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	V.H. Rolón-Garrido, M.H. Wagner, C. Luap, T. Schweizer Modeling non-Gaussian extensibility effects in elongation of nearly monodisperse polystyrene melts J. Rheol. 50 (2006) 327-340
Elongational viscosity and birefringence of two nearly monodisperse polystyrene melts with molar mass MW of 206  000  g  mol–1 (PS206k) and 465  000  g  mol–1 (PS465k), respectively, were measured simultaneously by Luap et al. [Rheol. Acta. 45, 83–91 (2005)]. The samples did not follow the stress optical rule (SOR). Elongational viscosity data can be modeled quantitatively by the molecular stress function (MSF) model of Wagner et al. [J. Rheol. 49, 1317–1327 (2005)], which is based on the assumption of a strain-dependent tube diameter and the interchain pressure term of Marrucci and Ianniruberto [Macromolecules 37, 3934–3942 (2004)], and which is modified here to account for non-Gaussian chain extension using the Padé approximation of the inverse Langevin function. The tube diameter relaxation time scales with Mw^2. While the transient elongational viscosity shows a small dependence on finite extensibility, the predicted steady-state elongational viscosity is not affected by non-Gaussian effects. The power-law exponent of the relation between steady-state elongational stress and Deborah number predicted is found to be 0.59 for PS465k, confirming a previous result of 0.6 for a similar molecular mass sample [Wagner et al. (2005)]. The power-law exponent is invariant with respect to temperature but slightly dependent on molar mass, thereby increasing with decreasing molar mass. Deviations from the SOR are described quantitatively by the MSF model by taking into account finite chain extensibility, and within the experimental window investigated, deviations from the SOR are predicted to be strain rate-, temperature-, and molar mass independent, in good agreement with experimental data. for LaTeX users @article{VHRolón-Garrido2006-50,  author = {V. H. Rolón-Garrido and M. H. Wagner and C. Luap and T. Schweizer},  title = {Modeling non-Gaussian extensibility effects in elongation of nearly monodisperse polystyrene melts},  journal = {J. Rheol.},  volume = {50},  pages = {327-340},  year = {2006} } \bibitem{VHRolón-Garrido2006-50} V.H. Rolón-Garrido, M.H. Wagner, C. Luap, T. Schweizer, Modeling non-Gaussian extensibility effects in elongation of nearly monodisperse polystyrene melts, J. Rheol. {\bf 50} (2006) 327-340. VHRolón-Garrido2006-50 V.H. Rolón-Garrido, M.H. Wagner, C. Luap, T. Schweizer Modeling non-Gaussian extensibility effects in elongation of nearly monodisperse polystyrene melts J. Rheol.,50,2006,327-340

---

© 19 May 2024 mk@mat.ethz.ch      1 out of 816 entries requested [H-factor to-date: > 0]