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Silver Nanowires
| Products Summary |
AgNW Brochure |
| Products: |
- AgNW-115
- AgNW-115-E
- AgNW-60
- Other size populations are available upon request with average diameters of 50-200 nm and lengths from 2-100 microns.
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| Custom Orders: |
Silver nanowires dispersed in other carrier fluids or with surface functionalization can be prepared. Additional charges may apply. |
| Quantity: |
Milligram to kilogram quantities. One milligram of material is
equivalent to 109 nanorods.
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Seashell Technology's silver nanowires referenced in selected academic articles:
- De, S; Higgins, TM; Lyons, PE; Doherty, EM; Nirmalraj, PN;
Blau, WJ; Boland, JJ; Coleman, JN. Silver Nanowire Networks
as Flexible, Transparent, Conducting Films: Extremely High DC to Optical
Conductivity Ratios. ACS Nano (2009): pp. 1767-1774
- Madaria, AR; Kumar, A; Ishikawa, FN; Zhou, C.
Uniform, Highly Conductive, and Patterned Transparent Films
of a Percolating Silver Nanowire Network on Rigid and Flexible
Substrates Using a Dry Transfer Technique. Nano Research (2010)
: pp. 564-573.
- Clayton, DA; Benoist, DM; Zhu, Y; Pan, S. Photoluminescence and Spectroelectrochemistry of
Single Ag Nanowires. ACS Nano (2010): pp. 2363-2373.
- Madaria, AR; Kumar, A; Zhou, C. Large scale, highly conductive and patterned
transparent films of silver nanowires on arbitrary substrates and their
application in touch screens. Nanotechnology (2011): pp. 245201.
- Liu, CH; Yu, X. Silver nanowier-based transparent, flexible, and conductive thin film.
Nanoscale Research Letters (2011): Vol. 6, No. 1, 75.
- Morgenstern, FSF; Lyons, PE; Kabra, D; Coleman, JN; Massip, S; Friend, RH. Ag-nanowire films
coated with ZnO nanoparticles as a transparent electrode for solar cells". Applied Physics Letters
(2011): 99, 183307.
- Scardaci, V; Coull, R; Lyons, PE; Rickard, D; Coleman, JN. Spray Deposition of Highly Transparent,
Low-Resistance Networks of Silver Nanowires of Large Areas. Small (2011): pp. 2621-2628.
- Kolesnik, MM; Hansel, S; Lutz, T; Kinahan, N; Boese, M; Krstic, V. Resolving In Situ
Specific-Contact, Current-Crowding, and Channel Resistivity in Nanowire Devices: a Case
Study with Silvern Nanowires. Small (2011): pp. 2873-2877.
- Barnes, TM; Reese, MO; Bergeson, JD; Larsen, BA; Blackburn, JL; Beard, MC; Bult, J; van de Lagemaat, J.
Comparing the Fundamental Physics and Device Performance of Transparent, Conductive
Nanostructured networks with Conventional Transparent Conducting Oxides. Advanced Energy Materials (2012): early view.
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