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 has been cited at least 38 times (SCI, 20-04-2024)

Article	R.J.A. Steenbakkers, C. Tzoumanekas, Y. Li, W.K. Liu, M. Kröger, J.D. Schieber Primitive-path statistics of entangled polymers: Mapping multi-chain simulations onto single-chain mean-field models New J. Phys. 16 (2014) 015027
We present a method to map the full equilibrium distribution of the primitive path (PP) length, obtained from multi-chain simulations of polymer melts, onto a single-chain mean-field .target. model. Most previous works used the Doi.Edwards tube model as a target. However, the average number of monomers per PP segment, obtained from multi-chain PP networks, has consistently shown a discrepancy of a factor of two with respect to tube-model estimates. Part of the problem is that the tube model neglects fluctuations in the lengths of PP segments, the number of entanglements per chain and the distribution of monomers among PP segments, while all these fluctuations are observed in multi-chain simulations. Here we use a recently proposed slip-link model, which includes fluctuations in all these variables as well as in the spatial positions of the entanglements. This turns out to be essential to obtain qualitative and quantitative agreement with the equilibrium PP-length distribution obtained from multi-chain simulations. By fitting this distribution, we are able to determine two of the three parameters of the model, which govern its equilibrium properties. This mapping is executed for four different linear polymers and for different molecular weights. The two parameters are found to depend on chemistry, but not on molecular weight. The model predicts a constant plateau modulus minus a correction inversely proportional to molecular weight. The value for well entangled chains, with the parameters determined ab initio, lies in the range of experimental data for the materials investigated. for LaTeX users @article{RJASteenbakkers2014-16,  author = {R. J. A. Steenbakkers and C. Tzoumanekas and Y. Li and W. K. Liu and M. Kr\"oger and J. D. Schieber},  title = {Primitive-path statistics of entangled polymers: Mapping multi-chain simulations onto single-chain mean-field models},  journal = {New J. Phys.},  volume = {16},  pages = {015027},  year = {2014} } \bibitem{RJASteenbakkers2014-16} R.J.A. Steenbakkers, C. Tzoumanekas, Y. Li, W.K. Liu, M. Kr\"oger, J.D. Schieber, Primitive-path statistics of entangled polymers: Mapping multi-chain simulations onto single-chain mean-field models, New J. Phys. {\bf 16} (2014) 015027. RJASteenbakkers2014-16 R.J.A. Steenbakkers, C. Tzoumanekas, Y. Li, W.K. Liu, M. Kr\"oger, J.D. Schieber Primitive-path statistics of entangled polymers: Mapping multi-chain simulations onto single-chain mean-field models New J. Phys.,16,2014,015027

---

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