List of Publications of
Surjit Singh

This page is under construction.
This page should really be called Surjit Singh's Ego corner.
I just blab on and brag about things I have accomplished.
Enter at your own risk

Here are four of my most important co-writers (in chronological order).

RKPathria

Raj Pathria

David Jasnow

David Jasnow

GWilseRobinson

G Wilse Robinson

REWilde

Richard Wilde

Publications from the University of Pittsburgh

1. M. N. Barber, D. Jasnow, S. Singh and R. A. Weiner

Critical Behavior of the Spherical Model with Enhanced Surface Exchange

J. Phys. C7, 3491 (1974)

2. S. Singh and D. Jasnow

Crossover Scaling Function for Exchange Anisotropy: XY and Planar Models

Phys. Rev. B11, 3445 (1975)

3. S. Singh and D. Jasnow

Crossover Scaling Function for Exchange Anisotropy: Heisenberg to XY-like Crossover

Phys. Rev. B12, 493 (1975)

4. S. Singh, D. Jasnow and M. N. Barber

Critical Behavior of the Spherical Model with Enhanced Surface Exchange: Two Spherical Field Model

J. Phys. C8, 3408 (1975)

Publications from India

5. G. P. Singh and S. Singh

Acoustic Longitudinal Mode Coupling to the Order Parameter and its Effect on the Ferroelectric Phase Transition

J. Phys. C12, 995 (1979)

*6. G. P. Singh, S. Singh and B. K. Basu

Electrostrictive Effects in RbH2 PO4

Ferroelectrics 25, 519 (1980)

*7. B. Dey and S. Singh

A New Phonon Frequency Distribution Function for Quasi-Two-Dimensional Systems

Phys. Lett. A81, 147 (1981)

*8. P. Shukla and S. Singh

Spin-Glass Dynamics in the Spherical Model

J. Phys. C14, L81 (1981)

*9. P. Shukla and S. Singh

A Quantum Spherical Model of Spin-Glass

Phys. Lett. A81, 477 (1981)

10. P. Shukla and S. Singh

Classical and Quantum Spherical Models of Spin-Glasses: A Complete Treatment of Statics and Dynamics

Phys. Rev. B23, 4661 (1981)

*11. W. L. Basaiawmoit and S. Singh

Crossover Behavior of the Susceptibility of Quasi-Two-Dimensional Ising Model: g=0 Behavior

Phys. Lett. A88, 251 (1982)

*12. W. L. Basaiawmoit and S. Singh

Scale-Factor Universality in the Anisotropic Crossover Behavior of the Susceptibility of Quasi-Two-Dimensional Ising Model

Phys. Lett. A89, 313 (1982)

*13. S. Singh and P. N. Pandita

Critical Behavior of a Relativistic Bose Gas with Pair Production

Phys. Lett. A92, 65 (1982)

*14. S. Singh

Surface Properties of an Ideal Relativistic Bose Gas with Pair Production

Phys. Lett. A93, 70 (1982)

15. W. L. Basaiawmoit and S. Singh

Crossover Scaling Function for the Lattice Anisotropy of the Quasi-Two-Dimensional Ising Model

J. Phys. C16, 369 (1983)

16. S. Singh

Kronig-Penney Model in Reciprocal Lattice Space

Am. J. Phys. 51, 179 (1983)

17. S. Singh and P. N. Pandita

Scaling and Universality of the Thermodynamics and Correlations of an Ideal Relativistic Bose Gas with Pair Production

Phys. Rev. A28, 1752 (1983)

*18. P. N. Pandita and S. Singh

Supersymmetric Phase Transition

Phys. Rev. Lett. 50, 1550 (1983)

*19. S. Singh

Crossover Scaling Behavior of Quasi-One-Dimensional n-Vector Models

Phys. Lett. A96, 225 (1983)

20. S. Singh and P. N. Pandita

Some Anomalies in the Treatment of Ideal Extreme Relativistic Bose Gas Condensation

Phys. Rev. A28, 3137 (1983)

Publications from Canada

21. S. Singh and R. K. Pathria

Bose-Einstein Condensation in Finite Non-Interacting Systems: A Relativistic Bose Gas with Pair Production

Phys. Rev. A30, 442 (1984)

22. S. Singh and R. K. Pathria

Bose-Einstein Condensation in an Einstein Universe

J. Phys. A17, 2983 (1984)

*23. P. N. Pandita and S. Singh

Response to a Comment on Paper Number 18

Phys. Rev. Lett. 52, 2006 (1984)

24. S. Singh and R. K. Pathria

Bose-Einstein Condensation in Finite Non-Interacting Systems: A Relativistic Bose Gas with Pair Production II

Phys. Rev. A30, 3198 (1984)

25. S. Singh and R. K. Pathria

Finite-Size Scaling for the Bose Condensate

Can. J. Phys. 63, 358 (1985)

26. S. Singh and R. K. Pathria

Privman-Fisher Hypothesis on Finite Systems: Verification in the Case of a Relativistic Bose Gas with Pair Production

Phys. Rev. A31, 1816 (1985)

27. S. Singh and R. K. Pathria

Privman-Fisher Hypothesis on Finite Systems: Verification in the Case of the Spherical Model of Ferromagnetism

Phys. Rev. B31, 4483 (1985)

*28. S. Singh and R. K. Pathria

Phase Transition in Finite Systems: Influence of Geometry on the Approach Toward Bulk Critical Behavior

Phys. Rev. Lett. 55, 347 (1985)

29. S. Singh and R. K. Pathria

Finite-Size Effects in the Spherical Model of Ferromagnetism: Antiperiodic Boundary Conditions

Phys. Rev. B32, 4618 (1985)

*30. S. Singh and J. R. Banavar

Random Field Critical Behavior: Finite-Size Effects

Phys. Rev. Lett. 55, 2220 (1985)

*31. S. Singh and R. K. Pathria

Spin-Spin Correlations in Finite Systems: Scaling Hypothesis and Corrections to Bulk Behavior

Phys. Rev. B33, 672 (1986) (Rapid Communications)

32. S. Singh, R. K. Pathria and M. E. Fisher

Finite-Size Effects in the Spherical Model of Ferromagnetism: Zero-Field Susceptibility under Antiperiodic Boundary Conditions

Phys. Rev. B33, 6415 (1986)

*33. S. Singh and R. K. Pathria

Response to a Comment on Paper Number 28

Phys. Rev. Lett. 56, 2226 (1986)

*34. S. Singh and R. K. Pathria

Role of Fluctuations in Determining Finite-Size Effects in a System Undergoing Phase Transition

Phys. Rev. B34, 2045 (1986) (Rapid Communications)

35. S. Singh and P. N. Pandita

Phase Transition in a Supersymmetric Theory

Phys. Rev. D34, 1859 (1986)

*36. S. Singh and R. K. Pathria

Finite-Size Scaling of O(n) Models in Higher Dimensions

Phys. Lett. A118, 131 (1986)

37. S. Singh and R. K. Pathria

Finite-Size Scaling for a Relativistic Bose Gas with Pair Production

Phys. Rev. A35, 4814 (1987)

38. J. K. Srivastava, J. A. Kulkarni, S. Ramakrishnan, S. Singh, V. R. Marathe, G. Chandra, V. S. Darshane and R. Vijayaraghavan

The Spin-Glass Behavior of Disordered Spinel Ferrite Co2TiO4

J. Phys. C20, 2139 (1987)

*39. J. K. Srivastava, S. Ramakrishnan, V. R. Marathe, G. Chandra, R. Vijayaraghavan, J. A. Kulkarni, V. S. Darshane and S. Singh

Magnetic Behavior of the Co2-x Zn xTiO4 and Co2SnO 4 Systems

J. Appl. Phys. 61, 3622 (1987)

40. S. Singh and R. K. Pathria

Spin-Spin Correlations in Finite Systems with O(n) Symmetry: Scaling Hypothesis and Corrections to Bulk Behavior

Phys. Rev. B36, 3769 (1987)

41. S. Singh and R. K. Pathria

Finite-Size Scaling for a Relativistic Bose Gas in an Einstein Universe

J. Phys. A20, 6357 (1987)

42. S. Singh and R. K. Pathria

Phase Transition in Finite Systems with O(n) Symmetry: Magnetization and Susceptibility in the Presence of an External Field

Phys. Rev. B37, 7806 (1988)

43. S. Singh and R. K. Pathria

Finite-Size Scaling of O(n) Models in Higher Dimensions

Phys. Rev. B38, 2740 (1988)

Publications from USA

44. S.-B. Zhu, S. Singh and G. W. Robinson

Breakdown of Brownian Motion Model in Ultrafast Dynamics

Phys. Rev. A40, 1109 (1989)

45. S. Singh and R. K. Pathria

Analytical Evaluation of a Class of Lattice Sums in Arbitrary Dimensions

J. Phys. A22, 1883 (1989)

46. S. Singh and R. K. Pathria

Finite-Size Scaling of O(n) Models with Long Range Interactions

Phys. Rev. B40, 9238 (1989)

*47. G. W. Robinson, S. Singh, R. Krishnan, S.-B. Zhu and J. Lee

Aspects of Modern Condensed Phase Chemistry

J. Phys. Chem. 94, 4 (1990)

48. S. Singh and R. K. Pathria

Finite-Size Scaling in Arbitrary Dimensions

J. Phys. A23, 4619 (1990)

*49. S. Singh, R. Krishnan and G. W. Robinson

Theory of Activated Rate Processes with Space-Dependent Friction

Chem. Phys. Lett. 175, 338 (1990)

50. S.-B. Zhu, S. Singh, J. Lee and G. W. Robinson

Velocity Dependence of Friction

Chem. Phys. 152, 221 (1991)

51. S.-B. Zhu, S. Yao, J.-B. Zhu, S. Singh and G. W. Robinson

A Flexible/Polarizable Simple Point Charge Water Model

J. Phys. Chem. 95, 6211 (1991)

52. S.-B. Zhu, S. Singh and G. W. Robinson

A New Flexible/Polarizable Water Model

J. Chem. Phys. 95, 2791 (1991)

53. S. Singh and R. K. Pathria

Exact Results for a Finite-Sized Spherical Model at the Borderline Dimensionality Four

Phys. Rev. B45, 9759 (1992)

54. R. Krishnan, S. Singh and G. W. Robinson

Space-Dependent Friction in the Theory of Activated Rate Processes

Phys. Rev. A45, 5408 (1992)

*55. S. Singh, R. Krishnan and G. W. Robinson

Critical Phenomena and Scaling Behavior in Theories of Activated Barrier Crossing

Phys. Rev. Lett. 68, 2608 (1992)

56. R. Krishnan, S. Singh and G. W. Robinson

Space-Dependent Friction in the Theory of Activated Rate Processes: The Hamiltonian Approach

J. Chem. Phys. 97, 5516 (1992)

57. S.-B. Zhu, S. Singh and G. W. Robinson

Field-Perturbed Water

Adv. Chem. Phys. 85 (3), 627 (1993)

58. S.-B. Zhu, J.-B. Zhu, J. Lee, G. W. Robinson and S. Singh

Ionic Dissociation Dynamics in a Polarizable Liquid

J. Mol. Liq. 57, 91 (1993)

59. M. Vedamuthu, S. Singh and G. W. Robinson

The Properties of Liquid Water: Origin of Density Anomalies

J. Phys. Chem. 98, 2222 (1994)

60. S. Singh and G. W. Robinson

A Study of the van der Zwan-Hynes Model for Dipole Isomerization Reaction Rate from the Point of View of Critical Phenomena

J. Chem. Phys. 100, 6640 (1994)

61. S. Singh and G. W. Robinson

Rate Processes in Dissipative Systems: Scaling in the Variational Transition State Theory

Chem. Phys. 183, 365 (1994)

62. S. Singh, R. Krishnan and G. W. Robinson

Critical Scaling Behavior in the Activated-Barrier-Crossing Problem

Phys. Rev. E49, 2540 (1994)

63. S. Singh and G. W. Robinson

Scaling in a Model of Chemical Reaction Rates with Space-Dependent Friction

J. Phys. Chem. 98, 7300 (1994)

64. M. Vedamuthu, S. Singh and G. W. Robinson

Accurate Mixture-Model Densities for D 2O

J. Phys. Chem. 98, 8591 (1994)

65. S. Singh and G. W. Robinson

A Study of the Quantum Activated Barrier Crossing Problem from the Viewpoint of Critical Phenomena

J. Phys. Chem. 99, 2764 (1995)

66. C. H. Cho, M. Chung, J. Lee, T. Nguyen, S. Singh, M. Vedamuthu, S. Yao, J.-B. Zhu and G. W. Robinson

Time- and Space-Resolved Studies of the Physics and Chemistry of Liquid Water near a Biologically Relevant Surface

J. Phys. Chem. 99, 7806 (1995)

67. S. Singh and G. W. Robinson

Study of the Reaction Rate, in the Critical Regime, of a Solute Embedded in a Lennard-Jones Crystal

J. Chinese Chem. Soc. 42, 367 (1995)

68. M. Vedamuthu, S. Singh and G. W. Robinson

Properties of Liquid Water. 4. The Isothermal Compressibility Minimum near 50 C

J. Phys. Chem. 99, 9263 (1995)

69. S. Singh and G. W. Robinson

An Analytical Study of the Berezhkovskii-Pollak-Zitserman theory of Rate Processes in the Memory-Suppression Region

Chem. Phys. 198, 257 (1995)

70. S. Singh and G. W. Robinson

Critical Scaling Behavior in the Activated Barrier Crossing Problem II. Power-law Potential

J. Chem. Phys. 103, 4920 (1995)

71. M. Vedamuthu, S. Singh and G. W. Robinson

A Simple Relationship Between the Properties of Isotopic Water

J. Phys. Chem. 100, 3825 (1996)

*72. C. H. Cho, S. Singh and G. W. Robinson

An Explanation of the Density Maximum in Water

Phys. Rev. Lett. 76, 1651 (1996)

73. M. Vedamuthu, S. Singh, Y. Onganer, D. R. Bessire, M. Yin, E. L. Quitevis and G. W. Robinson

Universality in Isomerization Reactions in Polar Solvents

J. Phys. Chem. 100, 11907 (1996)

74. S. Singh and G. W. Robinson

An Analytical Study of the Berezhkovskii-Pollak-Zitserman Theory of Rate Processes in the Critical Region. II. The critical coupling plane

Chem. Phys. 212, 125 (1996)

75. C. H. Cho, S. Singh and G. W. Robinson

Liquid Water and Biological Systems: The Most Important Problem in Science that Hardly Anyone Wants to See Solved

Faraday Discuss. 103, 19 (1996)

76. C. H. Cho, S. Singh and G. W. Robinson

Response to a Comment on Paper Number 72

Phys. Rev. Lett. 79, 180 (1997)

77. C. H. Cho, S. Singh and G. W. Robinson

Water Anamolies and the Double-well Takahashi Model

Chem. Phys. 232, 329 (1998)

78. J. Urquidi, C. H. Cho, S. Singh and G. W. Robinson

Temperature and Pressure Effects on the Structure of Water

J. Mol. Structure, 485-486, 363 (1999)

79. C. H. Cho, J. Urquidi, S. Singh and G. W. Robinson

Thermal Offset Viscosities of Liquid H 2O, D2O and T2O

J. Phys. Chem. B, 103, 1991 (1999)

*80. J. Urquidi, S. Singh, C. H. Cho and G. W. Robinson

Origin of Temperature and Pressure Effects on the Radial Distribution Function of Water

Phys. Rev. Lett. 83, 2348 (1999)

81. G. W. Robinson, J. Urquidi, S. Singh and C. H. Cho

Protein Denaturation Described by a Two-State Structure Model of Liquid Water

Cell and Mol. Biology, 47, 757 (2001)

82. C. H. Cho, J. Urquidi, S. Singh, S. C. Park and G. W. Robinson

Pressure Effect on the Density of Water

J. Phys. Chem. A, in print (2002)