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Publications

BOOKS, MONOGRAPHS AND BOOK CHAPTERS

  • Quaresimin M., Salviato M., Zappalorto M. Toughening Mechanisms in Nanoparticle Polymer Composites: Experimental Evidences, Modeling and Nanodesign. In “Toughening Mechanisms in Composite Materials, Chapter 4, pp 113-133- Editor(s): Q. Qin & J. Ye, Woodhead Publishing, ISBN: 9781782422914

JOURNAL ARTICLES

        2017

[26] Mefford H.C., Qiao Y., Salviato M., Failure and Scaling of Graphene Nanocomposites. Composite Structures, In press .

[25] Ceccato C, Salviato M., Pellegrino C., Cusatis G. Simulation of Concrete Failure and Fiber Reinforced Polymer Fracture in Confined Columns with Different Cross Sectional Shape. International Journal of Solids and Structures, 108:216-29, (2017) .

[24] Jin C, Salviato M., Li W., Cusatis G. Elastic Microplane Formulation for Transversely Isotropic Materials. ASME Journal of Applied Mechanics, 84(1) 011001, (2017) .

       2016

[23] Salviato M., Zappalorto M. A Unified Solution Approach for a Large Variety of Anti-Plane Shear and Torsion Notch Problems: Theory and Examples. International Journal of Solids and Structures, 102-103:10-20 (2016) .

[22] Salviato M., Chau V.T., Li W., Cusatis C. Direct Testing of Gradual Postpeak Softening of Fracture Specimens of Fiber Composites Stabilized by Enhanced Grip Stiffness and Mass. ASME Journal of Applied Mechanics, 83 (11), 111003, (2016).

[21] Salviato M., Kirane K., Ashari S., Bažant Z.P., Cusatis G. Experimental and Numerical Investigation of Intra-Laminar Energy Dissipation and Size Effect in Two Dimensional Textile Composites. Composites Science and Technology, 135:67-75 (2016).

[20]  Salviato M., S. E. Ashari, Cusatis G.. A Spectral Stiffness Microplane Model for Damage and Fracture of Textile Composites. Composite Structures; 137:170-184 (2016).

[19]  Kirane K., Salviato M., Bažant Z.P. Microplane-Triad Model for Elastic and Fracturing Behavior of Woven Composites. ASME Journal of Applied Mechanics; 83:0410061-14 (2016).

[18]  Kirane K., Salviato M., Bažant Z.P. Multiscale Microplane Model for Predicting Elastic Properties of Woven Fabric Composites. Journal of Composite Materials; 50:1247-1260 (2016).

       2015

[17]  Su Y., Bažant Z.P., Zhao Y., Salviato M, Kirane K. Viscous energy dissipation of kinetic energy of particles comminuted by high-rate shearing in projectile penetration, with potential ramification to gas shale. International Journal of Fracture; 193:77-85, (2015).

       2014

[16]  Bažant Z.P., Salviato M., Chau V.T., Viswanathan H., Zubelewicz A. Why Fracking Works. Journal of Applied Mechanics, 81,101010-1-10, (2014).

[15]  Salviato M., Kirane K., Bažant Z.P. Statistical Distribution and Size Effect of Residual Strength after a Period of Constant Load. Journal of Mechanics and Physics of Solids, 64, 440-54, (2014).

[14]  Salviato M., Bažant Z.P. The Asymptotic Stochastic Strength of Bundles of Elements Exhibiting General Stress-Strain Laws. Probabilistic Engineering Mechanics, 36, 1-7, (2014).

[13]  Quaresimin M., Salviato M., Zappalorto M. A multi-scale and multi-mechanism model for the fracture toughness of nanoparticle filled thermosetting polymers. Composites Science and Technology, 91, 16-21, (2014).

       2013

[12]  Zappalorto M., Salviato M., Quaresimin M. Mixed Mode (I+ II) Fracture Toughness of Polymer Nanoclay Nanocomposites. Engineering Fracture Mechanics, 111, 50-64, (2013).

[11]  Salviato M., Zappalorto M., Quaresimin M. Nanoparticle debonding strength: a comprehensive study on interfacial effects. International Journal of Solids and Structures, 50, 3225-3232, (2013).

[10]  Zappalorto M., Salviato M., Pontefisso A. Quaresimin M. Notch effect in clay-modified epoxy: a new perspective on nanocomposite properties. Composite Interfaces, 20:(6), 405-419, (2013).

[9]    Salviato M., Zappalorto M., Quaresimin M. Plastic shear bands and fracture toughness improvements of nanoparticle filled polymers: a multiscale analytical model. Composites Part A, 48, 144-152, (2013).

       2012

[8]    Zappalorto M., Salviato M., Quaresimin M. A multiscale model to describe nanocomposite fracture toughness enhancement by the plastic yielding of nanovoids. Composites Science and Technology, 72, 1683-1691, (2012).

[7]    Zappalorto M., Salviato M., Quaresimin M. Stress distributions around rigid nanoparticles. International Journal of Fracture, 176, 105-112, (2012).

[6]    Quaresimin M., Salviato M., Zappalorto M. Strategies for the assessment of nanocomposite mechanical properties. Composites part B: Engineering, 43, 2290-2297, (2012).

[5]    Quaresimin M., Salviato M., Zappalorto M., Fracture and interlaminar properties of clay-modified epoxies and their glass reinforced laminates. Engineering Fracture Mechanics, 81:80-   93, (2012).

       2011

[4]    Salviato M., Zappalorto M., Quaresimin M. The effect of surface stresses on the critical debonding stress around nanoparticles. International Journal of Fracture, 172:97-103, (2011).

[3]    Zappalorto M., Salviato M., Quaresimin M. Influence of the interphase zone on the nanoparticle debonding stress. Composites Science and Technology, 72, 48-55, (2011).

[2]    Salviato M., Zappalorto M., Quaresimin M. Plastic Yielding Around Nanovoids. Procedia Engineering, Vol. 10, pp. 3316 – 3321, (2011).

[1]    Zappalorto M., Salviato M., Quaresimin M. Assessment of Debonding-Induced Toughening in Nanocomposites. Procedia Engineering, Vol. 10, pp. 2973 – 2978, (2011).