Refereed Publications

1. X. Guo, W. Liang, and M. Zhou, Mechanism for the pseudoelastic behavior of FCC shape memory nanowires, Experimental Mechanics; 2009; Download a PDF copy
2. A.J. Kulkarni, K. Sarasamak, J. Wang, F.J. Ke, S. Limpijumnong, and M. Zhou, Effect of load triaxiality on polymorphic transitions in zinc oxide, Mechanics Research Communications; 35, 73-80, 2008; Download a PDF copy
3. J. Wang, A.J. Kulkarni, F.J. Ke, Y.L. Bai, and M. Zhou, Novel mechanical behavior of ZnO nanorods, Computer Methods in Applied Mechanics and Engineering; 197, 3182-3189, 2008; Download a PDF copy
4. A. J. Kulkarni and M. Zhou, Continuum Characterization of Novel Pseudoelasticity of ZnO Nanowires, Journal of the Mechanics and Physics of Solids; 56, 2473-2493, 2008; Download a PDF copy
5. R. Dingreville, A. J. Kulkarni, M. Zhou, and J. Qu, A semi-analytical method for quantifying the size-dependent elasticity of nanostructures, Modelling and Simulation in Materials Science and Engineering; 16, 025002-1-16, 2008; Download a PDF copy
6. K. Sarasamak, A. J. Kulkarni, M. Zhou, and S. Limpijumnong, Stability of wurtzite, unbuckled wurtzite, and rocksalt phases of SiC, GaN, InN, ZnO, and CdSe under loading of different triaxialities, Physical Review B; 77, 024104-1-12, 2008; Download a PDF copy
7. J. Wang, A. J. Kulkarni, K. Sarasamak, S. Limpijumnong, F. J. Ke, and M. Zhou, Molecular dynamics and density functional studies of a body-centered-tetragonal polymorph of ZnO, Physical Review B; 76, 172103-1-4, 2007; Download a PDF copy
8. A. J. Kulkarni and M. Zhou, Tunable thermal response of ZnO nanowires, Nanotechnology; 18, 435706-1-6, 2007; Download a PDF copy
9. W. Liang and M. Zhou, Discovery, characterization and modelling of novel shape memory behaviour of fcc metal nanowires, Philosophical Magazine; 87, 2191-2220, 2007; Download a PDF copy
10. A. J. Kulkarni, K. Sarasamak, S. Limpijumnong and M. Zhou, Characterization of novel pseudoelastic behaviour of zinc oxide nanowires, Philosophical Magazine; 87, 2117-2134, 2007; Download a PDF copy
11. S. Chen, F. Ke, M. Zhou, Y. Bai, Atomistic investigation of the effects of temperature and surface roughness on diffusion bonding between Cu and Al, Acta Materialia; 55, 3169–3175, 2007; Download a PDF copy
12. W. Liang, D. J. Srolovitz, M. Zhou, A micromechanical continuum model for the tensile behavior of shape memory metal nanowires, Journal of the Mechanics and Physics of Solids; 55, 1729-1761, 2007; Download a PDF copy
13. V. Tomar and M. Zhou, Analyses of tensile deformation of nanocrystalline alpha-Fe₂O₃+fcc-Al composites using molecular dynamics simulations, Journal of the Mechanics and Physics of Solids; 55, 1053-1085, 2007; Download a PDF copy
14. A. J. Kulkarni, M. Zhou, K. Sarasamak, S. Limpijumnong, Novel phase transformation in ZnO nanowires under tensile loading, Physical Review Letters; 97, 105502,2006; Download a PDF copy
15. V. Tomar, M. Zhou, Tension-compression strength asymmetry of nanocrystalline alpha-Fe₂O₃ + fcc-Al ceramic-metal composites, Applied Physics Letters; 88, 233107, 2006; Download a PDF copy
16. V. Tomar, M. Zhou, Classical molecular-dynamics potential for the mechanical strength of nanocrystalline composite fcc-Al + alpha-Fe₂O₃, Physical Review B; 73, 174116,2006; Download a PDF copy
17. A.J. Kulkarni, M. Zhou, Size-dependent thermal conductivity of zinc oxide nanobelts, Applied Physics Letters; 88, 141921,2006; Download a PDF copy
18. W. Liang, M. Zhou, Atomistic simulations reveal shape memory of fcc metal nanowires, Physical Review B; 73, 115409, 2006; Download a PDF copy
19. A.J. Kulkarni, M. Zhou, Surface-effects-dominated mechanical and thermal responses of zinc oxide nanobelts, Acta Mechanica Sinica; 22, 217, 2006; Download a PDF copy
20. M. Zhou, Thermomechanical Continuum Representation of Atomistic Deformation at Arbitrary Size Scales, Proceedings of the Royal Society A; 461, 3437-3472, 2005; Download a PDF copy
21. W. Liang, M. Zhou and F. J. Ke, Shape Memory Effect in Cu Nanowires, Nano Letters; 5(10), 2005; Download a PDF copy
22. A. J. Kulkarni, M. Zhou, and F. J. Ke, Orientation and Size Dependence of the Elastic Properties of Zinc Oxide Nanobelts, Nanotechnology; 16(10), 2005; Download a PDF copy
23. W. Liang and M. Zhou, Pseudoelasticity of Single Crystalline Cu Nanowires Through Reversible Lattice Reorientations, Journal of Engineering Materials and Technology; 127(4), 423-433, 2005; Download a PDF copy
24. V. Tomar and M. Zhou, Deterministic and Stochastic Analyses of Fracture Processes in a Brittle Microstructure System, Engineering Fracture Mechanics; 72, 1920-1941, 2005; Download a PDF copy
25. V. Tomar, J. Zhai and M. Zhou, Bounds for Element Size in a Variable Stiffness Cohesive Finite Element Model, International Journal for Numerical Methods in Engineering; 61, 1894-1920, 2004; Download a PDF copy
26. K. Minnaar and M. Zhou, A novel technique for time-resolved detection and tracking of interfacial and matrix fracture in layered materials, Journal of the Mechanics and Phyics of Solids; 52(12), 2771-2799, 2004, Download a PDF copy
27. M. Zhou, Thermomechanical Continuum Interpretation of Atomistic Deformation, International Journal for Multiscale Computational Engineering; 3(2), 177-197, 2005, Download a PDF copy
28. J. Zhai, V. Tomar and M. Zhou, Micromechanical Simulation of Dynamic Fracture Using the Cohesive Finite Element Method, Journal of Engineering Materials and Technology; 126, 179-191, 2004, Download a PDF copy
29. W. Liang and M. Zhou, Response of Copper Nanowires in Dynamic Tensile Deformation, Journal of Mechanical Engineering Science; 218 (6), 599-606, 2004, Download a PDF copy
30. M. Zhou, A New Look at the Atomic Level Virial Stress--On Continuum-Molecular System Equivalence, Proceedings of the Royal Society of London A; 459, 2347-2392, 2003, Download a PDF copy
31. G. Kennedy, L. Ferranti, R. Russell, M. Zhou, and N. Thadhani, Dynamic High-Strain-Rate Mechanical Behavior of Microstructurally-biased Two-Phase TiB2+Al2O3 Ceramics, Journal of Applied Physics, 91, no.4, pp. 1921-1927, 2002; Download a PDF copy
32. A. R. Keller and M. Zhou, Effect of Microstructure on Dynamic Failure Resistance of TiB₂/Al₂O₃ Ceramics, Journal of the American Ceramic Society, 86(3), pp.449-457, (2003); Download a PDF copy
33. M. Zhou and D. L. McDowell, Equivalent Continuum for Dynamically Deforming Atomistic Particle Systems, Philosophical Magazine A, 82(13), 2547-2574, 2002; Download a PDF copy
34. D. L. Grote, S. W. Park, and M. Zhou, Experimental Characterization of the Dynamic Failure Behavior of Mortar under Impact Loading, Journal of Applied Physics, 89, no. 4, pp. 2115-2123, 2001; Download a PDF copy or View the journal issue
35. D. L. Grote, S. W. Park and M. Zhou, "Dynamic Behavior of Concrete and Mortar at High Strain rates, Part I: Experimental Characterization", International Journal of Impact Engineering, 25(9), pp. 869-886, 2001; Download a PDF copy
36. S. W. Park, Q. Xia and M. Zhou, "Dynamic Behavior of Concrete and Mortar at High Strain rates, Part II: Numerical Simulations", International Journal of Impact Engineering, 25(9), pp. 887-910, 2001; Download a PDF copy
37. M. Zhou, "Effects of Microstructure on the Resistance to Shear Localization for a Class of Metal Matrix Composites", Fatigue and Fracture of Engineering Materials and Structures, 21, pp. 425-438, 1998; Download a PDF copy
38. M. Zhou, "The Growth of Shear Bands in Composite Microstructures", International Journal of Plasticity, 14, pp. 733-754, 1998; Download a PDF copy
39. K. Minnaar and M. Zhou, "An Analysis of the Dynamic Shear Failure Resistance of Structural Metals", Journal of the Mechanics and Physics of Solids, 46, pp. 2155-2170, 1998; Download a PDF copy
40. M. Zhou, A. J. Rosakis and G. Ravichandran, "On the Growth of Shear Bands and Failure-Mode Transition in Prenotched Plates: A comparison of singly and doubly notched specimens", International Journal of Plasticity, 14, pp.435-451, 1998; Download a PDF copy
41. S. W. Park, M. Zhou and D. R. Veazie, "Time-resolved Impact Response and Damage of Fiber-reinforced Composite Laminates", Journal of Composite Materials, 34(10), pp. 879-904, 2000; Download a PDF copy
42. S. W. Park and M. Zhou, "Separation of Elastic Waves in Split Hopkinson Bars using One-point Strain Measurements", Experimental Mechanics, 39, pp. 287-294, 1999; Download a PDF copy
43. J. Zhai and M. Zhou, "Finite Element Analysis of Micromechanical Failure Modes in Heterogeneous Brittle Solids", International Journal of Fracture, special issue on Failure Mode Transition in Solids, R. C. Batra, Y. D. S. Rajapakse, and A. J. Rosakis, eds., 101, pp. 161-180, 2000; Download a PDF copy
44. J. Zhai and M. Zhou, "Micromechanical Modeling of Mixed-mode Crack Growth in Ceramic Composites", Mixed Mode Crack Behavior, ASTM STP 1359, pp. 174-200, 1999, K. Miller and D. L. McDowell, eds.; Download a PDF copy
45. Veazie, D. R., Park, S. W., and Zhou, M., Post-Impact Behavior of Polymeric Composites and the Effects of Salt Water Aging on Tensile Properties, Journal of Advanced Composite Letters, 8, No. 5, pp. 257–264, 1999;
46. M. Zhou and R. J. Clifton, "Dynamic Constitutive and Failure Behavior of a Two-phase Tungsten Composite", Journal of Applied Mechanics, 64, pp. 487-494, 1997;Download a PDF copy
47. M. Zhou and R. J. Clifton, "Dynamic Ductile Rupture under the Conditions of Plan Strain", International Journal of Impact Engineering, 19, pp. 189-206, 1997; Download a PDF copy
48. M. Zhou, A. J. Rosakis and G. Ravichandran, "Dynamically Propagating Shear Bands in Impact-loaded Prenotched plates, I - Experimental Investigations of Temperature Signatures and Propagation Speed", Journal of the Mechanics and Physics of Solids, 44, pp. 981-1006, 1996; Download a PDF copy
49. M. Zhou, G. Ravichandran and A. J. Rosakis, "Dynamically Propagating Shear Bands in Impact-loading Prenotched plates, II - Numerical Simulations", Journal of the Mechanics and Physics of Solids, 44, pp. 1007-1032, 1996;Download a PDF copy
50. J. Rosakis, G. Ravichandran and M. Zhou, "Dynamically Growing Shear Bands in Metals: A study of Transient Temperature and Deformation Fields", Proc. IUTAM Symposium on Nonlinear Analysis of Fracture, September 1995, Cambridge, England;
51. M. Zhou, A. Needleman and R. J. Clifton, "Finite Element Simulations of Dynamic Shear Localization in Plate Impact", Journal of the Mechanics and Physics of Solids, 42, pp. 423-458, 1994; Download a PDF copy
52. Zhou, R. J. Clifton and A. Needleman, "Shear Band Formation in a W-Ni-Fe Heavy Alloy under Plate Impact", Tungsten & Tungsten Alloys, pp. 343-356, Nov. 1992, Metal Powder Industries Federation, Arlington, VA

Book Chapters

1. W. Liang, V. Tomar and M. Zhou, “Modeling and Simulation of The Mechanical Response of Nanowires”, Chapter IV of Nanowires and Nanobelts: Materials, Properties and Devices, Vol. 1, Metal and Semiconductor Nanowires, pp. 123-155, edited by Z. L. Wang, Kluwer Academic Publishers, 2003.

Other Publications

1. M. Zhou, R. J. Clifton and A. Needleman, “Shear Band Formation in a W-Ni-Fe Heavy Alloy under Plate Impact”, Tungsten & Tungsten Alloys, pp. 343-356, Nov. 1992, Metal Powder Industries Federation, Arlington, VA;
2. W. Liang and M. zhou, Surface-stress-driven pseudoelasticity and shape memory effect at the nanoscale, Proceedings of the 16th European Conference of Fracture (ECF16), Alexandroupolis, Greece, July 3-7, 2006;
3. A. J. Kulkarni and M. Zhou Thermomechanical behavior of zinc oxide nanobelts, Proceedings of the 16th European Conference of Fracture (ECF16), Alexandroupolis, Greece, July 3-7, 2006;
4. V. Tomar and M. Zhou, A study of shock wave propagation in fcc-Al and a-Fe₂O₃ and an interface between these phases, Proceedings of the MRS 2005 Fall Meeting, Nov. 28 – Dec. 2, 2005, Boston, MA;
5. W. Liang and M. Zhou, Shape memory effect and pseudoelasticity in Cu nanowires, Proceedings of the IUTAM Symposium on Mechanical Behavior and Micro-mechanics of Nanostructured Materials, June 25-30, 2005, Beijing, China;
6. V. Tomar and M. Zhou, A molecular dynamics simulation framework for quasi-static and dynamic strength analyses of Fe₂O₃+Al nanocomposites, Proceedings of the ASME IMECE, November 13-19, 2004, Anaheim, California;
7. V. Tomar and M. Zhou, Deterministic and stochastic analyses of failure in heterogeneous microstructures with explicit resolution of fracture processes, Proceedings of the 11^th International Conference on Fracture, Turin, Italy, March 20-25, 2005;
8. W. Liang and M. Zhou, Dynamic deformation and failure of nanowires, Proceedings of the 11^th International Conference on Fracture, Turin, Italy, March 20-25, 2005;
9. V. Tomar and M. Zhou, An Empirical Potential for Molecular Dynamics Simulations of An Al+Fe2O3 Reactive Metal Powder Mixture, Proceedings of the 2004 MRS (Materials Research Society) Spring Meeting, April 12-16, 2004, San Francisco, CA; Mat. Res. Soc. Symp. Proc. Vol. 821, 2004, MRS, P3.27.1-P3.27.7;
10. V. Tomar and M. Zhou, An empirical molecular dynamics potential for an Al+Fe2O 3 reactive metal powder mixture, Collection of Technical Papers - AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics and Materials Conference, Vol. 3, Collect. of Tech. Pap. - 45th AIAA/ASME/ASCE/AHS/ASC Struct., Struct. Dyn. and Mater. Conf.; 12th AIAA/ASME/AHS Adapt. Struct. Conf.; 6th AIAA Non-Deterministic Approaches Forum; 5th AIAA Gossamer Spa, 2004, AIAA 2004-1697, pp. 2051-2056;
11. W. Liang and M. Zhou, Deformation mechanisms of copper nanowires under tensile loading, Collection of Technical Papers - AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics and Materials Conference, Vol. 3, Collect. of Tech. Pap. - 45th AIAA/ASME/ASCE/AHS/ASC Struct., Struct. Dyn. and Mater. Conf.; 12th AIAA/ASME/AHS Adapt. Struct. Conf.; 6th AIAA Non-Deterministic Approaches Forum; 5th AIAA Gossamer Spa, 2004, AIAA 2004-1698, pp. 2057-2065;
12. V. Tomar and M. Zhou, Molecular Dynamics Simulation of Shock-Induced Thermite Reaction, Materials Science Forum, Vol. 465-466, pp. 157-162, 2004, Trans Tech Publications, Switzerland, Proceedings of the 1^st International Symposium on Explosion, Shock Wave and Hypervelocity Phenomena, (1st ESHP Symposium), March 15-17, 2004, Kumamoto University, Kumamoto, Japan;
13. M. Zhou, A Thermomechanical Continuum Theory of Atomistic Deformation, Proceedings of the International Conference on Heterogeneous Material Mechanics, Chongqing, China, June 21-27, 2004;
14. V. Tomar and M. Zhou, Deterministic and Stochastic Analyses of Microscopic Fracture Processes, Proceedings of the International Conference on Heterogeneous Material Mechanics, Chongqing, China, June 21-27, 2004;
15. V. Tomar and M. Zhou, Molecular Dynamics Simulation of Shock-Induced Detonation, in Shock Compression of Condensed Matter-2003, M. D. Furnish, Y.M. Gupta, and J. W. Forbes (eds), AIP Press, pp. 413-416, Proceedings of the 13^th American Physical Society Topical Conference on Shock Compression of Condensed Matter July 20 - 25, 2003, Portland, Oregon;
16. W. Liang and M. Zhou, Dynamic Tensile Deformation and Failure of Single CrystalQuebec, July 7-11, 2003;
17. W. Liang and M. Zhou, Dynamic tensile deformation of Cu nanowires, Proceedings of the 9th International Conference on the Mechanical Behavior of Materials (ICM-9), May 25-29, 2003, Geneva, Switzerland;
18. M. Zhou, Theoretical Interpretation of the Virial Stress, Proceedings of the 44^th AIAA/ASME/ASCE/AHS Structures Structural Dynamics, and Materials Conference, Norfolk, VA, April 7-10, 2003;
19. W. Liang and M. Zhou, Size and Strain Rate Effects in Tensile Deformation of Cu Nanowires, Proceedings of the 44^th AIAA/ASME/ASCE/AHS Structures Structural Dynamics, and Materials Conference, Norfolk, VA, April 7-10, 2003, no. AIAA 2003-1612;
20. Vikas *Tomar, Mahesh Shenoy, Wuwei Liang, David L. McDowell and Min Zhou, Continuum Fields for Dynamically Deforming Atomistic Particle Systems, U.S. National Congress on Computational Mechanics July 28-30, 2003, Albuquerque, NM;
21. W. Liang and M. Zhou, Size and strain rate effects in tensile deformation of Cu nanowires, NANOTECH2003, Technical Proceedings of the 2003 Nanotechnology Conference and Trade Show (Nanotech 2003), Feb. 23-27, San Francisco, CA, Vol. 1: pp.324-327, Vol: 2: 452-455, Computational Publications, Boston/Geneva/San Francisco;
22. K. Minnar and M. Zhou, Time-resolved characterization of impact damage in composites laminates, Proceedings of the 5^th China-Japan-US Joint Conference on Composites, 263-269, August 21-24, 2002, Kunming, China;
23. K. Minnar and M. Zhou, Analysis of Delamination in Composite Laminates under Impact Loading, Proceedings of the 17^th Annual Technical Conference of the American Composites Society (ASC), West Lafayette, Indiana, October 21-23, 2002;
24. A. R. Keller and M. Zhou, Experimental characterization of the dynamic failure of TiB2/Al2O3 composites, Shock compression of condensed matter-2001, ed. M. D. Furnish, N. N. Thadhani, and Y. Horie, American Institute of Physics, 795-798, 2001;
25. K. Minnaar and M. Zhou, Characterization of Impact Damage in Composite Laminates, Shock compression of condensed matter-2001, ed. M. D. Furnish, N. N. Thadhani, and Y. Horie, American Institute of Physics, AIP Conference Proceedings, no. 620, Part 2, 2002, 1208-1211;
26. G. Kennedy, L. Ferranti, R. Russell, M. Zhou, and N. Thadhani, Influence of microstructural bias on the hugoniol elastic limit and spall strength of two-phase TiB2+Al2O3 ceramics, Shock compression of condensed matter-2001, ed. M. D. Furnish, N. N. Thadhani, and Y. Horie, American Institute of Physics, 755-758, 2001;
27. A. Keller and M. Zhou, Microscopic and Nanoscopic Fracture in Heterogeneous in a Heterogeneous Material System, Proceedings of 2002 SEM Annual Conf. and Expo. on Exp. & Appl. Mechanics, June 10-12, 2002, Milwaukee, WI;
28. . M. Zhou, The Virial Stress is Not a Measure of Mechanical Stress, Material Research Society Symposium Proceedings, 731, 59-70, (2002), eds. A. Zavaliangos, V. Tikare, and E. A. Olevsky;
29. M. Zhou, Equivalent Continuum for Discrete Molecular Dynamic Systems, Developments in Theoretical and Applied Mechanics, Vol. XXI, ed. A. J. Kassab, D. W. Nicholson, and I. Ionescu, Rivercross Publishing, Inc., Orlando, FL, 2002, pp. 513-523;
30. A. Keller, G. Kennedy, L. Ferranti, M. Zhou, and N. Thandani, Correlation of Dynamic Behavior with Mircrostructural-bias in Two-phase TiB₂+Al₂O₃ Ceramics, Impact Engineering and Application, Proceedings of the Fourth International Symposium on Impact Engineering (ISIE/4), pp. 321- 326, July 16-18, Kumamoto, Japan, elsevier, 2001
31. M. Zhou, Numerical Simulation of Micro and Nano Scale Fracture, Proceedings of The 10^th International Congress of Fracture, December 2-7, 2001, Honolulu, Hawaii;
32. Minnaar and M. Zhou, Experimental Characterization and Numerical Simulation of Impact Damage in Composite Laminates, American Society of Mechanical Engineers, Applied Mechanics Division, AMD. v247, 2001, p 81 - 91, ASME IMECE, NY, NY< Nov.2001;
33. K. Minnar and M. Zhou, Time-resolved characterization of impact damage in composites laminates, Proceedings of the 5^th China-Japan-US Joint Conference on Composites, 263-269, August 21-24, 2002, Kunming, China;
34. K. Minnar and M. Zhou, Analysis of Delamination in Composite Laminates under Impact Loading, Proceedings of the 17^th Annual Technical Conference of the American Composites Society (ASC), West Lafayette, Indiana, October 21-23, 2002;
35. K. Minnaar and M. Zhou, Real-time Detection and Explicit Finite Element Simulation of Delamination in Composite Laminates under Impact Loading, Proceedings of ICCM-13, June 25-29, 2001, Beijing, China;
36. Greg Kennedy, Andrew Keller, Rod Russell, Louis Ferranti, Jun Zhai, Min Zhou, and Naresh Thadhani; Dynamic Mechanical Properties of Microstructurally-biased Two-phase TiB2+Al2O3 Ceramics, Proc. of EXPLOMET 2000 Conference, eds. K.P. Staudhammer, L.E. Murr, and M.A. Meyers;
37. K. Minnaar and M. Zhou, Real-time Detection and Explicit Finite Element Simulation of Delamination in Composite Laminates under Impact Loading, AMD-Vol. 243, pp. 67-78, ASME IMECE, Orlando FL, Nov. 2000;
38. K. Minnaar, J. Zhai, S. W. Park, and M. Zhou, Damage Growth in FRP laminates under Low Velocity Impact, Proceedings of the 9^th U.S.-Japan Conference on Composite Materials, pp. 461-468, H. Fukuda, T. Ishikawa, and Y. Kogo eds., 2000;
39. S. W. Park, D. R. Veazie, and M. Zhou, Post-impact aging of FRP composite laminates in the marine environment, Proc., EM2000, 14th Engineering Mechanics Conference (CD-ROM), Austin, TX, May 21-24, 2000;
40. S. W. Park and M. Zhou, Nondestructive assessment of the post-impact properties of FRP composite laminates, Structural Materials Technology IV- An NDT Conference, Atlantic City, NJ, February 29- March 3, 2000, pp. 219-224.
41. M. Zhou and J. Zhai, Micromechanical Characterization of the Fracture Resistance of A TiB₂/Al₂O₃ Ceramic Composite System, American Ceramic Society 102nd Annual Meeting & Exposition, St. Louis, Missouri, April 30 - May 3, 2000;
42. G. Kennedy, J. Zhai, R. Russell, M. Zhou, and N. Thadhani, High-Strain-Rate Behavior of Microstructurally-biased Two-Phase TiB₂+Al₂O₃ Ceramics, Proceedings of the 24th Annual Cocoa Beach Conference of The American Ceramic Society, January 23-28, Ceramic Engineering Science Proceedings, 213, pp. 705-712, 2000
43. D. R. Veazie, S.W. Park, and M. Zhou, “Effects of Salt Water Aging on the Post-Impact Behavior of Polymeric Composites”, Proc. 12^th International Conference on Composite Materials (ICCM12), T. Massard and A. Vautrin, Eds., Paris, France, July 5-9, 1999;
44. G.Kennedy.A. Keller, R. Russell, L. Ferranti, J. Zhai, M. Zhou, and N. Thadhani: Proc.2000 Int. conf. on Fundamental Issues and Applications of Shock Wave and High-Straian-Rate Phenomena, Elsevier, New York, NY, 2001, pp. 63-70'
45. S. W. Park, C. Cao, M. Zhou and R. Talreja, “Post-impact Fatigue Behavior of an IM7/PETI-5 Cross-ply Laminate”, FATIGUE’99, Proceedings of the Seventh International Fatigue Congress, June 8-12, Beijing, China, X. R. Wu and Z. G. Wang, Eds., EMAS, West Midlands, UK, Vol. 3, 1999, pp. 1711-1718;
46. J. Zhai and M. Zhou, “Numerical Modeling of Damage and Fracture Evolution in Ceramic Composites”, The Relationship between properties, Processing, and Microstructure of Advanced Composites, Guo and X. Yao, eds., pp. 137-146, 1999;
47. D. L. Grote, S. W. Park, and M. Zhou, An Experimental Characterization of the Dynamic Impact Failure of Mortar, Shock Compression of Condensed Matter-1999, M. D. Furnish, L. C. Chhabildas, and R. S. Hixon, eds., pp. 1271-1274;
48. M. Zhou and J. Zhai, Modeling of Micromechanical Fracture using a Cohesive Finite Element Method, CP505, Shock Compression of Condensed Matter-1999, M. D. Furnish, L. C. Chhabildas, and R. S. Hixon, eds., pp. 623-628, 1999;
49. J. Zhai and M. Zhou, Micromechanical Modeling of Fracture in Heterogeneous Solids, Proceedings of the Sixth Pan American Congress of Applied Mechanics, pp. 1011-1014, Rio de Janeiro, Brazil, January 4 - 8, 1999;
50. J. Zhai and M. Zhou, Numerical Modeling of Fracture in Multiphase Ceramic Materials, Proceedings of the 15th U.S. Army Solid Mechanics Symposium, April 12-14, 1999, Myrtle Beach, SC;
51. J. Zhai and M. Zhou, “Numerical Simulation of Dynamic Crack Growth in Ceramic Composites”, Proceedings of the 12^th ASCE Engineering Mechanics Conference, pp. 1255-1258, 1998;
52. Q. Xia, L. Grote and M. Zhou, “Dynamic Deformation and Failure Behavior of Concrete at High Strain Rates”, Proceedings of the 12^th ASCE Engineering Mechanics Conference, pp. 1307-1310, 1998;
53. S. W. Park, D. R. Veazie and M. Zhou, “Characterization of Impact Damage and Residual Strength of Structural Composites”, Proceedings of the 12^th ASCE Engineering Mechanics Conference, pp. 1311-1314, 1998;
54. S. W. Park and M. Zhou, “Ultrasonic Characterization of Impact-Induced Damage in Fiber-reinforced Laminated Composites”, Fifth International Conference on Composites Engineering (ICCE/5), pp. 711-712, July 5-11, 1998, Las Vegas, NV;
55. S. W. Park and M. Zhou, “An Improved Analysis Technique for Impact Experiments on Composites using the Split Hopkinson Pressure Bar”, Fifth International Conference on Composites Engineering (ICCE/5), pp. 1021-1022, July 5-11, 1998, Las Vegas, NV;
56. M. Zhou, “Numerical Analyses of the Influence of Microstructural Changes on Shear Localization in Tungsten Composites”, Proceedings of the 14^th Army Symposium on Solid Mechanics, pp. 409-423, Myrtle Beach, SC, 1996;
57. A. J. Rosakis, G. Ravichandran and M. Zhou, “Real-Time Experimental Observations of Two-dimensional Dynamic Shear Band Growth”, AMD-Vol. 200/MD-Vol. 57, pp. 95-100, Plastic and Fracture Instabilities in Materials, 1995;
58. High temperature and deformation field measurements at the vicinity of dynamically growing shear bands, Rosakis, A.J., Ravichandran, G., and Zhou, M., American Society of Mechanical Engineers, Applied Mechanics Division, AMD, 200, p. 93, Plastic and Fracture Instabilities in Materials, 1995;
59. M. Zhou, A. J. Rosakis and G. Ravichandran, “Adiabatic Shear Band Formation in Asymmetrically Impacted Prenotched Plates - An Investigation of Temperature Signatures”, Materials Instabilities: Theory and Application, AMD-Vol. 183/MD-Vol. 50, pp. 35-49, Nov., 1994;
60. M. Zhou, A. J. Rosakis, and G. Ravichandran, Dynamically propagating shear bands in prenotched plates, GALCIT Report SM94-1, 1994, Caltech, Pasadena, California
61. A. J. Rosakis, G. Ravichandran and M. Zhou, "Dynamically Growing Shear Bands in Metals: High Speed Optical and Infrared Measurements of Temperature and Deformation Fields," Proceedings of IUTAM Symposium on Nonlinear Fracture Mechanics, J. R. Willis (Ed.), Cambridge, U. K. (1995);
62. M. Zhou, R. J. Clifton and A. Needleman, “Shear Bands in Pressure-shear Plate Impact”, Proc. 13th Army Symposium on Solid Mechanics, pp. 117-135, Aug. 1993, Plymouth, MA;
63. M. Zhou, R. J. Clifton and A. Needleman, “The Role of Materials Inhomogeneities in The Localization of Strains”, Joint AIRAPT/APS Conference, pp. 1185-1188, June 28-July 2 1993, Colorado Springs, CO;
64. M. Zhou and R. J. Clifton, "Dynamic Ductile Rupture in a Spheroidized 1045 Steel", Proc. 12th Army Symposium on Solid Mechanics, pp. 451-472, Nov. 1991, Plymouth, MA;