Alan Windle
Affiliations: | University of Cambridge, Cambridge, England, United Kingdom |
Area:
Nano materialsGoogle:
"Alan Windle"Mean distance: 106866
Cross-listing: Physics Tree
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Publications
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| Gspann TS, Ngern NH, Kiley PJ, et al. (2020) A comparative study of the tensile failure of carbon nanotube, Dyneema and carbon fibre tows over six orders of strain rate Carbon. 164: 407-421 |
| Kaniyoor A, Bulmer J, Gspann T, et al. (2019) High throughput production of single-wall carbon nanotube fibres independent of sulfur-source. Nanoscale |
| Smail F, Boies A, Windle A. (2019) Direct spinning of CNT fibres: Past, present and future scale up Carbon. 152: 218-232 |
| Gspann TS, Ngern NH, Fowler A, et al. (2018) Triboluminescence flashes from high-speed ruptures in carbon nanotube Macro-Yarns Materials Letters. 213: 298-302 |
| Sundaram RM, Windle AH. (2017) One-step purification of direct-spun CNT fibers by post-production sonication Materials & Design. 126: 85-90 |
| Mikhalchan A, Gspann T, Windle A. (2016) Aligned carbon nanotube–epoxy composites: the effect of nanotube organization on strength, stiffness, and toughness Journal of Materials Science. 51: 10005-10025 |
| Gspann TS, Montinaro N, Windle AH. (2015) CNT fibres - yarns between the extremes Mrs Proceedings. 1752: 117-123 |
| Sundaram RM, Windle AH. (2015) Effect of carbon precursors on the structure and properties of continuously spun carbon nanotube fibers Science of Advanced Materials. 7: 643-653 |
| Montinaro N, Gspann TS, Pantano A, et al. (2015) Stress Transfer within CNT Fibres: A FEA Approach Procedia Engineering. 109: 435-440 |
| Gspann TS, Montinaro N, Pantano A, et al. (2015) Mechanical properties of carbon nanotube fibres: St Venant's principle at the limit and the role of imperfections Carbon. 93: 1021-1033 |