A Mass-Temperature Decoupled Discretization Strategy for Large-Scale Molecular-Level Kinetic Model

The molecular conversion of complex mixture involves a large number of species and reactions. The corresponding kinetic model is consist of a series of ordinary differential equations (ODEs) with severe stiffness, leading to an exponentially growing computational time. To reduce the computational time, we proposed a mass-temperature decoupled discretization strategy for a large-scale molecular-level kinetic model. The method separates the mass balance and heat balance calculations in the rigorous adiabatic reactor model and divided the reactor into several isothermal segments. After discretization, the differential equations for heat balance can be replaced by algebraic equations between nodes. We used a molecular-level diesel hydrotreating kinetic model as the case to validate the proposed method. We investigated the effects of temperature estimation methods and node number on the accuracy of the model. A good agreement between the discretization model and rigorous model was observed while the computational time was significantly shortened

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Stochastic Kinetic Analysis of Developmental Pathway Bifurcation in Phage λ-Infected Escherichia coli Cells

Genetics ◽

10.1093/genetics/149.4.1633 ◽

1998 ◽

Vol 149 (4) ◽

pp. 1633-1648 ◽

Cited By ~ 2

Author(s):

Adam Arkin ◽

John Ross ◽

Harley H McAdams

Keyword(s):

Gene Expression ◽

Kinetic Model ◽

Kinetic Analysis ◽

Molecular Level ◽

Host Responses ◽

Statistical Thermodynamic ◽

Regulatory Systems ◽

Regulatory Circuit ◽

Phenotype Selection ◽

Decision Circuit

Abstract Fluctuations in rates of gene expression can produce highly erratic time patterns of protein production in individual cells and wide diversity in instantaneous protein concentrations across cell populations. When two independently produced regulatory proteins acting at low cellular concentrations competitively control a switch point in a pathway, stochastic variations in their concentrations can produce probabilistic pathway selection, so that an initially homogeneous cell population partitions into distinct phenotypic subpopulations. Many pathogenic organisms, for example, use this mechanism to randomly switch surface features to evade host responses. This coupling between molecular-level fluctuations and macroscopic phenotype selection is analyzed using the phage λ lysis-lysogeny decision circuit as a model system. The fraction of infected cells selecting the lysogenic pathway at different phage:cell ratios, predicted using a molecular-level stochastic kinetic model of the genetic regulatory circuit, is consistent with experimental observations. The kinetic model of the decision circuit uses the stochastic formulation of chemical kinetics, stochastic mechanisms of gene expression, and a statistical-thermodynamic model of promoter regulation. Conventional deterministic kinetics cannot be used to predict statistics of regulatory systems that produce probabilistic outcomes. Rather, a stochastic kinetic analysis must be used to predict statistics of regulatory outcomes for such stochastically regulated systems.

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Carbothermic Reduction of Zinc Containing Industrial Wastes: A Kinetic Model

Metallurgical and Materials Transactions B ◽

10.1007/s11663-020-02047-9 ◽

2021 ◽

Author(s):

M. Leuchtenmueller ◽

C. Legerer ◽

U. Brandner ◽

J. Antrekowitsch

Keyword(s):

Mass Transfer ◽

Zinc Oxide ◽

Kinetic Model ◽

Large Scale ◽

Industrial Wastes ◽

Oxide Reduction ◽

Transfer Coefficients ◽

Metallothermic Reduction ◽

Metal Bath ◽

Zinc Recovery

AbstractEffective recycling of zinc-containing industrial wastes, most importantly electric arc furnace dust, is of tremendous importance for the circular economy of the steel and zinc industry. Herein, we propose a comprehensive kinetic model of the combined carbothermic and metallothermic reduction of zinc oxide in a metal bath process. Pyro-metallurgical, large-scale lab experiments of a carbon-saturated iron melt as reduction agent for a molten zinc oxide slag were performed to determine reaction constants and accurately predict mass transfer coefficients of the proposed kinetic model. An experimentally determined kinetic model demonstrates that various reactions run simultaneously during the reduction of zinc oxide and iron oxide. For the investigated slag composition, the temperature-dependent contribution of the metallothermic zinc oxide reduction was between 25 and 50 pct of the overall reaction mechanism. The mass transfer coefficient of the zinc oxide reduction quadrupled from 1400 °C to 1500 °C. The zinc recovery rate was > 99.9 pct in all experiments.

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A linear auroral current-voltage relation in fluid theory

Annales Geophysicae ◽

10.5194/angeo-22-1719-2004 ◽

2004 ◽

Vol 22 (5) ◽

pp. 1719-1728 ◽

Cited By ~ 11

Author(s):

J. Vedin ◽

K. Rönnmark

Keyword(s):

Kinetic Model ◽

Large Scale ◽

Equations Of State ◽

Potential Drop ◽

Fluid Models ◽

Linear Current ◽

Current Voltage ◽

Auroral Phenomena ◽

Auroral Current ◽

Current Voltage Relation

Abstract. Progress in our understanding of auroral currents and auroral electron acceleration has for decades been hampered by an apparent incompatibility between kinetic and fluid models of the physics involved. A well established kinetic model predicts that steady upward field-aligned currents should be linearly related to the potential drop along the field line, but collisionless fluid models that reproduce this linear current-voltage relation have not been found. Using temperatures calculated from the kinetic model in the presence of an upward auroral current, we construct here approximants for the parallel and perpendicular temperatures. Although our model is rather simplified, we find that the fluid equations predict a realistic large-scale parallel electric field and a linear current-voltage relation when these approximants are employed as nonlocal equations of state. This suggests that the concepts we introduce can be applied to the development of accurate equations of state for fluid simulations of auroral flux tubes.Key words. Magnetospheric physics (auroral phenomena; magnetosphere-ionosphere interactions) – Space plasma physics (kinetic and MHD theory)

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Fiber networks amplify active stress

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1514208113 ◽

2016 ◽

Vol 113 (11) ◽

pp. 2827-2832 ◽

Cited By ~ 71

Author(s):

Pierre Ronceray ◽

Chase P. Broedersz ◽

Martin Lenz

Keyword(s):

Large Scale ◽

Molecular Level ◽

Stress Generation ◽

Biological Functions ◽

Force Transmission ◽

Fiber Networks ◽

Stress Amplification ◽

Shed Light ◽

Network Microstructure

Large-scale force generation is essential for biological functions such as cell motility, embryonic development, and muscle contraction. In these processes, forces generated at the molecular level by motor proteins are transmitted by disordered fiber networks, resulting in large-scale active stresses. Although these fiber networks are well characterized macroscopically, this stress generation by microscopic active units is not well understood. Here we theoretically study force transmission in these networks. We find that collective fiber buckling in the vicinity of a local active unit results in a rectification of stress towards strongly amplified isotropic contraction. This stress amplification is reinforced by the networks’ disordered nature, but saturates for high densities of active units. Our predictions are quantitatively consistent with experiments on reconstituted tissues and actomyosin networks and shed light on the role of the network microstructure in shaping active stresses in cells and tissue.

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A Novel Kinetic Model for Complex Reaction Systems in Molecular Level: Part 1. Monte Carlo Simulation of Feedstock

Petroleum Science and Technology ◽

10.1080/10916460701304485 ◽

2008 ◽

Vol 26 (15) ◽

pp. 1811-1821

Author(s):

F.-Sh. Ouyang ◽

B. Li ◽

H.-B. Jiang ◽

H.-X. Weng ◽

F.-S. Ma

Keyword(s):

Monte Carlo Simulation ◽

Monte Carlo ◽

Kinetic Model ◽

Molecular Level ◽

Complex Reaction ◽

Reaction Systems

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A molecular-level analysis of gas-phase reactions in chemical vapor deposition of carbon from methane using a detailed kinetic model

Journal of Materials Science ◽

10.1007/s10853-015-9709-2 ◽

2016 ◽

Vol 51 (8) ◽

pp. 3897-3906 ◽

Cited By ~ 7

Author(s):

Chunxia Hu ◽

Hejun Li ◽

Shouyang Zhang ◽

Wei Li

Keyword(s):

Chemical Vapor Deposition ◽

Kinetic Model ◽

Gas Phase ◽

Vapor Deposition ◽

Molecular Level ◽

Chemical Vapor ◽

Gas Phase Reactions ◽

Detailed Kinetic Model ◽

Level Analysis

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Improved Insights into Protein Thermal Stability: From the Molecular to the Structurome Scale

10.1101/055897 ◽

2016 ◽

Cited By ~ 2

Author(s):

Fabrizio Pucci ◽

Marianne Rooman

Keyword(s):

Thermal Stability ◽

Amino Acid ◽

Protein Stability ◽

Large Scale ◽

Molecular Level ◽

Temperature Dependent ◽

Natural Evolution ◽

Multi Scale ◽

Large Scale Analysis ◽

Thermal Stability Of

AbstractDespite the intense efforts of the last decades to understand the thermal stability of proteins, the mechanisms responsible for its modulation still remain debated. In this investigation, we tackle this issue by showing how a multi-scale perspective can yield new insights. With the help of temperature-dependent statistical potentials, we analyzed some amino acid interactions at the molecular level, which are suggested to be relevant for the enhancement of thermal resistance. We then investigated the thermal stability at the protein level by quantifying its modification upon amino acid substitutions. Finally, a large scale analysis of protein stability - at the structurome level - contributed to the clarification of the relation between stability and natural evolution, thereby showing that the mutational profile of thermostable and mesostable proteins differ. Some final considerations on how the multi-scale approach could help unraveling the protein stability mechanisms are briefly discussed.

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