We consider damped stochastic systems in a controlled (time-varying) potential and study their transition between specified Gibbs-equilibria states in finite time. By the second law of thermodynamics, the minimum amount of work needed to transition from one equilibrium state to another is the difference between the Helmholtz free energy of the two states and can only be achieved by a reversible (infinitely slow) process. The minimal gap between the work needed in a finite-time transition and the work during a reversible one, turns out to equal the square of the optimal mass transport (Wasserstein-2) distance between the two end-point distributions times the inverse of the duration needed for the transition. This result, in fact, relates non...
This paper reviews a new theory for non-equilibrium statistical mechanics. This gives the non-equili...
We study the thermodynamics of open systems weakly driven out-of-equilibrium by nonconservative and ...
Fokker-Planck equations, along with stochastic differential equations, play vital roles in physics, ...
We consider damped stochastic systems in a controlled (time-varying) potential and study their trans...
Stochastic thermodynamics lays down a broad framework to revisit the venerable concepts of heat, wor...
We present a stylized model of controlled equilibration of a small system in a fluctuating environme...
Stochastic thermodynamics lays down a broad framework to revisit the venerable concepts of heat, wor...
We analyze Furth's 1933 classical uncertainty relations in the modern language of stochastic differe...
We present a stylized model of controlled equilibration of a small system in a fluctuating environme...
Classical thermodynamics is aimed at quantifying the efficiency of thermodynamic engines by bounding...
In this paper, we present connections between recent developments on the linearly-solvable stochasti...
In 1931-1932, Erwin Schrödinger studied a hot gas Gedankenexperiment (an instance of large deviation...
The starting point of my thesis is a recent result of microscopic thermodynamics obtained with techn...
Quantifying energy flows at nanometer scales promises to guide future research in a variety of disci...
Complex systems can convert energy imparted by nonequilibrium forces to regulate how quickly they tr...
This paper reviews a new theory for non-equilibrium statistical mechanics. This gives the non-equili...
We study the thermodynamics of open systems weakly driven out-of-equilibrium by nonconservative and ...
Fokker-Planck equations, along with stochastic differential equations, play vital roles in physics, ...
We consider damped stochastic systems in a controlled (time-varying) potential and study their trans...
Stochastic thermodynamics lays down a broad framework to revisit the venerable concepts of heat, wor...
We present a stylized model of controlled equilibration of a small system in a fluctuating environme...
Stochastic thermodynamics lays down a broad framework to revisit the venerable concepts of heat, wor...
We analyze Furth's 1933 classical uncertainty relations in the modern language of stochastic differe...
We present a stylized model of controlled equilibration of a small system in a fluctuating environme...
Classical thermodynamics is aimed at quantifying the efficiency of thermodynamic engines by bounding...
In this paper, we present connections between recent developments on the linearly-solvable stochasti...
In 1931-1932, Erwin Schrödinger studied a hot gas Gedankenexperiment (an instance of large deviation...
The starting point of my thesis is a recent result of microscopic thermodynamics obtained with techn...
Quantifying energy flows at nanometer scales promises to guide future research in a variety of disci...
Complex systems can convert energy imparted by nonequilibrium forces to regulate how quickly they tr...
This paper reviews a new theory for non-equilibrium statistical mechanics. This gives the non-equili...
We study the thermodynamics of open systems weakly driven out-of-equilibrium by nonconservative and ...
Fokker-Planck equations, along with stochastic differential equations, play vital roles in physics, ...