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相关概念视频

Catalysis02:50

Catalysis

26.9K
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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Introduction to Enzyme Kinetics01:19

Introduction to Enzyme Kinetics

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Enzyme kinetics studies the rates of biochemical reactions. Scientists monitor the reaction rates for a particular enzymatic reaction at various substrate concentrations. Additional trials with inhibitors or other molecules that affect the reaction rate may also be performed.
The experimenter can then plot the initial reaction rate or velocity (Vo) of a given trial against the substrate concentration ([S]) to obtain a graph of the reaction properties. For many enzymatic reactions involving a...
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Enzyme Kinetics01:19

Enzyme Kinetics

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Enzymes speed up reactions by lowering the activation energy of the reactants. The speed at which the enzyme turns reactants into products is called the rate of reaction. Several factors impact the rate of reaction, including the number of available reactants. Enzyme kinetics is the study of how an enzyme changes the rate of a reaction.
Scientists typically study enzyme kinetics with a fixed amount of enzyme in the controlled environment of a test tube. When more reactant, or substrate, is...
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Energy Diagrams, Transition States, and Intermediates02:13

Energy Diagrams, Transition States, and Intermediates

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Free-energy diagrams, or reaction coordinate diagrams, are graphs showing the energy changes that occur during a chemical reaction. The reaction coordinate represented on the horizontal axis shows how far the reaction has progressed structurally. Positions along the x-axis close to the reactants have structures resembling the reactants, while positions close to the products resemble the products.  Peaks on the energy diagram represent stable structures with measurable lifetimes, while...
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Molecular Models02:00

Molecular Models

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Physical models representing molecular architectures of chemical compounds play essential roles in understanding chemistry. The use of molecular models makes it easier to visualize the structures and shapes of atoms and molecules.
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E1 Reaction: Kinetics and Mechanism02:46

E1 Reaction: Kinetics and Mechanism

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Here, in contrast to the E2 reaction mechanism, we delve into the aspects of the E1 reaction mechanism, which has two steps: rate-limiting loss of the leaving group and abstraction of the beta hydrogen by a weak base. Typically, the experimental proof for the E1 mechanism is via kinetic studies or isotope studies. While the former demonstrates the first-order kinetics—the dependence of the reaction solely on substrate concentration—the latter proves the abstraction of hydrogen only...
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相关实验视频

Updated: Jun 26, 2025

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

Published on: April 12, 2019

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想象动态单原子催化剂的可视化

Edward D Boyes1, Pratibha L Gai2

  • 1The York Nanocentre, Department of Physics, University of York, York, YO10 5DD, UK.

Advanced materials (Deerfield Beach, Fla.)
|May 17, 2024
PubMed
概括
此摘要是机器生成的。

先进的现场电子显微镜 (EM) 可以实时可视化单个原子的催化. 这使我们能够更深入地了解催化剂的功能,改善工业过程和材料的稳定性.

关键词:
在现场分析的ESTEM具有单原子分辨率.动态单原子催化物的可视化和分析.

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Last Updated: Jun 26, 2025

Multiscale Sampling of a Heterogeneous Water/Metal Catalyst Interface using Density Functional Theory and Force-Field Molecular Dynamics
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Visualizing Single Molecular Complexes In Vivo Using Advanced Fluorescence Microscopy
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科学领域:

  • 材料科学 材料科学 材料科学
  • 化学工程是化学工程的重要组成部分.
  • 纳米技术纳米技术

背景情况:

  • 不同质的催化剂对于燃料和制药生产等工业过程至关重要.
  • 原子级动态显著影响催化剂的稳定性和性能.
  • 在反应条件下实时,现场分析是理解和改进催化剂的关键.

研究的目的:

  • 审查创新的实时现场电子显微镜 (EM) 方法来研究动态单原子催化.
  • 为突出环境 (扫描) 传输EM (E(STEM)) 进行原子尺度可视化方面的进步.
  • 讨论跟踪反应原子的挑战和机遇.

主要方法:

  • 使用环境扫描TEM (ESTEM) 和环境传输EM (ETEM) 来实现单原子分辨率.
  • 使用受控的流动气体反应环境.
  • 结合先进的现场技术,如专用样本持有器和纳米图谱.

主要成果:

  • 在反应和烧结失活过程中,ESTEM成功地可视化了单个原子的动态.
  • 实时原子尺度分析为催化剂产量和稳定性提供了洞察力.
  • 电子,科学和技术 (STEM) 的进步有助于理解基本的催化过程.

结论:

  • 在现场的EM方法显著提高了对动态单原子催化物的理解.
  • 更好的理解可以导致更好的催化剂设计,提高工业效率.
  • 进步通过优化催化提供了宝贵的经济,环境和社会效益.