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Potentiometry: Membrane Electrodes01:15

Potentiometry: Membrane Electrodes

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Membrane electrodes, also known as p-ion electrodes, use membranes that selectively interact with free analyte ions, generating a potential difference across the membrane. The resulting membrane potential, known as the asymmetry potential, is not zero even when analyte concentrations on both sides of the membrane are equal. The membrane's response is typically not selective to a single analyte but proportional to the concentration of all ions in the sample solution capable of interacting at...
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Ethers from Alkenes: Alcohol Addition and Alkoxymercuration-Demercuration02:35

Ethers from Alkenes: Alcohol Addition and Alkoxymercuration-Demercuration

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Overview
Ethers can also be prepared from alkenes through acid-catalyzed addition of alcohols and alkoxymercuration–demercuration.
Preparation of Ethers by Acid-Catalyzed Addition of Alcohol to Alkenes
The acid-catalyzed addition of alcohol to an alkene involves treating the alkene with an excess of alcohol in the presence of an acid catalyst to form an ether under suitable conditions. The hydrogen will add to the less substituted carbon so that the nucleophile can attack the more...
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Olefin Metathesis Polymerization: Overview01:13

Olefin Metathesis Polymerization: Overview

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Recently, the development of olefin metathesis polymerization advanced the field of polymer synthesis. Simply put, the reorganization of substituents on their double bonds between two olefins in the presence of a catalyst is known as the olefin metathesis reaction. The use of metathesis reaction for polymer synthesis is called olefin metathesis polymerization.
Ruthenium-based Grubbs catalyst is the most commonly used catalyst for olefin metathesis polymerization. Grubbs catalyst consists...
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Preparation of Alcohols via Addition Reactions02:15

Preparation of Alcohols via Addition Reactions

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Overview
The acid-catalyzed addition of water to the double bond of alkenes is a large-scale industrial method used to synthesize low-molecular-weight alcohols. An acidic atmosphere is required to allow the hydrogen in the water molecule to act as an electrophile and attack the double bond in an alkene. The addition of a proton to the double bond creates a carbocation intermediate. The proton preferentially bonds to the less substituted end of the double bond to create a more stable carbocation...
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Olefin Metathesis Polymerization: Acyclic Diene Metathesis (ADMET)00:53

Olefin Metathesis Polymerization: Acyclic Diene Metathesis (ADMET)

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Acyclic diene metathesis polymerization or ADMET polymerization involves cross-metathesis of terminal dienes, such as 1,8-nonadiene, to give linear unsaturated polymer and ethylene. As ADMET is a reversible process, the formed ethylene gas must be removed from the reaction mixture to complete the polymerization process.
Similar to cross-metathesis, ADMET also involves the formation of metallacyclobutane intermediate by [2+2] cycloaddition of one of the double bonds of a terminal diene with...
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Regioselectivity of Electrophilic Additions to Alkenes: Markovnikov's Rule02:17

Regioselectivity of Electrophilic Additions to Alkenes: Markovnikov's Rule

15.0K
If a set of reactants can yield multiple constitutional isomers, but one of the isomers is obtained as the major product, the reaction is said to be regioselective. In such reactions, bond formation or breaking is favored at one reaction site over others.
The hydrohalogenation of an unsymmetrical alkene can yield two haloalkane products, depending on which vinylic carbon takes up the halogen. However, one product usually predominates, where hydrogen adds to the vinylic carbon bearing the...
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Related Experiment Video

Updated: Oct 22, 2025

Electrophoretic Crystallization of Ultrathin High-performance Metal-organic Framework Membranes
07:45

Electrophoretic Crystallization of Ultrathin High-performance Metal-organic Framework Membranes

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Membrane-Assisted Methanol Synthesis Processes and the Required Permselectivity.

Homa Hamedi1, Torsten Brinkmann1, Sergey Shishatskiy1

  • 1Department of Process Engineering, Institute of Membrane Research, Helmholtz-Zentrum Hereon, Max-Planck-Straße P1, 21502 Geesthacht, Germany.

Membranes
|August 26, 2021
PubMed
Summary

Water-selective membrane reactors can improve methanol production, but energy losses from hydrogen co-permeation must be considered. Evaluating the entire methanol plant process reveals membranes need higher selectivity than currently available for significant energy savings.

Keywords:
Aspen Custom ModelerCO2 hydrogenationcarbon capturecarbon utilizationgreen fuelmembrane reactormethanol synthesissynthetic fuel

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Area of Science:

  • Chemical Engineering
  • Process Systems Engineering
  • Materials Science

Background:

  • Water-selective membrane reactors are proposed to enhance methanol synthesis yield.
  • Evaluating standalone reactor performance overlooks energy losses due to hydrogen co-permeation, impacting overall system efficiency.

Purpose of the Study:

  • To assess the true effectiveness of water-selective membrane reactors at a process flowsheet level.
  • To determine the minimum membrane property requirements for integrated methanol synthesis.
  • To identify potential energy savings and optimal operating conditions.

Main Methods:

  • Developed an equation-based model for a membrane reactor in Aspen Custom Modeler.
  • Integrated the membrane reactor model into a methanol plant process flowsheet.
  • Conducted simulations to explore favorable conditions and analyze power requirements and exergy.

Main Results:

  • The upper limit for power saving with a conceptual water-selective membrane reactor is 32%.
  • Minimum required H2O/H2 selectivity values are 190 (exergy analysis) and 970 (power requirement).
  • Literature-reported membrane permselectivity is insufficient for significant overall process improvement.

Conclusions:

  • Standalone reactor improvements do not guarantee overall process benefits.
  • High membrane selectivity is crucial for effective energy integration in methanol synthesis.
  • Current membrane technologies require substantial advancement to meet process demands.