Mesoscopic Coulomb Drag, Broken Detailed Balance, and Fluctuation Relations

We review the physical meaning and mathematical implementation of the condition of local detailed balance for a class of nonequilibrium mesoscopic processes. A central concept is that of fluctuating entropy flux for which the steady average gives the mean entropy production rate. We repeat how local detailed balance is essentially equivalent to the widely discussed fluctuation relations for that entropy flux and hence is at most ``only half of the story.''

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Dielectronic Recombination in the Average-Atom Model

International Astronomical Union Colloquium ◽

10.1017/s0252921100107730 ◽

1988 ◽

Vol 102 ◽

pp. 215

Author(s):

R.M. More ◽

G.B. Zimmerman ◽

Z. Zinamon

Keyword(s):

Detailed Balance ◽

Systematic Errors ◽

Dielectronic Recombination ◽

Rate Equations ◽

Strong Correlations ◽

Dense Plasmas ◽

Atom Model ◽

New Feature ◽

Average Atom Model ◽

Attachment Process

Autoionization and dielectronic attachment are usually omitted from rate equations for the non–LTE average–atom model, causing systematic errors in predicted ionization states and electronic populations for atoms in hot dense plasmas produced by laser irradiation of solid targets. We formulate a method by which dielectronic recombination can be included in average–atom calculations without conflict with the principle of detailed balance. The essential new feature in this extended average atom model is a treatment of strong correlations of electron populations induced by the dielectronic attachment process.

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The Rotterdam Initiative in Reducing Waste Discharges at Source

Water Science & Technology ◽

10.2166/wst.1991.0289 ◽

1991 ◽

Vol 24 (10) ◽

pp. 171-177

Author(s):

T. Vellinga ◽

J. P. J. Nijssen

Keyword(s):

Public Relations ◽

Action Plan ◽

Detailed Balance ◽

River Rhine ◽

The North ◽

Complementary Role ◽

Action Programme ◽

The North Sea ◽

Set Up

Much of the material dredged from the port of Rotterdam is contaminated to such a degree that it must be placed in specially constructed sites. The aim of Rotterdam is to ensure that the dredged material will once again be clean. This will entail the thorough cleansing of the sources of the contamination of the sediment in the harbours and in the River Rhine. The Rotterdam Rhine Research Project (RRP) is one of the means to achieve this based on: technical research, legal research, public relations and dialogues with dischargers. The programme for five selected heavy metals is almost complete. For many heavy metal discharge points between Rotterdam and Rheinfelden, a specially devised independent load assessment has been carried out four times. Balance studies were used to determine the relative contributions of the point discharges to the total. Currently the results are being used in an attempt to negotiate agreements with a selected number of the major dischargers. At present, more detailed balance studies are being set up and exploratory measurements carried out for organic micropollutants. It may be concluded that the research is progressing successfully and methods and techniques developed seem satisfactory and broadly applicable. The Rhine Action Programme encompasses an international effort to improve the quality of the Rhine water. Although the RRP plays a modest complementary role to the Rhine Action Plan, there is no doubt of the value of this Rotterdam initiative. The mode of work followed in the RRP contains elements that can be of use in combatting the contamination of the North Sea by rivers other than the Rhine.

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Coarse-grained entropy production with multiple reservoirs: Unraveling the role of time scales and detailed balance in biology-inspired systems

Physical Review Research ◽

10.1103/physrevresearch.2.043257 ◽

2020 ◽

Vol 2 (4) ◽

Author(s):

Daniel M. Busiello ◽

Deepak Gupta ◽

Amos Maritan

Keyword(s):

Entropy Production ◽

Time Scales ◽

Detailed Balance ◽

Coarse Grained

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Photon recycling in perovskite solar cells assessed by a detailed-balance compatible dipole emission model

10.1109/pvsc43889.2021.9518720 ◽

2021 ◽

Author(s):

Urs Aeberhard ◽

Simon J. Zeder ◽

Beat Ruhstaller

Keyword(s):

Solar Cells ◽

Detailed Balance ◽

Perovskite Solar Cells ◽

Emission Model ◽

Dipole Emission ◽

Photon Recycling

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Fluctuation Relations for Dissipative Systems in Constant External Magnetic Field: Theory and Molecular Dynamics Simulations

Entropy ◽

10.3390/e23020146 ◽

2021 ◽

Vol 23 (2) ◽

pp. 146

Author(s):

Alessandro Coretti ◽

Lamberto Rondoni ◽

Sara Bonella

Keyword(s):

Magnetic Field ◽

Molecular Dynamics ◽

External Magnetic Field ◽

Molecular Dynamics Simulations ◽

Nonequilibrium Molecular Dynamics ◽

Dissipative Systems ◽

Common Belief ◽

Fluctuation Relations ◽

Dynamics Simulations ◽

Constant External Magnetic Field

We illustrate how, contrary to common belief, transient Fluctuation Relations (FRs) for systems in constant external magnetic field hold without the inversion of the field. Building on previous work providing generalized time-reversal symmetries for systems in parallel external magnetic and electric fields, we observe that the standard proof of these important nonequilibrium properties can be fully reinstated in the presence of net dissipation. This generalizes recent results for the FRs in orthogonal fields—an interesting but less commonly investigated geometry—and enables direct comparison with existing literature. We also present for the first time a numerical demonstration of the validity of the transient FRs with nonzero magnetic field via nonequilibrium molecular dynamics simulations of a realistic model of liquid NaCl.

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Fast Reaction Limits via $$\Gamma $$-Convergence of the Flux Rate Functional

Journal of Dynamics and Differential Equations ◽

10.1007/s10884-021-10024-2 ◽

2021 ◽

Author(s):

Mark A. Peletier ◽

D. R. Michiel Renger

Keyword(s):

Evolution Equations ◽

Detailed Balance ◽

Approximate Solutions ◽

Reaction Rates ◽

Convergence Result ◽

Rate Function ◽

Jump Processes ◽

Kolmogorov Equations ◽

Markov Jump ◽

Fast Reaction

AbstractWe study the convergence of a sequence of evolution equations for measures supported on the nodes of a graph. The evolution equations themselves can be interpreted as the forward Kolmogorov equations of Markov jump processes, or equivalently as the equations for the concentrations in a network of linear reactions. The jump rates or reaction rates are divided in two classes; ‘slow’ rates are constant, and ‘fast’ rates are scaled as $$1/\epsilon $$ 1 / ϵ , and we prove the convergence in the fast-reaction limit $$\epsilon \rightarrow 0$$ ϵ → 0 . We establish a $$\Gamma $$ Γ -convergence result for the rate functional in terms of both the concentration at each node and the flux over each edge (the level-2.5 rate function). The limiting system is again described by a functional, and characterises both fast and slow fluxes in the system. This method of proof has three advantages. First, no condition of detailed balance is required. Secondly, the formulation in terms of concentration and flux leads to a short and simple proof of the $$\Gamma $$ Γ -convergence; the price to pay is a more involved compactness proof. Finally, the method of proof deals with approximate solutions, for which the functional is not zero but small, without any changes.

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