Network model for the viscoelastic behavior of polymer nanocomposites AS Sarvestani, CR Picu Polymer 45 (22), 7779-7790, 2004 | 150 | 2004 |
Elastic fields in double inhomogeneity by the equivalent inclusion method HM Shodja, AS Sarvestani J. Appl. Mech. 68 (1), 3-10, 2001 | 103 | 2001 |
Modeling the solid-like behavior of entangled polymer nanocomposites at low frequency regimes AS Sarvestani European Polymer Journal 44 (2), 263-269, 2008 | 90 | 2008 |
Viscoelastic Characterization and Modeling of Gelation Kinetics of Injectable In Situ Cross-Linkable Poly(lactide-co-ethylene oxide-co-fumarate) Hydrogels AS Sarvestani, X He, E Jabbari Biomacromolecules 8 (2), 406-415, 2007 | 82 | 2007 |
Swelling characteristics of acrylic acid polyelectrolyte hydrogel in a dc electric field E Jabbari, J Tavakoli, AS Sarvestani Smart Materials and Structures 16 (5), 1614, 2007 | 68 | 2007 |
Effect of osteonectin‐derived peptide on the viscoelasticity of hydrogel/apatite nanocomposite scaffolds AS Sarvestani, X He, E Jabbari Biopolymers: Original Research on Biomolecules 85 (4), 370-378, 2007 | 65 | 2007 |
Modeling the viscoelastic response of suspension of particles in polymer solution: the effect of polymer‐particle interactions AS Sarvestani, E Jabbari Macromolecular theory and simulations 16 (4), 378-385, 2007 | 60 | 2007 |
Modeling and experimental investigation of rheological properties of injectable poly (lactide ethylene oxide fumarate)/hydroxyapatite nanocomposites AS Sarvestani, E Jabbari Biomacromolecules 7 (5), 1573-1580, 2006 | 60 | 2006 |
Gelation and degradation characteristics of in situ photo-crosslinked poly(l-lactide-co-ethylene oxide-co-fumarate) hydrogels AS Sarvestani, W Xu, X He, E Jabbari Polymer 48 (24), 7113-7120, 2007 | 59 | 2007 |
A frictional molecular model for the viscoelasticity of entangled polymer nanocomposites AS Sarvestani, CR Picu Rheologica Acta 45, 132-141, 2005 | 58 | 2005 |
Vitrimer transition temperature identification: coupling various thermomechanical methodologies AM Hubbard, Y Ren, D Konkolewicz, A Sarvestani, CR Picu, GS Kedziora, ... ACS Applied Polymer Materials 3 (4), 1756-1766, 2021 | 56 | 2021 |
Effect of chain length distribution on mechanical behavior of polymeric networks M Tehrani, A Sarvestani European Polymer Journal 87, 136-146, 2017 | 54 | 2017 |
Osteonectin-derived peptide increases the modulus of a bone-mimetic nanocomposite AS Sarvestani, X He, E Jabbari European Biophysics Journal 37, 229-234, 2008 | 43 | 2008 |
Analysis of cell locomotion on ligand gradient substrates AS Sarvestani, E Jabbari Biotechnology and bioengineering 103 (2), 424-429, 2009 | 40 | 2009 |
Material properties and bone marrow stromal cells response to In situ crosslinkable RGD‐functionlized lactide‐co‐glycolide scaffolds E Jabbari, X He, MT Valarmathi, AS Sarvestani, W Xu Journal of Biomedical Materials Research Part A: An Official Journal of The …, 2009 | 40 | 2009 |
On the overall elastic moduli of composites with spherical coated fillers AS Sarvestani International journal of solids and structures 40 (26), 7553-7566, 2003 | 38 | 2003 |
On the emergence of the Payne effect in polymer melts reinforced with nanoparticles AS Sarvestani Macromolecular Theory and Simulations 25 (3), 312-321, 2016 | 33 | 2016 |
Creep mechanics of epoxy vitrimer materials AM Hubbard, Y Ren, CR Picu, A Sarvestani, D Konkolewicz, AK Roy, ... ACS Applied Polymer Materials 4 (6), 4254-4263, 2022 | 24 | 2022 |
Advances in cell mechanics S Li, B Sun, S Li Springer, 2011 | 21 | 2011 |
A model for the viscoelastic behavior of nanofilled hydrogel composites under oscillatory shear loading AS Sarvestani, E Jabbari Polymer composites 29 (3), 326-336, 2008 | 20 | 2008 |