A Novel Sustainable Process for Multilayer Graphene Synthesis Using CO2 from Ambient Air

Matthew Colson, Leandro Alvarez, Stephanie Michelle Soto, Sung Hee Joo, Kai Li, Andrew Lupini, Kashif Nawaz, Ignatius Fomunung, Mbakisya A. Onyango, Michael K. Danquah, Joseph Owino, Sungwoo Yang

Research output: Contribution to journalArticlepeer-review

1 Scopus citations

Abstract

Graphene produced by different methods can present varying physicochemical properties and quality, resulting in a wide range of applications. The implementation of a novel method to synthesize graphene requires characterizations to determine the relevant physicochemical and functional properties for its tailored application. We present a novel method for multilayer graphene synthesis using atmospheric carbon dioxide with characterization. Synthesis begins with carbon dioxide sequestered from air by monoethanolamine dissolution and released into an enclosed vessel. Magnesium is ignited in the presence of the concentrated carbon dioxide, resulting in the formation of graphene flakes. These flakes are separated and enhanced by washing with hydrochloric acid and exfoliation by ammonium sulfate, which is then cycled through a tumble blender and filtrated. Raman spectroscopic characterization, FTIR spectroscopic characterization, XPS spectroscopic characterization, SEM imaging, and TEM imaging indicated that the graphene has fifteen layers with some remnant oxygen-possessing and nitrogen-possessing functional groups. The multilayer graphene flake possessed particle sizes ranging from 2 µm to 80 µm in diameter. BET analysis measured the surface area of the multilayer graphene particles as 330 m2/g, and the pore size distribution indicated about 51% of the pores as having diameters from 0.8 nm to 5 nm. This study demonstrates a novel and scalable method to synthesize multilayer graphene using CO2 from ambient air at 1 g/kWh electricity, potentially allowing for multilayer graphene production by the ton. The approach creates opportunities to synthesize multilayer graphene particles with defined properties through a careful control of the synthesis parameters for tailored applications.

Original languageEnglish
Article number5894
JournalMaterials
Volume15
Issue number17
DOIs
StatePublished - Sep 2022

Funding

L.A. gratefully acknowledges the resources, equipment, and expertise provided by Harley Grant and Jeff Henry at ATC-CES. Scanning transmission electron microscopy supported by U.S. Department of Energy, Office of Science, Office of Basic Energy Sciences, Materials Sciences and Engineering Division, Oak Ridge National Laboratory. This work was supported by Center of Excellence for Applied Computational Science and Engineering under award CEACSE-FY2023 and an internal funding from the department of Civil and Chemical Engineering at UTC.

Keywords

  • atmospheric CO mitigation
  • multilayer graphene
  • multilayer graphene characterization
  • sustainability

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