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791520

Sigma-Aldrich

Graphene oxide, ammonia functionalized

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1 mg/mL, dispersion in H2O

Synonym(s):

N-doped GO, N-doped graphene oxide

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About This Item

UNSPSC Code:
12352103
NACRES:
NA.23

form

dispersion in H2O

Quality Level

greener alternative product characteristics

Design for Energy Efficiency
Learn more about the Principles of Green Chemistry.

sustainability

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concentration

1 mg/mL

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SMILES string

NC1=C2C3=C4C=C5C=C6C7=C8C9=C%10C%11=C%12C=C(O)C%13C%11C%14=C9C(N)(C7=O)c%15cc%16C%17=C(C(O)=O)C%18=CC%19=C%20C(=C1)C%21=C%22C%23=C%24C=C%25C%26=C%27C=C%28C%29=C%30C%31=C%32C%33=C%34C(C=CC(N)(C%28=C%35C(=O)C=C%36C%37OC%37%38C=C%39C=C%40C(=O)C%41(O)C=C%42C=C%43C=C(O)c%44cc(C(O)=O)c%45c%46c%44c%43c%47c%42c%48C%41=C%49C%40=C%50C(C%19=C%51C(=C%26C(=C%38C%51(N)C%39%50N)C%36%52OC%27%35%52)C%20%53OC%22%25%53)=C%18C%49%54OC%17%54c%48c%55c%16c%56c(c%57c%45ccc%13c%57c%14c%15%56)C%46%58OC%47%55%58)C%30%34N)=CC%59C(=O)C%60=CC%61=C(C(O)=O)c%62ccc(C(O)=O)c%63C=C%64C(=O)C%65%66OC%65%67C%68=C%64C(C%61C%69=C%60C(=C%33%59)C%70(N)C(=C%68%69)C%71=C%67C%72=C%73C%74=C%75C%76=C%77C%78(OC%78%79C=C%24C%80(N)C%81=C%23C%82(OC2%21%82)C%83=C3C%84=C(C(O)=C(O)C%85=CC%86=C(C(O)=O)C%87=CC%88=CC%89=C(C(O)=O)c%90ccc(O)c%12c%90C%10%91OC%89%91C8=C%88C6=C%87C5=C%86C4(N)C%84%85N)C%92%93OC%92C%94=C%95C(=O)C(O)=C%96C=C%97C%98C%99C%96=C%95C%100=C%101C%99=C%102C%103%104OC%103%105C%106=C%107C%108=C%109C(C%110=CC=C(O)C%111=CC%112=CC(=C%97C(O)=O)C(C%106=C%112C%108C%110%111)=C%98%104)=C(C=C%113C(=O)C%66=C%72C%114(OC%109%113%114)C%107=C%73C%105=C%75C%102%115OC%77%115C%101=C%79C%80(N)C%100=C%94C%81=C%83%93)C(O)=O)C(=C%29)C%31=C%76C(=C%71%74)C%32%70N)c%62%63

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General description

N-doped graphene may be prepared by chemical vapor deposition (CVD), direct synthesis of N-graphene and also by electrical annealing of graphene nanoribbons in NH3 in the presence of NH3.Another technique of preparing N-doped graphene by microbial reduction of graphene oxide was reported. N doping alters the electrical properties of graphene effectively by modifying its band structure. A report also shows that doped graphene can act as excellent support for Pt catalysts and show better performance in Li ion batteries.
We are committed to bringing you Greener Alternative Products, which adhere to one or more of The 12 Principles of Greener Chemistry. This product belongs to Enabling category of greener alternatives thus aligns with "Design for energy efficency". High concentrated graphene oxide sheets provide the prerequisite viscosity to bind the electrode materials together and enable 3D printing. Using water as a green solvent makes this aqueous ink system feasible for processing and drying safety and low cost. Click here for more information.

Application

Dielectric Materials for Field Effect Transistors (FET); Non-silicon-based materials for integrated circuits (IC).
Nitrogen doping (N-doping) can improve electro-conductivity of graphene sheet .

Storage Class Code

10 - Combustible liquids

WGK

WGK 2

Flash Point(F)

Not applicable

Flash Point(C)

Not applicable


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Chemical vapor deposition of N-doped graphene and carbon films: the role of precursors and gas phase.
Ito Y, et al.
ACS Nano, 8.4, 3337-3346 (2014)
Laser mediated programmable N doping and simultaneous reduction of graphene oxide.
Guo L,et al.
Advanced Optical Materials, 2, 120-125 (2014)
Preparation of N-doped graphene by reduction of graphene oxide with mixed microbial system and its haemocompatibility
Fan M, et al.
Nanoscale, 6, 4882-4882 (2014)
Nitrogen-doped graphene sheets grown by chemical vapor deposition: synthesis and influence of nitrogen impurities on carrier transport.
Lu Y, et al.
ACS Nano, 7.8, 6522-6532 (2013)
Influence of N-doping on the structural and photoluminescence properties of graphene oxide films.
Khai TV, et al.
Carbon, 50, 3799- 3806 (2012)

Articles

Carbon nanomaterials (CNMs), such as single-walled carbon nanotubes (SWCNTs), multi-walled carbon nanotubes (MWCNTs), and graphene (Figure 1), have diverse commercial applications including lighter and stronger composite materials, improved energy storage devices, more sensitive sensors, and smaller transistors.

Since its discovery little more than a decade ago,1 the two-dimensional (2D) allotrope of carbon—graphene—has been the subject of intense multidisciplinary research efforts.

Graphene is a one-atomic-layer thick two-dimensional material made of carbon atoms arranged in a honeycomb structure. Its fascinating electrical, optical, and mechanical properties ignited enormous interdisciplinary interest from the physics, chemistry, and materials science fields.

Advanced technologies for energy conversion and storage are widely sought after for their potential to improve consumer and electronic device performance as well as for the prospect of reducing the societal and environmental impact of energy generation.

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