MATERIALS CATALOG

Graphene Nanoplatelets (2-10nm)

Graphene Nanoplatelets (2-10nm)

Price From: $115.00

Availability: In stock

Thickness: 2-10 nm; True Density: 2.3g/cm3

Product Detail

 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
GNNP0031 1kg
GNNP01A5 Graphene Nanoplatelets (1-2nm thick) 1-2nm 5-10µm 500mg
GNNP0201 Graphene Nanoplatelets (1-5nm thick)   1-5nm   ~5µm   1g
GNNP0205 5g
GNNP0211 10g

* Email or call ACS Material for the pricing and availibilty of industrial quantities.

* ACS Material can also provide Fluorinated Graphene Nanoplatelets. Read more >>

 

1. Preparation Method

Interlayer Cleavage Method

 

2. Characterizations 

Appearance:

Black/Grey Powder

Diameter:

2-7 μm

Thickness:

2-10 nm

Specific Surface Area:

20-40 m2/g

Electrical Conductivity:

80000 S/m

Carbon Content:

>99%

Apparent Density:

0.06-0.09 g/ml

Water Content:

<2 wt.%

Residual Impurities:

<1 wt.%

 TEM-Graphene Nanoplatelets

Typical TEM Image (1) of ACS Material Graphene Nanoplatelets (2-10nm)

 TEM-Graphene Nanoplatelets 2

Typical TEM Image (2) of ACS Material Graphene Nanoplatelets (2-10nm)

 

3. Application Fields

  • Conductive rubbers, conductive plastics, antistatic plastics
  • Thermal plastics, thermal polymer composites, thermal interface materials, thermal materials
  • High temperature lubricating materials
  • Use as a high performance additive for composites with PPO‚ POM ‚PPS‚ PC‚ ABS‚ PP‚ PE‚ PS‚ Nylon and rubbers.
  • Can improve composites tensile strength‚ stiffness‚ corrosion resistance‚ abrasion resistance and anti-static electricity and lubricant properties. 
  • For all mechanical properties modifications‚ typical amounts are about 2-6wt%
  • For conductivity modification‚ typical amounts are about 2-8wt%

Graphene nanoplatelets (2-10nm) consist of stacks of multi-layer graphene sheets in a platelet morphology‚ with a high aspect ratio (width–to-thickness). 

True density: 2.3g/cm3

Bulk Characteristics

Appearance

Carbon Content

Bulk Density

Water Content

Residual Impurities

Black and Grey Powder

>99%

~0.10 g/ml

<2 wt%

<1 wt%

Physical Properties

Diameter

Thickness

Specific Surface Area

Electrical Conductivity

Tensile Strength

2-7 μm

2-10 nm

20-40 m2/g

80000 S/m

5 Gpa

Structure Features: The layered structure is as same as graphite crystal

 

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) 866-227-0656

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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  12. Zhang, Genlei, et al. “Small-Sized and highly dispersed Pt nanoparticles loading on graphite nanoplatelets as an effective catalyst for methanol oxidation.” Nanoscale, vol. 7, no. 22, 2015, pp. 10170–10177., doi:10.1039/c5nr01882j.
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  14. Zhang, Genlei, et al. “Facile synthesis of graphene nanoplate-Supported porous Pt–Cu alloys with high electrocatalytic properties for methanol oxidation.” Journal of Materials Chemistry A, vol. 4, no. 9, 2016, pp. 3316–3323., doi:10.1039/c5ta09937d.
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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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  42. Ranjan, Rachit, Nirmal Kumar Singh, Anand Prakash Jaiswal, and Vivek Bajpai. "Metal matrix nano composites using graphene nano platelets indented on copper particles in aluminium matrix." Indent 60 (2018): 600rpm.
  43. Gupta, Tejendra K., M. Choosri, K. M. Varadarajan, and S. Kumar. "Self-sensing and mechanical performance of CNT/GNP/UHMWPE biocompatible nanocomposites." Journal of materials science 53, no. 11 (2018): 7939-7952.
  44. Anas, Muhammad, Muhammad Ali Nasir, Zeeshan Asfar, Saad Nauman, Mehmet Akalin, and Faiz Ahmad. "Structural health monitoring of GFRP laminates using graphene-based smart strain gauges." Journal of the Brazilian Society of Mechanical Sciences and Engineering 40, no. 8 (2018): 397.
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