SMSE

Faculty, by Name

Yongxing SHEN

Yongxing SHEN

Platform:
Research Base of Introduce Talents
Title:
Associate Professor
Office:
Room 212, UM-SJTU Joint Institute
Tel:
86-2134207218
Fax:
 
Email:
yongxing.shen@sjtu.edu.cn
URL:
 
 

Biographical Information

04/2015 to present, Associate Professor, School of Materials Science and Engineering, Shanghai Jiao Tong University

01/2014 to present, Associate Professor, University of Michigan-Shanghai Jiao Tong University Joint Institute

04/2011—01/2014, Professor Lector, Departament de Matematica Aplicada III, Universitat Politecnica de Catalunya, Barcelona, Spain

07/2008—03/2011, Postdoctoral Scholar, Stanford University

09/2003—08/2006, PhD in Materials Science and Engineering, Stanford University

09/2003—06/2006, M.S. in Mechanical Engineering, Stanford University

09/1999—07/2003, B.Eng in Materials Science and Engineering, Tsinghua University

 

Research Interests

Computational Fracture Mechanics

Computational Materials Science

 

Selected Publications

[1]  V. Ziaei-Rad, L. Shen, J. Jiang, and Y. Shen. Identifying the crack path for the phase field approach to fracture with non-maximum suppression. Computer Methods in Applied Mechanics and Engineering. DOI: 10.1016/j.cma.2016.08.025

[2]  S. Zahiri, C. Shao, Y. Shen, and H. Bao. Collocation meshfree method to solve the gray phonon Boltzmann transport equation. Numerical Heat Transfer, Part B: Fundamentals. DOI: 10.1080/10407790.2016.1215719

[3]  V. Ziaei-Rad and Y. Shen. Massive parallelization of the phase field formulation for crack propagation with time adaptivity. Computer Methods in Applied Mechanics and Engineering. DOI: 10.1016/j.cma.2016.04.013

[4]  M. M. Chiaramonte, Y. Shen, L. M. Keer, and A. J. Lew. Computing stress intensity factors for curvilinear cracks. International Journal for Numerical Methods in Engineering 104(4) (2015) 260—296.

[5]  R. Rangarajan, M. M. Chiaramonte, M. J. Hunsweck, Y. Shen, A. J. Lew. Simulating curvilinear crack propagation in two dimensions with universal meshes. International Journal for Numerical Methods in Engineering 102(3-4) (2015) 632–670.

[6]  Y. Shen and A. J. Lew. A locking-free and optimally convergent discontinuous-Galerkin-based extended finite element method for cracked nearly incompressible solids. Computer Methods in Applied Mechanics and Engineering 273 (2014) 119-142.

[7]  Y. Shen. A variational inequality formulation to incorporate the fluid lag in fluid-driven fracture propagation. Computer Methods in Applied Mechanics and Engineering 272 (2014) 17-33.

[8]  F. Amiri, D. Millán, Y. Shen, T. Rabczuk and M. Arroyo. Phase-field modeling of fracture in linear thin shells. Theoretical and Applied Fracture Mechanics 69 (2014) 102-109.

[9]  M. J. Hunsweck, Y. Shen and A. J. Lew. A finite element approach to the simulation of hydraulic fractures with lag. International Journal for Numerical and Analytical Methods in Geomechanics 37(9) (2013) 993-1015.

[10] Y. Shen and A. J. Lew. A family of discontinuous Galerkin mixed methods for nearly and perfectly incompressible elasticity. ESAIM: Mathematical Modelling and Numerical Analysis 46(5) (2012) 1003-1028.

[11] Y. Shen and A. Lew. Stability and convergence proofs for a discontinuous-Galerkin-based extended finite element method for fracture mechanics. Computer Methods in Applied Mechanics and Engineering 199(37-40) (2010) 2360-2382.

[12] Y. Shen and A. Lew. An optimally convergent discontinuous-Galerkin-based extended finite element method for fracture mechanics. International Journal for Numerical Methods in Engineering 82(6) (2010) 716-755.

[13] Y. Shen, D. M. Barnett, and P. M. Pinsky. Modeling electrostatic force microscopy for conductive and dielectric samples using the boundary element method. Engineering Analysis with Boundary Elements 32(8) (2008) 682-691.

[14] Y. Shen, D. M. Barnett, and P. M. Pinsky. Analytic perturbation solution to the capacitance system between a hyberboloidal tip and a rough surface. Applied Physics Letters 92(13) (2008) 134105.

[15] Y. Shen, D. M. Barnett, and P. M. Pinsky. Simulating and interpreting Kelvin probe force microscopy images on dielectrics with boundary integral equations. Review of Scientific Instruments 79(2) (2008) 023711.

[16] Y. Shen, M. Lee, W. Lee, D. M. Barnett, P. M. Pinsky, and F. B. Prinz. A resolution study for electrostatic force microscopy on bimetallic samples using the boundary element method. Nanotechnology 19(3) (2008) 035710.

[17] D. Qiu, Y. X. Shen, and W. Z. Zhang. An extended invariant line analysis for fcc/bcc precipitation systems. Acta Materialia 54(2) (2006) 339-347.