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Adhesion, Stiffness, and Instability in Atomically Thin MoS2 Bubbles.

David Lloyd1, Xinghui Liu2, Narasimha Boddeti2

  • 1Department of Mechanical Engineering, Boston University , Boston, Massachusetts 02215 United States.

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|August 2, 2017
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Summary
This summary is machine-generated.

Researchers measured the adhesion of molybdenum disulfide (MoS2) membranes to silicon oxide substrates. They determined the work of separation and Young

Keywords:
AdhesionMoS2Young’s modulusadhesion hysteresisbubblefriction

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Area of Science:

  • Materials Science
  • Nanotechnology
  • Solid Mechanics

Background:

  • Molybdenum disulfide (MoS2) is a promising 2D material with diverse electronic and mechanical properties.
  • Understanding the adhesion and mechanical behavior of 2D materials on substrates is crucial for device fabrication and performance.
  • Existing models may not fully capture the complex delamination mechanics of 2D membranes.

Purpose of the Study:

  • To quantify the work of separation and 2D Young's modulus of single and few-layer MoS2 membranes.
  • To investigate the delamination mechanics of MoS2 bubbles under varying pressures.
  • To identify and explain phenomena not covered by current adhesion and delamination models.

Main Methods:

  • Mechanical blister test to measure the work of separation and Young's modulus.
  • Controlled inflation and deflation of pressurized MoS2 bubbles on a SiO2 substrate.
  • Analysis of bubble transitions between laminated and delaminated states.

Main Results:

  • Measured work of separation of 220 ± 35 mJ/m² for MoS2 membranes.
  • Determined the 2D Young's modulus of single-layer MoS2 to be 160 ± 40 N/m.
  • Observed adhesion hysteresis, edge pinning, and snap-in transitions during bubble deflation, not predicted by prior models.

Conclusions:

  • The study provides key mechanical and adhesion parameters for MoS2 membranes.
  • New insights into delamination mechanics, including adhesion hysteresis, are presented.
  • Results highlight the need for refined models to describe 2D material-substrate interactions.