The control of chemical dynamics requires understanding the effect of time-dependent transition rates between states of chemomechanical molecular configurations. Pumping refers to generating a net current, e.g., per period in the time dependence, through a cycle of consecutive states. The work of artificial machines or synthesized molecular motors depends on it. In this paper we give short and simple proofs of no-go theorems, some of which appeared before but here with essential extensions to non-Markovian dynamics, including the study of the diffusion limit. It allows to exclude certain protocols in the working of chemical motors where only the depth of the energy well is changed in time and not the barrier height between pairs of states. ...
The global stability of dynamical systems and networks is still challenging to study. We developed a...
Stochastic thermodynamics lays down a broad framework to revisit the venerable concepts of heat, wor...
Complex systems can convert energy imparted by nonequilibrium forces to regulate how quickly they tr...
The control of chemical dynamics requires understanding the effect of time-dependent transition rate...
Despite inherent randomness and thermal fluctuations, controllable molecular devices or molecular ma...
Despite inherent randomness and thermal fluctuations, controllable molecular devices or molecular ...
Under static conditions, a system satisfying detailed balance generically relaxes to an equilibrium ...
From molecular machines to quantum dots, a wide range of mesoscopic systems can be modeled by period...
A major goal in the design of synthetic molecular machines is the creation of pumps that can use the...
Quantifying energy flows at nanometer scales promises to guide future research in a variety of disci...
We show that a reversible pumping mechanism operating between two states of a kinetic network can gi...
In this thesis we study two stochastic models related to operation of a molecular mo- tor. The first...
Molecular motors and nanomachines are considered that are coupled to exergonic processes which provi...
The concepts of equilibrium and nonequilibrium steady states are introduced in the present review as...
Stochastic thermodynamics lays down a broad framework to revisit the venerable concepts of heat, wor...
The global stability of dynamical systems and networks is still challenging to study. We developed a...
Stochastic thermodynamics lays down a broad framework to revisit the venerable concepts of heat, wor...
Complex systems can convert energy imparted by nonequilibrium forces to regulate how quickly they tr...
The control of chemical dynamics requires understanding the effect of time-dependent transition rate...
Despite inherent randomness and thermal fluctuations, controllable molecular devices or molecular ma...
Despite inherent randomness and thermal fluctuations, controllable molecular devices or molecular ...
Under static conditions, a system satisfying detailed balance generically relaxes to an equilibrium ...
From molecular machines to quantum dots, a wide range of mesoscopic systems can be modeled by period...
A major goal in the design of synthetic molecular machines is the creation of pumps that can use the...
Quantifying energy flows at nanometer scales promises to guide future research in a variety of disci...
We show that a reversible pumping mechanism operating between two states of a kinetic network can gi...
In this thesis we study two stochastic models related to operation of a molecular mo- tor. The first...
Molecular motors and nanomachines are considered that are coupled to exergonic processes which provi...
The concepts of equilibrium and nonequilibrium steady states are introduced in the present review as...
Stochastic thermodynamics lays down a broad framework to revisit the venerable concepts of heat, wor...
The global stability of dynamical systems and networks is still challenging to study. We developed a...
Stochastic thermodynamics lays down a broad framework to revisit the venerable concepts of heat, wor...
Complex systems can convert energy imparted by nonequilibrium forces to regulate how quickly they tr...