The oxidised version of graphene is called graphene oxide (GO). The oxidation of inexpensive and widely accessible graphite results in the formation of this one-atomic-layer substance. Since graphene oxide disperses in water and other solvents, processing it is simple. Graphene oxide is not conductive because of the oxygen in its lattice, but it can be chemically converted to graphene. The fact that graphene oxide disperses in water is one of its key benefits. This enables the use of solution-based methods. Chemical vapour deposition is the main technique for producing graphene films (CVD). However, this technique is costly and necessitates high temperatures and lengthy deposition durations. Additionally, it restricts the deposition to materials that can withstand high temperatures that are problematic for deposition on top of polymers. Another advantage of graphene oxide is that it may be chemically, thermally, or electrochemically converted into graphene. Reduced graphene oxide is the name of the substance (rGO). One of the most apparent options to utilise when significant amounts of graphene are required for commercial purposes like energy storage is the rGO. The quality of the rGO produced is greatly influenced by the reduction process, making it essential.
Ephraim Suhir
Portland State University, United States
Thomas J Webster
Interstellar Therapeutics, United States
Robert Buenker
University of Wuppertal, Germany
Will Skene
Montreal University, Canada
Valeriy A Buryachenko
Micromechanics & Composites LLC, United States
Anis Rahman
Applied Research & Photonics, Inc, United States
Will Skene
Montreal University, Canada
Robert Guidoin
Laval University, Canada
Robert Buenker
University of Wuppertal, Germany
Martin Krus
Fraunhofer Institute for Building Physics, GermanySubmit your abstract Today
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