Julia M. Yeomans
Affiliations: | 1979 | University of Oxford, Oxford, United Kingdom |
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Sign in to add trainee| Davide Marenduzzo | post-doc | Oxford (Cell Biology Tree) | |
| Jörn Dunkel | post-doc | 2008-2010 | Oxford |
| Tyler N. Shendruk | post-doc | 2014-2016 | Oxford |
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Publications
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| Mori F, Bhattacharyya S, Yeomans JM, et al. (2024) Viscoelastic confinement induces periodic flow reversals in active nematics. Physical Review. E. 108: 064611 |
| Hadjifrangiskou I, Ruske LJ, Yeomans JM. (2023) Active nematics with deformable particles. Soft Matter |
| Xu H, Nejad MR, Yeomans JM, et al. (2023) Geometrical control of interface patterning underlies active matter invasion. Proceedings of the National Academy of Sciences of the United States of America. 120: e2219708120 |
| Bhattacharyya S, Yeomans JM. (2023) Phase Separation Driven by Active Flows. Physical Review Letters. 130: 238201 |
| Ruske LJ, Yeomans JM. (2023) Activity-driven tissue alignment in proliferating spheroids. Soft Matter. 19: 921-931 |
| Ruske LJ, Yeomans JM. (2022) Activity gradients in two- and three-dimensional active nematics. Soft Matter. 18: 5654-5661 |
| Nejad MR, Yeomans JM. (2022) Active Extensile Stress Promotes 3D Director Orientations and Flows. Physical Review Letters. 128: 048001 |
| Samui A, Yeomans JM, Thampi SP. (2021) Flow transitions and length scales of a channel-confined active nematic. Soft Matter. 17: 10640-10648 |
| Bhattacharyya S, Yeomans JM. (2021) Coupling Turing stripes to active flows. Soft Matter |
| Thijssen K, Khaladj DA, Aghvami SA, et al. (2021) Submersed micropatterned structures control active nematic flow, topology, and concentration. Proceedings of the National Academy of Sciences of the United States of America. 118 |