| Competing protein-RNA interaction networks control multiphase intracellular organization DW Sanders, N Kedersha, DSW Lee, AR Strom, V Drake, JA Riback, ... Cell 181 (2), 306-324. e28, 2020 | 655 | 2020 |
| Phase Transitions in Biological Systems with Many Components WM Jacobs, D Frenkel Biophysical Journal 112 (4), 683-691, 2017 | 168 | 2017 |
| Rational design of self-assembly pathways for complex multicomponent structures WM Jacobs, A Reinhardt, D Frenkel Proceedings of the National Academy of Sciences 112 (20), 6313-6318, 2015 | 131 | 2015 |
| Evidence of evolutionary selection for cotranslational folding WM Jacobs, EI Shakhnovich Proceedings of the National Academy of Sciences 114 (43), 11434-11439, 2017 | 105 | 2017 |
| Self-assembly of structures with addressable complexity WM Jacobs, D Frenkel Journal of the American Chemical Society 138 (8), 2457-2467, 2016 | 101 | 2016 |
| Accessibility of the Shine-Dalgarno Sequence Dictates N-Terminal Codon Bias in E. coli S Bhattacharyya, WM Jacobs, BV Adkar, J Yan, W Zhang, EI Shakhnovich Molecular cell 70 (5), 894-905. e5, 2018 | 70 | 2018 |
| Predicting phase behavior in multicomponent mixtures WM Jacobs, D Frenkel The Journal of chemical physics 139 (2), 2013 | 65 | 2013 |
| Self-assembly of biomolecular condensates with shared components WM Jacobs Physical Review Letters 126 (25), 258101, 2021 | 57 | 2021 |
| Self-assembly of photonic crystals by controlling the nucleation and growth of DNA-coated colloids A Hensley, WM Jacobs, WB Rogers Proceedings of the National Academy of Sciences 119 (1), e2114050118, 2022 | 54 | 2022 |
| Cotranslational folding allows misfolding-prone proteins to circumvent deep kinetic traps A Bitran, WM Jacobs, X Zhai, E Shakhnovich Proceedings of the National Academy of Sciences 117 (3), 1485-1495, 2020 | 54 | 2020 |
| Communication: Theoretical prediction of free-energy landscapes for complex self-assembly WM Jacobs, A Reinhardt, D Frenkel The Journal of Chemical Physics 142 (2), 021101, 2015 | 42 | 2015 |
| Phase separation in solutions with specific and nonspecific interactions WM Jacobs, DW Oxtoby, D Frenkel The Journal of Chemical Physics 140 (20), 204109, 2014 | 33 | 2014 |
| Direct observation and rational design of nucleation behavior in addressable self-assembly M Sajfutdinow, WM Jacobs, A Reinhardt, C Schneider, DM Smith Proceedings of the National Academy of Sciences 115 (26), E5877-E5886, 2018 | 27 | 2018 |
| Structure-based prediction of protein-folding transition paths WM Jacobs, EI Shakhnovich Biophysical Journal 111 (5), 925-936, 2016 | 26 | 2016 |
| Theory and simulation of multiphase coexistence in biomolecular mixtures WM Jacobs Journal of Chemical Theory and Computation 19 (12), 3429-3445, 2023 | 25 | 2023 |
| Effect of protein structure on evolution of cotranslational folding V Zhao, WM Jacobs, EI Shakhnovich Biophysical Journal 119 (6), 1123-1134, 2020 | 22 | 2020 |
| Self-assembly protocol design for periodic multicomponent structures WM Jacobs, D Frenkel Soft Matter 11 (46), 8930-8938, 2015 | 20 | 2015 |
| Acoustic energy dissipation and thermalization in carbon nanotubes: Atomistic modeling and mesoscopic description WM Jacobs, DA Nicholson, H Zemer, AN Volkov, LV Zhigilei Physical Review B—Condensed Matter and Materials Physics 86 (16), 165414, 2012 | 20 | 2012 |
| Active learning of the thermodynamics-dynamics tradeoff in protein condensates Y An, MA Webb, WM Jacobs Science Advances 10 (1), adj2448, 2024 | 18 | 2024 |
| Accurate protein-folding transition-path statistics from a simple free-energy landscape WM Jacobs, EI Shakhnovich The Journal of Physical Chemistry B 122 (49), 11126-11136, 2018 | 18 | 2018 |
Daan FrenkelUniversity of Cambridge, UK在 cam.ac.uk 的电子邮件经过验证
