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Related Concept Videos

Chemical Reactions02:26

Chemical Reactions

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A balanced chemical equation provides the information of chemical formulas of the reactants and products involved in the chemical change. A reaction’s stoichiometry helps predict how much of the reactant is needed to produce the desired amount of product, or in some cases, how much product will be formed from a specific amount of the reactant.
The relative amounts of reactants and products represented in a balanced chemical equation are often referred to as stoichiometric amounts.
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Synthesis and Decomposition Reactions02:17

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Synthesis and decomposition are two types of redox reactions. Synthesis means to make something, whereas decomposition means to break something. The reactions are accompanied by chemical and energy changes. 
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Introduction to Chemical Reactions01:23

Introduction to Chemical Reactions

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All chemical reactions begin with a reactant, the general term for one or more substances entering the reaction. Sodium and chloride ions, for example, are the reactants in the production of table salt. One or more substances produced by a chemical reaction are called the product. Chemical reactions follow the law of conservation of mass, which means that matter cannot be created nor destroyed in a chemical reaction. The components of the reactants—the number of atoms and the...
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Multi-Step Reactions02:31

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Chemical reactions often occur in a stepwise fashion involving two or more distinct reactions taking place in a sequence. A balanced equation indicates the reacting species and the product species, but it reveals no details about how the reaction occurs at the molecular level. The reaction mechanism (or reaction path) provides details regarding the precise, step-by-step process by which a reaction occurs. Each of the steps in a reaction mechanism is called an elementary reaction. These...
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Thermal and Photochemical Electrocyclic Reactions: Overview01:26

Thermal and Photochemical Electrocyclic Reactions: Overview

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Electrocyclic reactions are reversible reactions. They involve an intramolecular cyclization or ring-opening of a conjugated polyene. Shown below are two examples of electrocyclic reactions. In the first reaction, the formation of the cyclic product is favored. In contrast, in the second reaction, ring-opening is favored due to the high ring strain associated with cyclobutene formation.
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Catalytically Perfect Enzymes01:07

Catalytically Perfect Enzymes

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The theory of catalytically perfect enzymes was first proposed by W.J. Albery and J. R. Knowles in 1976. These enzymes catalyze biochemical reactions at high-speed. Their catalytic efficiency values range from 108-109 M-1s-1. These enzymes are also called 'diffusion-controlled' as the only rate-limiting step in the catalysis is that of the substrate diffusion into the active site. Examples include triose phosphate isomerase, fumarase, and superoxide dismutase.
 
Most enzymes...
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Optimization of the Ugi Reaction Using Parallel Synthesis and Automated Liquid Handling
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An integrated self-optimizing programmable chemical synthesis and reaction engine.

Artem I Leonov1, Alexander J S Hammer1, Slawomir Lach1

  • 1School of Chemistry, The University of Glasgow, University Avenue, Glasgow, G12 8QQ, UK.

Nature Communications
|February 9, 2024
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Summary
This summary is machine-generated.

This study introduces a dynamic robotic chemistry system that adapts in real-time. The automated platform optimizes reactions and discovers novel molecules using sensors and a new programming language.

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Area of Science:

  • Chemistry
  • Robotics
  • Artificial Intelligence

Background:

  • Current robotic chemistry platforms lack real-time adaptability.
  • Dynamic control is crucial for efficient chemical synthesis and discovery.

Purpose of the Study:

  • To develop a dynamically programmable robotic system for real-time chemical reaction adaptation.
  • To demonstrate the system's capability in scaling, optimizing, and discovering molecules.

Main Methods:

  • Utilized a robotic platform with seven integrated sensors for continuous reaction monitoring.
  • Developed a dynamic programming language for adaptive control.
  • Employed in-line spectroscopy (HPLC, Raman, NMR) for closed-loop optimization.

Main Results:

  • Achieved a 10-fold scale-up of an exothermic oxidation reaction and detected hardware failures.
  • Demonstrated yield improvements up to 50% in known and novel reactions through closed-loop optimization.
  • Successfully explored a trifluoromethylation reaction space, leading to the discovery of new molecules.

Conclusions:

  • The dynamically programmable robotic system offers significant advancements in chemical synthesis and discovery.
  • Real-time adaptation and in-line monitoring enable efficient optimization and exploration of chemical spaces.
  • This approach accelerates the discovery of novel molecules and improves reaction yields.