Large Surface Area Single Walled Carbon Nanotubes, Purity: > 95%, SSA: 400 m2/g
- SKU:
- NG01SW0601
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- Calculated at Checkout
Description
5 grams/170 €
25 grams/560 €
100 grams/1950 €
500 grams/7460 €
1000 grams/11850 €
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Large Surface Area Single Walled Carbon Nanotubes
Purity: > 95%, SSA: 400 m2/g, Dia: 1.0 nm
Single walled carbon nanotubes (SWCNTs, SWNTs) comprise of one-atom-thick sheets of graphene that rolled up to form long hollow tubes. SWCNTs possess exceptional thermal, mechanical and electrical properties. These remarkable properties lead to advances in performance in a wide range of materials and devices. Single-walled carbon nanotubes are actively used in diverse area including energy storage, molecular electronics, nanomechanial devices, composites and bio-sensing. Our company sells Large Surface Area Single Wall Carbon Nanotubes with high purity and low prices.
Technical Properties:
| Purity | > 95 % |
| Color | black |
| Average Diameter | 1.0 nm |
| Length | 5-35 µm |
| OD | 1-2 nm |
| ID | 0.8-1.6 nm |
| True Density | 2.2 g/cm3 |
| SSA | 400 m2/g |
| Ignited Temperature | 620 °C |
| Thermal Conductivity | 45-190 W/m.K |
| Electrical Conductivity | 98 S/cm |
| Manufacturing Method | CVD |
| CAS No | 308068-56-6 |
Applications:
- Transparent Conductive Films & Displays: These SWCNTs are highly suited for the fabrication of transparent conductive films used in touch screens, flat panel displays, OLEDs, and thin-film solar cells. Their excellent conductivity and optical clarity enable flexible, lightweight alternatives to conventional transparent electrodes.
- Energy Storage & Conversion: With their expansive surface area and high structural integrity, these nanotubes enhance charge transport and interface behavior in energy devices such as supercapacitors, lithium-ion batteries, and fuel cells. They support efficient energy conversion and long-term cycling stability.
- Catalysis & Surface Chemistry: Their clean graphitic surfaces and high reactivity make them ideal supports for catalytic systems. They are used in heterogeneous and electrocatalytic reactions, as well as in surface modification and template-assisted synthesis, where active site exposure is critical.
- Composites & Coatings: These nanotubes disperse uniformly in polymer matrices and functional coatings, improving mechanical strength, thermal conductivity, and electrical performance. Their morphology supports strong interfacial bonding and processability in advanced composite systems.
- Sensors & Nanodevices: Their nanoscale dimensions and defect-free structure enable high sensitivity in gas sensors, biosensors, and nanoelectronic devices. They provide stable signal transmission and reliable integration into miniaturized platforms.