1320 beal ave john andrew shaw - university of michigan · 2019-10-08 · john andrew shaw...
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John Andrew ShawCurriculum Vitae
1320 Beal AveUniv. of Michigan
Aerospace EngineeringAnn Arbor, MI 48109
H (734)476-9772T (734)764-3395
Employment2011–present Professor, University of MIchigan, Aerospace Engineering.
2003–2011 Associate Professor, University of Michigan, Aerospace Engineering.1997–2003 Assistant Professor, University of Michigan, Aerospace Engineering.
2001 Visiting Research Scholar, École Polytechnique, France, CNRS.
1997 Postdoctoral Research Fellow, University of Texas at Austin.1996 Assistant Instructor, University of Texas at Austin.
1991–1996 Graduate Research Assistant, University of Texas at Austin.1985–1991 Project Engineer, U.S. Navy, Division of Naval Reactors.1984–1985 Physics Lab Technician, University of Michigan.
Education1997 Ph.D., University of Texas at Austin, Austin, TX.
Engineering Mechanics
1989 M.S., Virginia Poly. Inst. & State Univ., Blacksburg, VA.Computer Science
1985 B.S.E., University of Michigan, Ann Arbor, MI, (Summa Cum Laude).Aerospace Engineering
DissertationTitle Material Instabilities in a Nickel-Titanium Shape Memory Alloy
Chair Professor Stelios Kyriakides
Research Interests{Analytical & experimental mechanics of solids & structures{ Instabilities in materials & structures{ Thermo-mechanics of shape memory alloys & polymers, & adaptive structures{ Chemo-thermo-rheology of polymeric materials & structures{ Biomechanics of human heart & cardiovascular system
PatentsIssued
[1] A. Browne, N. Johnson, P. Alexander, J. Shaw, C. Churchill, A. Keefe, G. Knight, G. Herrera,N. Mankame, R. Skurkis, and W. Brown, “Energy harvesting system,” U.S. Patent 2015/9 003 789,April 14, 2015.
[2] A. L. Browne, N. L. Johnson, J. A. Shaw, C. B. Churchill, A. C. Keefe, G. P. McKnight, P. W.Alexander, G. A. Herrera, J. R. Yates, and J. W. Brown, “Shape memory alloy heat engines andenergy harvesting systems,” U.S. Patent 8,844,281, September 30, 2014.
[3] A. Browne, N. Johnson, N. Mankame, P. Alexander, J. Shaw, C. Churchill, A. Keefe, G. Herrera,J. Brown, and R. Skurkis, “Method of starting and operating a shape memory alloy heat engine,”U.S. Patent 8,800,283 B2, August 12, 2014.
[4] J. Shaw and D. Grummon, “Manufacture of shape-memory alloy cellular materials and structuresby transient-liquid reactive joining.” U.S. Patent 8,465,847 B2, June 18, 2013.
[5] J. E. Luntz, J. A. Shaw, D. Brei, C. B. Churchill, A. Pathak, N. D. Mankame, A. Browne, N. L.Johnson, P. W. Alexander, X. Gao, and P. D. Zavattieri, “Apparatus for and method of conditioningshape memory alloy wire,” U.S. Patent 8,388,773, March 5, 2013.
[6] N. Mankame, J. Shaw, B. Reedlunn, A. Browne, X. Gao, P. Alexander, J. Aase, N. Johnson,K. Strom, S. Naik, C. Namuduri, R. Stevenson, W. R. Rodgers, J. Ulicny, C. Henry, P. Krajewski,and R. Brammajyosula, “Shape memory alloy cables,” U.S. Patent 8,272,214, September 25,2012.
[7] J. Shaw and D. Grummon, “Manufacture of shape-memory alloy cellular materials and structuresby transient-liquid reactive joining.” U.S. Patent 8,273,194, September 25, 2012.
[8] ——, “Manufacture of shape-memory alloy cellular materials and structures by transient-liquidreactive joining.” U.S. Patent 7,896,222, March 1, 2011.
PublicationsJournal Articles
[1] Gong, L., Wang, S., Shen, L., Liu, C., Shenouda, M., Li, B., Liu, X., Shaw, J., Wineman, A., Yang,Y., Xiong, D., Eichmann, A., Evans, S., Weiss, S. J., and Si, M.-S. SLIT3 deficiency attenuatespressure overload-induced cardiac fibrosis and remodeling. The Journal of Clinical Investigation(JCI) Insight, 5(12):e136852, 2020.
[2] LePage, W. S., Daly, S., and Shaw, J. A. Effects of Texture on the Functional and StructuralFatigue of a NiTi Shape Memory Alloy. International Journal of Solids and Structures, (inreview), 2020.
[3] Reedlunn, B., LePage, W. S., Daly, S., and Shaw, J. A. Axial-Torsion Behavior of SuperelasticTubes: Part I, Proportional Isothermal Experiments. International Journal of Solids and Structures,199:1–35, August 2020.
[4] Wineman, A. S. and Shaw, J. A. Coupled thermal- and deformation-induced degradation in planarrubber membranes under radial loading. Mathematics and Mechanics of Solids, 24(10):3103–3124, 2019.
[5] Watkins, R., Reedlunn, B., Daly, S., and Shaw, J. A. Uniaxial, Pure Bending and BucklingExperiments on Superelastic NiTi Rods and Tubes. International Journal of Solids and Structures,148:1–28, 2018.
[6] LePage, W., Ahadi, A., Lenthe, W., Qing-Ping, S., Pollock, T., Shaw, J., and Daly, S. Grainsize effects on NiTi shape memory alloy fatigue crack growth. Journal of Materials Research,33(2):91–107, 2018.
[7] Watkins, R. and Shaw, J. A. Unbuckling of Superelastic Shape Memory Alloy Columns. Journalof Intelligent Material Systems and Structures, (29)(7):1360–1378, 2018.
[8] Biggs, D. B., Churchill, C. B., and Shaw, J. A. Heat Transfer of Springs in Oblique Crossflows.Journal of Heat Transfer, 140(4):041702–041702–13, 01 2018.
[9] LePage, W., Shaw, J. A., and Daly, S. Optimum Paint Sequence for Speckle Patterns in DigitalImage Correlation. Experimental Techniques, 41:557–563, June 2017.
[10] Mas, B., Biggs, D., Vieito, I., Cladera, A., Shaw, J., and Martínez-Abella, F. Superelastic shapememory alloy cables for reinforced concrete applications. Construction & Building Materials,148:307–320, 2017.
[11] LePage, W., Daly, S., and Shaw, J. A. Cross Polarization for Improved Digital Image Correlation.Experimental Mechanics, 56(6):969 – 985, 2016.
[12] Shaw, J. A., Wineman, A. S., Dasharathi, K., and Si, M.-S. A Simple Model for MyocardialChanges in a Failing Heart. International Journal of Non-Linear Mechanics, 68:132–145, January2015.
[13] Jian, Z., Han, H., Zhang, T., Puglisi, J., Izu, L. T., Shaw, J. A., Onofiok, E., Erickson, J. R.,Chen, Y.-J., Horvath, B., Shimkunas, R., Pan, T., Chan, J., Banyasz, T., Chiamvimonvat, N., Bers,D. M., Lam, K. S., and Chen-Izu, Y. Mechanochemotransduction During Cardiac Contraction IsMediated by Localized Nitric Oxide Signaling. Science Signaling, 7(317):1–9, 2014.
[14] Reedlunn, B., Churchill, C. B., Nelson, E., Daly, S., and Shaw, J. A. Tension, Compression, andBending of Superelastic Shape Memory Alloy Tubes. Journal of the Mechanics and Physics ofSolids, 63:506–537, 2014.
[15] Shaw, J. A., Izu, L. T., and Chen-Izu, Y. Mechanical Analysis of Single Myocyte Contraction in a3-D Elastic Matrix. PLOS ONE, 8(10):e75492, October 2013.
[16] Reedlunn, B., Daly, S., and Shaw, J. A. Superelastic Shape Memory Alloy Cables: Part II –Isothermal Subcomponent Responses. International Journal of Solids and Structures, 50:3027–
3044, 2013.[17] Reedlunn, B., Daly, S., and Shaw, J. A. Superelastic Shape Memory Alloy Cables: Part I –
Isothermal Tension Experiments. International Journal of Solids and Structures, 50:3009–3026,2013. (2013 IJSS best paper award).
[18] Reedlunn, B., Daly, S., Hector, L. G. J., Zavattieri, P., and Shaw, J. A. Tips and Tricks forCharacterizing Shape Memory Alloy Wire: Part 5 – Full-field Strain Measurement by DigitalImage Correlation. Experimental Techniques, 37(3):62–78, 2011.
[19] Elliott, R. S., Triantafyllidis, N., and Shaw, J. A. Reversible Stress-induced martensitic phasetransformations in a bi-atomic crystal. Journal of the Mechanics and Physics of Solids, 59:216–236, 2011.
[20] Sondergaard, C. S., Hodonsky, C. J., Khait, L., Shaw, J., Sarkar, B., Birla, R., Bove, E., Nolta,J., and Si, M.-S. Human Thymus Mesenchymal Stromal Cells Augment Force Production inSelf-Organized Cardiac Tissue. Annals of Thoracic Surgery, 90:796–804, 2010.
[21] Churchill, C. B., Shaw, J. A., and Iadicola, M. A. Tips and Tricks for Characterizing ShapeMemory Alloy Wire: Part 4 – Thermo-mechanical Coupling. Experimental Techniques, 34(2):63–80, Mar/Apr 2010.
[22] Churchill, C. B., Shaw, J. A., and Iadicola, M. A. Tips and Tricks for Characterizing ShapeMemory Alloy Wire: Part 3 – Localization and Propagation Phenomena. Experimental Techniques,33(5):70–78, Sept/Oct 2009.
[23] Michailidis, P., Triantafyllidis, N., Shaw, J., and Grummon, D. Superelasticity and Stability of aShape Memory Alloy Hexagonal Honeycomb under In-plane Compression. International Journalof Solids and Structures, 46:2724–2738, 2009.
[24] Churchill, C. B., Shaw, J. A., and Iadicola, M. A. Tips and Tricks for Characterizing ShapeMemory Alloy Wire: Part 2 – Fundamental Isothermal Responses. Experimental Techniques,33(1):51–62, Jan-Feb 2009.
[25] Shaw, J. A. and Churchill, C. B. A Reduced-order Thermomechanical Model and AnalyticalSolution for Uniaxial Shape Memory Alloy Wire Actuators. Smart Materials and Structures,18(6):065001 (21pp), 2009.
[26] Shaw, J. A., Churchill, C. B., and Iadicola, M. A. Tips and Tricks for Characterizing Shape Mem-ory Alloy Wire: Part 1 – Differential Scanning Calorimetry & Basic Phenomena. ExperimentalTechniques, pages 55–62, Sep-Oct 2008.
[27] Wineman, A. S. and Shaw, J. A. Influence of thermally induced scission and crosslinking on thepost-scission inflation of circular elastomeric membranes. International Journal of EngineeringScience, 46(8):758–774, 2008. ISSN 0020-7225.
[28] Wineman, A. and Shaw, J. Combined deformation- and temperature-induced scission in a rubbercylinder in torsion. International Journal of Non-Linear Mechanics, 42(2):330 – 335, 2007. ISSN0020-7462. Special Issue in Honour of Dr Ronald S. Rivlin.
[29] Shaw, J. A., Grummon, D. S., and Foltz, J. Superelastic NiTi Honeycombs: Fabrication andExperiments. Smart Materials and Structures, 16:S170–S178, 2007.
[30] Iadicola, M. A. and Shaw, J. A. An experimental method to measure initiation events duringunstable stress–induced martensitic transformation in a shape memory alloy wire. Smart Materialsand Structures, 16:S155–S169, 2007.
[31] Grummon, D., Shaw, J., and Foltz, J. Fabrication of Cellular Shape Memory Alloy Materials byReactive Eutectic Brazing Using Niobium. Materials Science and Engineering, A, 438-440:1113–1118, Nov. 2006.
[32] Jones, A., Shaw, J., and Wineman, A. An Experimental Facility to Measure the Chemorheological
Response of Inflated Elastomeric Membranes at High Temperature. Experimental Mechanics,46(5):579–587, 10 2006.
[33] Chang, B.-C., Shaw, J. A., and Iadicola, M. A. Thermodynamics of Shape Memory AlloyWire: Modeling, Experiments, and Application. Continuum Mechanics and Thermodynamics,18(1-2):83–118, 2006.
[34] Wineman, A. and Shaw, J. Influence of thermally induced chemorheological changes on thetorsion of elastomeric circular cylinders. Continuum Mechanics and Thermodynamics, 17(7):477–492, 05 2006.
[35] Elliott, R., Shaw, J. A., and Triantafyllidis, N. Stability of Crystalline Solids—II: Applicationto temperature-induced martensitic phase transformations in a bi-atomic crystal. Journal of theMechanics and Physics of Solids, 54:193–232, 2006.
[36] Elliott, R., Triantafyllidis, N., and Shaw, J. A. Stability of Crystalline Solids—I: Continuum andAtomic Lattice Considerations. Journal of the Mechanics and Physics of Solids, 54:161–192,2006.
[37] Wineman, A. S. and Shaw, J. A. Influence of Thermally Induced Chemorheological Changeson the Inflation of Spherical Elastomeric Membranes. Journal of Elasticity, 80(1-3):73–95, July2005.
[38] Shaw, J. A., Jones, A. S., and Wineman, A. S. Chemorheological response of elastomers atelevated temperatures: Experiments and simulations. Journal of the Mechanics and Physics ofSolids, 53(12):2758 – 2793, 2005. ISSN 0022-5096.
[39] Wineman, A. and Shaw, J. A Correspondence Principle for Scission-Induced Stress Relaxation inElastomeric Components. Journal of Applied Mechanics, 71(6):769–773, 2004.
[40] Iadicola, M. A. and Shaw, J. A. Rate and Thermal Sensitivities of Unstable TransformationBehavior in a Shape Memory Alloy. International Journal of Plasticity, 20:577–605, 2004.
[41] Grummon, D. S., Shaw, J. A., and Gremillet, A. Low-Density Open-cell Foams in the NiTiSystem. Applied Physics Letters, 82(16):2727–2729, 2003.
[42] Wineman, A. S., Jones, A. S., and Shaw, J. A. Thermo–Mechanics of Elastomers UndergoingScission and Cross–Linking at High Temperatures. Tire Science and Technology, 31(2):68–86,April–June 2003.
[43] Shaw, J. A. A Thermomechanical Model for a 1–D Shape Memory Alloy with PropagatingInstabilities. International Journal of Solids and Structures, 39(5):1275–1305, 2002.
[44] Corona, E., Iadicola, M., and Shaw, J. Buckling of Steel Bars with Lüders Bands. InternationalJournal of Solids and Structures, 39:3313–3336, 2002.
[45] Elliott, R., Shaw, J., and Triantafyllidis, N. Stability of Thermally–induced Martensitic Transfor-mation in Bi–Atomic Lattices. Journal of the Mechanics and Physics of Solids, 39:3845–3856,2002.
[46] Elliott, R. S., Shaw, J. A., and Triantafyllidis, N. Stability of pressure-dependent, thermally-induced displacive transformations in bi-atomic crystals. International Journal of Solids andStructures, 39(13-14):3845 – 3856, 2002. ISSN 0020-7683.
[47] Iadicola, M. A. and Shaw, J. A. An Experimental Setup for Measuring Unstable Thermo–Mechanical Behavior of Shape Memory Alloy Wire. Journal of Intelligent Material Systems andStructures, 13(2):157–166, 2002.
[48] Iadicola, M. A. and Shaw, J. A. The Effect of Uniaxial Cyclic Deformation on the Evolution ofPhase Transformation Fronts in Pseudoelastic NiTi Wire. Journal of Intelligent Material Systemsand Structures, 13(2):143–156, 2002.
[49] Wineman, A. S. and Shaw, J. A. Scission and Healing in a Spinning Elastomeric Cylinder at
Elevated Temperature. Journal of Applied Mechanics, 69:602–609, 2002.[50] Shaw, J. A. Simulations of Localized Thermo–Mechanical Behavior in a NiTi Shape Memory
Alloy. International Journal of Plasticity, 16(5):541–562, 2000.[51] Shaw, J. A. and Kyriakides, S. Initiation and Propagation of Localized Deformation in Elasto–
Plastic Strips under Uniaxial Tension. International Journal of Plasticity, 13(10):837–871,1998.
[52] Shaw, J. A. and Kyriakides, S. On the Nucleation and Propagation of Phase TransformationFronts in a NiTi Alloy. Acta Materialia, 45(2):683–700, 1997.
[53] Shaw, J. A. and Kyriakides, S. Thermomechanical Aspects of NiTi. Journal of the Mechanicsand Physics of Solids, 43(8):1243–1281, 1995.
Books Edited[1] Shaw, J. A. and Frecker, M., editors. Adaptive Structures and Material Systems, volume AD-67.
American Society of Mechanical Engineers, Aerospace Division, New York, NY, 2002.[2] Main, J. and Shaw, J. A., editors. Adaptive Structures and Material Systems, volume AD-64.
American Society of Mechanical Engineers, Aerospace Division, New York, NY, 2001.
Book Chapters[1] Kazemi-Lari, M. A., Dostine, A. D., Zhang, J., Wineman, A. S., and Shaw, J. A. A Biomimetic
Robotic Jellyfish Based on Shape Memory Alloy Springs. In N. W. Derek A. Paley, editor, Bioin-spired Sensing, Actuation, and Control in Underwater Soft Robotic Systems, volume (accepted).Springer, 2020.
[2] Shaw, J. A. and Elliott, R. S. Variational principles in structural mechanics. In R. Blockley andW. Shyy, editors, Encyclopedia of Aerospace Engineering, volume 3, chapter 122. John Wiley &Sons, NY, 2010.
[3] Shaw, J. A., Churchill, C. B., Lagoudas, D. C., and Kumar, P. Shape Memory Alloys. InR. Blockley and W. Shyy, editors, Encyclopedia of Aerospace Engineering, volume 4, chapter203. John Wiley & Sons, 2010.
[4] Wineman, A. S., Jones, A. S., and Shaw, J. A. Life–Cycle and Durability Predictions ofElastomeric Components. In S. Saigal, K. P. Chong, S. T. Thynell, and H. Morgan, editors,Modeling and Simulation–based Life Cycle Engineering, pages 155–169. Taylor and FrancisGroup Ltd., London, 2002.
Conference Proceedings[1] Redoutey, M., Ahquist, S., Shaw, J. A., and Filipov, E. Bending active structures with a variable
cross-section boundary. In E. O. C. Lazari, K.-U. Bletzinger, editor, Proceedings IASS AnnualSymposia. International Association for Shell & Spatial Structures, Oct. 2019.
[2] Kazemi-Lari, M. A., Dostine, A. D., Zhang, J., Wineman, A. S., and Shaw, J. A. Robotic jellyfishactuated with a shape memory alloy spring. In A. L. Raul J. Martin-Palma, Mato Knez, editor,Proceedings of SPIE, volume 10965: Bioinspiration, Biomimetics, and Bioreplication IX, pages1096504–1 to 1096504–17. SPIE, Denver, CO, March 2019.
[3] Kazemi-Lari, M. A., Shaw, J. A., Wineman, A. S., Shimkunas, R., Izu, L. T., and Chen-Izu,Y. Viscoelastic Eshelby Analysis of Cardiomyocyte Contraction in the Cell-In-Gel System. InConference on Smart Materials, Adaptive Structures and Intelligent Systems (SMASIS 2018),volume 2: Mechanics and Behavior of Active Materials; Integrated System Design and Imple-mentation; Bioinspired Smart Materials and Systems; Energy Harvesting. ASME, San Antonio,TX, September 2018.
[4] Biggs, D. B. and Shaw, J. A. Periodic and Propagating Instabilities in Superelastic NiTi Wire
Twists. In Proceeding of ICTAM, volume XXIV. ICTAM, August 2016.[5] Elliott, R., Triantafyllidis, N., and Shaw, J. A. Reversible temperature- and stress-induced
martensitic transformations in bi-atomic crystals. In Proceeding of ICTAM XXIV. ICTAM, August2016.
[6] LePage, W., Shaw, J., and Daly, S. Thermomechanical Characterization of Shape Memory AlloyMode I Fracture Behavior. In Proceedings of the Society of Experimental Mechanics. SEM, June2016.
[7] Biggs, D. B. and Shaw, J. A. Experimental characterization of shape memory alloy actuatorcables (3rd place, best student paper). In N. C. Goulbourne, editor, Proceedings of the SPIEAnnual International Symposium on Smart Structures and Materials, volume 9800: Behavior andMechanics of Multifunctional Materials and Composites, pages 98000D–1,12. ASME, March2016.
[8] Watkins, R., Reedlunn, B., and Shaw, J. A. Uniaxial, Pure Bending and Buckling Characterizationof Superelastic NiTi Rods and Tubes: An Experimental Study. In Conference on Smart Materials,Adaptive Structures and Intelligent Systems (SMASIS 2014), volume 2: Mechanics and Behaviorof Active Materials; Integrated System Design and Implementation; Bioinspired Smart Materialsand Systems; Energy Harvesting, page 10 pgs. ASME, Newport, Rhode Island, September 2014.
[9] Dasharathi, K. and Shaw, J. A. The Influence of Chemo-Rheological Degradation on the Viscoelas-tic Behavior of SMPs. In Conference on Smart Materials, Adaptive Structures and IntelligentSystems (SMASIS 2014), volume 2, Mechanics and Behavior of Active Materials; Integrated Sys-tem Design and Implementation; Bioinspired Smart Materials and Systems; Energy Harvesting.ASME, Newport, Rhode Island, September 2014.
[10] Reedlunn, B., Nelson, E., Daly, S., Shaw, J., and Churchill, C. Tension, Compression, and Bendingof Superelastic NiTi Tubes. In Proceedings of Shape Memory and Superelastic Technologies.SMST, May 2013.
[11] Dasharathi, K. and Shaw, J. Visco-Chemo-Rheological behavior in high Tg Shape MemoryPolymers. In Proceedings of Shape Memory and Superelastic Technologies, pages 268–269.SMST, ASM International, May 2013.
[12] Biggs, D., Shaw, J., and Churchill, C. Convective Heat Transfer of Wires and Springs for usein SMA Heat Engines. In Proceedings of Shape Memory and Superelastic Technologies, pages382–383. SMST, ASM International, May 2013.
[13] Watkins, R. T. and Shaw, J. A. Rate Sensitivity of Superelastic Column Buckling: An Exper-imental Study. In Proceedings of Shape Memory and Superelastic Technologies. SMST, May2013.
[14] Reedlunn, B., Daly, S., and Shaw, J. Biaxial Behavior of Superelastic NiTi Tubes. In Proceedingsof Shape Memory and Superelastic Technologies. SMST, May 2013.
[15] Dasharathi, K. and Shaw, J. A. Aging Effects in Epoxy Shape Memory Polymers. In Proceedingsof the SPIE Annual International Symposium on Smart Structures and Materials, volume 8689:Behavior and Mechanics of Multifunctional Materials and Composites. March 2013.
[16] Watkins, R. T., Shaw, J. A., and Grummon, D. S. Shape memory thermal lag and superelasticrate sensitivity of SMA cellular structures. In Proceedings of the SPIE Annual InternationalSymposium on Smart Structures and Materials, volume 8689: Behavior and Mechanics ofMultifunctional Materials and Composites. March 2013.
[17] Reedlunn, B., Daly, S., and Shaw, J. A. Tension-Torsion Experiments on Superelastic ShapeMemory Alloy Tubes. In Proceedings of the ASME Conference on Smart Materials, AdaptiveStructures and Intelligent Systems (SMASIS 2012), volume 2: Mechanics and Behavior of Active
Materials; Integrated System Design and Implementation; Bio-Inspired Materials and Systems;Energy Harvesting, pages 213–222. ASME, September 2012.
[18] Churchill, C. B. and Shaw, J. A. Thermo-mechanical modeling of a shape memory alloy heatengine. In Proceedings of the ASME 2011 Conference on Smart Materials, Adaptive Structuresand Intelligent Systems (SMASIS 2011), volume 1, pages 641–650. Sep. 2011.
[19] Reedlunn, B., Churchill, C. B., Nelson, E., Daly, S., and Shaw, J. A. Bending of SuperelasticShape Memory Alloy Tubes. In Proceedings of the ASME Conference on Smart Materials,Adaptive Structures and Intelligent Systems (SMASIS 2011), volume 1, pages 249–258. ASME,September 2011.
[20] Watkins, R., Shaw, J. A., Triantafyllidis, N., and Grummon, D. S. Design Study of Shape MemoryAlloy Honeycombs for Energy Absorption. In Proceedings of the ASME 2011 Conference onSmart Materials, Adaptive Structures and Intelligent Systems (SMASIS11). Sep. 2011.
[21] Shaw, J. A. Cyclic Shakedown Effects in Nitinol Structures. In D. Grummon, editor, Proceedingsof the International Conference on Shape Memory and Superelastic Technologies (SMST10).2010.
[22] Low, K.-B., Grummon, D. S., and Shaw, J. A. Exploring Methodologies for Improving theMechanical and Microstructural Properties of Nitinol Braze Joints. In Proceedings of the Interna-tional Conference on Shape Memory and Superelastic Technologies (SMST10). 2010.
[23] Reedlunn, B., Shaw, J., and Daly, S. Pseudoelastic Shape Memory Alloy Cables. In D. S. Grum-mon, M. R. Mitchell, and M. Mertmann, editors, Proceedings of the International Conference onShape Memory and Superelastic Technologies (SMST 2010). ASM, Springer, May 2010.
[24] Luntz, J., Brei, D., Mane, P., Redmond, J., Barnes, B., Shaw, J., Johnson, N. L., Browne, A. L.,Alexander, P. W., and Mankame, N. Automotive Research Advances in Smart Materials andDevices at the GM/UM SMS Collaborative Research Laboratory. In Proceedings of the 20thInternational Conference on Adaptive Structures and Technologies (ICAST). Hong Kong, Oct.2009.
[25] Churchill, C. B. and Shaw, J. A. Thermo-Electro-Mechanical Shakedown Response of Condi-tioned Shape Memory Alloy Wires. In Proceedings of the ASME 2009 Conference on SmartMaterials, Adaptive Structures and Intelligent Systems (SMASIS 2009), volume 1, pages 137–148.ASME, Sep. 2009.
[26] Reedlunn, B., Shaw, J. A., and Daly, S. Shape Memory Alloy Cables: Exploratory Experiments.In Proceedings of the ASME Conference on Smart Materials, Adaptive Structures and IntelligentSystems (SMASIS 2009), volume 1 : Active Materials, Mechanics and Behavior; Modeling,Simulation and Control, pages 149–160. ASME, September 2009.
[27] Shaw, J. A., Michailidis, P., Triantafyllidis, N., and Grummon, D. Superelasticity, Shape Memoryand Stability of Nitinol Honeycombs under In-plane Compression. In Y. Brechet, J. D. Embury,and P. R. Onck, editors, Materials Research Society Symposium Proceedings: ArchitecturedMultifunctional Materials, volume 1188. Materials Research Society, Pittsburgh, PA, April 2009.
[28] Grummon, D. S., Shaw, J. A., and Low, K.-B. Reactive Eutectic Brazing of Nitinol using Niobium.In Proceedings of ICOMAT08. Sante Fe, NM, United States, June 2008.
[29] Churchill, C. B. and Shaw, J. A. Shakedown Response of Conditioned Shape Memory AlloyWire. In Behavior and Mechanics of Multifunctional and Composite Materials, Proceedings ofthe SPIE 15th Annual International Symposium on Smart Structures and Materials, volume 6929,page 6929F. 2008.
[30] Reedlunn, B. and Shaw, J. A. Shape Memory Alloy Cables. In M. J. Dapino and Z. Ounaies,editors, Proceedings of the SPIE 15th Annual International Symposium in Smart Structures and
Materials, volume 6929: Behavior and Mechanics of Multifunctional Materials and Composites,page 69291G. SPIE, April 2008.
[31] Pathak, A., AuBuchon, J., Brei, D., Shaw, J., Luntz, J., and Jin, S. Carbon nanotube (CNT) finsfor enhanced cooling of shape memory alloy wire. In M. J. Dapino and Z. Ounaies, editors, In:Proceedings of SPIE, Behavior and Mechanics of Multifunctional and Composite Materials 2008,volume 6929, page 69291K. SPIE, 2008.
[32] Brei, D., Luntz, J., Shaw, J., Strom, K., Johnson, N., Alexander, P., Mankhame, N., and Browne, A.General Motors / University of Michigan Smart Materials and Structures Collaborative ResearchLaboratory: The First Year. In Proceedings of the SPIE 15th Annual International Symposium onSmart Structures and Materials. March 2008.
[33] Grummon, D. S., Low, K.-B., Foltz, J., and Shaw, J. A. A new method for brazing Nitinol basedon the quasibinary TiNi-Nb system. In Proceedings of the AIAA/ASME/ASCE/AHS/ASC Structures,Structural Dynamics and Materials Conference, volume 1, pages 447 – 453. Waikiki, HI, UnitedStates, 2007. ISSN 0273-4508.
[34] Shaw, J. A., Churchill, C., Triantafyllidis, N., Michailidis, P., Grummon, D., and Foltz,J. Shape memory alloy honeycombs: Experiments and simulation. In Proceedings of theAIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics and Materials Conference, vol-ume 1, pages 428 – 436. Waikiki, HI, United States, 2007. ISSN 0273-4508.
[35] Brei, D., Luntz, J., Shaw, J., Johnson, N. L., Browne, A. L., Alexander, P. W., and Mankame,N. D. General Motors and the University of Michigan smart materials and structures collabo-rative research laboratory. In L. P. Davis, B. K. Henderson, and M. B. McMickell, editors, In:Proceedings of SPIE, Industrial and Commercial Applications of Smart Structures Technologies2008, volume 6527, page 65270U. SPIE, 2007.
[36] Grummon, D. S., Shaw, J. A., and Foltz, J. Fabrication of cellular shape memory alloy materialsby transient-liquid reactive brazing using niobium. In Proceeding of The International Conferenceon Martensitic Transformations (ICOMAT ’05). China, Shanghai, June 2005.
[37] Elliott, R. S., Shaw, J. A., and Triantafyllidis, N. Stability of dispersive bi-atomic crystals.In D. C. Lagoudas, editor, In: Proceedings of SPIE, Smart Structures and Materials 2004:Active Materials: Behavior and Mechanics, volume 5387: Smart Structures and Materials, pages239–248. SPIE, 2004.
[38] Shaw, J., Chang, B.-C., Iadicola, M., and Leroy, Y. Thermodynamics of a 1-D Shape MemoryAlloy: Modeling, Experiments, and Application. In Proceedings of the SPIE 10th AnnualInternational Symposium on Smart Structures and Materials, volume 5049: Smart Structures andMaterials. 2003.
[39] Shaw, J. A., Gremillet, A., and Grummon, D. S. The Manufacture of NiTi Foams. In Proceedingsof the Adaptive Structures and Material Systems Symposium, ASME International MechanicalEngineering Congress and Exposition, volume Adaptive Structures and Materials Systems, pages3–12. November 2002.
[40] Iadicola, M. A. and Shaw, J. A. The Effect of Uniaxial Cyclic Deformation on the Evolutionof Phase Transformation Fronts in Pseudoelastic NiTi Wire. In Proceedings of the AdaptiveStructures and Material Systems Symposium, ASME International Mechanical EngineeringCongress and Exposition. Nov. 2001.
[41] Iadicola, M. A. and Shaw, J. A. An experimental setup for Measuring Unstable Thermo–Mechanical Behavior of a Shape Memory Alloy Wire. In Proceedings of the Adaptive Structuresand Material Systems Symposium, ASME International Mechanical Engineering Congress andExposition, volume 60, pages 19–23. Nov. 2000.
[42] Elliott, R., Triantafyllidis, N., and Shaw, J. A. Reversible temperature- and stress-inducedmartensitic transformations in bi-atomic crystals. International Congress of Theoretical andApplied Mechanics. Montreal, Canada. August 2016.
Conference Proceedings (un-refereed)[1] Shaw, J. A. Shape Memory Alloy Cables. In NSF CMMI Innovation and Research Conference.
June 2009.[2] Elliott, R., Shaw, J., and Triantafyllidis, N. Stability of thermally-induced martensitic transforma-
tions in Bi-atomic lattices. In ICOMAT03: Journal De Physique. IV : JP, volume 112 II, pages1203 –. Espoo, Finland, 2003. ISSN 1155-4339. Biatomic lattices;Thermally induced martensitictransformations;Continuum energy density function;.
[3] Shaw, J. and Kyriakides, S. Numerical Simulation of Stress-Induced Instability and Propagationin Uniaxial Strips. In Proceedings of the American Society of Civil Engineers 12th EngineeringMechanics Conference. 1998.
[4] Shaw, J. and Kyriakides, S. Initiation and Propagation of Localized Deformation in the Pseudoe-lastic Response of NiTi. In Proceedings of SPIE Symposium in Smart Structures and Materials,volume 3324: Smart Structures and Materials. 1998.
[5] Shaw, J. and Kyriakides, S. Evolution of Localized Deformation in NiTi Strips. In Proceedingsof Plasticity ‘97, Physics and Mechanics of Finite Plastic and Viscoplastic Deformation, pages173–174. 1997.
Technical PresentationsConference Presentations
[1] Kazemi-Lari, M. A., Dostine, A. D., Zhang, J., Bergeron, L., Wineman, A. S., and Shaw, J. ABiomimetic Robotic Jellyfish Based on Shape Memory Alloy Springs. International MechanicalEngineering Congress & Exposition 2019. Salt Lake City, UT. Nov. 2019.
[2] Redoutey, M., Ahquist, S., Shaw, J. A., and Filipov, E. Bending active structures with a variablecross-section boundary. IASS Annual Symposium 2019 – Force and Form. Barcelon, Spain. Oct.2019.
[3] Shaw, J. A., Kazemi-Lari, M. A., Wineman, A. S., Shimkunas, R., Izu, L. T., and Chen-Izu, Y.Viscoelastic Eshelby Analysis of Cardiomyocyte Contraction in the Cell-In-Gel System. 16thPan-American Congress of Applied Mechanics. Ann Arbor, MI. May 2019.
[4] Shaw, J. A., Reedlunn, B., and Daly, S. Extension-Twist Responses of Superelastic Shape MemoryAlloy Tubes. Invited Talk, IUTAM ’19 on Phase Transformations in Shape Memory Materials:Modeling and Applications. University of Texas at Austin, Austin, TX. May 2019.
[5] Kazemi-Lari, M. A., Dostine, A. D., Zhang, J., Wineman, A. S., and Shaw, J. Robotic jellyfishactuated with a shape memory alloy spring. SPIE Smart Structures Conference. Denver, CO.March 2019.
[6] Shaw, J. A., Kazemi-Lari, M. A., Wineman, A. S., Shimkunas, R., Izu, L. T., and Chen-Izu, Y.Viscoelastic Eshelby Analysis of Cardiomyocyte Contraction in the Cell-In-Gel System. SMASIS2018. San Antonio, TX. Sep. 2018.
[7] Shaw, J. A. Shape Memory Alloy Spring Heat Engines. Invited Talk. DFG Focus Meeting C:Elastocalorics. Saarbrüken, German. March 2018.
[8] Shaw, J. A., Wineman, A. S., Shimkunas, R., Izu, L. T., and Chen-Izu, Y. Viscoelastic EshelbyAnalysis of the Cell-In-Gel System. Biophysical Society Meeting. San Francisco. Feb. 2018.
[9] Reedlunn, B., Daly, S., and Shaw, J. Axial-Torsion Behavior of Superelastic NiTi Tubes. ShapeMemory and Superelastic Technologies Conference and Exposition. San Diego, California. May2017.
[10] Biggs, D. B. and Shaw, J. A. History dependence of temperature and load on transformationinduced plasticity in nickel titanium. Society of Engineering Science 53rd Annual TechnicalMeeting. College Park, MD. October 2016.
[11] Shaw, J. A. and Biggs, D. B. Shape Memory Cables and Springs. Invited Talk. Conferenceon Smart Materials, Adaptive Structures and Intelligent Systems (SMASIS 2016). Stowe, VT.September 2016.
[12] Biggs, D. B. and Shaw, J. A. Periodic and Propagating Instabilities in Superelastic NiTi WireTwists. International Congress of Theoretical and Applied Mechanics. Montreal, Canada. August2016.
[13] LePage, W., Ahadi, A., Sun, Q., Shaw, J., and Daly, S. Grain Size Effects on Fatigue CrackGrowth in Nanocrystalline NiTi. Society of Experimental Mechanics Annual Meeting. Orlando,FL. June 2016.
[14] LePage, W., Shaw, J., and Daly, S. Cross Polarization for Improved Digital Image Correlation.Society of Experimental Mechanics Annual Meeting. Orlando, FL. June 2016.
[15] Biggs, D. B. and Shaw, J. A. Experimental characterization of shape memory alloy actuatorcables (3rd place, best student paper). SPIE Annual International Symposium on Smart Structuresand Materials. Las Vegas, NV. March 2016.
[16] LePage, W., Shaw, J., and Daly, S. Thermomechanical Characterization of Shape Memory AlloyMode I Fracture. TMS annual meeting & exhibition. Nashville, TN. February 2016.
[17] LePage, W., Shaw, J., and Daly, S. Cross Polarization for Improved Digital Image Correlation(poster). TMS annual meeting & exhibition. Nashville, TN. February 2016.
[18] Shaw, J. A., Biggs, D., Reedlunn, B., and Daly, S. Thermomechanical Behavior of Shape MemoryAlloys Cables (poster). Multifunctional Materials and Structures, Gordon Research Conference.Ventura, CA. January 2016.
[19] Biggs, D. and Shaw, J. A. Shape Memory Alloys Cables. SMASIS 2015. Colorado Springs, CO.September 2015.
[20] Shaw, J. A., Watkins, R., and Reedlunn, B. Buckling of Superelastic NiTi Rods and Tubes.McMat 2015. Seattle, WA. June 2015.
[21] LePage, W., Shaw, J., and Daly, S. Fracture behavior of NiTi shape-memory alloy. Society ofExperimental Mechanics (SEM) Conference. Costa Mesa, CA. June 2015.
[22] Dasharathi, K. and Shaw, J. A. Influence of experimental variables on the thermo-mechanicalbehavior of epoxy shape memory polymers. SPIE Annual International Symposium on SmartStructures and Materials. San Diego, CA. April 2015.
[23] Watkins, R., Reedlunn, B., and Shaw, J. A. Uniaxial, Pure Bending and Buckling Characterizationof Superelastic NiTi Rods and Tubes: An Experimental Study. Conference on Smart Materials,Adaptive Structures and Intelligent Systems (SMASIS 2014). Newport, Rhode Island. September2014.
[24] Dasharathi, K. and Shaw, J. A. The Influence of Thermo-Oxidative Degradation on the Behaviorof Epoxy Shape Memory Polymers. Conference on Smart Materials, Adaptive Structures andIntelligent Systems (SMASIS 2014). Newport, Rhode Island. September 2014.
[25] Shaw, J. A., Wineman, A. S., Dasharathi, K., and Si, M.-S. A Simple Model for MyocardialChanges in a Failing Heart. U.S. National Congress of Theoretical and Applied Mechanics. EastLansing, MI. June 2014.
[26] Reedlunn, B., Daly, S., and Shaw, J. A. Loading-Rate Sensitivity in Shape Memory Alloy Cables.U.S. National Congress of Theoretical and Applied Mechanics. East Lansing, MI. June 2014.
[27] Dasharathi, K., Shaw, J. A., and Wineman, A. S. The Influence of Chemo-Rheological Degrada-tion on the Viscoelastic Behavior of SMPs. U.S. National Congress of Theoretical and AppliedMechanics. East Lansing, MI. June 2014.
[28] Watkins, R. and Shaw, J. A. Buckling and Unbuckling of Shape Memory Alloy Columns. U.S.National Congress of Theoretical and Applied Mechanics. East Lansing, MI. June 2014.
[29] Shaw, J. A. An Experimentalist’s Journey with Shape Memory Alloys. Keynote Talk, Societyof Experimental Mechanics (SEM) Meeting. Greenville, SC. June 2014.
[30] Shaw, J. A., Izu, L. T., and Chen-Izu, Y. Mechanical Analysis of Single Myocyte Contraction in a3-D Elastic Matrix. Biophysical Society Meeting. San Francisco. Feb. 2014.
[31] Shaw, J., Reedlunn, B., and Daly, S. Extension-Twist Response of Superelastic Shape MemoryAlloy Tubes. 24th International Conference on Adaptive Structures and Technologies (ICAST).Aruba. October 2013.
[32] Watkins, R. T. and Shaw, J. A. Shape Memory Alloy Column Buckling: An Experimental Study.24th International Conference on Adaptive Structures and Technologies (ICAST). Aruba. October2013.
[33] Shaw, J., Reedlunn, B., and Daly, S. Instabilities during Tension-Torsion of Superelastic NiTiTubes. Society of Engineering Science 50th Annual Technical Meeting & ASME-AMD AnnualSummer Meeting. Providence, RI. July 2013.
[34] Reedlunn, B., Nelson, E., Daly, S., Shaw, J., and Churchill, C. Tension, Compression, andBending of Superelastic NiTi Tubes. Shape Memory and Superelastic Technologies Conference
and Exposition. Prague, Czech Republic. May 2013.[35] Dasharathi, K. and Shaw, J. Visco-Chemo-Rheological behavior in high Tg Shape Memory
Polymers. Shape Memory and Superelastic Technologies Conference and Exposition. Prague,Czech Republic. May 2013.
[36] Biggs, D., Shaw, J., and Churchill, C. Convective Heat Transfer of Wires and Springs for use inSMA Heat Engines. Shape Memory and Superelastic Technologies Conference and Exposition.Prague, Czech Republic. May 2013.
[37] Watkins, R. T. and Shaw, J. A. Rate Sensitivity of Superelastic Column Buckling: An Experimen-tal Study. Shape Memory and Superelastic Technologies Conference and Exposition. Prague,Czech Republic. May 2013.
[38] Reedlunn, B., Daly, S., and Shaw, J. Biaxial Behavior of Superelastic NiTi Tubes. Shape Memoryand Superelastic Technologies Conference and Exposition. Prague, Czech Republic. May 2013.
[39] Dasharathi, K. and Shaw, J. A. Aging Effects in Epoxy Shape Memory Polymers. SPIE AnnualInternational Symposium on Smart Structures and Materials. San Diego, CA. March 2013.
[40] Watkins, R. T., Shaw, J. A., and Grummon, D. S. Shape memory thermal lag and superelasticrate sensitivity of SMA cellular structures. SPIE Annual International Symposium on SmartStructures and Materials. San Diego, CA. March 2013.
[41] Reedlunn, B., Daly, S., and Shaw, J. A. Tension-Torsion Experiments on Superelastic ShapeMemory Alloy Tubes. ASME Conference on Smart Materials, Adaptive Structures and IntelligentSystems (SMASIS12). Stone Mountain, GA. September 2012.
[42] Browne, A. L., Johnson, N. L., Alexander, P. W., Mankame, N., Aase, J., Sarosi, P., Keefe, A. C.,McKnight, G. P., Herrera, G., Churchill, C., Shaw, J., and Brown, J. Lightweight thermal energyrecovery system based on shape memory alloys: a DOE ARPA-E initiative. ASME Conferenceon Smart Materials, Adaptive Structures and Intelligent Systems (SMASIS12). Stone Mountain,GA. September 2012.
[43] Churchill, C. B. and Shaw, J. A. Thermo-mechanical modeling of a shape memory alloy heatengine. ASME Conference on Smart Materials, Adaptive Structures and Intelligent Systems(SMASIS11). Scottsdale, AZ. Sep. 2011.
[44] Reedlunn, B., Churchill, C. B., Nelson, E., Daly, S., and Shaw, J. A. Bending of SuperelasticShape Memory Alloy Tubes. ASME Applied Mechanics and Materials Conference (McMat2011). Chicago, IL. May 2011.
[45] Reedlunn, B., Churchill, C. B., Nelson, E., Daly, S., and Shaw, J. A. Tension, Compression, andBending of Superelastic Shape Memory Alloy Tubes. ASME Conference on Smart Materials,Adaptive Structures and Intelligent Systems (SMASIS 2011). Scottsdale, AZ. September 2011.
[46] Dasharathi, K. and Shaw, J. A. High Temperature Behavior of an Epoxy-Based Shape MemoryPolymer. ASME Conference on Smart Materials, Adaptive Structures and Intelligent Systems(SMASIS11). Scottsdale, AZ. Sep. 2011.
[47] Watkins, R., Shaw, J. A., Triantafyllidis, N., and Grummon, D. S. Design Study of Shape MemoryAlloy Honeycombs for Energy Absorption. ASME Conference on Smart Materials, AdaptiveStructures and Intelligent Systems (SMASIS11). Scottsdale, AZ. Sep. 2011.
[48] Shaw, J. A. and Churchill, C. B. Thermo-mechanical Modeling of a Shape Memory Alloy HeatEngine. Invited Talk, 5th ECCOMAS Thematic Conference on Smart Structures and Materials(SMART11). Saarbrueken, Germany. July 2011.
[49] Shaw, J. A. Shape Memory Alloy Cables. Invited Talk, Kyriakides-Liechti Symposium:Advances in Solid and Structural Mechanics. University of Texas at Austin, Austin, TX. May2011.
[50] Shaw, J. A. Characterization of New Forms of Nitinol Structures. Invited Talk, TMS (Minerals,Metals, & Materials Society) Spring Meeting. San Diego, CA. Feb. 2011.
[51] Shaw, J. A., Reedlunn, B., and Daly, S. Thermomechanical Behavior of Shape Memory AlloyCables. ASME International Mechanical Engineering Conference & Exibition (IMECE 2010).Vancouver, British Columbia, Canada. November 2010.
[52] Shaw, J. A., Reedlunn, B., and Daly, S. Superelastic Shape Memory Alloy Cables. Invited Talk,ASME Conference on Smart Materials, Adaptive Structures and Intelligent Systems (SMASIS2010). Philadelphia, PA. September 2010.
[53] Reedlunn, B., Shaw, J., and Daly, S. Pseudoelastic Shape Memory Alloy Cables: Loading-rateEffects. Society of Experimental Mechanics (SEM) Meeting. Indiannapolis, IN. June 2010.
[54] Shaw, J. A. Cyclic Shakedown Effects in Nitinol Structures. Keynote Talk, Shape Memory &Superelastic Technologies (SMST) Meeting. Pacific Grove, CA. May 2010.
[55] Reedlunn, B., Shaw, J., and Daly, S. Pseudoelastic Shape Memory Alloy Cables. InternationalConference on Shape Memory and Superelastic Technologies (SMST 2010). Pacific Grove, CA.May 2010.
[56] Shaw, J. A., Triantafyllidis, N., and Grummon, D. Cellular Shape Memory Alloy: Experiments &Modeling. Annual Grantees’/Contractors’ Meeting, Mechanics of Multifunctional Materials &Microsystems. Reston, VA. May 10-13 2010.
[57] Shaw, J. A. An Introduction to Shape Memory Alloys. Invited Talk Workshop on Shape-ShiftingMaterials. In-Q-Tel, U.S. intelligence community, Arlington, VA. Feb. 18 2010.
[58] Si, M.-S., Hodonsky, C., Khait, L., Shaw, J., Ohye, R., Birla, R., and Bove, E. ThymusMesenchymal Stromal Cells Augment Force Production in Bioengineered Heart Muscle. Societyof Thoracic Surgeons Annual Meeting. Fort Lauderdale, Florida. Jan 2010.
[59] Churchill, C. B. and Shaw, J. A. Thermo-Electro-Mechanical Shakedown Response of Condi-tioned Shape Memeory Alloy Wires. ASME 2009 Conference on Smart Materials, AdaptiveStructures and Intelligent Systems (SMASIS09). Oxnard, CA. Sep 2009.
[60] Reedlunn, B., Shaw, J. A., and Daly, S. Shape Memory Alloy Cables: Exploratory Experi-ments. ASME 2009 Conference on Smart Materials, Adaptive Structures and Intelligent Systems(SMASIS 2009). Oxnard, CA. September 2009.
[61] Shaw, J. A., Michailidis, P., Triantafyllidis, N., and Grummon, D. Superelasticity, Shape Memoryand Stability of Nitinol Honeycombs under In-plane Compression. Invited Talk, MaterialsResearch Society Spring Meeting. San Francisco, CA. April 2009.
[62] Michailidis, P., Shaw, J. A., Triantafyllidis, N., and Grummon, D. Stability of Shape MemoryAlloy Honeycomb under Finite-Strain Isothermal Compression Cycles of Various Amplitudes.Society of Engineering Science 45th Annual Meeting. Univ. Illinois at Urbana-Champaign. Oct.2008.
[63] Wineman, A. S., Shaw, J. A., and Leach, M. Influence of Large Deformations on the Scissionof Elastomeric Materials. Society of Engineering Science 45th Annual Meeting. University ofIllinois at Urbana-Champaign. Oct. 2008.
[64] Grummon, D. S., Shaw, J. A., and Low, K.-B. Reactive Eutectic Brazing of Nitinol using Niobium.ICOMAT08. Sante Fe, NM. June 2008.
[65] Wineman, A. S. and Shaw, J. A. Network Evolution in Elastomers at Large Deformations andElevated Temperatures: Experiments and Simulations. Invited Talk, 173rd American ChemicalSociety Rubber Division Technical Meeting. Dearborn, MI. April 2008.
[66] Wineman, A. S. and Shaw, J. A. Dynamic Inflation of Elastomeric Spheres Undergoing Chemorhe-ological Changes in Microstructure. Invited Talk, 6th International Conference on Mechanics
of Time Dependent Materials. Monterrey, CA. April 2008.[67] Churchill, C. B. and Shaw, J. A. Shakedown Response of Conditioned Shape Memory Alloy
Wire. SPIE 15th Annual International Symposium on Smart Structures and Materials. San Diego,CA. March 2008.
[68] Reedlunn, B. and Shaw, J. A. Shape memory alloy cables. SPIE 15th Annual InternationalSymposium on Smart Structures and Materials. San Diego, CA. March 2008.
[69] Pathak, A., AuBuchon, J., Brei, D., Shaw, J., Luntz, J., and Jin, S. Carbon Nanotube (CNT)fins for the enhanced cooling of shape memory alloy wire. SPIE 15th Annual InternationalSymposium on Smart Structures and Materials. San Diego, CA. March 2008.
[70] Brei, D., Luntz, J., Shaw, J., Strom, K., Johnson, N., Alexander, P., Mankhame, N., and Browne, A.General Motors / University of Michigan Smart Materials and Structures Collaborative ResearchLaboratory: The First Year. SPIE 15th Annual International Symposium on Smart Structures andMaterials. San Diego, CA. March 2008.
[71] Churchill, C. B. and Shaw, J. A. Rate effects, Localization, and Phase Transformation duringTensile Loading of NiTi Tubes:. ASME Applied Mechanics and Materials Conference (McMat07). The University of Texas at Austin, Austin, TX. June 2007.
[72] Michailidis, P. A., Triantafyllidis, N., and Shaw, J. A. Simulations of Shape Memory AlloyHoneycombs. ASME Applied Mechanics and Materials Conference (McMat 07). The Universityof Texas at Austin, Austin, TX. June 2007.
[73] Wineman, A. S. and Shaw, J. A. Mechanochemistry of Scission During Torsion of a RubberCylinder. ASME Applied Mechanics and Materials Conference (McMat 07). The University ofTexas at Austin, Austin, TX. June 2007.
[74] Grummon, D. S., Low, K.-B., Foltz, J., and Shaw, J. A. A New Method for Brazing Nitinol Basedon the Quasibinary TiNi-Nb System. 15th AIAA/ASME/AHS Adaptive Structures Conference.Honolulu, Hawaii. April 2007.
[75] Churchill, C. B. and Shaw, J. A. Tension and Compression Characterization of NiTi SMA Tubes.ASME Winter Meeting. Chicago, IL. Nov. 2006.
[76] Wineman, A. S. and Shaw, J. A. An Experimental Study of the Inflation of Elastomeric MembranesUndergoing Thermally Induced An Experimental Study of the Inflation of Elastomeric MembranesUndergoing Thermally Induced Chemorheological Changes. 44th Annual Technical Meeting ofthe Society of Engineering Science. Penn State University. Aug. 2006.
[77] Elliott, R., Triantafyllidis, N., and Shaw, J. Stress-Induced Martensitic Transformations in PerfectBi-Atomic Crystals. U.S. National Congress of Theoretical and Applied Mechanics. Boulder,CO. June 2006.
[78] Shaw, J. A., Grummon, D. S., and Foltz, J. Shape Memory Alloy Honeycombs: Opportunities &Challenges. Shape Memory & Superelastic Technologies Meeting. Asilomar, CA. May 2006.
[79] Wineman, A. S. and Shaw, J. A. Chemorheological Response of Natural Rubber at HighTemperature. NSF/SNL Grantees Conference. Albuquerque, NM. Mar. 2006.
[80] Shaw, J. A. and Wineman, A. S. Chemorheological Response of Natural Rubber at HighTemperature. NSF/SNL Grantees Conference. San Francisco, CA. Feb. 2006.
[81] Iadicola, M. A. and Shaw, J. A. The Influence of Cyclic Stress-induced Transformation on theMaterial Instabilities in a NiTi Shape Memory Alloy. ASME AMD/MD Mechanics and MaterialsConference. Baton Rouge, LA. June 2005.
[82] Shaw, J. A., Grummon, D. S., and Foltz, J. Manufacture of Shape Memory Alloy Honeycombs byTransient-Liquid Reactive Joining. Materials Research Society Spring Meeting. San Francisco,CA. Mar. 2005.
[83] Shaw, J. A., Grummon, D. S., and Foltz, J. Manufacture of Shape Memory Alloy Honeycombsby Transient-Liquid Reactive Joining. ASME Winter Meeting. Orlando, FL. Nov. 2005.
[84] Shaw, J. A. and Wineman, A. S. Chemorheological Response of Natural Rubber at HighTemperature. NSF/SNL Grantees Conference. Albuquerque, NM. Feb. 2005.
[85] Shaw, J., Jones, A., and Wineman, A. Chemorheological Response of Natural Rubber at ElevatedTemperatures: Experiments and Simulation. 41st Annual Technical Meeting of the Society ofEngineering Science. Lincoln, NE. Oct. 2004.
[86] Shaw, J. A. and Iadicola, M. A. Cyclic Nucleation Behavior of Uniaxially Deformed PseudoelasticNiTi. 41st Annual Technical Meeting of the Society of Engineering Science. Lincoln, NE. Oct.2004.
[87] Shaw, J. and Wineman, A. Thermally-Induced Chemorheological Changes and the Torsion ofElastomeric Cylinders. 41st Annual Technical Meeting of the Society of Engineering ScienceAnnual Technical Meeting of the Society of Engineering Science. Lincoln, NE. Oct. 2004.
[88] Shaw, J. and Wineman, A. Thermally-Induced Chemorheological Changes and the Inflation ofSpherical Elastomeric Membranes. 41st Annual Technical Meeting of the Society of EngineeringScience Annual Technical Meeting of the Society of Engineering Science. Lincoln, NE. Oct.2004.
[89] Elliott, R., Triantafyllidis, N., and Shaw, J. Stability of Multi-Atomic Crystal Structures. 41stAnnual Technical Meeting of the Society of Engineering Sciencet Annual Technical Meeting ofthe Society of Engineering Science. Lincoln, NE. Oct. 2004.
[90] Shaw, J., Chang, B.-C., Iadicola, M., and Leroy, Y. Thermodynamics of a 1-D Shape MemoryAlloy: Modeling, Experiments, and Application. Invited Talk, SPIE 10th Annual InternationalSymposium on Smart Structures and Materials. San Diego, CA. Mar. 2003.
[91] Elliott, R., Shaw, J., and Triantafyllidis, N. Bifurcation and Stability of Multilattice Crystalswith Internal Shifts. 40th Annual Technical Meeting of the Society of Engineering Science. AnnArbor, MI. Oct. 2003.
[92] Elliott, R., Triantafyllidis, N., and Shaw, J. Wavelength-Dependent stability Considerations for aNanoscale Thermomechanical Model of Bi-Atomic Crystals. 40th Annual Technical Meeting ofthe Society of Engineering Science. Ann Arbor, MI. Oct. 2003.
[93] Jones, A., Shaw, J., and Wineman, A. Time-Dependent Response of Natural Rubber at ElevatedTemperature due to Scission and Healing. 40th Annual Technical Meeting of the Society ofEngineering Science. Ann Arbor, MI. Oct. 2003.
[94] Iadicola, M. and Shaw, J. Localization and Cyclic Behavior of Uniaxially Deformed PseudoelasticNiTi. 40th Annual Technical Meeting of the Society of Engineering Science. Ann Arbor, MI.Oct. 2003.
[95] Iadicola, M. and Shaw, J. Evolution of Phase Transformation Fronts During Uniaxial CyclicDeformation in Pseudoelastic NiTi Wire. 14th US National Congress of Theoretical and AppliedMechanics. Blacksburg, VA. June 2002.
[96] Elliott, R., Shaw, J., and Triantafyllidis, N. Thermally Induced Displacive Transformations in Bi-Atomic Crystals. 14th US National Congress of Theoretical and Applied Mechanics. Blacksburg,VA. June 2002.
[97] Jones, A., Wineman, A., and Shaw, J. An Experimental Study of the Thermo-MechanicalResponse of Elastomers Undergoing Scission and Cross Linking at High Temperatures. 14th USNational Congress of Theoretical and Applied Mechanics. Blacksburg, VA. June 2002.
[98] Wineman, A. S., Jones, A. S., and Shaw, J. A. Thermo-Mechanics of Elastomers UndergoingScission and Cross-linking at High Temperatures. Tire Society, 21st Annual Meeting and
Conference on Tire Science and Technology. Akron, OH. Sep. 2002.[99] Shaw, J., Gremillet, A., and Grummon, D. The Manufacture of NiTi Foams. ASME Adaptive
Structures & Materials Systems Symposium, ASME Winter Meeting. New Orleans, LA. Nov.2002.
[100] Shaw, J., Elliott, R., and Triantafyllidis, N. Temperature-Induced Martensitic Transformationsin Bi-Atomic Lattices. Invited Talk, Symposium on Material Instabilities and the Effect ofMicrostructure. Austin, TX. May 2001.
[101] Iadicola, M. A. and Shaw, J. A. The Effect of Uniaxial Cyclic Deformation on the Evolution ofPhase Transformation Fronts in Pseudoelastic NiTi Wire. ASME Adaptive Structures & MaterialsSystems Symposium. New York, NY. Nov. 2001.
[102] Iadicola, M. A., Shaw, J. A., and Corona, E. Buckling of Steel Bars with Luders Bands. InvitedTalk, Symposium on Stability, ASME/SES/ASCE Mechanics of Materials. San Diego, CA. Nov.2001.
[103] Elliott, R., Shaw, J., and Triantafyllidis, N. Stability of Biatomic Lattices. International Congressof Theoretical and Applied Mechanics. Chicago, Illinois. Aug. 2000.
[104] Iadicola, M. and Shaw, J. Parametric Study of Thermo-Mechanical Instabilities in a ShapeMemory Alloy. Invited Talk, International Congress of Theoretical and Applied Mechanics.Chicago, Illinois. Aug. 2000.
[105] Shaw, J. and Iadicola, M. An Experimental Setup for Measuring Unstable Thermo-MechanicalBehavior of a Shape Memory Alloy Wire. ASME Adaptive Structures & Materials SystemsSymposium. Orlando, FL. Nov. 2000.
[106] Shaw, J. Thermo-mechanical Simulations of Stress-Induced Transformation in a NiTi ShapeMemory Alloy. Invited Talk, Plasticity ’99. Cancun, Mexico. Jan. 1999.
[107] Shaw, J. Thermo-Mechanical Simulations of a NiTi Shape Memory Alloy. ASME Winter Meeting.Nashville, TN. Nov. 1999.
[108] Shaw, J. and Triantafyllidis, N. Stability of Thermally Loaded NiTi Pure Crystals. ASMEAMD/MD Summer Conference. Blacksburg, VA. June 1999.
[109] Shaw, J. Initiation and Propagation of Localized Deformation in the Pseudoelastic Response ofNiTi. SPIE Symposium in Smart Structures and Materials. San Diego, CA. Mar. 1998.
[110] Shaw, J. Numerical Simulation of Stress-Induced Instability and Propagation in Uniaxial Strips.Invited Talk, American Soc. of Civil Engin. 12th Engin. Mechanics Conference. La Jolla, CA.May 1998.
[111] Shaw, J. Stress-Induced Instability and Propagation in Uniaxial Strips. Invited Talk, 13th U.S.National Congress of Theoretical and Applied Mechanics, Univ. of Florida. Gainesville, FL. June1998.
Seminars[1] Shaw, J. A. Analysis of Cardiomyocyte Contraction in the Cell-In-Gel System. Invited Seminar.
TX A&M, College Station, TX. Nov. 2019.[2] Shaw, J. A. Cool (& Hot) Aerospace Applications of Materials with a Memory. Sigma Gamma
Tau/AIAA Lecture. UM-Aerospace Engineering. Oct. 2015.[3] Shaw, J. A. and Biggs, D. Shape Memory Alloy Actuator Cables. Seminar. Fort Wayne Metals
Research. March 2015.[4] Shaw, J. A. New Structural Forms of Shape Memory Alloys. Invited Seminar. University of
California–Davis, Biomechanical Engineering Dept. Feb. 2011.[5] Shaw, J. A. Shape Memory Alloys. Guest Lecture. UM - ME 559. Mar. 2011.[6] Shaw, J. A. Shape Memory Alloy Structures. Seminar. Sandia National Laboratory. Jan. 2011.
[7] Shaw, J. A. A Deep-dive into Shape Memory Alloys. Invited Seminar with the GM’s VicePresident for Research. General Motors Tech Center. Oct. 2010.
[8] Shaw, J. A. Thermo-mechanical Behavior and Instabilities in Shape Memory Alloy Structures.Invited Seminar. Ecole Polytechnique, Paris, France. Apr. 2010.
[9] Shaw, J. A. A Gentle Introduction to Shape Memory Alloys. Sigma Gamma Tau Lecture.UM-Aerospace Engineering. Mar. 2010.
[10] Shaw, J. A. What Make Aerospace Structures Special. Guest Lecture. UM - AE 245. Jan. 282010.
[11] Shaw, J. A. Shape Memory Alloys. Guest Lecture. UM - ME 559. Oct. 2009.[12] Shaw, J. A., Girard, A., and Atkins, E. Unmanned Micro-Air Vehicles. Guest Lecture. UM - AE
585. Oct. 2009.[13] Shaw, J. A. New Structural Forms of Shape Memory Alloys. Seminar. University of Michigan -
Aerospace Engineering. Feb. 2009.[14] Shaw, J. A. Shape Memory Alloy Honeycombs: Opportunities & Challenges. Invited Seminar.
General Motors Tech Center. Feb. 2006.[15] Shaw, J. A. Thermomechanical behavior of shape memory alloy wire. Invited Seminar.
University of Texas at Austin, Austin, TX. Feb. 2006.[16] Shaw, J. A. Some Complexities in the Thermomechanical Behavior of NiTi Shape Memory
Alloys. Invited Seminar. Los Alamos National Laboratory, Los Alamos, NM. Feb. 2005.[17] Shaw, J. and Iadicola, M. Complexities in the Thermomechanical Behavior of NiTi Shape
Memory Alloys. Invited Seminar, Baithak on Phase Transformations. California Institute ofTechnology, Pasadena, CA. Jan. 2005.
[18] Shaw, J. and Iadicola, M. Some Complexities in the Thermomechanical Behavior of NiTi ShapeMemory Alloys. Invited Seminar. California Institute of Technology, Pasadena, CA. Feb. 2003.
[19] Shaw, J. and Iadicola, M. Complexities in the Thermomechanical Behavior of NiTi ShapeMemory Alloys. Invited Seminar. North Carolina State University, Raleigh, NC. Nov. 2003.
[20] Shaw, J. A., Grummon, D. S., and Gremillet, A. Fabrication of Shape-Memory and SuperelasticOpen-Cell Foams. Invited Seminar. General Motors Tech Center, Warren, MI. June 2002.
[21] Shaw, J. A. Shape Memory Alloys. Invited Seminar. Ford Scientific Laboratory, Dearborn, MI.June 2001.
[22] Shaw, J. Thermo-Mechanical Instabilities in a Shape Memory Alloy. Invited Seminar. Univ.Illinois at Urbana-Champaign, Urbana, IL. Sep 1999.
[23] Shaw, J. Thermomechanical Instabilities in a Shape Memory Alloy. Invited Seminar. EcolePolytechnique, Palaiseau, France. Nov. 1998.
[24] Shaw, J. Thermomechanical Behavior of NiTi. Invited Seminar. University of Notre Dame,Notre Dame, IN. Sep 1998.
Current External Research FundingTitle GM/UM Collaborative Research Laboratory in Multifunctional Vehicle Systems .PI’s D. Brei (ME), J. Luntz (ME), J. Shaw (Aero), S. Ahlquist (Arch)
Source General MotorsType Contract
Amount $5.6MDates 1/17 – 12/21
Past External Research FundingTitle Novel Cell-in-Gel Device for Mechanotransduction Study at Single Cell Level.
PI Ye Chen-Izu (UC-Davis)Source NIH
Type GrantAmount $308K (UM portion)
Dates 7/15 – 6/19Title GM/UM Collaborative Research Laboratory in Smart Materials & Structures.PI’s D. Brei (ME), J. Luntz (ME), J. Shaw (Aero)
Source General MotorsType Grant/Contract
Amount $4.5MDates 5/11 – 4/16Title Lightweight Thermal Energy Recovery (LighTER) Systems.PI’s A. Brown (GM), J. Brown (Dynalloy), J. Shaw (UM), G. McKnight (HRL)
Source Dept. of Energy, ARPA-EType Grant/Sub-contract
Amount $2.7M, UM part $305KDates 1/10 – 3/12Title Cellular Shape Memory Structures.PI’s N. Triantafyllidis (UM), J. Shaw (UM), D. Grummon (MSU)
Source Dept. of Defense, AFOSRType Grant
Amount $390KDates 1/08 – 12/11Title Shape Memory Alloy Cables.
PI J. ShawSource National Science Foundation
Type GrantAmount $159K
Dates 10/07 – 8/12
Title GM/UM Collaborative Research Laboratory in Smart Materials & Structures.PI’s D. Brei (ME), J. Luntz (ME), J. Shaw (Aero)
Source General MotorsType Grant/Contract
Amount $2.9MDates 5/06 – 4/11
Title Functional Superelastic Interlayers for Control of Friction and Wear in Hard-CoatedComponents.
PI’s D. Grummon (MSU), Y. Cheng (GM), J. Shaw (UM)Source National Science Foundation
Type Grant (GOALI)Amount $115K (UM portion)
Dates 7/05 – 6/09Title Thermo-mechanical Experiments &Modeling of SMA Structural Elements.
PI J. ShawSource National Science Foundation
Type GrantAmount $156K
Dates 6/04 – 12/07
Title Modeling, Simulation, & Experimental Study of Thermo-mechanical Degradation in Elas-tomeric Components.
PI’s Wineman (ME), J. ShawSource Sandia National Laboratory
Type ContractAmount $318K
Dates 1/04 – 8/06Title Thermomechanical Instabilities in M-Lattices with Application to SMAs.PI’s N. Triantafyllidis, J. Shaw
Source National Science FoundationType Grant
Amount $350KDates 6/04 – 12/08Title Thermomechanical Instabilities in M-Lattices with Application to SMAs.PI’s N. Triantafyllidis, J. Shaw
Source National Science FoundationType Grant
Amount $350KDates 6/04 – 12/08Title Life Cycle and Durability Prediction of Elastomeric Components.
PI’s A. Wineman (ME), J. Shaw (Aero), A. Waas (Aero)Source National Science Foundation
Type GrantAmount $328K
Dates 10/99 – 12/03Title Experimental Mechanics &Modeling of Interactive Solids and Structures.
PI J. ShawSource National Science Foundation
Type Grant (CAREER)Amount $236K
Dates 5/00 – 4/06Title Manufacture & Characterization of Shape Memory Alloy Foams.
PI J. ShawSource Dept. of Defense, ONR
Type Grant (Young Investigator Program)Amount $300K
Dates 6/01 – 5/04Title Design and Thermo–Mechanical Characterization of NiTi Smart Composites.
PI J. ShawSource Dept. of Defense, AFOSR
Type GrantAmount $31K
Dates 5/99 – 7/00Title Instrumentation to Characterize Smart Materials and Composites.PI’s A. Waas, J. Shaw
Source Dept. of Defense, DURIPType Grant (DURIP)
Amount $441KDates 5/98 – 8/99
Professional Service{ Experimental Mechanics, Associate Editor, 2016-present{ Continuum Mechanics and Thermodynamics, Associate Editor, 2005-2011{ NSF panelist, 2012, 2015{ U.S. Army Basic Research Review Panel, Aug. 2010{ Member, American Society of Mechanical Engineers, 1996-present
- Technical Committee – Adaptive Structures and Materials Systems (2000-2004)- Technical Committee – Experimental Mechanics (2000)- Technical Committee – Instabilities in Solids and Structures (2000)
{ Associate Fellow, American Institute for Aeronautics and Astronautics{ Member, Biophysical Society{ Member, Materials Research Society{ Member, Society of Experimental Mechanics{ Reviewer
- Acta Materialia- AIAA Journal- Continuum Mechanics and Thermodynamics- Experimental Mechanics- Journal of Applied Mechanics- Journal of Applied Physics Letters- Journal of Biomedical Materials Research A- Journal of Engineering Materials and Technology- Journal of Engineering Mechanics- Journal of Intelligent Material Systems and Structures- Journal of Materials Engineering and Performance- Journal of Mechanical Design- Journal of the Mechanics and Physics of Solids- Journal of Vibration and Acoustics- International Journal of Nonlinear Mechanics- International Journal of Plasticity- International Journal of Solids and Structures- Mechanics of Materials- Smart Materials and Structures
Technical Sessions Organized{ Symposium in honor of Alan Wineman’s 50th year at the University of Michigan, U.S. National Congress of
Theoretical and Applied Mechanics, June 2014.{ Co-organizer, Session track, Society of Experimental Mechanics (SEM), June 2010.{ Co-organizer, Session track, Shape Memory and Superelastic Technologies (SMST), May 2010.{ Co-organizer, Phase Transformation in Solids and Structures, ASME Applied Mechanics and Materials Confer-
ence (McMat 07), June 2007.{ Co-organizer, Symposium on Shape Memory Materials, Society of Engineering Science Meeting, Ann Arbor,
MI, Oct. 2003.{ General Chair, Adaptive Structures and Materials Systems Symposium, ASME Winter Meeting, New Orleans,
LA, Nov. 2002.{ Technical Chair, Adaptive Structures and Materials Systems Symposium, ASME Winter Meeting, New York,
NY, Nov. 2001.{ “Issues in Adaptive Materials and Structures: Part I and Part II,” under the auspices of the Adaptive Structures
and Materials Systems Technical Committee, ASME Winter Meeting, Orlando, FL, Nov. 2000.{ “Experimental Mechanics of Interactive Materials,” under the auspices of the Experimental Mechanics Technical
Committee, ASME Winter Meeting, Nashville, TN, Nov. 1999.
Teaching at UM
Year Term Course Q1(a) Q2(b)
2019 Winter AE 518 (Theory of Elastic Stability I) 4.90 5.002019 Fall AE 513 (Found. of Solid & Structural Mechanics I) 5.00 5.002019 Winter AE 518 (Theory of Elastic Stability I) 4.80 5.002018 Fall AE 315 (Aircraft & Spacecraft Structures) 3.90 4.502018 Winter AE 518 (Theory of Elastic Stability I) 4.70 4.832017 Fall —Sabbatical— – –2017 Winter AE 518 (Theory of Elastic Stability I) 4.75 4.942016 Fall AE 513 (Found. of Solid & Structural Mechanics I) 4.25 4.672016 Winter AE 518 (Theory of Elastic Stability I) 4.75 4.752015 Fall AE 513 (Found. of Solid & Structural Mechanics I) 4.75 4.902015 Winter AE 315 (Aircraft & Spacecraft Structures) 4.68 4.892015 Winter AE 518 (Theory of Elastic Stability I) 4.38 4.632014 Fall AE 315 (Aircraft & Spacecraft Structures) 4.33 4.852014 Winter AE 518 (Theory of Elastic Stability I) 4.25 4.802013 Fall AE 315 (Aircraft & Spacecraft Structures) 4.18 4.672013 Winter AE 514 (Found. of Solid & Structural Mechanics II) 4.50 4.902012 Fall AE 215 (Intro to Solids Mechanics/Aero Structures) 4.75 4.902012 Fall AE 285 (Aerospace Engineering Seminar) 3.94 3.922012 Winter —Sabbatical— – –2011 Fall AE 518 (Theory of Elastic Stability I) 4.80 4.922011 Winter —ABET— – –2010 Fall AE 513 (Found. of Solid & Structural Mechanics I) 4.25 4.882010 Winter AE 315 (Aircraft & Spacecraft Structures) 4.38 4.682009 Fall AE 513 (Found. of Solid & Structural Mechanics I) 4.17 4.752009 Winter AE 215 (Intro to Solids Mechanics/Aero Structures) 4.37 4.772008 Fall AE 215 (Intro to Solids Mechanics/Aero Structures) 4.35 4.762008 Winter AE 215 (Intro to Solids Mechanics/Aero Structures) 4.48 4.862007 Fall AE 215 (Intro to Solids Mechanics/Aero Structures) 4.14 4.522007 Fall AE 513 (Found. of Solid & Structural Mechanics I) 4.60 4.602007 Winter AE 714∗ (Interactive Solids & Structures) 4.21 4.882006 Fall AE 215 (Intro to Solids Mechanics/Aero Structures) 4.34 4.742006 Fall AE 513 (Found. of Solid & Structural Mechanics I) 4.58 4.712006 Winter AE 215 (Intro to Solids Mechanics/Aero Structures) 4.22 4.562005 Fall AE 513 (Found. of Solid & Structural Mechanics I) 4.89 5.002005 Winter —ABET— – –2004 Fall AE 513 (Found. of Solid & Structural Mechanics I) 4.25 4.58
Year Term Course Q1(a) Q2(b)
2004 Winter —Sabbatical— – –2003 Fall AE 215 (Intro to Solid Mechanics/Aero Structures) 4.32 4.762003 Fall AE 513 (Found. of Solid & Structural Mechanics I) 4.25 4.562003 Winter AE 285 (Intro to Solids Mechanics/Design) 4.11 4.602003 Winter AE 518 (Theory of Elastic Stability I) 4.60 4.862002 Fall AE 513 (Found. of Solid & Structural Mechanics I) 4.40 4.862002 Winter AE 513 (Found. of Solid & Structural Mechanics I) 4.25 4.812001 Fall AE 285 (Intro to Solids Mechanics/Design) 4.60 4.832001 Winter AE 285 (Intro to Solids Mechanics/Design) 4.02 4.282000 Fall AE 513 (Found. of Solid & Structural Mechanics I) 4.22 4.692000 Winter AE 315 (Aircraft & Spacecraft Structures) 4.12 4.681999 Fall AE 513∗ (Found. of Solid & Structural Mechanics I) 4.61 4.611999 Winter AE 301 (Intro to Instrumentation & Measurement) 4.04 4.271998 Fall AE 414 (Structural Mechanics II) 4.03 4.451998 Winter AE 414 (Structural Mechanics II) 4.23 4.641997 Fall AE 414 (Structural Mechanics II) 4.12 4.75
(a) Student course evaluation Q1 “Overall this was an excellent course”. Scale: 1 (strongly disagree) to 5 (strongly agree).(b) Student course evaluation Q2 “Overall this was an excellent instructor”. Scale: 1 (strongly disagree) to 5 (strongly agree).*New course introduced
Students Supervised{ Post-doctoral fellows advised:
- Benjamin Reedlunn, 2012Research topic – Multi-axial Behavior of Shape Memory Alloys
- Chris Churchill, 2010-2011Research topic – Shape Memory Alloy Heat Engines for Waste Heat Harvesting
- Mark Iadicola, 2002Research topic – Nucleation Instabilities & Propagating Phase Transformation Fronts under Cyclic Loadingin Nickel-Titanium Shape Memory Alloys
{ Doctoral students advised:- Mohammad Kazemi (2020, expected)
Dissertation – Experimental and Theoretical Investigation of Soft Bio-inspired Smart Composite Systems- Will LePage (2018, co-advised with Samantha Daly)
Dissertation – Fracture of Nitinol- Daniel Biggs, 2017
Dissertation – Shape Memory Alloy Cable Actuators and Superelastic Devices- Ryan Watkins, 2015
Dissertation – Thermomechanical Characterization and Modeling of Superelastic Shape Memory AlloyBeams and Frames
- Kannan Dasharathi, 2015Dissertation – Thermomechanical Aging of Shape Memory Polymers
- Benjamin Reedlunn, 2011 (co-advised with Samantha Daly)Dissertation – Shape Memory Alloy Cables
- Chris Churchill, 2009Dissertation – Experimental Techniques for Characterizing the Thermo-Electro-Mechanical ShakedownResponse of SMA Wires and Tubes
- Petros Michailidis, 2009 (co-advised with Nicolas Triantafyllidis)Dissertation – Shape Memory Alloy Honeycombs: Simulation and Stability Aspects
- Bi-chiau Chang, 2005Dissertation – Thermodynamics of Shape Memory Alloy Wire: Modeling, Experimental Calibration, andSimulation
- Ryan Elliott, 2004 (co-advised with Nicolas Triantafyllidis)Dissertation – Lattice Instabilities in Bi-atomic Alloys
- Alan Jones, 2003 (co-advised with Alan Wineman)Dissertation – An Experimental Study of the Thermomechanical Response of Elastomers UndergoingScission and Cross-linking at High Temperatures
- Mark Iadicola, 2002Dissertation – On Propagating Instabilities in Nickel-Titanium and Steel Alloys
{ Masters students advised:- Murtaza Lokhandwala, Mechanics of Technical Knits, 2019- Abdul Khan, Mechanics of Abdominal Suturing, 2019- Corin Bowen, Mechanics of Shape Memory Alloy Springs, 2019- Alexander Van Kainen, Mechanics of Technical Knits and Adaptive Structures, 2017- Ana Vasquez, Shape Memory Alloy/Polymer Hybrid Composites, 2016- Matt Leach, High Temperature Elastomer Degradation Experiments, 2008- Jeff Bronson, High Temperature Elastomer Experimental Setup, 2004
- Antoine Gremillet, SMA Foams/Honeycombs, 2003- Brian MacLachlan, Morphing Wing, 1999
{ Undergraduate students advised:- Development of Visual Education Software for Undergraduate Aerospace Engineering Structures Couses
(honors capstone project): Ronnie Frank Pires Stone, winter 2020{ Undergraduate student projects:
- SMA self-assembly cube: Logan Bergeron, fall 2019–winter 2020- SMA jellyfish robot: Logan Bergeron, summer 2019–fall 2019- SMA-actuated biomimetic hand: Hanson Li, winter 2020- Kirigami SMA composites: Hanson Li, fall 2019- SMA spring heat engine: Lennon Metz, fall 2019- SMA spring heat engine: TingKang Wang, winter 2019- SMA jellyfish robot: Anthony Dostine, winter–fall 2018- SMA jellyfish robot: Jiadi Zhang, winter–fall 2018- Synthetic SMA jellyfish: Jing Yang, summer–fall 2017- Bioreactor pump and ventricular assist device: James Strandbergh, summer 2015–summer 2016- Geometry Dependence of Stress-Induced Martensitic Phase Transformation in NiTi SMAs: Avery Samuel,
fall 2015–winter 2016- Tension-torsion characterization of elastomers and shape memory alloys: Arnaud Lepers (intern from Ecole
Polytechnique), summer 2015- Experimental characterization of an SMA heat engine: David (Yi) Yang, winter, summer 2015- Modeling of an SMA-actuated tensegrity structure: Nathanael England, winter 2015- Experimental characterization of a Shape Memory Polymer: Liang Liu, winter 2015- Experimental studies of materials and structures designed for medical applications: Florian Rouzies (intern
from Ecole Polytechnique), summer 2014- SMA-actuated tensegrity structures: Shun Zhang, fall 2013- SMA spring heat transfer: Kaitlyn Powers, fall 2013- Space Wings II, SMP fabrication: Ruiqi Chen, summer, fall 2013- Bioreactor pump, SMA heat transfer: Avinash Davalla, summer, fall 2013- SMA heat engine & heat transfer: Daniel Biggs, 2011-2012- SMA Catapult project: Trevor Glick, Adam Ourchane, Andrew Ridgway, Paul Rakowski, 2010-2011- SMA heat engine: Grant Hazard, 2010-2011- UAV quad-rotor project: Daniel Pencak, Nicolas Ristow, Alex Simpson, Guan Song, 2010-2011- SMA braid project: Robert Andrew Mattingly, 2010- SMA Thermobile project: Paul Rakowski, 2009- Shape Memory Polymer Aging project: Steve Mazur, Andrew Ridgway, 2009- UAV project: Eric Boekeloo, Sally Haselschwardt, Cory Kennedy, 2009- SMA actuator project: Clarence Hanson, 2008- SMA heat engine project: Michael Dombroski, 2007-2008- SMA honeycomb experiments: Curtis Spicer, 2006- SMA dry-ice actuator project: Gail Booren, 2006- SMA cables project: Antoine Gremillet (from Ecole Polytechnique), 2002- Thermoelectrics project: Geoffroy Lenglin, 2000- Smart Wing project: 1998-2000 (30 students)
UM Service{ Other Ph.D. Committees
- Callan Luetkemeyer (ME), 2020- James Gorman (ME), 2019- Sriram Ganesan (AE), 2017- Yali Li (AE), 2017- Yue (Joyce) Gong (ME), 2017- Alyssa Skulborstad (AE), 2016- Michael Kimiecik (ME), 2015- Wonhee Kim (ME), 2015- Julianna Abel (ME), 2014- Kyubum Kim (ME), 2013- John Redmund (ME), 2010- Anupam Pathak (ME), 2009- Hai H. Dinh (CEE), 2009- Kittinun Sirijaroonchai (CEE), 2008- Jesse Thomas (AE), 2008- Robert (C.E.) Sun (AE), 2007- Sunny (S.V.) Kankanala (AE), 2007- Ke-Bin Low (Chem Eng/Mat. Sci., Michigan State Univ.), 2006- Wei Xu (ME), 2003- Miroslav Nestorovic (AE), 2002- Trevor Harding (MSE), 2000- Joel Hetrick (ME), 1999- Jung Hyun Ahn (AE), 1999- Seung Hoon Lee (AE), 1998- Mark Hilburger (AE), 1998
{ Aero Department- Member, Veera Sundararaghavan promotion casebook committee, 2019- Chairman, Henry Sodano promotion casebook committee, 2016- Chairman, undergraduate curriculum committee: winter 2010, fall 2011, fall 2012–2016- Chairman, Timothy Smith lecturer promotion casebook committee, 2014- Chairman, Veera Sundararaghavan promotion/tenure casebook committee, 2012- Member, Nakhiah Goulbourne 3-year reappointment casebook committee, 2011-2012- Member, Veera Sundararaghavan 3-year reappointment casebook committee, 2010- Member, Aero undergraduate curriculum committee, 2004-present- ABET coordinator, 2005-2011- Member, Aero faculty search committee, 2008-2009- Member, Aero faculty search committee, 2006-2007
{ College of Engineering- Member, College rules committee, 2020-present- Chairman, McIvor award committee, 2014-present- Member, Safety committee, 2014-present- Member, Samantha Daly, tenure/promotion casebook committee, 2013- Member, Samantha Daly, 3-year reappointment casebook committee, 2011- Member, College curriculum committee, winter 2010
- Member, McIvor award committee, 2009-2014{ University
- Member, Rackham predoctoral fellowship committee, 2016- Honors Convocation Ceremonies Marshal, Mar. 2006- Graduation Ceremonies Marshal, Dec. 2005- Graduation Ceremonies Marshal, Apr. 2004
Honors/AwardsBest paper of the year award International Journal of Solids &
Structures2013
Outstanding Accomplishment Award Dept. of Aerospace Engineering 2012Monroe-Brown Foundation Education Excellence Award UM College of Engineering 2011Distinguished Service Certificate AIAA 2002Beer/Johnston Outstanding New Mechanics Educator Award ASEE 2002Young Investigator Grant ONR 2001CAREER Grant NSF 2000Sigma Gamma Tau, Aerospace Prof. of the Year Award University of Michigan 1999Ford Foundation Loan/Grant Univ. of Texas at Austin 1995-96Thrust 2000 Engineering Scholarship Univ. of Texas at Austin 1991-95Continuing Graduate Fellowship Univ. of Texas at Austin 1993Preemptive Graduate Fellowship Univ. of Texas at Austin 1991-92Top Graduate in NROTC class University of Michigan 1985Graduated Summa Cum Laude University of Michigan 1985James B. Angel Scholar University of Michigan 1985Lt. Francis B. Lowry Scholarship University of Michigan 1985Dean’s List University of Michigan 1981-85Navy ROTC Scholarship University of Michigan 1981-85Navy ROTC Academic Stars University of Michigan 1981-85Outstanding Undergraduate in Engineering Physics University of Michigan 1984
Consulting{ Triton Systems, 2017-present{ Medplate Life Sciences Corp, 2010-present{ Soble, Rowe, & Krichbaum LLP, 2015-2016{ Morgan & Finnegan LLP, 2002{ Accumed Systems Inc, 2001, 2004
Interestspiano, downhill skiing, bicycling, sailing, tennis, private pilot, motorcycling
Favorite Quotes[In response to being asked to teach at 9:00am] ... “I’m not sure I can stay up that late!” – Mark Newman
[Regarding the energy criterion of elastic stability] “When the second variation method fails, it appears that theminimum of the potential energy is destroyed only by the presence of obscure secret passages in function spaceinto which no self-respecting structure would venture except by wildly improbable accident. Accordingly, anappropriately defined probability of failure should, under these circumstances, be absurdly low.” – Budiansky andHutchinson, 1979
“Scholarship asks, thank God, no recompense but Truth. It is not for the sake of material reward that she(Scholarship) pursues her (Truth) through the undergrowth of Ignorance, shining on Obscurity the bright torch ofReason and clearing aside the tangled thorns of Error with the keen secateurs of Intellect. Nor is it for the sakeof public glory and the applause of the multitude: the scholar is indifferent to vulgar acclaim. Nor is it even inthe hope that those few intimate friends who have observed at first hand the labour of the chase will mark with aword or two of discerning congratulation its eventual achievement. Which is very fortunate, because they don’t.” –Sarah Caudwell, Thus Was Adonis Murdered