GEt Quote

Graphene Oxide (S Method)

As low as $696.00 $0.00
In stock
SKU# 1178

Graphene Oxide by Staudenmaier Method

Product Detail

CAS No.: 7782-42-5

Preparation Method: Staudenmaier Method

Characterizations

  *Type A Type B
SKU GNOS0010 GNOS0111
Diameter 1~15 μm 0.5~20 μm
Specific Surface Area (SSA) 5-10 m2/g ~ 0.55 m2/g
Oxygen Content ~35 wt% ~ 27.14 wt%
Bulk Density 0.008g/cm3 0.452g/cm3

*This product has been Discontinued

TEM Image 1 of Graphene Oxide (S Method), Type B -- ACS Material

TEM Image 2 of Graphene Oxide (S Method), Type B -- ACS Material

 

XPS Results

  Weight Content % Weight Content %
Element Type A Type B
C1s 65.71 71.87
N1s 0.5 0.99
O1s 33.8 27.14

Application Fields

Supercapacitors; Catalyst; Solar energy; Graphene semiconductor chips; Conductive graphene film; Graphene computer memory; Biomaterials; Transparent conductive coatings.

 

Disclaimer: ACS Material LLC believes that the information on our website is accurate and represents the best and most current information available to us. ACS Material makes no representations or warranties either express or implied, regarding the suitability of the material for any purpose or the accuracy of the information listed here. Accordingly, ACS Material will not be responsible for damages resulting from use of or reliance upon this information.

Research Citations of ACS Material Products

  1. Nieto, Andy, et al. “Graphene reinforced metal and ceramic matrix composites: a review.” International Materials Reviews, vol. 62, no. 5, 2016, pp. 241–302., doi:10.1080/09506608.2016.1219481.
  2. Gutić, Sanjin J., et al. “Improved catalysts for hydrogen evolution reaction in alkaline solutions through the electrochemical formation of nickel-Reduced graphene oxide interface.” Physical Chemistry, vol. 19, no. 20, 2017, pp. 13281–13293., doi:10.1039/c7cp01237c.
  3. Gutić, S.j., et al. “Simple routes for the improvement of hydrogen evolution activity of Ni-Mo catalysts: From sol-Gel derived powder catalysts to graphene supported co-Electrodeposits.” International Journal of Hydrogen Energy, 2017, doi:10.1016/j.ijhydene.2017.11.131.
  4. Wang, Mei, et al. “Concurrent aggregation and transport of graphene oxide in saturated porous media: Roles of temperature, cation type, and electrolyte concentration.” Environmental Pollution, vol. 235, 2018, pp. 350–357., doi:10.1016/j.envpol.2017.12.063.
  5. Palmieri, Alessandro, Neil Spinner, Shuai Zhao, and William E. Mustain. "Explaining the role and mechanism of carbon matrices in enhancing reaction reversibility of metal oxide anodes for high performance Li ion batteries." carbon 130 (2018): 515-524.
  6. Gutić, Sanjin J., Muharema Šabanović, Dino Metarapi, Igor A. Pašti, Fehim Korać, and Slavko V. Mentus. "Electrochemically Synthesized Ni@ reduced Graphene Oxide Composite Catalysts for Hydrogen Evolution in Alkaline Media–the Effects of Graphene Oxide Support." Int. J. Electrochem. Sci 14 (2019): 8532-8543.
  7. Berning, T.; Bessarabov, D. GOMEA: A Conceptual Design of a Membrane Electrode Assembly for a Proton Exchange Membrane Electrolyzer. Membranes 2023, 13, 614. https://doi.org/10.3390/membranes13070614