This is a list of Related websites.

Researcher web sites[edit source]

1. Alec Boyd's website
2. Andre Barato's website
3. Andy Adamatzky GS profile
4. Anne Condon's website.
5. Artemy Kolchinsky
6. Avinash Lingamneni's website
7. Aviv Bergman's website
8. Benjamin Machta's website
9. Homepage
10. Bruno Loff's website
11. Carl T. Bergstrom's website
12. Carlton M. Caves's website
13. Chris Kempe's SFI website.
14. Christian van den Broeck's homepage.
15. Christoph Flamm
16. Chris Jarzynski's UMD website.
17. David Doty's website
18. David Krakaeur's website
19. David Sivak's SFU website.
20. David Wolpert's SFI website
21. Dorit Aharonov's wesbite
22. Edith Cohen's website
23. Eric Libby's website
24. Erik Demaine's website
25. Erik Winfree's Caltech website.
26. Florent Krzakala's website.
27. (Old) LBNL group website.
28. Tkačik Group IST website.
29. Harry Buhrman
30. Hong Qian's UW website.
31. Ilya's website.
32. Jim Crutchfield's website.
33. Janet Anders's website
34. Jennifer Chayes's website
35. Jeremy England's website
36. Jessica Flack's homepage
37. John C. Doyle's website
38. John's UCDavis Web page
39. Jordan M. Horowitz's website
40. Joseph Lizier's website
41. Joshua Grochow's CU Boulder Website
42. Julia Kempe's website
43. Karl Friston's website
44. Special Session: Exploring the Ultimate Limits of Adiabatic Circuits (co-authors: M. Frank, R. Brocato; T. Conte; A. Hsia; A. Jain; N. Missert; B. Tierney)
45. Quantum Foundations of Classical Reversible Computing
46. Lance Fortnow's website
47. Lenka Zdeborová's website.
48. Manoj Gopalkrishnan's home page
49. Video lecture on thermodynamics of information processing
50. Marc Mézard's website.
51. Massimiliano Esposito's website.
52. Michael Deweese's website
53. (19) My new home page at Sandia
54. (2) K. Eric Drexler, Engines of Creation: The Coming Era of Nanotechnology, Anchor Books, 1987.
55. (16) M.P. Frank, Reversibility for Efficient Computing, Ph.D. thesis, MIT EECS Dept., June 1999.
56. (3) K. Eric Drexler, Molecular Machinery and Manufacturing with Applications to Computation, Ph.D. thesis, MIT, 1991.
57. (28) M.P. Frank, "Generalized Reversible Computing," extended postprint, arxiv:1806.10183 (cs.ET), Jun. 2018.
58. (9) Information Mechanics group home page.
59. (10) Edward Fredkin and Tommaso Toffoli, "Conservative Logic," IJTP 21(3/4), 1982.
60. (24) M.P. Frank, "Physical Foundations of Landauer's Principle," slides for invited talk, 10th Conf. on Reversible Computation, Leicester, UK, Sep. 2018.
61. (13) C. Vieri, M.J. Ammer, M. Frank, N. Margolus, T. Knight, "A Fully Reversible Asymptotically Zero Energy Microprocessor," in Power Driven Microarchitecture Workshop, pp. 138-142, May 1998.
62. (17) Archived copy of my old home page at UF
63. (14) M.P. Frank and T.F. Knight, Jr., "Ultimate Theoretical Models of Nanocomputers," Nanotechnology 9(3), 1998.
64. (11) Saed G. Younis and Thomas F. Knight, Jr., "Practical implementation of charge recovering asymptotically zero power CMOS," Proc.1993 Symp. on Research on Integrated Systems, MIT Press, pp. 234-250.
65. (27) M.P. Frank, "Foundations of Generalized Reversible Computing," talk slides, 9th Conf. on Reversible Computation, Kolkata, India, July 2017.
66. (1) C.H. Bennett and R. Landauer, "The Fundamental Physical Limits of Computation," Scientific American, July 1985.
67. (29) M.P. Frank, "Reversible Computing as a Path towards Unbounded Energy Efficiency: Challenges and Opportunities," slides for invited talk, 3rd IEEE Int'l. Conf. on Rebooting Computing, Washington, DC, Nov. 2018.
68. (5) M.P. Frank, Advances in Decision-Theoretic AI: Limited Rationality and Abstract Search, M.S. thesis, MIT EECS Dept., 1994.
69. (26) M.P. Frank, "Foundations of Generalized Reversible Computing," 9th Conf. on Reversible Computation, Kolkata, India, July 2017.
70. (18) My old home page at FSU (still up)
71. (20) Physical Limits of Computing course directory
72. (12) M.J. Ammer, M. Frank, T. Knight, N. Love, N. Margolus, and C. Vieri, "A Scalable Reversible Computer in Silicon," Unconventional Models of Computation, Calude, Casti, Dineen (eds.), Springer, 1998.
73. (7) Steven Levy, Hackers: Heroes of the Computer Revolution, Doubleday, 1984.
74. (4) K. Eric Drexler, Nanosystems: Molecular Machinery, Manufacturing, and Computation, Wiley, 1992.
75. (6) M.P. Frank, "Cyclic Mixture Mutagenesis for DNA-Based Computing," unpublished Ph.D. proposal, MIT EECS Dept., Sep. 1995.
76. (15) M.P. Frank, T.F. Knight, Jr., and N.H. Margolus, "Reversibility in optimally scalable computer architectures," Unconventional Models of Computation, Calude, Casti, Dineen (eds.), Springer, 1998.
77. (22) Reversible Computation conference series
78. (21) RC'05 home page
79. (8) Tommaso Toffoli and Norman Margolus, Cellular Automata Machines: A New Environment for Modeling, MIT Press, 1987.
80. (25) M.P. Frank, "Physical Foundations of Landauer's Principle," extended postprint, arxiv:1901.10327 (cs.ET), Jan. 2019.
81. (23) M.P. Frank, "Physical Foundations of Landauer's Principle," invited paper, 10th Conf. on Reversible Computation, Leicester, UK, Sep. 2018.
82. Michael Lachmann's website
83. Ming Li's website
84. Tishby Hebrew University website.
85. Nigel Goldenfeld's website
86. Nihat Ay's website
87. Paul Davies's website
88. Reference Materials
89. Peter Stadler's Leipzing website.
90. Personal Website
91. University Website
92. Pieter Rein ten Wolde's website.
93. Rakesh Kumar's website
94. LinkedIn profile
95. Lab webpage
96. Riccardo Zecchina's Research Website
97. Statistical Inference and Computational Biology at the Human Genetics Foundation
98. Rory Brittain's website.
99. Non-equilibrium dynamics of electrons in weakly ionized plasmas from Boltzmann Equation
100. Lessons from Nature for Computing
101. Maxwell’s Demon, Schrodinger’s Cat, and Broca’s Brain: Gate keepers to the Future of Computing
102. Untangling Feynman's puzzle: Examining the future of computing
103. Die Stacking (3D) Microarchitecture
104. Physical Bioenergetics
105. CAN WE LEARN (AGAIN) FROM NEUROSCIENCE ABOUT HOW TO DO COMPUTING?
106. Computation from Devices to System Level Thermodynamics
107. APS March Meeting 2021: Use of Carnot’s Engine and Bernoulli’s Pump to identify efficiency of information processing for computing beyond Moore's Law
108. Carnot’s Engine, Bernoulli’s Pump, and Turing’s Machine - Some clues to realization of ideal computing
109. Harvard Bio Page
110. Stanford Web Page
111. Q&A: How to make computing more sustainable
112. Energy as a design variable in computing
113. Design for Sustainability: Energy Efficiency and Computing
114. Energy Estimates Across Layers of Computing
115. Scott Aaronson's website
116. Sebastian Deffner's website
117. Seth Lloyd's website
118. Shafi Goldwasser's website
119. Twitter
120. Google Scholar
121. Personal Homepage
122. Sharon Glotzer's website
123. Simon Laughlin's Cambridge website
124. Srividya Iyer-Biswas's website
125. Steve Frank's website
126. Susan Fitzpatrick's website
127. Takahiro Sagawa's website.
128. Terry Sejnowski's Salk Institute website.
129. Website for the group "Principles of biomolecular systems"
130. Thomas Ouldridge's website
131. Udo Seifert's website
132. Virginia Vassilevska Williams' website.
133. Walter Fontana's website
134. Bialek's Princeton page.
135. Wojciech H. Zurek's website.
136. webpage

Conference/summer school websites[edit source]

1. Santa Fe institute summer school
2. Beg Rohu Summer school
3. Boulder Summer School
4. Gordon Research Conferences
5. Berkeley Mini Stat Mech
6. Statistical Mechanics Conference in Rutgers

Funding agencies[edit source]

1. NSF
2. DARPA
3. DOE
4. MRSEC
5. Simons Foundation

Events calendar meetings sites[edit source]

1. 119th Statistical Mechanics Conference
2. APS March Meeting 2019
3. Beilstein Bozen Symposium
4. Entropy 2018
5. Max Ent 2018