Udo Seifert
Biography: Udo Seifert is physicist working on stochastic thermodynamics and information processing in biology.
Field(s) of Research: Chemical Reaction Networks, General Non-equilibrium Statistical Physics, Stochastic Thermodynamics, Thermodynamics and Computation in Biological Systems"Thermodynamics and Computation in Biological Systems" is not in the list (Chemical Reaction Networks, Computer Science Engineering to Address Energy Costs, Computer Science Theory, General Non-equilibrium Statistical Physics, Stochastic Thermodynamics, Thermodynamics of Neurobiology, Thermodynamics of Single Cells, Artificial Biological Computation, Logically Reversible Computing, Naturally Occurring Biological Computation, ...) of allowed values for the "Field of Research" property., Thermodynamics of Single Cells
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Reference Materials
- An autonomous and reversible Maxwell's demon
- Communications: Can one identify nonequilibrium in a three-state system by analyzing two-state trajectories?
- Dissipated work in driven harmonic diffusive systems: General solution and application to stretching Rouse polymers
- Distribution of work in isothermal nonequilibrium processes
- Effective confinement as origin of the equivalence of kinetic temperature and fluctuation-dissipation ratio in a dense shear-driven suspension
- Efficiency at maximum power: An analytically solvable model for stochastic heat engines
- Efficiency of autonomous soft nanomachines at maximum power
- Efficiency of cellular information processing
- Efficiency of molecular motors at maximum power
- Einstein relation generalized to nonequilibrium
- Entropy production along a stochastic trajectory and an integral fluctuation theorem
- Entropy production for mechanically or chemically driven biomolecules
- Experimental accessibility of generalized fluctuation-dissipation relations for nonequilibrium steady states
- Experimental test of the fluctuation theorem for a driven two-level system with time-dependent rates
- Extended fluctuation-dissipation theorem for soft matter in stationary flow
- Extracting work from a single heat bath through feedback
- Fluctuation theorem for a single enzym or molecular motor
- Fluctuation theorem for birth-death or chemical master equations with time-dependent rates
- Generalized einstein or green-kubo relations for active biomolecular transport
- Information-theoretic versus thermodynamic entropy production in autonomous sensory networks
- Integral fluctuation theorem for the housekeeping heat
- Large deviation function for entropy production in driven one-dimensional systems
- Measurement of stochastic entropy production
- Nonequilibrium steady states in contact: Approximate thermodynamic structure and zeroth law for driven lattice gases
- Nonexistence of classical diamagnetism and nonequilibrium fluctuation theorems for charged particles on a curved surface
- Optimal finite-time processes in stochastic thermodynamics
- Optimal potentials for temperature ratchets
- Optimal protocols for minimal work processes in underdamped stochastic thermodynamics
- Probing molecular free energy landscapes by periodic loading
- Rate of Mutual Information Between Coarse-Grained Non-Markovian Variables
- Role of external flow and frame invariance in stochastic thermodynamics
- Role of hidden slow degrees of freedom in the fluctuation theorem
- Stochastic thermodynamics of bipartite systems: Transfer entropy inequalities and a Maxwell's demon interpretation
- Stochastic thermodynamics of chemical reaction networks
- Stochastic thermodynamics of single enzymes and molecular motors
- Stochastic thermodynamics with information reservoirs
- Stochastic thermodynamics, fluctuation theorems and molecular machines
- The Jarzynski relation, fluctuation theorems, and stochastic thermodynamics for non-Markovian processes
- Thermodynamic Uncertainty Relation for Biomolecular Processes
- Thermodynamics of a colloidal particle in a time-dependent nonharmonic potential
- Thermodynamics of genuine nonequilibrium states under feedback control
- Unifying three perspectives on information processing in stochastic thermodynamics