Carboxyl Graphene
Good solubility in polar solvents.
Product Detail
CAS No.: 7782-42-5
Carboxyl graphene (-COOH) from ACS Material is produced using our own in-house proprietary methods meeting all our standards for quality, consistency, and purity. The carboxyl group ratio reaches up to 5% and the total product is upwards of 99% pure. Grain size ranges from 1-5 microns and can be easily suspended in DI, DMF, or other polar solvents. This black powder is ideal for depositing on various substrates using conventional mechanical exfoliation or by using a solution for spin coating. Carboxyl graphene is an ideal material for biological, chemical, and physical applications.
ACS Material is an experienced and reputable provider of graphene and other advanced nanomaterials to leading researchers around the globe. We have what you need to create the products for a better tomorrow. Contact a member of our team today for more information about carboxyl graphene or any of our other innovative materials.
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FT-IR of ACS Material Carboxyl Graphene
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FAQ
How you get the graphene in the first place? Is it through Hummer's method‚ hydrazine treatment and then some method of functionalization or maybe a different route?
ACS Material prepares Graphene Oxide using the Modified Hummer’s Method. The synthesis following that is proprietary and we cannot disclose the details‚ but we are able to produce the functional group: -COOH as a stock item‚ and the groups: -NH‚ -NH2‚ -Amino-PEG‚ and rGO-NH-Carboimidazole as special order items. Typically‚ the (-COOH) can be produced by organic reaction using (-OH) and (C-O-C).
What is the structure of Carboxyl Graphene? The carboxyl groups are only at edges‚ or they are also attached to the basil plane of graphene? What is the electrical conductivity of this product?
Most Carboxyl groups (-COOH) are at the edges. The other related group present is derived from –OH or C-O-H which yields O-CH2-COOH. Carboxyl Graphene is non-conductive.
Research Citations of ACS Material Products
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- Su, Weitao, Naresh Kumar, Andrey Krayev, and Marc Chaigneau. "In situ topographical chemical and electrical imaging of carboxyl graphene oxide at the nanoscale." Nature communications 9, no. 1 (2018): 2891.
- Wang, Liu, Zhicheng Huang, Yibo Liu, Jian Wu, and Juewen Liu. "Fluorescent DNA Probing Nanoscale MnO2: Adsorption, Dissolution by Thiol, and Nanozyme Activity." Langmuir 34, no. 9 (2018): 3094-3101.
- Zhang, Zijie, and Juewen Liu. "An engineered one-site aptamer with higher sensitivity for label-free detection of adenosine on graphene oxide." Canadian Journal of Chemistry 96, no. 11 (2018): 957-963.
- Chand, Rohit, Yi Lan Wang, David Kelton, and Suresh Neethirajan. "Isothermal DNA amplification with functionalized graphene and nanoparticle assisted electroanalysis for rapid detection of Johne’s disease." Sensors and Actuators B: Chemical 261 (2018): 31-37.