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Related Concept Videos

Catalysis02:50

Catalysis

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The presence of a catalyst affects the rate of a chemical reaction. A catalyst is a substance that can increase the reaction rate without being consumed during the process. A basic comprehension of a catalysts’ role during chemical reactions can be understood from the concept of reaction mechanisms and energy diagrams.
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Predicting Reaction Outcomes02:24

Predicting Reaction Outcomes

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Kinetics describes the rate and path by which a reaction occurs. In contrast, thermodynamics deals with state functions and describes the properties, behavior, and components of a system. It is not concerned with the path taken by the process and cannot address the rate at which a reaction occurs. Although it does provide information about what can happen during a reaction process, it does not describe the detailed steps of what appears on an atomic or a molecular level. On the other hand,...
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Introduction to Mechanisms of Enzyme Catalysis01:13

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For many years, scientists thought that enzyme-substrate binding took place in a simple "lock-and-key" fashion. This model stated that the enzyme and substrate fit together perfectly in one instantaneous step. However, current research supports a more refined view scientists call induced fit. The induced-fit model expands upon the lock-and-key model by describing a more dynamic interaction between enzyme and substrate. As the enzyme and substrate come together, their interaction causes...
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Coupled Reactions01:17

Coupled Reactions

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Cellular processes such as building and breaking down complex molecules occur through stepwise chemical reactions. Some of these chemical reactions are spontaneous and release energy, whereas others require energy to proceed. Cells often couple the energy-releasing reaction with the energy-requiring one to carry out important cell functions. 
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Pore Transport and Ion-Pair Transport01:17

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Pore transport and ion-pair formation are critical mechanisms for the absorption and distribution of drugs in the body.
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Passive Diffusion: Overview and Kinetics01:17

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Passive diffusion is a critical process that allows small lipophilic drugs to cross the cell membrane along a concentration gradient. This mechanism's efficiency depends on four primary factors: the membrane's surface area, the drug's lipid-water partition coefficient, the concentration gradient, and the membrane's thickness.
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Related Experiment Video

Updated: Jan 9, 2026

Multiscale Sampling of a Heterogeneous Water/Metal Catalyst Interface using Density Functional Theory and Force-Field Molecular Dynamics
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Multiscale Sampling of a Heterogeneous Water/Metal Catalyst Interface using Density Functional Theory and Force-Field Molecular Dynamics

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A Machine Learning-Driven Pore-Scale Network Model Coupling Reaction Kinetics and Interparticle Transport for

Ming-Liang Qu1,2,3, Zhao-Bin Ding4, Dingyue Zhang5

  • 1State Key Laboratory of Clean Energy Utilization, Zhejiang University, Hangzhou, 310027, China.

Advanced Science (Weinheim, Baden-Wurttemberg, Germany)
|December 3, 2025
PubMed
Summary

A new dual-network model with kinetics (DNMK), enhanced by machine learning, efficiently models catalytic reactions in porous materials. This approach accelerates simulations, optimizing catalyst design and reactor performance for chemical processes.

Keywords:
CO2 hydrogenationCatalytic processesKineticsMachine learningPore‐scale modelingPorous media

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Area of Science:

  • Chemical Engineering
  • Catalysis Science
  • Computational Chemistry

Background:

  • Catalytic processes in porous systems involve complex interactions between microkinetics and transport phenomena.
  • Accurate modeling requires bridging disparate spatial and temporal scales, posing significant computational challenges.
  • Existing methods often struggle to capture the intricate interplay governing apparent catalytic performance.

Purpose of the Study:

  • To develop an efficient multiscale modeling framework for reaction-transport coupled catalytic processes.
  • To integrate machine learning to accelerate microkinetic modeling within a dual-network approach.
  • To provide mechanistic insights into catalyst arrangement and transport limitations for reactor optimization.

Main Methods:

  • Development of a pore-scale dual-network model with kinetics (DNMK).
  • Integration of machine learning (ML)-based surrogates to accelerate the microkinetic module.
  • Application and validation of the DNMK framework for sorption-enhanced CO2 hydrogenation to methanol.

Main Results:

  • Achieved up to a 750-fold computational speed-up compared to traditional methods.
  • Preserved full physical and chemical fidelity in the multiscale modeling.
  • Identified optimal catalyst-sorbent configurations for enhanced apparent activity and reactor performance.

Conclusions:

  • DNMK offers a high-resolution, ML-driven platform for digital catalytic experimentation.
  • The framework enables predictive, in silico optimization of catalyst scaling, utilization, and process intensification.
  • DNMK reduces reliance on experimental trials, paving the way for data-driven reactor design.