Publication List for David R.M. Williams

( 115 publications)

Invited Reviews

44. Hairpin Defects in Liquid-Crystalline Polymers.
D.R.M. Williams, A. Halperin,
Materials Research Society Bulletin 20, 39, 1995.
54. Liquid Crystalline Polymers at Interfaces
D.R.M. Williams, A. Halperin,
Macromolecular Symposia 106, 167, 1996.
55. Switching properties of Liquid Crystalline Polymers at Interfaces
D.R.M. Williams, A. Halperin,
Annual Reviews of Materials Science 26, 279, 1996.
56. Liquid Crystalline Polymers at Interfacs - deformations and Phase transitions.
D.R.M. Williams, A. Halperin,
Progress in Polymer Science 21, 1089, 1996.

Refereed Research Papers

1. Response Tensors for Spin Zero and Spin One Boson/Anti-Boson Plasmas.
D.R.M. Williams, D.B. Melrose,
Australian Journal of Physics 42, 59, 1989.
2. Computer Simulation of Hairpin Dynamics in Worm-Like Main Chain NematicPolymer LiquidCrystals.
D.R.M. Williams, M. Warner,
Polymer Preprints 30, 69, 1989.
3. Statics and Dynamics of Hairpins in Worm-like main chain NematicPolymer Liquid Crystals.
D.R.M. Williams, M. Warner,
Journal de Physique 51, 317, 1990.
4. Computer Simulation of Hairpin Dynamics in Worm-Like Main Chain Nematic Polymer Liquid Crystals.
D.R.M. Williams, M. Warner,
In: Computer Simulation of Polymers.
Editors: R.J. Roe,
page 158, Prentice Hall New Jersey 1991.
5. Rollers - a new type of defect in dipoled polymer chains.
D.R.M. Williams,
Journal of Physics A 24, 4427, 1991.
6. On the Confinement of Liquid Crystalline Polymers: A Fredericks-Like Transition.
D.R.M. Williams, A. Halperin,
Europhysics Letters 19, 693, 1992.
7. Liquid Crystalline Polymers as Ising Chains: Stretching and Swelling.
A. Halperin, D.R.M. Williams,
Europhysics Letters 20, 601, 1992.
8. NMR Broadening from Molecular Defects in Nematic Polymer Liquid Crystals.
M. Warner, D.R.M. Williams,
Journal de Physique 2, 471, 1992.
9. Cylindrical Micelles in Rod-Coil Block Copolymers.
D.R.M. Williams, *G.H. Fredrickson,
Macromolecules 25, 3561, 1992.
10. Cylindrical Micelles in Rigid-Flexible Diblock Copolymers
D.R.M. Williams, G.H. Fredrickson,
In: Complex Fluids
Editors: E.B. sirota, D. Weitz, T. Witten, J. Israelachvili,
page 377, MRS Pittsburgh 1992.
11. Liquid Crystalline Polymers in Nematic Solvents: Confinement and Field Effects.
D.R.M. Williams, A. Halperin,
Macromolecules 26, 2025, 1993.
12. Nematic Polymers: Hairpins, Ringlets and Excimer Fluorescence.
D.R.M. Williams, A. Halperin,
Journal de Physique 3, 69, 1993.
13. Liquid Crystalline Brushes: An Anchoring Transition.
A. Halperin, D.R.M. Williams,
Europhysics Letters 21, 575, 1993.
14. Microphases of Nematic Diblock Copolymers: Reentry and Finite Size Effects.
D.R.M. Williams, A. Halperin,
Physical Review Letters 71, 1557, 1993.
15. Grafted Polymers in Bad Solvents - Octopus Surface Micelles.
D.R.M. Williams,
Journal de Physique 3, 1313, 1993.
16. Surface Tension of Melt Polymer Brushes and Diblock Copolymers.
D.R.M. Williams,
Langmuir 9, 2215, 1993.
17. Periodic faceting on vicinal GaAs(110)
M. Krishnamurthy, M. Wassermeier, D.R.M. Williams, P.M. Petroff,
Applied Physics Letters. 62, 1922, 1993.
18. Molecular-Beam Epitaxial Growth Mechanisms of (Al, Ga)As on Vicinial GaAs Surfaces - Self-Ornaization and Step Bunching.
M. Krishnamurthy, A. Lorke, M. Wassermeier, D.R.M. Williams, P.M. Petroff,
Journal of Vaccuum Science and Technology, B 11, 1384, 1993.
19. Liquid Crsytalline Polymers in Good Nematic Solvents - Free Chains, Mushrooms and Brushes.
D.R.M. Williams, A. Halperin,
Macromolecules 26, 4208, 1993.
20. Nematic Networks -On Thermoelasicity and the Bridging Fraction.
A. Halperin, D.R.M. Williams,
Macromolecules 26, 6652, 1993.
21. Cylindrical and Spherical Polymer Brushes - Moduli and Force Laws.
D.R.M. Williams,
Macromolecules 26, 6667, 1993.
22. Cell Motility by Non-linear Osmotic Swimming.
D.R.M. Williams, P.G. de Gennes,
Europhysics Letters 24, 311, 1993.
23. Nematic Liquid Crystal in a Tube - The Freedericksz Transition.
D.R.M. Williams, A. Halperin,
Physical Review E, Rapid Communications 48, 2366, 1993.
24. Grafted Polymers in Poor Solvents - Shear-Induced Shrinkage.
D.R.M. Williams,
Macromolecules 26, 5806, 1993.
25. Filled Polymer Brushes: A Hydrodynamic Analogy.
D.R.M. Williams, P. Pincus,
Europhysics Letters 24, 29, 1993.
26. Moduli of Polymer Brushes, Contact Mechanics, and Atomic Force Microscope Experiments.
D.R.M. Williams,
Macromolecules 26, 5096, 1993.
27. Step equalization in epitaxial growth - a noise-limited process.
D.R.M. Williams, M. Krishnamurthy,
Applied Physics Letters. 62, 1351, 1993.
28. 3D Convex Particles at Interfaces.
D.R.M. Williams, E. Raphael,
Journal of Colloid and Interface Science 155, 509, 1993.
29. Dynamics of periodic step-bunching during growth on vicinal GaAs(1001) surfaces: computer simulations and experiments.
M. Krishnamurthy, D.R.M. Williams, P.M. Petroff,
In: Common Themes and Mechanisms of Epitaxial Growth.
Editors: P.H. Fuoss, J. Tsao, D. Kisker, A. Zangwill, T. Kuech,
page 312, MRS Pittsburgh 1993.
30. Instabilities in MBE Growth.
A.W. Hunt, C. Orme, D.R.M. Williams, B.G. Orr, L.M. Sander,
Europhysics Letters 27, 611, 1994.
31. Escape Transitions and Force Laws for Compressed Polymer Mushrooms.
G. Subramanian, D.R.M. Williams, P. Pincus,
Europhysics Letters 29, 285, 1994.
32. Cylindrical Phases of Isotropic Diblock Copolymers as Giant Nematic Worms: Frank Elasticity and Fr\'eedericksz Transitions.
D.R.M. Williams,
Physical Review E, Rapid Communications 49, 1811, 1994.
33. Shear of Diblock Copolymer Lamellae: Width changes and Undulational Instabilities.
D.R.M. Williams, F.C. MacKintosh,
Macromolecules 26, 7677, 1994.
34. Polymer Brushes as Pressure-Sensitive Automated Microvalves.
E.M. Sevick, D.R.M. Williams,
Macromolecules 27, 5285, 1994.
35. Doubly Anchored Nematic Polymer Brushes: Shear, Field Effects and Quasi-Piezolectricity.
A. Halperin, D.R.M. Williams,
Physical Review E, Rapid Communications 49, 986, 1994.
36. Liquid Crystalline Polymers in Nematic Solvents: Extension and Confinement.
A. Halperin, D.R.M. Williams,
In: Soft Order in Physical Systems.
Editors: R. Bruinsma, Y. Rabin,
page 159, Plenum New York 1994.
37. Liquid crystalline Polymers in Nematic Solvents: Interfacial Behavior and Active Anchoring.
A. Halperin, D.R.M. Williams,
Journal of Physics, Condensed Matter 6, 297, 1994.
38. Nematic Distortions in Adjustable Geometries: Repartitioning and Instabilities.
D.R.M. Williams, A. Halperin,
Journal de Physique 4, 1633, 1994.
39. Nematic Liquid Crystals Between Antagonistic Cylinders - Spirals with Bend-Splay Director Undulations.
D.R.M. Williams,
Physical Review E 50, 1686, 1994.
40. Liquid Crystalline Polymers in Nematic Solvents.
D.R.M. Williams, A. Halperin,
In: Electrical, Optical, and Magnetic Properties of Organic Solid State Materials
Editors: L. Dalton,
page 0, MRS Pittsburgh 1994.
41. Liquid Crystalline Polymers-Interfacial Properties.
A. Halperin, D.R.M. Williams,
Discussions of the Faraday Society 98, 295, 1994.
42. Instabilities in MBE Growth: the SLUG Model.
A.W. Hunt, C. Orme, D.R.M. Williams, B.G. Orr, L.M. Sander,
In: Patterns and Scaling in the Growth of Thin Films
Editors: Unknown ,
page 0, NATO, ASI Cambridge 1994.
43. Motion of a Polyelectrolyte Chain Hooked around a Post.
E.M. Sevick, D.R.M. Williams,
Physical Review E, Rapid Communications 50, 3357, 1994.
45. Corrugational Instabilities of Thin Copolymer Films.
D.R.M. Williams,
Physical Review Letters 75, 453, 1995.
46. Coil-Stretch Transitions for Grafted Polymers in Spatially Varying Flows
E.M. Sevick, D.R.M. Williams,
Europhysics Letters 31, 357, 1995.
47. Swelling Kinetics of Layered Structures: Triblock Copolymer Mesogels.
C.-M. Chen, F.C. MacKintosh, D.R.M. Williams,
Langmuir 11, 2471, 1995.
48. Pressure-Sensitive Microvalves Made From Polymer Brushes.
E.M. Sevick, D.R.M. Williams,
In: Materials for Smart Systems
Editors: E.P. George,
page 217, MRS Pittsburgh 1995.
49. Porous Membranes With Grafted Polymers: Valves and Sensors.
E.M. Sevick, D.R.M. Williams,
In: Advances in Porous Materials
Editors: S. Komarneni,
page 119, MRS Pittsburgh 1995.
50. 1D Excited Granular Media: Clustering and Equation of State.
D.R.M. Williams, F.C. MacKintosh,
In: Fractal Aspects of Materials
Editors: F. Family,
page 151, MRS Pittsburgh 1995.
51. Polymer Mushrooms Compressed Under Curved Surfaces
D.R.M. Williams, F.C. MacKintosh,
Journal de Physique 5, 1407, 1995.
52. Rod-like Polymers in Nematic Solvents: Mechanically and Electrically Driven Frederiks-likeTransitions.
D.R.M. Williams, A. Halperin,
Langmuir 11, 3626, 1995.
53. Polymer Brush-Lined Membranes for Flow and Filtration Control.
E.M. Sevick, F.A. Bruce, D.R.M. Williams,
In: Polymer/InorganicInterfaces II
Editors: L.T. Drzal,
page 151, MRS Pittsburgh 1995.
57. Collision of a Field-Driven Polymer with a Post: Electrophoresis in Microlithographic Arrays.
E.M. Sevick, D.R.M. Williams,
Physical Review Letters 76, 2595, 1996.
58. Driven Granular Media in 1-d: Correlations and Equation ofState.
D.R.M. Williams, F.C. MacKintosh,
Physical Review E, Rapid Communications 54, 9, 1996.
59. Interactions Between Finite-Sized Particles and End-Grafted Polymers.
G. Subramanian, D.R.M. Williams, P. Pincus,
Macromolecules 29, 4045, 1996.
60. Driven Granular Media and Dissipative Gases: Correlations and Liquid-Gas Phase Transitions.
D.R.M. Williams,
Physica A 233, 718, 1996.
61. Strain Effects in Epitaxial Growth.
D.R.M. Williams, L.M. Sander,
In: Evolution of Epitaxial Structure and Morphology
Editors: A. Zangwill,
page 0, MRS Pittsburgh 1996.
62. Collision of a field-driven polymer with a post: Implications for Electrophoresis in Microlithographic Arrays.
E.M. Sevick, D.R.M. Williams,
In: MRS Fall Symposium
Editors: Unknown ,
page 0, MRS Pittsburgh 1996.
63. Anomalous Height Increases Upon Bending for an Alexander-de Gennes Polymer Brush.
E.M. Sevick, D.R.M. Williams,
Journal of Chemical Physics 105, 9334, 1997.
64. Driven Granular Media and Dissipative Gases: Phase Transitions and Instabilities.
D.R.M. Williams,
Australian Journal of Physics 50, 425, 1997.
65. Grafted Rod-Coil Polymers: Jellyfish Surface Micelles.
E.M. Sevick, D.R.M. Williams,
Colloids and Surfaces A 130, 387, 1997.
66. Escape Transitions for Grafted Polymers in Theta Solvents.
M. Guffond, E.M. Sevick, D.R.M. Williams,
Langmuir 13, 5691, 1997.
67. Diffusivity transients and radiative recombination in intermixed In0.5Ga0.5As/GaAs quantum structures.
R. Leon, D.R.M. Williams, J Krueger, E.R. Weber, M.R. Melloch,
Physical Review B, Rapid Communications 56, 4336, 1997.
68. Diblock copolymer thin films on heterogeneous striped surfaces: Commensurate, incommensurate and inverted lamellae.
G.G. Pereira, D.R.M. Williams,
Physical Review Letters 80, 2849, 1998.
69. Surface crinkling of strained diblock copolymer smectic thin films on striped substrates
G.G. Pereira, D.R.M. Williams,
Europhysics Letters 44, 302, 1998.
70. Formation of self-assembled trenches and quantum-wires during epitaxial growth of strained GeSn alloys on Ge(100): Kinetic pathway to phase separation?
X. Deng, B.-K. Yang, S.A. Hackney, M. Krishnamurthy, D.R.M. Williams,
Physical Review Letters 80, 1022, 1998.
71. Semi-Flexible Polymers Grafted to Surfaces: Doughnut and Tower Micelles
J.N. Bright, D.R.M. Williams,
In: Materials Science of the Cell
Editors: B. Mulder, V. Vogel, C. Schmidt,
page 277, MRS Pittsburgh 1998.
72. Equilibrium properties of diblock copolymer thin film on a heterogeneous striped surface
G.G. Pereira, D.R.M. Williams,
Macromolecules 31, 5904, 1998.
73. Collapse of semi-flexible brushes in poor solvents: tilting and bending
J.N. Bright, D.R.M. Williams,
Europhysics Letters 48, 540, 1999.
74. A polymer end-tethered to a potential stripe: A simple example of an escape transition
E.M. Sevick, D.R.M. Williams,
Macromolecules 32, 6841, 1999.
75. Undulational instabilitiesof smectic thin films on a heterogeneous patterned surface under positive and negative strains: The caseof diblock copolymers.
G.G. Pereira, D.R.M. Williams,
Journal of Chemical Physics 110, 9223, 1999.
76. Thin diblock films on patterned surfaces: Computer simulations and the Frenkel-Kontorowa model.
G.G. Pereira, D.R.M. Williams,
Physical Review E 60, 3431, 1999.
77. Polymers Grafted onto Strongly Adsorbing Surfaces in Poor Solvents: Stretching, Fission, Phase Separation and Globular Micelles in 2D.
E.M. Sevick, D.R.M. Williams,
Physical Review Letters 82, 2701, 1999.
78. Grafted semiflexible polymers in poor solvents: Toroidal and tower surface micelles.
J.N. Bright, D.R.M. Williams,
Europhysics Letters 45, 321, 1999.
79. Coil to globule collapse transitions of polymers: The effect of adsorbed surfactants.
G.G. Pereira, D.R.M. Williams, D.H. Napper,
Langmuir 15, 906, 1999.
80. Diblock copolymer thin film melts on striped heterogeneous surfaces: Parallel, perpendicular and mixed lamellar morphologies
G.G. Pereira, D.R.M. Williams,
Macromolecules 32, 758, 1999.
81. Thin films of perpendicularly oriented diblock copolymers: Lamellar distortions driven by surface-diblockinterfacial tensions
G.G. Pereira, D.R.M. Williams,
Macromolecules 32, 1661, 1999.
82. Lamellar distortionsof thin, commensurately aligned diblock copolymer films on patterned surfaces.
G.G. Pereira, D.R.M. Williams,
Langmuir 15, 2125, 1999.
83. Diblock copolymers in electric fields: The transition from parallel to perpendicular alignment using a capacitor analogy.
G.G. Pereira, D.R.M. Williams,
Macromolecules 32, 8734, 1999.
84. Membrane- and surface-grafted polymers and proteins in shear flows: Chain mobility and transport coefficients.
J.N. Bright, D.R.M. Williams,
Langmuir 15, 3836, 1999.
85. Compression of a polymer chain by a small obstacle: The effect of fluctuations on the escape transition.
J. Ennis, E.M. Sevick, D.R.M. Williams,
Physical Review E 60, 6906, 1999.
86. Dynamical Intermediates in the collapse of semiflexible polymers inpoor solvents
B. Schnurr, F.C. MacKintosh, D.R.M. Williams,
Europhysics Letters 51, 279, 2000.
87. Steric Interaction of an Incoming Particle with Grafted Rods: Exact Solutions and Unusual Force Profiles
I.C.B. Miller, D.R.M. Williams,
Physical Review E, Rapid Communications 61, 4706, 2000.
88. Smectic rod-coil meltthin films confined between flat plates: Monolayer-bilayer and parallel-perpendicular transitions.
G.G. Pereira, D.R.M. Williams,
Macromolecules 33, 3166, 2000.
89. Interfacial profiles of mismatched lamellae in thin diblock copolymer films.
G.G. Pereira, D.R.M. Williams, A. Chakrabarti,
Journal of Chemical Physics 112, 10011, 2000.
90. Crystaline Toroidal Globules of DNA andother Semi-flexible Polymers: Jumps in Radius Caused by Hexagonal Packing.
G.G. Pereira, D.R.M. Williams,
Europhysics Letters 50, 559, 2000.
91. Specific ion effects: Why DLVO theory fails for biology and colloid systems.
M. Bostrom, D.R.M. Williams, B.W. Ninham,
Physical Review Letters 8716, 8103, 2001.
92. Toroidal condensates ofsemi-flexible polymers in poor solvents: Adsorption, stretching and compression
G.G. Pereira, D.R.M. Williams,
Biophysical Journal 80, 161, 2001.
93. Surface Tension of Electrolytes:Specific Ion Effects Explained by Dispersion Forces.
M. Bostrom, D.R.M. Williams, B.W. Ninham,
Langmuir 17, 4475, 2001.
94. Shear-dependent boundary slip in aqueous Newtonian liquid.
C. Netto, V. Craig, D.R.M. Williams,
Physical Review Letters 8705, 4504, 2001.
95. Long-lived States in Electrophoresis: Collision of a PolymerChain with Two or More Obstacles
E.M. Sevick, D.R.M. Williams,
Europhysics Letters 5, 529, 2001.
96. Influence of Hofmeister effects on surface pH and binding of peptides to membranes.
M. Bostrom, D.R.M. Williams, B.W. Ninham,
Langmuir 18, 8609, 2002.
97. Ion specificity of micelles explained by ionic dispersion forces.
M. Bostrom, D.R.M. Williams, B.W. Ninham,
Langmuir 18, 6010, 2002.
98. The influence of ionic dispersion potentials on counterion condensation onpolyelectrolytes.
M. Bostrom, D.R.M. Williams, B.W. Ninham,
Journal of Physical Chemistry B 106, 7908, 2002.
99. Stretching polymers in poor and bad solvents: Pullout peaks and an unraveling transition.
I.R. Cooke, D.R.M. Williams,
Europhysics Letters 64, 267, 2003.
100. Hofmeister effects in membrane biology: The role of ionic dispersion potentials.
M. Bostrom, D.R.M. Williams, P.R. Stewart, B.W. Ninham,
Physical Review E 18, 6804, 2003.
101. Specific ion effects: The role of co-ions in biology.
M. Bostrom, D.R.M. Williams, B.W. Ninham,
Europhysics Letters 63, 620, 2003.
102. Hofmeister Effects in pH Measurements: Role of Added Salt and Co-Ions.
M. Bostrom, V.S.J. Craig, R. Albion, D.R.M. Williams, B.W. Ninham,
Journal of Physical Chemistry B 107, 2875, 2003.
103. Collapse Dynamics of Block Copolymers in Selective Solvents: Micelle Formation and theEffect of Chain Sequence.
I.R. Cooke, D.R.M. Williams,
Macromolecules 36, 2149, 2003.
104. Specific Ion Effects: why the properties of Lysozyme in Salt Solutions follow aHofmeister Series
M. Bostrom, D.R.M. Williams, B.W. Ninham,
Biophysical Journal 85, 686, 2003.
105. Evidence of Shear-dependent boundary slip in Newtonian liquids.
C. Neto, V. Craig, D.R.M. Williams,
European Physics Journal E (electronic) 12, 71, 2003.
106. Specific ion effects: Why Colloid Science has Failed to Contribute to Biology.
M. Bostrom, D.R.M. Williams, B.W. Ninham,
Current Opinion in Colloid and Interface Science 123, 110, 2004.
107. Hofmeister effects in colloid science and biology explained by dispersion forces: analyticresults for the double layer interaction
S.A. Edwards, D.R.M. Williams,
Current Opinion in Colloid and Interface Science 9, 139, 2004.
108. Collapse of Flexible-Semiflexible Copolymers in Selective Solvents:Single Chain Rods, Cages and Networks
I.R. Cooke, D.R.M. Williams,
Macromolecules 37, 5778, 2004.
109. Novel Conformations of Isolated Semiflexible Block Copolymers.
E. Hernandez Zapata, I.R. Cooke, D.R.M. Williams,
Physica A 339, 45, 2004.
110. Condensed States of a Semiflexible Homopolymer: ordered globules and Toroids.
I.R. Cooke, D.R.M. Williams,
Physica A 339, 45, 2004.
111. Specific ion effects: Role of salt and buffer in protonation ofcytochrome c
M. Bostrom, D.R.M. Williams, B.W. Ninham,
European Physics Journal E 13, 239, 2004.
112. Specific Ion Effects: Why Colloid Science has failed to Contribute to Biology
M. Bostrom, D.R.M. Williams, B.W. Ninham,
Progress in Colloid and Polymer Science 123, 110, 2004.
113. Double layers and interparticle forces in colloid scienceand biology: Analytic results for the effect of ionicdispersion forces.
S. A. Edwards, D.R.M. Williams,
Physical Review Letters 92, 248303, 2004.
114. Experimental study of the fluctuation theorem in a nonequilibrium steady state .
G.M. Wang, J.C. Reid, D.M. Carberry, D.R.M. Williams, E.M. Sevick, D.J. Evans,
Physical Review E 0, 0, 2005.
115. Constrained dewetting of polymers grafted onto a nonadsorbing surface in poor solvents: Frompancake micelles to the holey layer.
J Huh, C.H. Ahn, W.H. Jo, J.N. Bright, D.R.M. Williams,
Macromolecules 38, 2974, 2005.