(1) C.H. Bennett and R. Landauer, "The Fundamental Physical Limits of Computation," Scientific American, July 1985.  +

(10) Edward Fredkin and Tommaso Toffoli, "Conservative Logic," IJTP 21(3/4), 1982.  +

(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.  +

(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.  +

(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.  +

(14) M.P. Frank and T.F. Knight, Jr., "Ultimate Theoretical Models of Nanocomputers," Nanotechnology 9(3), 1998.  +

(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.  +

(16) M.P. Frank, Reversibility for Efficient Computing, Ph.D. thesis, MIT EECS Dept., June 1999.  +

(17) Archived copy of my old home page at UF  +

(18) My old home page at FSU (still up)  +

(19) My new home page at Sandia  +

(2) K. Eric Drexler, Engines of Creation: The Coming Era of Nanotechnology, Anchor Books, 1987.  +

(20) Physical Limits of Computing course directory  +

(21) RC'05 home page  +

(22) Reversible Computation conference series  +

(23) M.P. Frank, "Physical Foundations of Landauer's Principle," invited paper, 10th Conf. on Reversible Computation, Leicester, UK, Sep. 2018.  +

(24) M.P. Frank, "Physical Foundations of Landauer's Principle," slides for invited talk, 10th Conf. on Reversible Computation, Leicester, UK, Sep. 2018.  +

(25) M.P. Frank, "Physical Foundations of Landauer's Principle," extended postprint, arxiv:1901.10327 (cs.ET), Jan. 2019.  +

(26) M.P. Frank, "Foundations of Generalized Reversible Computing," 9th Conf. on Reversible Computation, Kolkata, India, July 2017.  +

(27) M.P. Frank, "Foundations of Generalized Reversible Computing," talk slides, 9th Conf. on Reversible Computation, Kolkata, India, July 2017.  +

(28) M.P. Frank, "Generalized Reversible Computing," extended postprint, arxiv:1806.10183 (cs.ET), Jun. 2018.  +

(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.  +

(3) K. Eric Drexler, Molecular Machinery and Manufacturing with Applications to Computation, Ph.D. thesis, MIT, 1991.  +

(4) K. Eric Drexler, Nanosystems: Molecular Machinery, Manufacturing, and Computation, Wiley, 1992.  +

(5) M.P. Frank, Advances in Decision-Theoretic AI: Limited Rationality and Abstract Search, M.S. thesis, MIT EECS Dept., 1994.  +

(6) M.P. Frank, "Cyclic Mixture Mutagenesis for DNA-Based Computing," unpublished Ph.D. proposal, MIT EECS Dept., Sep. 1995.  +

(7) Steven Levy, Hackers: Heroes of the Computer Revolution, Doubleday, 1984.  +

(8) Tommaso Toffoli and Norman Margolus, Cellular Automata Machines: A New Environment for Modeling, MIT Press, 1987.  +

(9) Information Mechanics group home page.  +

(Old) LBNL group website.  +

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  +

Alec Boyd's website  +

Andre Barato's website  +

Andy Adamatzky GS profile  +

Anne Condon's website.  +

Artemy Kolchinsky  +

Avinash Lingamneni's website  +

Aviv Bergman's website  +

Benjamin Machta's website  +

Bialek's Princeton page.  +

Bruno Loff's website  +

CAN WE LEARN (AGAIN) FROM NEUROSCIENCE ABOUT HOW TO DO COMPUTING?  +

Carl T. Bergstrom's website  +

Carlton M. Caves's website  +

Carnot’s Engine, Bernoulli’s Pump, and Turing’s Machine - Some clues to realization of ideal computing  +

Chris Jarzynski's UMD website.  +

Chris Kempe's SFI website.  +

Christian van den Broeck's homepage.  +

Christoph Flamm  +

Computation from Devices to System Level Thermodynamics  +

David Doty's website  +

David Krakaeur's website  +

David Sivak's SFU website.  +

David Wolpert's SFI website  +

Design for Sustainability: Energy Efficiency and Computing  +

Die Stacking (3D) Microarchitecture  +

Dorit Aharonov's wesbite  +

Edith Cohen's website  +

Energy Estimates Across Layers of Computing  +

Energy as a design variable in computing  +

Eric Libby's website  +

Erik Demaine's website  +

Erik Winfree's Caltech website.  +

Florent Krzakala's website.  +

Google Scholar  +

Harry Buhrman  +

Harvard Bio Page  +

Homepage  +

Hong Qian's UW website.  +

Ilya's website.  +

Janet Anders's website  +

Jennifer Chayes's website  +

Jeremy England's website  +

Jessica Flack's homepage  +

Jim Crutchfield's website.  +

John C. Doyle's website  +

John's UCDavis Web page  +

Jordan M. Horowitz's website  +

Joseph Lizier's website  +

Joshua Grochow's CU Boulder Website  +

Julia Kempe's website  +

Karl Friston's website  +

Lab webpage  +

Lance Fortnow's website  +

Lenka Zdeborová's website.  +

Lessons from Nature for Computing  +

LinkedIn profile  +

Manoj Gopalkrishnan's home page  +

Marc Mézard's website.  +

Massimiliano Esposito's website.  +

Maxwell’s Demon, Schrodinger’s Cat, and Broca’s Brain: Gate keepers to the Future of Computing  +

Michael Deweese's website  +

Michael Lachmann's website  +

Ming Li's website  +

Nigel Goldenfeld's website  +

Nihat Ay's website  +

Non-equilibrium dynamics of electrons in weakly ionized plasmas from Boltzmann Equation  +

Paul Davies's website  +

Personal Homepage  +

Personal Website  +