 96. not available
1995
294. L. Degiorgi, H.R. Ott, M. Dressel, G. Grüner, C. Geibel, F. Steglich, and Z. Fisk, “Optical Investigation of the Antiferromagnetic Phase Transitions in Heavy-electron Compounds, Physica B 206-207, 441-443.
295. St. Thieme, L. Degiorgi, G. Grüner, and P. Wachter, “Thermal Lattice Fluctuations in (TaSe4)2I," Synth. Metals 70, 1305.
296. A. Schwartz, M. Dressel, B. Alavi, A. Blank, S. Dubois, G. Grüner, B.P. Gorshunov, A.A. Volkov, G.V. Kozlov, S. Thierne, L. Degiorgi, and F. Levy, “Fluctuation Effects on the Electrodynamics of Quasi One-Dimensional Conductors Above the Charge-density-wave Transition," Phys. Rev. B 52, 5643-5652.
297. M. Dressel, O. Klein, S. Bruder, G. Grüner, K.D. Carlson, H.H. Wang, and J.M. Williams,”Surface Impedance Studies on the Electrodynamical Response of Organic Superconductors,", Synthetic Metals 70, 895-898.
298. M. Dressel, G. Grüner, K.D. Carlson, H.H. Wang, and J.M. Williams, “Studies of the Microwave Resistivity of κ - (BEDT-TTF)2Cu[N4(CN)2]Cl," Synthetic Metals, 70, 927-928.
299. M. Dressel, G. Grüner, J.P. Pouget, A. Breining, and D. Schweitzer, “Non-linear
Transport in α-(BEDT-TTF)2I3,", Synthetic Metals 70, 929-930.
23 300. Y.M. Kim, G. Mihály, H.W. Jiang, and G. Grüner, “The Low Temperature Spin
Density Wave Transport: Effects of Magnetic Field in (TMTSF)2PF6 and Disorder in (TMTSF)2X's," Synthetic Metals 70, 1287-1290.
301. M. Dressel, A. Schwartz, A. Blank, T. Csiba, G. Grüner, B.P. Gorshunov, A.A. Volkov, G.V. Kozlov, and L. Degiorgi, “Charge-density-wave Paraconductivity," Synthetic Metals 71, 1893-1894.
302. L. Degiorgi and St. Thieme, B. Alavi and G. Grüner, R.H. McKenzie, K. Kim, and F. Levy, “Fluctuation Effects in Quasi-one-dimensional Conductors: Optical Probing of Thermal Lattice Fluctuations," Phys. Rev. B 52, 5603-5610.
303. A. Schwartz, M. Dressel, A. Blank, T. Csiba, and G. Grüner, A.A. Volkov, B.P. Gorshunov, and G.V. Kozlov, “Resonant Techniques for Studying the Complex Electrodynamic Response of Conducting Solids in the Millimeter and Submillimeter Wave Spectral Range," Rev. Sci. Instrum., Vol. 66, No. 4, 2943-2953.
1996
304. M. Dressel and G. Grüner, “Frequency Dependent Conductivity in Organic Superconductors," in Mol. Cryst. Liq. Cryst., Vol. 284, 107-119.
305. G. Grüner, “Density Waves in Linear Chain Compounds," Physics and Chemistry of Low-Dimensional Inorganic Conductors, NATO ASI Series B, Vol. 354, 101-114.
306. L. Degiorgi, St. Thieme, B. Alavi, G. Grüner, R.H. McKenzie, K. Kim, and F. Lévy, “Thermal Lattice Fluctuations in Quasi One-Dimensional Conductors: Optical Experiments," Physics and Chemistry of Low-Dimensional Inorganic Conductors, NATO ASI Series B, Vol. 354, 337-344.
307. L. Degiorgi, M. Dressel, A. Schwartz, B. Alavi, and G. Grüner, “Direct
Observation of the Spin-Density-WaveGap in (TMTSF)2PF6," Phys. Rev. Lett. 76, (no.20), APS, 13 May 1996. p.3838-41.
308. M. Dressel, A. Schwartz, G. Grüner, and L. Degiorgi, “Deviations from Drude Response in Low-Dimensional Metals: Electrodynamics of the Metallic State of
(TMTSF)2PF6," Phys. Rev. Lett. 77, (no.2), APS, 8 July 1996. p.398-401.
309. M. Dressel, O. Klein, S. Donovan, G. Grüner, “High Frequency Resonant Techniques for the Study of the Complex Electrodynamic Response in Solids," Ferroelectrics 176, (no.1-4), p.285-308.
310. A. Schwartz, M. Dressel, and G. Grüner, B.P. Gorshunov, A.A. Volkov, and G.V. Kozlov, “Evidence of Charge-Density-Wave Fluctuations in the Low Frequency Optical
Conductivity of K0.3Mo03 and (TaSe4)2I,"Ferroelectrics 176, (no.1-4), p.309-19.
24 311. S. Donovan, A. Schwartz, M. Dressel, Y. Kim, O. Tráetteberg, R. Gáal, G. Grüner, “Effects of Anion Disorder on the Electrodynamical Response of A Spin Density Wave," Ferroelectrics 176 (no.1-4), p.343-52.
312. G. Grüner, “The Electrodynamics of Low Dimensional Metals," Journal de Physique I, 6, 1711.
1997
313. G. Mihály, A. Virosztek, and G. Grüner, “Thermal and Optical Gaps in Nearly One-Dimensional Compounds," Phys. Rev. B 55, 13456
314. L. Degiorgi, St. Thieme, H.R. Ott, M. Dressel, G. Grüner, Y. Dalichaouch, M.B. Maple, and Z. Fisk, “The Electrodynamic Response of Heavy-Electron Materials with Magnetic Phase Transitions," Z. Phys. B 102, 367
315. G. Grüner, “The Electrodynamics of Interacting Electrons in Anisotropic Metals," Physica B 230, 966
316. M. Dressel, G. Grüner, J.E. Eldridge, J.M. Williams, “Optical Properties of Organic Superconductors" Synthetic Metals 85, 1503
317. A. Schwartz, S. Donovan, M. Dressel, L. Degiorgi, and G. Grüner, “Normal State Electrodynamics of Compounds with Charge- and Spin-Density-Wave Ground States," Physica B 230, 1005-1007.
318. M. Dressel, L. Degiorgi, J. Brinckmann, A. Schwartz, and G. Grüner, “Optical Response of the Spin-Density-Wave Ground State," Physica B 230, 1008
319. S. Donovan, A. Schwartz, and G. Grüner, “Observation of an Optical Pseudogap in
UPt3," Phys. Rev. Lett.79,1401
320. A. Schwartz, S. Donovan, M. Dressel, L. Degiorgi, and G. Grüner, “Normal State Electrodynamics Properties of Charge- and Spin-Density-Wave Compounds," Synthetic Metals 86, 2129-2130.
321. S. Donovan, M. Dressel, L. Degiorgi, A. Schwartz, A. Virosztek, and G. Grüner,
“Electrodynamic Properties of (TMTSF)2PF6," Synthetic Metals 86, 2181
1998
322. Y. Suzumura, M. Tsuchiizu and G. Grüner, “Confinement of interchain hopping by umklapp scattering in two coupled chains," Physical Review B, 57, 15040
323. G. Grüner,”Pseudogaps and correlations in metals with electron-electron interactions," Physica B 244, 70 25
324. V. Vescoli, L. Degiorgi, W. Henderson, G. Grüner, K.P. Starkey and L.K. Montgomery , “Dimensionality-Driven Insulator-to-Metal Transition in the Bechgaard Salts," Science, 281, 1181
325. G. Grüner, “Waveguide Configuration Optical Spectroscopy”,in Millimeter and Submillimeter Wave Spectroscopy of Solids, edited by G. Grüner, Series: Topics in Applied Physics, Vol. No. 74, Ch. 4., 111-166, Springer Verlag, Berlin
326. H-L Lee, J.P. Carini, D.V. Baxter, and G. Grüner, “Temperature-Frequency Scaling in Amorphous Niobium-Silicon near the Metal-Insulator Transition”,Physical Review Letters, 80, 4261
327. Schwartz, A., Dressel, M., Grüner, G., Vescoli, V., Degiorgi, L., Giamarchi, T.
“On-chain electrodynamics of metallic (TMTSF)2X salts: Observation of Tomonaga- Luttinger liquid response”. Physical Review B, 58, 1261
328. W. Henderson and G. Grüner,”Resonant Measurement Techniques Using Backward Wave Oscillators," International Conference on Millimeter and Submillimeter Waves, San Diego, July 1998.
329. V. Vescoli, L. Degiorgi, B. Alavi and G. Grüner, “The spin-density-wave gap in
(TMTSF)2ClO4", Physica B 244, 121
330. G. Grüner, The Electrodynamics of Heavy Fermions in “Physical Phenomena at High Magnetic Fields”, Eds., Z. Fisk, L. Gorkov and R. Schrieffer, World Scientific, Singapore, p. 142-147
1999
331. Y. Suzumura, M. Tsuchiizu and G. Grüner, “Confinement by umklapp scattering in two coupled chains,“ Synthetic Metals,.103, (1-3),.2191-2.
332. W. Henderson, V. Vescoli, P. Tran, L. Degiorgi and G. Grüner, “Anisotropic
Electrodynamics of Low Dimensional Metals: Optical Studies of (TMTSF)2CIO4,“ The European Physical Journal B 11, 365
333. V. Vescoli, L. Degiorgi, M. Dressel, A. Schwartz, W. Henderson, B. Alavi, G.
Grüner et al, “The spin-density-wave gap in the Bechgaard salts (TMTSF)2X - Phys. Rev. B 60 (11), 8019
334. M. Dressel, B.P. Gorshunov, N.E. Sluchanko, A.A. Volkov, W. Henderson, G.
Grüner, A. Loidl and S. Kunii, “Dielectric Response of SmB6 in the Millimeter Wave Range,“ International Conference on Solid State Spectroscopy, Physica Status Solidi (b), 215, 161
26 2000
335. F. Zwick, M. Grioni, G. Margaritondo, V. Vescoli, L. Degiorgi, B. Alavi and G. Grüner, “The transition from a pseudogapped metal to an insulator: photoemission and optics of (TMTSF)2ReO4“ Solid State Comm..113 (4), 179-84
336. V. Vescoli, F. Zwick, W. Henderson, L. Degiorgi, M. Grioni, G. Grüner, and L.K. Montgomery, "Optical and photoemission evidence for a Tomonaga-Luttinger liquid in the Bechgaard salts," Eur. Phys. J. B 13, 503
337. V. Vescoli, F. Zwick, J. Voit, H. Berger, M. Zacchigna, L. Degiorgi, M. Grioni, and G. Grüner, "Dynamical properties of the one-dimensional band insulator (NbSe4)3I", Phys. Rev. Lett. 84, 1272 - 1275
338. H.-L. Lee, J.P. Carini, D.V. Baxter, W. Henderson and G. Grüner, "Quantum- Critical Conductivity Scaling for a Metal-Insulator Transition ", Science 287, 633 – 636 (2000)
339. N. E. Sluchanko, V. V. Glushkov, B. P. Gorshunov, S. V. Demishev, M. V. Kondrin, A. A. Pronin, A. A. Volkov, A. K. Savchenko, G. Grüner, Y. Bruynseraede, V.
V. Moshchalkov and S. Kunii, “Intragap states in SmB6”, Phys. Rev. B 61 (15),9906-9909
340. P. Tran, B. Alavi, and G. Grüner, “Charge Transport along the λ DNA Double Helix”, Phys Rev Lett 85, 1564-1567
341. J. Voit, L. Parfetti, F. Zwick, G. Margaritondo, G. Grüner, H. Hochst and M. Grioni, “Electronic Structure of solids with Competing Periodic Potentials”, Science 290, 501-503
342. R. Bruinsma, G. Grüner, M.R. D'Orsogna, and J.Rudnick, “Fluctuation-facilitated charge migration along DNA” Phys Rev Lett 85,4393
343. Kwanghee Lee, Reghu Menon, A. J. Heeger, K. H. Kim, Y. H. Kim, A. Schwartz, M. Dressel, and G. Grüner, “Density-wave charge dynamics in conducting polypyrrole”, Phys. Rev. B 61, 1635-1638 (2000)
2001
344. G. Grüner, “Pseudogaps in nearly one-dimensional metals”, Journal of Phys and Chem of Solids 62, 89-92
345. L. Degiorgi, F.B.B. Anders and G. Grüner, "Charge excitations in heavy electron metals", The European Physical Journal B 19 , 167-170
346. Helgren E, Grüner G, Ciofalo MR, Baxter DV, Carini JP. “Measurements of the complex conductivity of NbxSi1-x alloys on the insulating side of the metal-insulator transition”, Physical Review Letters, 87, 116602/1-4. (2001)
27 2002
347. M. Dressel, N. Kasper, K. Petukhov, B. Gorshunov, G. Grüner, M. Huth, and H. Adrian, “Nature of Heavy Quasiparticles in Magnetically Ordered Heavy Fermions
UPd2Al3 and UPt3”, Phys. Rev. Lett. 88, 186404 (2002)
348. P, Tran, S. Donovan, G. Grüner, “Charge excitation spectrum in UPt3”, Physical Review B-Condensed Matter.65, 205102/1-8 (2002)
349. E. Helgren, N. P. Armitage, and G. Grüner, “Electrodynamics of a Coulomb Glass in n-Type Silicon”, Phys. Rev. Lett. 89, 246601 (2002)
2003
350. N.P. Armitage, E. Helgren, G. Grüner, Taxonomy of Electron Glasses, 189-197, in Concepts in Electron Correlation, Proceedings of the ARW NATO Workshop, Hvar, Croatia, October 2002, eds. A.C. Hewson and V. Zlatic (Kluwer Academic Publishers, The Netherlands, 2003)
351. A. Montrichok, G. Grüner, and G. Zocchi, “Trapping intermediates in the melting transition of DNA oligomers”,Europhys. Lett. 62, 452 (2003)
352. Alexander Star, Jean-Christophe P. Gabriel, Keith Bradley, and George Grüner, “Electronic Detection of specific Protein Binding Using Nanotube FET Devices”,Nano Lett. 3, 459-463 (2003
353. Keith Bradley, John Cumings, Alexander Star, Jean-Christophe P. Gabriel, and George Grüner, “Influence of Mobile Ions on Nanotube Based FET Devices”,Nano Lett. 3, 639-641 (2003)
354. K. Bradley, J-C P Gabriel and G. Grüner, “Flexible Nanotube Electronics”, Nano Lett 3,1353 (2003)
355. K. Bradley, J.-C. P. Gabriel, M. Briman, A. Star, G. Grüner, , “Charge Transfer from Ammonia Physisorbed on Nanotubes”, Phys. Rev. Lett. 91, 218301
356. Star, A., Han, T.-R., Gabriel, J.-C. P., Bradley, K., Grüner, G., “Interaction of Aromatic Compounds with Carbon Nanotubes: Correlation to the Hammett parameter of the substituent and measured carbon nanotube FET response”,Nano Lett. 3, 1421-1423.
357. Bradley, K., Gabriel, J.-C. P., Star, A., Grüner, G., “Short-Channel Effects in Contact-Passivated Nanotube Chemical Sensors”, Appl. Phys. Lett. 83, 3821-3823.
358. Star, A., Bradley, K., Gabriel, J.-C., Grüner, G., “Nano-Electronic Sensors: Chemical Detection Using Carbon Nanotubes”, Pol. Mater.: Sci. Eng. 89, 204.
28 359. Star, A., Han, T.-R., Joshi, V., Grüner, G.,“Polymer Coatings of Carbon Nanotube Sensors”, Polymer Prep., 44, 201.
360. J.R. Stetter, K. Bradley, J. Cumings, J-C Gabriel, G. Gruner and A. Star, “Nano- Electronic Sensors - Practical Device Designs for Sensors”, in Nanotech 2003 Vol. 3, Chapter 7: Nano Devices and Systems, 313 - 316
2004
361. N.P. Armitage, M. Briman, G. Grüner, “Charge Transfer and Charge Transport on the Double Helix”, Phys. Stat. Sol. 241, 69-75 (2004).
362. N.P. Armitage, J-C P. Gabriel and G. Grüner, “Quasi-Langmuir–Blodgett thin film deposition of carbon nanotubes”, J. Appl. Phys. 95, 3228
363. Bradley, K., Briman, M., Star, A., Grüner, G., “Charge Transfer from Adsorbed Proteins”, Nano Lett. 4, 253-256
364. Briman, M., Armitage, N. P., Helgren, E., Grüner, G., “Dipole Relaxation Losses in DNA”, Nano Lett., 4, 733 (2004)
365. A. Star, Y. Lu, K. Bradley, G. Grüner, “Nanotube optoelectronic memory devices”, Nano Lett 4, 1587–1591 (2004)
366. A. Star, V. Joshi, T.-R. Han, M. V. P. Altoé, G. Grüner, J. F. Stoddart, “Electronic detection of the enzymatic degradation of starch”, Org. Lett. 6, 2089 – 2092
367. A. Star, T.-R. Han, V. Joshi, J.-C. P. Gabriel, G. Grüner, “Nanoelectronic carbon dioxide sensors”, Adv. Mater 16, 2049-2052
368. L. Hu, D.S. Hecht and G. Grüner, “Percolation in Transparent and Conducting Carbon Nanotube Networks”, Nano Letters 4, 2513-2517 (2004)
369. E. Helgren, N.P. Armitage, G. Gruner., "The Frequency Dependent Conductivity of Electron Glasses", Phys. Rev. B, 69, 014201 (2004).
2005
370. K. Bradley, A. Davis, J-C. P. Gabriel, and G. Grüner, “Integration of Cell Membranes and Nanotube Transistors”, Nano Lett 5, 841-845 (2005)
371. E. Artukovic, M. Kaempgen, D. S. Hecht, S. Roth, G. Grüner, “Transparent and Flexible Carbon Nanotube Transistors”, Nano Lett. 5. 757-760 (2005)
2006
372. G. Grüner “Carbon Nanotube Transistors for Biosensing Applications”, Analytical and Bioanalytical Chemistry 384, 322-335 (2006) 29
373. Y. Zhou, L. Hu and G. Grüner, “A method of printing carbon nanotube thin films”, Appl. Phys. Lett. 88, 123109 (2006)
374. Michael W.Rowell, Mark A.Topinka, Michael D. McGehee, Hans-Juergen Prall, Gilles Dennler, Niyazi Serdar Sariciftci, Liangbing Hu, George Grüner, “Organic solar cells with carbon nanotube network electrodes,” Appl. Phys. Lett., 88, 233506 (2006)
375. M. Briman, K. Bradley, G. Grüner, “Source of 1/f noise in carbon nanotube devices”, Journal of Applied Physics 100, 013505 (2006)
376. G. Grüner, “Carbon nanotube films for transparent and plastic electronics”, Journal of Materials Chemistry, 16, 3533-3539 (2006)
377. David S.Hecht, Robert J. A. Ramirez, Mikhail Briman, Erika Artukovic, Kelly S.Chichak, J. Fraser Stoddart, George Grüner, “Bioinspired detection of light using a porphyrin-sensitized single-wall nanotube field effect transistor”, Nano Letters, 6, 2031- 2036 (2006)
378. David Hecht, Liangbing Hu, George Grüner, “Conductivity scaling with bundle length and diameter in single walled carbon nanotube network”, Applied Physics Letters, 89, 133112 (2006)
379. J. Li, L. Hu, L. Wang, Y. Zhou, G. Grüner, and T. J. Marks, “Organic light- emitting diodes having carbon nanotube anodes”, Nano Letters, 6, 2472-2477 (2006)
2007
380. David S.Hecht, Liangbing Hu George, Grüner, “Electronic properties of carbon nanotube/fabric composites”, Current Applied Physics 7, 60-63 (2007)
381. L. Hu, G. Grüner, D. Li, R. B Kaner, and J. Cech, “Patternable transparent carbon nanotube films for electrochromic devices”, Journal of Applied Physics 101, 016102 (2007)
382. Liangbing Hu, George Grüner, Jian Gong, Chang-Jin Kim, Bjoern Hornbostel, “Electrowetting devices with transparent single-walled carbon nanotube electrodes”, Applied Physics Letters 90, 093124 (2007)
383. G. Grüner, “Carbon Nanonets Spark New Electronics”, Scientific American 296, 76-83 (2007)
384. R. W. Crane, N. P. Armitage, A. Johansson, G. Sambandamurthy, D. Shahar, and G. Grüner, “Fluctuations, dissipation, and nonuniversal superfluid jumps in two- dimensional superconductors ”, Phys. Rev. B 75, 094506 (2007)
30 385. H. Xu and S. M. Anlage, L. Hu and G. Gruner, “Microwave shielding of transparent and conducting single-walled carbon nanotube films”, Appl. Phys. Lett. 90, 183119 (2007)
386. Mikhail Briman, Erika Artukovic, Li Zhang, David Chia, Lee Goodglick, George Grüner, “Direct Electronic Detection of Prostate-Specific Antigen in Serum”, Small 3, 758-762 (2007)
387. L. B. Hu, G. Grüner, D. Li, , R. B. Kaner, and J. Cech, “Patternable transparent carbon nanotube films for electrochromic devices”, Journal of Applied Physics 101 (2007).
388. M. Kaempgen, J. Ma, G. Grüner, G. Wee, and S. G. Mhaisalkar, “Bifunctional carbon nanotube networks for supercapacitors”, Appl. Phys. Lett. 90, 264104 (2007)
389. R. Crane, N. P. Armitage, A. Johansson, G. Sambandamurthy, D. Shahar, and G. Grüner, “Survival of superconducting correlations across the two-dimensional superconductor-insulator transition: A finite-frequency study”, Phys. Rev. B 75, 184530 (2007)
390. Wei Yuan, Tuling Lam, James Biggs, Liangbing Hu, Zhibin Yu, Soonmok Ha, Dongjuan Xi, Matthew K. Senesky, George Grüner, and Qibing Pei, “New electrode materials for dielectric elastomer actuators”, Proc. SPIE 6524, 65240N (2007)
391. A. Kiebele and G. Grüner , “Carbon nanotube based battery architecture”, Appl. Phys. Lett. 91, 144104 (2007)
392. N.P. Armitage, R. W. Crane, G. Sambandamurthy, A. Johansson, D. Shahar, V. Zaretskey, G. Grüner, “Direct observation of quantum superconducting fluctuations in an insulating groundstate”, arXiv:0706.0144v1 [cond-mat.supr-con] (2007)
2008
393. L. Hu, Y.-L. Zhao, K. Ryu, C. Zhou, J. F. Stoddart, G. Grüner, “Light-Induced Charge Transfer in Pyrene/CdSe-SWNT Hybrids”, Advanced Materials 20, 5939-946 (2008).
394. V. Jain, H.M. Yochum, R. Montazami, J.R. Heflin, L. Hu, G. Grüner, “Modification of single-walled carbon nanotube electrodes by layer-by-layer assembly for electrochromic devices”, J. Appl. Phys. 103, 074504:1-5 (2008)
395. N. P. Armitage, R. Crane, G. Sambandamurthy, A. Johansson, D. Shahar, V. Zaretskey, G. Grüner, “Direct observation of quantum superconducting fluctuations across the 2D superconductor-insulator transition”, Physica B-Condensed Matter 403, 1208-1210 (2008)
396. H. Xu, SX. Zhang, S. M. Anlage, LB. Hu, and G. Grüner, “Frequency- and electric-field-dependent conductivity of single-walled carbon nanotube networks of 31 varying density”, Physical Review B 77, 075418 (2008)
397. W. Yuan, L. Hu, Z. Yu, T. Lam, J. Biggs, S.M. Ha, D. Xi, B. Chen, M.K. Senesky, G. Grüner, and Q. Pei, "Fault-Tolerant Dielectric Elastomer Actuators Using Single- Walled Carbon Nanotube Electrodes", Advanced Materials, 20, 621-625 (2008)
398. Wei Yuan, Liangbing Hu, Soonmok Ha, Tuling Lam, George Grüner, and Qibing Pei, “Self-clearable carbon nanotube electrodes for improved performance of dielectric elastomer actuators”, Proc. SPIE 6927, 69270P (2008)
399. Yan-Li Zhao, Liangbing Hu, J. Fraser Stoddart, and George Grüner, “Pyrenecyclodextrin-Decorated Single-Walled Carbon Nanotube Field-Effect Transistors as Chemical Sensors”, Advanced Materials, 20, 1910-1915 (2008)
400. Jianfeng Li, Liangbing Hu, Jun, Liu, Lian Wang, Tobin J Marks, and George Grüner, “Indium tin oxide modified transparent nanotube thin films as effective anodes for flexible organic light-emitting diodes”, Appl. Phys. Lett. 93, 083306 (2008)
401. Yan-Li Zhao, Liangbing Hu, George Grüner and J. Fraser Stoddart, “A Tunable Photosensor”, J. Am. Chem. Soc., 130 (50), 16996–17003 (2008)
2009
402. Liangbing Hu, Wei Yuan, Paul Brochu, George Gruner, and Qibing Pei, “Highly stretchable, conductive, and transparent nanotube thin films”, Appl. Phys. Lett. 94, 161108 (2009)
403. Mark A. Topinka, Michael W. Rowell, David Goldhaber-Gordon, Michael D. McGehee, David S. Hecht and George Gruner, “Charge Transport in Interpenetrating Networks of Semiconducting and Metallic Carbon Nanotubes”, Nano Lett. 9, 1866–1871 (2009)
404. Liangbing Hu, David S. Hecht, and George Grüner, “Infrared transparent carbon nanotube thin films”, Appl. Phys. Lett. 94, 081103 (2009)
405. Martti Kaempgen , Candace K. Chan , J. Ma , Yi Cui and George Gruner, “Printable Thin Film Supercapacitors Using Single-Walled Carbon Nanotubes”, Nano letters 9, 1872-1876 (2009)
406. Liangbing Hu,Wei Yuan, Paul Brochu, George Gruner, and Qibing Pei, “Highly stretchable, conductive, and transparent nanotube thin films”, Appl. Phys. Lett. 94, 161108 (2009)
407. L. Hu, G. Gruner, J. Jenkins and C.-J. Kim , “Flash dry deposition of nanoscale material thin films”, J. Mater. Chem.19, 5845-5849 (2009)
32 408. Liangbing Hu, David S Hecht and George Grüner, “A method of fabricating highly transparent and conductive interpenetrated carbon nanotube–parylene networks”, Nanotechnology 20, 465304 (2009)
409. Zhibin Yu, Liangbing Hu, Zhitian Liu, Mingliang Sun, Meiliang Wang, George Grüner, and Qibing Pei, “Fully bendable polymer light emitting devices with carbon nanotubes as cathode and anode”, Appl. Phys. Lett. 95, 203304 (2009)
410. Eric C-W. Ou, Liangbing Hu, Gan Ching Ruey Raymond, Ong Kian Soo, Jisheng Pan, Zhang Zheng, Youngbae Park, David Hecht, Glen Irvin, Paul Drzaic and George Gruner, “Surface-Modified Nanotube Anodes for High Performance Organic Light- Emitting Diode”, ACS Nano 3, 2258–2264 (2009)
2010
411. Grace Wee, Wai F. Mak, Nopphawan Phonthammachai, Andreas Kiebele, M. V. Reddy, B. V. R. Chowdari, George Gruner, Madhavi Srinivasan, and Subodh G. Mhaisalkar, “Particle Size Effect of Silver Nanoparticles Decorated Single Walled Carbon Nanotube Electrode for Supercapacitors’, Journal of The Electrochemical Society, 157, A179-A184 (2010)
412. Liangbing Hu, Jianfeng Li, Jun Liu, George Grüner and Tobin Marks, “Flexible organic light-emitting diodes with transparent carbon nanotube electrodes: problems and solutions”, Nanotechnology 21, 155202 (2010)
413. Liangbing Hu, David S. Hecht, and George Gruner, “Carbon Nanotube Thin Films: Fabrication, Properties, and Applications”, Chem. Rev., 110, 5790–5844 (2010)
2011
414. Ting Wang, Andreas Kiebele, Jason Ma, Subodh Mhaisalkar, and George Gruner, “Charge Transfer Between Polyaniline and Carbon Nanotubes Supercapacitors: Improving Both Energy and Power Densities”, J. Electrochem. Soc., 158, pp. A1-A5 (2011)
Books
1. G. Grüner,”Density Waves in Solids”,Addison-Wesley Publishing Company, 1994.
2. Japanese edition of the above book.
3. M. Dressel and G. Grüner, ``Electrodynamics of Solids: Optical Properties of Electrons in Matter'', Cambridge University Press, Cambridge 2002
CONFERENCE PUBLICATIONS
1. G. Grüner, “Two-Dimensional Carbon Nanotube Networks: A Transparent Electronic Material”, MRS Symposium DD Paper 0905-DD06-05 (2006) 33 2. G. Gruner, Carbon Nanotube Transistors for Biosensing Applications, 175 - 180, in Nanofabrication: Technologies, Devices, and Applications, Proceedings of SPIE, Vol. 5592, Philadelphia, Pennsylvania, USA, October 2004, eds. Warren Y-C. Lai, Stanley Pau, O. Daniel Lopez (SPIE, Bellingham, WA, 2005) 3. Carbon nanotube nanoelectronic devices for chemical detection in liquid hydrocarbons – A. Star, K. Bradley, J.-C. P. Gabriel, G. Grüner, Fuel Chemistry Division Preprints 2004. 4. Nano-electronic sensors: Chemical detection using carbon nanotubes – A. Star, K. Bradley, J.-C. P. Gabriel, G. Grüner, Polymeric Materials: Science & Engineering 2003, 89, 204. 5. Polymer coatings of carbon nanotube sensors – A. Star, T.-R. Han, V. Joshi, G. Grüner, Polymer Preprints 2003, 44, 201. 6. Nano-electronic sensors; Practical device designs for sensors – J. R. Stetter, K. Bradley, J. Cumings, J.-C. P. Gabriel, G. Grüner, A. Star, Nanotech 2003, 3, 313-316.
34