Selected ETH Polymer Physics publications

All All Article Preprint Proc Report Thesis Book Book Review Patent Review Project All latest All 2024 All 2023 All 2022 All 2021 All 2020 All 2019 All 2018 All 2017 All 2016 All 2015 All 2014 All 2013 All 2012 All 2011 All 2010 All 2009 All 2008 All 2007 All 2006 All 2005 All 2004 All 2003 All 2002 All 2001 All 2000 All 1999 All 1998 All 1997 All 2025 by default year impact cited downloads downloads/a submission author title journal classical default bibitems bibtex Hcitations newcommand twiki (&y=year) citations per author impact per author bibtex e-collection

abstracts hide pdf's show images matching keyword & author

1 selected entry

Article	G. Chen, L. Tao, M. Kröger, Y. Li Inverse Hall-Petch effect in nanocrystalline ice predicted by machine-learned coarse-grained molecular simulations J. Micromech. Molec. Phys. 8 (2023) 1-10
We study the grain-size effect on mechanical behaviors of polycrystalline ice at nanoscale through large-scale molecular dynamics simulations, enabled by an accurate and efficient machine-learned coarse-grained water model [H. Chan, M. J. Cherukara, B. Narayanan, T. D. Loeffler, C. Benmore, S. K. Gray and S. K. Sankaranarayanan. Machine learning coarse grained models for water. Nature Communications 10(1), p. 379, 2019]. Polycrystalline ice systems with different grain sizes in the range of ∼ 30 nm are systematically investigated through uniaxial tensile tests. Simulation results reveal that Young’s modulus and yield strength increase as the grain size increases, leading to an inverse Hall–Petch effect in nanocrystalline ice. Such an observation is significantly different from the conventional Hall–Petch effect in polycrystalline ice observed by experiments at millimeter scale. The deformation behavior suggests that grain boundaries (GBs), rather than grain interiors, play the active role in accommodating external loading in nanocrystalline ice. Further void analysis of nanocrystalline ice during deformation reveals that nanocrack initiates and propagates along GBs and eventually leads to failure of systems with larger grain sizes (≥ 20nm), yielding a sudden drop in the stress–strain curve. While for systems with smaller grain sizes (≤ 15nm), only extensive plastic deformation is presented without significant void growth. Our simulation results demonstrate that the GB sliding is the governing mechanism for the inverse Hall–Petch effect observed in nanocrystalline ice. for LaTeX users @article{GChen2023-8,  author = {G. Chen and L. Tao and M. Kr\"oger and Y. Li},  title = {Inverse Hall-Petch effect in nanocrystalline ice predicted by machine-learned coarse-grained molecular simulations},  journal = {J. Micromech. Molec. Phys.},  volume = {8},  pages = {1-10},  year = {2023} } \bibitem{GChen2023-8} G. Chen, L. Tao, M. Kr\"oger, Y. Li, Inverse Hall-Petch effect in nanocrystalline ice predicted by machine-learned coarse-grained molecular simulations, J. Micromech. Molec. Phys. {\bf 8} (2023) 1-10. GChen2023-8 G. Chen, L. Tao, M. Kr\"oger, Y. Li Inverse Hall-Petch effect in nanocrystalline ice predicted by machine-learned coarse-grained molecular simulations J. Micromech. Molec. Phys.,8,2023,1-10

---

© 03 May 2024 mk@mat.ethz.ch      1 out of 810 entries requested [H-factor to-date: > 0]