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Related Concept Videos

Membrane Fluidity01:23

Membrane Fluidity

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Cell membranes are composed of phospholipids, proteins, and carbohydrates loosely attached to one another through chemical interactions. Molecules are generally able to move about in the plane of the membrane, giving the membrane its flexible nature called fluidity. Two other features of the membrane contribute to membrane fluidity: the chemical structure of the phospholipids and the presence of cholesterol in the membrane.
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Updated: Sep 25, 2025

Automated Lipid Bilayer Membrane Formation Using a Polydimethylsiloxane Thin Film
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Thin robust Pd membranes for low-temperature application.

Yuyu Ma1,2, Meiyi Wang1,3, Chunhua Tang1

  • 1Dalian National Laboratory for Clean Energy, Dalian Institute of Chemical Physics, Chinese Academy of Sciences Dalian 116023 China hui.li@dicp.ac.cn.

RSC Advances
|May 2, 2022
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Summary
This summary is machine-generated.

Ultrathin palladium (Pd) membranes resist hydrogen embrittlement in hollow fiber designs, unlike tubular ones. This geometry enables robust performance at lower temperatures, expanding applications for Pd membranes.

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Temperature-Controlled Assembly and Characterization of a Droplet Interface Bilayer
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Area of Science:

  • Materials Science
  • Chemical Engineering
  • Hydrogen Technology

Background:

  • Hydrogen embrittlement causes structural failure in pure palladium (Pd) membranes, restricting their use to temperatures above 293 °C.
  • Understanding the influence of membrane geometry on hydrogen embrittlement resistance is crucial for expanding the operational range of Pd membranes.

Purpose of the Study:

  • To investigate the correlation between membrane geometry and hydrogen embrittlement resistance in ultrathin pure Pd membranes.
  • To evaluate the performance of different Pd membrane geometries under hydrogen exposure at various temperatures.

Main Methods:

  • Fabrication and testing of ultrathin pure Pd membranes with varying geometries (tubular and hollow fiber).
  • Exposure of membranes to hydrogen (H2) at room temperature and during repeated heating/cooling cycles.
  • In situ X-ray diffraction (XRD) analysis to assess lattice strain and residual stresses.

Main Results:

  • Thin tubular Pd membranes (2.7–6.3 μm thickness, 4–12 mm o.d.) experienced immediate structural destruction when exposed to H2 at room temperature.
  • Thin hollow fiber Pd membranes (thickness < 4 μm, 2 mm o.d.) demonstrated strong resistance to hydrogen embrittlement below 100 °C.
  • Hollow fiber membranes withstood repeated heating/cooling cycles (up to 10 °C min-1) under H2 atmosphere without structural degradation.

Conclusions:

  • Hollow fiber geometry significantly enhances hydrogen embrittlement resistance in ultrathin pure Pd membranes at lower temperatures.
  • Reduced lattice strain gradients and lower residual stresses in hollow fiber structures contribute to improved stability during the α-β phase transition.
  • The findings indicate a promising potential for hollow fiber Pd membranes in low-temperature hydrogen separation applications.