The ability to implement adiabatic processes in the mesoscale is of key importance in the study o... more The ability to implement adiabatic processes in the mesoscale is of key importance in the study of artificial or biological micro- and nanoengines. Microadiabatic processes have been elusive to experimental implementation due to the difficulty in isolating Brownian particles from their fluctuating environment. Here we report on the experimental realization of a microscopic quasistatic adiabatic process employing a trapped Brownian particle. We circumvent the complete isolation of the Brownian particle by designing a protocol where both characteristic volume and temperature of the system are changed in such a way that the entropy of the system is conserved along the process. We compare the protocols that follow from either the overdamped or underdamped descriptions, demonstrating that the latter is mandatory in order to obtain a vanishing average heat flux to the particle. We provide analytical expressions for the distributions of the fluctuating heat and entropy and verify them expe...
In this work, the ratchet dynamics of Brownian particles driven by an external sinusoidal (harmon... more In this work, the ratchet dynamics of Brownian particles driven by an external sinusoidal (harmonic) force is investigated. The gating ratchet effect is observed when another harmonic is used to modulate the spatially symmetric potential in which the particles move. For small amplitudes of the harmonics, it is shown that the current (average velocity) of particles exhibits a sinusoidal shape as a function of a precise combination of the phases of both harmonics. By increasing the amplitudes of the harmonics beyond the small-limit regime, departures from the sinusoidal behavior are observed and current reversals can also be induced. These current reversals persist even for the overdamped dynamics of the particles.
ABSTRACT Carnot engine played a crucial role in the development of thermodynamics, setting a fund... more ABSTRACT Carnot engine played a crucial role in the development of thermodynamics, setting a fundamental upper limit to the efficiency of a motor operating between two thermal baths. Nowadays, micromanipulation techniques make possible to explore the thermodynamics of small systems at scales where fluctuations cannot be neglected. Here, we report on an experimental realization of a Carnot engine with a single optically trapped Brownian particle as working substance. We fully characterize the thermodynamics of the engine when operating both in and out of equilibrium, observing that our device reaches Carnot efficiency for slow driving. We also report on the fluctuations of the finite-time stochastic efficiency, showing that Carnot efficiency can be surpassed in individual or ensembles of a few number of non-equilibrium realizations of the engine. We analyze the stochastic efficiency large deviation behaviour and find a minimum of the distribution which can provide information about the fundamental characteristics of the engine. http://arxiv.org/abs/1412.1282
Two rectification mechanisms in vortex lattice dynamics in Nb films have been studied. These two ... more Two rectification mechanisms in vortex lattice dynamics in Nb films have been studied. These two effects are based on ratchet effects, that is, an ac driving force induces a net dc vortex flow. In our case, an input ac current applied to the Nb films, grown on top of arrays of Ni nanotriangles, yields an output dc voltage. These two rectification effects occur when the vortex lattice moves in periodic asymmetric potentials. These pinning potentials are induced by the array of Ni triangles. In one configuration (longitudinal effect) the driven force is applied perpendicular to the triangle reflection symmetry axis; in the second one (transverse effect) the input current is injected parallel to the triangle reflection symmetry axis. In the framework of the rocking ratchet mechanism, the appropriate Langevin equation allows us to model the experimental data, taking into account the vortex-vortex interaction.
The ability to implement adiabatic processes in the mesoscale is of key importance in the study o... more The ability to implement adiabatic processes in the mesoscale is of key importance in the study of artificial or biological micro- and nanoengines. Microadiabatic processes have been elusive to experimental implementation due to the difficulty in isolating Brownian particles from their fluctuating environment. Here we report on the experimental realization of a microscopic quasistatic adiabatic process employing a trapped Brownian particle. We circumvent the complete isolation of the Brownian particle by designing a protocol where both characteristic volume and temperature of the system are changed in such a way that the entropy of the system is conserved along the process. We compare the protocols that follow from either the overdamped or underdamped descriptions, demonstrating that the latter is mandatory in order to obtain a vanishing average heat flux to the particle. We provide analytical expressions for the distributions of the fluctuating heat and entropy and verify them expe...
In this work, the ratchet dynamics of Brownian particles driven by an external sinusoidal (harmon... more In this work, the ratchet dynamics of Brownian particles driven by an external sinusoidal (harmonic) force is investigated. The gating ratchet effect is observed when another harmonic is used to modulate the spatially symmetric potential in which the particles move. For small amplitudes of the harmonics, it is shown that the current (average velocity) of particles exhibits a sinusoidal shape as a function of a precise combination of the phases of both harmonics. By increasing the amplitudes of the harmonics beyond the small-limit regime, departures from the sinusoidal behavior are observed and current reversals can also be induced. These current reversals persist even for the overdamped dynamics of the particles.
ABSTRACT Carnot engine played a crucial role in the development of thermodynamics, setting a fund... more ABSTRACT Carnot engine played a crucial role in the development of thermodynamics, setting a fundamental upper limit to the efficiency of a motor operating between two thermal baths. Nowadays, micromanipulation techniques make possible to explore the thermodynamics of small systems at scales where fluctuations cannot be neglected. Here, we report on an experimental realization of a Carnot engine with a single optically trapped Brownian particle as working substance. We fully characterize the thermodynamics of the engine when operating both in and out of equilibrium, observing that our device reaches Carnot efficiency for slow driving. We also report on the fluctuations of the finite-time stochastic efficiency, showing that Carnot efficiency can be surpassed in individual or ensembles of a few number of non-equilibrium realizations of the engine. We analyze the stochastic efficiency large deviation behaviour and find a minimum of the distribution which can provide information about the fundamental characteristics of the engine. http://arxiv.org/abs/1412.1282
Two rectification mechanisms in vortex lattice dynamics in Nb films have been studied. These two ... more Two rectification mechanisms in vortex lattice dynamics in Nb films have been studied. These two effects are based on ratchet effects, that is, an ac driving force induces a net dc vortex flow. In our case, an input ac current applied to the Nb films, grown on top of arrays of Ni nanotriangles, yields an output dc voltage. These two rectification effects occur when the vortex lattice moves in periodic asymmetric potentials. These pinning potentials are induced by the array of Ni triangles. In one configuration (longitudinal effect) the driven force is applied perpendicular to the triangle reflection symmetry axis; in the second one (transverse effect) the input current is injected parallel to the triangle reflection symmetry axis. In the framework of the rocking ratchet mechanism, the appropriate Langevin equation allows us to model the experimental data, taking into account the vortex-vortex interaction.
Uploads
Papers by Luis Dinis