Steepest-entropy-ascent nonequilibrium quantum thermodynamic framework to model chemical reaction rates at an atomistic level

J. Phys.: Condens. Matter

Reynolds

2019

The magnetization of body-centered cubic iron at low temperatures is calculated with the steepestentropy-ascent quantum thermodynamics (SEAQT) framework. This framework assumes that a thermodynamic property in an isolated system traces the path through state space with the greatest entropy production. Magnetization is calculated from the expected value of a thermodynamic ensemble of quantized spin waves based on the Heisenberg spin model applied to an ensemble of coupled harmonic oscillators. A realistic energy landscape is obtained from a magnon dispersion relation calculated using spin-density-functional-theory. The equilibrium magnetization as well as the evolution of magnetization from a non-equilibrium state to equilibrium are calculated from the path of steepest entropy ascent determined from the SEAQT equation of motion in state space. The framework makes it possible to model the temperature-and time-dependence of magnetization without a detailed description of magnetic damping. The approach is also used to define intensive properties (temperature and magnetic field strength) that are fundamentally, i.e., canonically or grand canonically, valid for any non-equilibrium state. Given the assumed magnon dispersion relation, the SEAQT framework is used to calculate the equilibrium magnetization at different temperatures and external magnetic fields and the results are shown to closely agree with experiment for temperatures less than 500 K. The time-dependent evolution of magnetization from different initial states and interactions with a reservoir is also predicted. arXiv:1809.10619v2 [cond-mat.mtrl-sci]

Section: System Reservoirmentioning

confidence: 99%

Low-temperature atomistic spin relaxation and non-equilibrium intensive properties using steepest-entropy-ascent quantum-inspired thermodynamics modeling

Yamada

J. Phys.: Condens. Matter

Reynolds

2019

“…The thermodynamic state of the system at any given instant of time is then represented by a probability distribution among the system eigenstates. More detailed descriptions of this novel approach describing the chemical and electrochemical kinetics of reacting quantum systems can be found in [29,30,43]. Given the energy eigenlevels of the system and each nonequilibrium state represented by a probability distribution {p i , i = 1, 2, ⋯}, the SEAQT equation of motion is used to model the chemical and electrochemical reaction pathways.…”

Section: Seaqt Chemical/electrochemical Reaction and Transport Model:mentioning

confidence: 99%

“…To address these issues of time and length scales and the influence of microscopic and mesoscopic parameters, a novel approach based on the SEAQT mathematical framework of intrinsic quantum thermodynamics (IQT) [24][25][26][27][28][29][30][31][32][33][34][35][36] is used here. The resulting model with a significantly smaller computational burden than that of the conventional approach links atomistic-level information with macroscopic, predicting both transport coefficients and reaction rate constants in the presence of coupled and uncoupled phenomena and doing so without the inclusion of all the intermediate models used in the more conventional approach.…”

Section: Introductionmentioning

confidence: 99%

Multiscale Transient and Steady-State Study of the Influence of Microstructure Degradation and Chromium Oxide Poisoning on Solid Oxide Fuel Cell Cathode Performance

Journal of Non-Equilibrium Thermodynamics

Shen

et al. 2018

Oxygen reduction in a solid oxide fuel cell cathode involves a nonequilibrium process of coupled mass and heat diffusion and electrochemical and chemical reactions. These phenomena occur at multiple temporal and spatial scales, making the modeling, especially in the transient regime, very difficult. Nonetheless, multiscale models are needed to improve the understanding of oxygen reduction and guide cathode design. Of particular importance for long-term operation are microstructure degradation and chromium oxide poisoning both of which degrade cathode performance. Existing methods are phenomenological or empirical in nature and their application limited to the continuum realm with quantum effects not captured. In contrast, steepest-entropy-ascent quantum thermodynamics can be used to model nonequilibrium processes (even those far-from equilibrium) at all scales. The nonequilibrium relaxation is characterized by entropy generation, which can unify coupled phenomena into one framework to model transient and steady behavior. The results reveal the effects on performance of the different timescales of the varied phenomena involved and their coupling. Results are included here for the effects of chromium oxide concentrations on cathode output as is a parametric study of the effects of interconnect-three-phase-boundary length, oxygen mean free path, and adsorption site effectiveness. A qualitative comparison with experimental results is made.

“…In such an approach, the evolution of state can occur non-unitarily consistent with both the postulates of QM and thermodynamics. One such approach is that of intrinsic quantum thermodynamics (IQT) [31][32][33][34][35][36][37][38][39][40] and its mathematical framework steepest-entropy-ascent quantum thermodynamics (SEAQT) [41][42][43][44][45][46][47][48][49][50][51][52][53][54][55]. It is this approach and the ones described above that are representative of the contrasting views of the origins of irreversible changes that form the basis of the field of quantum thermodynamics [25,56,57], which has developed over the last four decades and has grown exponentially in the last decade and a half.…”

Section: Introductionmentioning

confidence: 99%

“…Both reactive and non-reactive quantum and classical systems have been investigated successfully using SEAQT [46][47][48][49][50][51][52][53][54][55] and some validations with experiment have been made [49,50]. It has furthermore been shown that not only does the equation of motion of SEAQT predict the unique thermodynamic path, which the system takes, [37,38] but that the kinetics of this path (i.e., movement along it) and its dynamics (i.e., the time it takes for this movement) can be treated separately [47].…”

Section: Introductionmentioning

confidence: 99%

Ab initiorelaxation times and time-dependent Hamiltonians within the steepest-entropy-ascent quantum thermodynamic framework

Kim

2017

Phys. Rev. E

Quantum systems driven by time-dependent Hamiltonians are considered here within the framework of steepest-entropy-ascent quantum thermodynamics (SEAQT) and used to study the thermodynamic characteristics of such systems. In doing so, a generalization of the SEAQT framework valid for all such systems is provided, leading to the development of an ab initio physically relevant expression for the intrarelaxation time, an important element of this framework and one that had as of yet not been uniquely determined as an integral part of the theory. The resulting expression for the relaxation time is valid as well for time-independent Hamiltonians as a special case and makes the description provided by the SEAQT framework more robust at the fundamental level. In addition, the SEAQT framework is used to help resolve a fundamental issue of thermodynamics in the quantum domain, namely, that concerning the unique definition of process-dependent work and heat functions. The developments presented lead to the conclusion that this framework is not just an alternative approach to thermodynamics in the quantum domain but instead one that uniquely sheds new light on various fundamental but as of yet not completely resolved questions of thermodynamics.