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Related Experiment Video

Updated: Aug 30, 2025

Optimized Fabrication Procedure for High-Quality Graphene-based Moir&#233; Superlattice Devices
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Laser-Engineered Multifunctional Graphene-Glass Electronics.

Raul D Rodriguez1, Maxim Fatkullin1, Aura Garcia1

  • 1Tomsk Polytechnic University, Lenin ave. 30, Tomsk, 634050, Russia.

Advanced Materials (Deerfield Beach, Fla.)
|August 30, 2022
PubMed
Summary
This summary is machine-generated.

A novel laser-induced backward transfer method creates robust, conductive glass-graphene nanocomposites for smart surfaces. This technique enables scalable, inexpensive fabrication of electronic circuits and sensors without harsh chemicals or high temperatures.

Keywords:
conductive nanostructuresglass electronicsgraphene heatersgraphene oxidelaser-engineered nanostructureslaser-induced backward transfersensors

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Area of Science:

  • Materials Science
  • Nanotechnology
  • Surface Engineering

Background:

  • Smart functional surfaces are emerging from glass electronics.
  • Scalable, inexpensive, and conductive glass-based nanocomposites are needed.
  • Existing methods for integrating graphene into glass are energy-intensive and lack patterning capabilities.

Purpose of the Study:

  • To develop a scalable, inexpensive method for creating conductive glass-graphene nanocomposites.
  • To achieve firm integration of graphene into glass without energy-intensive processes or harsh chemicals.
  • To enable robust patterning for electronic circuits on glass surfaces.

Main Methods:

  • Single-step laser-induced backward transfer (LIBT) of graphene oxide (GO).
  • Simultaneous chemical transformations: silicon compound formation and GO reduction during LIBT.
  • Functionalization of the resulting graphene-reduced GO (rGO)-glass nanocomposite with silver.

Main Results:

  • Achieved a conductive (160 Ω/sq) and resilient glass-graphene nanocomposite.
  • Generated and transferred high-quality laser-reduced GO (rGO) with ID/IG = 0.31.
  • Fabricated a dual-channel plasmonic optical and electrochemical sensor with high sensitivity (10-9 m).
  • Demonstrated an electrothermal heater reaching >300 °C with 48h continuous operation.

Conclusions:

  • Single-step LIBT offers a scalable and efficient route to conductive glass-graphene nanocomposites.
  • This method overcomes limitations of previous techniques for graphene integration and patterning in glass.
  • The developed nanocomposite shows promise for advanced applications in sensors and electronics.