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Graphene Nanoplatelets (1-2nm)

As low as $396.00 $0.00
In stock
SKU# GNNP01

Thickness: 1-2 nm

Product Detail

With an average thickness of 1-2 nanometers, graphene nanoplatelets provide improved barrier properties that guarantee strength, security, and reliability. Their completely graphitic composition also means that they make tremendous thermal and electrical conductors. Inevitably, this makes graphene nanoplatelets a highly sought-after product that can be used in a variety of applications, including thermoset composites, natural rubber, strong adhesives, and much more. By reducing the component’s overall mass without diminishing its strong properties, graphene nanoplatelets are a cost-effective tool that can be used to enhance overall conductivity.

CAS No.: 7782-42-5

Types of Graphene Nanoplatelets

Product No. Product Name Thickness Diameter Size
GNNP0051 Graphene Nanoplatelets (2-10nm thick)  2-10nm  2-7µm  50g
GNNP0052 500g
GNNP01A5 Graphene Nanoplatelets (1-2nm thick) 1-2nm 2-3µm 500mg
GNNP0201 Graphene Nanoplatelets (1-5nm thick)   1-5nm   ~5µm   1g
GNNP0205 5g
GNNP0211 10g

 

1. Preparation Method

Ultrasonic exfoliation method

2. Characterizations

Thickness

~2 nm

Flake Diameter

2-3 μm

Purity

98%

Electrical Conductivity

400~1000 S/cm

 3. Storage Conditions

Sealed, avoid light, and keep at normal temperature. Expiry date: Six months before unsealing.

 

SEM Image of ACS Material Graphene Nanoplatelets (1-2nm)

 

SEM Image of ACS Material Graphene Nanoplatelets (1-2nm)

 

Raman Spectrum of ACS Material Graphene Nanoplatelets (1-2nm) 

Applications

  • New energy battery, antistatic, heat elimination, improve mechanical strength, conductive composites, coating modifiers, basic physics research, graphene transistors, electronic chips, antenna materials, aerospace etc.

Application Instruction

  • Mix Graphene nanoplatelets with the target polymer using a double-roller‚ banburymixer‚ twin screw extruder or other mixer commonly used in the plastics industry. For better dispersion of the product powder in the target polymer matrix‚ some surface modifiers‚ such as silane coupling agent‚ titanate coupling agent or aluminate coupling agent‚ etc are recommended to use before mixing the powder with plastics resin.

Attention

  • The effectiveness of modification depends very much on the type and the amount of surface modifiers used. We would be delighted to speak with you about what works best for your application. Please call (US) (888)-742-0534

 

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.

Q&A

Q: What are the thermal stability of Graphene Nanoplatelets at ambient pressure?

A: GNPs will not oxide below 600 Celsius‚ and they are very stable.

Research Citations of ACS Material Products

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  11. Li, Mingqi, et al. “Fabrication of graphene nanoplatelets-Supported SiO x -Disordered carbon composite and its application in lithium-Ion batteries.” Journal of Power Sources, vol. 293, 2015, pp. 976–982., doi:10.1016/j.jpowsour.2015.06.019.
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  35. Karimi, Samira, Ismaeil Ghasemi, and Foroud Abbassi-Sourki. "A study on the crystallization kinetics of PLLA in the presence of Graphene Oxide and PEG-grafted-Graphene Oxide: Effects on the nucleation and chain mobility." Composites Part B: Engineering 158 (2019): 302-310.
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  38. Yehia, Hossam M., F. Nouh, and Omayma El-Kady. "Effect of graphene nano-sheets content and sintering time on the microstructure, coefficient of thermal expansion, and mechanical properties of (Cu/WC–TiC-Co) nano-composites." Journal of Alloys and Compounds 764 (2018): 36-43.
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  48. Phuong, M. T., P. V. Trinh, N. V. Tuyen, N. N. Dinh, P. N. Minh, N. D. Dung, and B. H. Thang. "Effect of Graphene Nanoplatelet Concentration on the Thermal Conductivity of Silicone Thermal Grease." Journal of Nano-and Electronic Physics 11, no. 5 (2019).
  49. Mai, Phuong Thi, Tuan Anh Bui, Hau Van Tran, Trinh Van Pham, Dinh Nang Nguyen, Minh Ngoc Phan, and Thang Hung Bui. "Application of Graphene Silicone Grease in heat dissipation for the Intel Core i5 Processor." JOIV: International Journal on Informatics Visualization 3, no. 2-2 (2019): 222-226.
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  51. Zrinski, Ivana, Kingkan Pungjunun, Sanja Martinez, Janez Zavašnik, Dalibor Stanković, Kurt Kalcher, and Eda Mehmeti. "Evaluation of phenolic antioxidant capacity in beverages based on laccase immobilized on screen-printed carbon electrode modified with graphene nanoplatelets and gold nanoparticles." Microchemical Journal 152 (2020): 104282.
  52. Yaqoob, Basit, Riffat Asim Pasha, Mokhtar Awang, Muhammad Ali Nasir, Azhar Hussain, and Kamran Nazir. "Comparison of Mixing Strategies and Hybrid Ratio Optimization for Mechanical Properties Enhancement of Al-CeO 2-GNP’s Metal Matrix Composite Fabricated by Friction Stir Processing." Metallography, Microstructure, and Analysis 8, no. 4 (2019): 534-544.
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