Thermodynamics of Open Chemical Reaction Networks: Theory and Applications
Invited
Abstract
After formulating a nonequilibrium thermodynamics for open chemical reaction networks, the theory will be applied to assess the thermodynamics performance of a dissipative self-assembly scheme. Power-efficiency and noise-dissipation trade-offs will be discussed.
References:
- R. Rao and M. Esposito, "Nonequilibrium Thermodynamics of Chemical Reaction Networks: Wisdom from Stochastic Thermodynamics", Phys. Rev. X 6, 041064 (2016)
- G. Falasco, R. Rao and M. Esposito, "Information Thermodynamics of Turing Patterns", Phys. Rev. Lett. 121, 108301 (2018)
- E. Penocchio, R. Rao and M. Esposito, "Thermodynamic Efficiency in Dissipative Chemistry", Nature Communications 10, 3865 (2019)
- G. Falasco, T. Cossetto, E. Penocchio and M. Esposito, "Negative differential response in chemical reactions", New J. Phys. 21, 073005 (2019)
References:
- R. Rao and M. Esposito, "Nonequilibrium Thermodynamics of Chemical Reaction Networks: Wisdom from Stochastic Thermodynamics", Phys. Rev. X 6, 041064 (2016)
- G. Falasco, R. Rao and M. Esposito, "Information Thermodynamics of Turing Patterns", Phys. Rev. Lett. 121, 108301 (2018)
- E. Penocchio, R. Rao and M. Esposito, "Thermodynamic Efficiency in Dissipative Chemistry", Nature Communications 10, 3865 (2019)
- G. Falasco, T. Cossetto, E. Penocchio and M. Esposito, "Negative differential response in chemical reactions", New J. Phys. 21, 073005 (2019)
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Presenters
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Massimiliano Esposito
University of Luxembourg Limpertsberg, University of Luxembourg
Authors
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Massimiliano Esposito
University of Luxembourg Limpertsberg, University of Luxembourg