Group of

Prof. Wei Lu

  
 
Prof. Wei Lu
 
Last updated on
12/16/2008

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Mechanical Engineering, University of Michigan

Selected Publication
  1. S. Lee and W. Lu, “Effect of Mechanical Load on the Shuttling Operation of Molecular Muscles,” Applied Physics Letters, 94, Art. No. 233114, 2009.
  2. J. Park and W. Lu, “Self-assembly of Functionally Gradient Nanoparticle Structures,” Applied Physics Letters, 93, Art. No. 243109, 2008.
  3. Q. Wei, J. Lian, W. Lu, and L. Wang, “Highly Ordered Ga Nanodroplets on a GaAs Surface Formed by a Focused Ion Beam,” Physical Review Letters, 100, Art. No. 076103, 2008.
  4. D. Salac and W. Lu, “A Local Semi-Implicit Level-Set Method for Interface Motion,” Journal of Scientific Computing, 35, 330-349, 2008.
  5. D. Salac and W. Lu, “Stability and Shape Evolution of Voids and Channels due to Surface Misfit,” International Journal of Solids and Structures, 45, 3793-3806, 2008.
  6. J. Park and W. Lu, “Electric Field Processing of Core-Shell Nanoparticles,” Journal of Computational and Theoretical Nanoscience, 5, 659-665, 2008.
  7. H. Guo and W. Lu, “Electromigration and Thermal Stress-induced Surface Diffusion and Morphology Evolution of Micro Solder Joints,” Journal of Computational and Theoretical Nanoscience, 5, 1310-1317, 2008.
  8. W. Lu and A.M. Sastry, “Self-assembly for Semiconductor Industry,” IEEE Transactions on Semiconductor Manufacturing, 20, 421-431, 2007.
  9. J. Park and W. Lu, “Orientation of Core-shell Nanoparticles in an Electric Field,” Applied Physics Letters, 91, Art. No. 053113, 2007. (Selected by Virtual Journal of Nanoscale Science & Technology, Reported in Nanotech News).
  10. D. Salac and W. Lu, “A Level Set Approach to Model Directed Nanocrack Patterns,” Computational Materials Science, 39, 849–856, 2007.
  11. W. Lu, H. Koerner and R. Vaia, “Effect of Electric Field on Exfoliation of Nanoplates,” Applied Physics Letters, 89, Art. No. 223118, 2006.
  12. D. Salac and W. Lu, “Ordering of Metallic Quantum Dots,” Applied Physics Letters, 89, Art. No. 073105, 2006. (Selected by Virtual Journal of Nanoscale Science & Technology).
  13. D. Salac and W. Lu, “Design Nanocrack Patterns in Heterogeneous Films,” Nanotechnology, 17, 5185–5191, 2006.
  14. D. Kim and W. Lu, “Creep Flow, Diffusion, and Electromigration in Small Scale Interconnects,” Journal of the Mechanics and Physics of Solids, 54, 2554-2568, 2006.
  15. W. Lu and D. Salac, “Interactions of Metallic Quantum Dots on a Semiconductor Substrate,” Physical Review B, 74, 073304, 2006. (Selected by Virtual Journal of Nanoscale Science & Technology).
  16. W. Lu and D. Kim, “Thin-Film Structures Induced by Electrostatic Field and Substrate Kinetic Constraint,” Applied Physics Letters, 88, Art. No. 153116, 2006. (Selected by Virtual Journal of Nanoscale Science & Technology).
  17. W. Lu, “Theory and Simulation of Nanoscale Self-assembly on Substrates”, Journal of Computational and Theoretical Nanoscience, 3, 342–361, 2006.
  18. D. Kim and W. Lu, “Interface Instability and Nanostructure Patterning,” Computational Materials Science, 38, 418-425, 2006.
  19. D. Kim and W. Lu, “Three-dimensional Model of Electrostatically Induced Pattern Formation in Thin Polymer Films,” Physical Review B, 73, 035206, 2006. (Selected by Virtual Journal of Nanoscale Science & Technology).
  20. D. Salac and W. Lu, “Controlled Nanocrack Patterns for Nanowires”, Journal of Computational and Theoretical Nanoscience, 3, 263-268, 2006.
  21. W. Lu and D. Salac, “Patterning Multilayers of Molecules via Self-Organization,” Physical Review Letters, 94, 146103, 2005. (Selected by Virtual Journal of Nanoscale Science & Technology)
  22. H.C. Yu and W. Lu, “Dynamics of the Self-assembly of Nanovoids and Nanobubbles in Solids,” Acta Materialia, 53, 1799-1807, 2005.
  23. W. Lu and D. Kim, “Engineering nanophase self-assembly with elastic field,” Acta Materialia, 53, 3689-3694, 2005.
  24. W. Lu and D. Salac, “Programmable Nanoscale Domain Patterns in Multilayers,” Acta Materialia, 53, 3253-3260, 2005.
  25. W. Lu and D. Kim, "Simulation on Nanoscale Self-assembly of Ternary-epilayers," Computational Materials Science, 32, 20-30, 2005.
  26. W. Lu and D. Kim, “Patterning Nanoscale Structures by Surface Chemistry,” Nano Letters, 4, 313-316, 2004. (Reported in Technology Research News and NanoBiotech News).
  27. D. Salac, W. Lu, C.W. Wang, and A.M. Sastry, “Pattern formation in a polymer thin film induced by an in-plane electric field,” Applied Physics Letters, 85, 1161-1163, 2004. (Selected by Virtual Journal of Nanoscale Science & Technology)
  28. D. Kim and W. Lu, “Stability of Multi-component Epilayers and Nanopattern Formation,” Journal of Nanoparticle Research, 6, 495-507, 2004.
  29. D. Kim and W. Lu, “Self-organized Nanostructures in Multi-phase Epilayers,” Nanotechnology, 15, 667-674, 2004.
  30. K.S. Schneider, W. Lu, T.M. Owens, D.R. Fosnacht, M.M. Banaszak Holl, and B.G. Orr, “Monolayer Pattern Evolution Via Substrate Strain-mediated Spinodal Decomposition,” Physical Review Letters, 93, 166104, 2004.
  31. W. Lu and D. Kim, “Dynamics of Nanoscale Self-Assembly of Ternary Epilayers,” Microelectronic Engineering, 75, 78-84, 2004.
  32. K.S. Schneider, W. Lu, D.R. Fosnacht, B.G. Orr, and M.M. Banaszak Holl, “Dynamic In Situ Characterization of Organic Monolayer Formation via a Novel Substrate-Mediated Mechanism,” Langmuir, 20, 1258-1268, 2004.
  33. Y.F. Gao, W. Lu, and Z. Suo, “A Mesophase Transition in a Binary Monolayer on a Solid Surface,” Acta Materialia, 50, 2297-2308, 2002.
  34. W. Lu and Z. Suo, “Symmetry Breaking in Self-assembled Monolayers on Solid Surfaces. II. Anisotropic Substrate Elasticity,” Physical Review B, 65, Art. No. 205418, 2002.
  35. W. Lu and Z. Suo, “Symmetry Breaking in Self-assembled Monolayers on Solid Surfaces: Anisotropic Surface Stress,” Physical Review B, 65, Art. No. 085401, 2002.
  36. W. Lu and Z. Suo, “Dynamics of Nanoscale Pattern Formation of an Epitaxial Monolayer,” Journal of the Mechanics and Physics of Solids, 49, 1937-1950, 2001.
  37. W. Lu, D.N. Fang, and K.C. Hwang, “Micromechanics of Ferroelectric Domain Switching Behavior Part II: Constitutive Relations and Hysteresis,” Theoretical and Applied Fracture Mechanics, 37, 39-47, 2001.
  38. W. Lu, D.N. Fang, and K.C. Hwang, “Micromechanics of Ferroelectric Domain Switching Behavior Part I: Coupled Electromechanical Field of Domain Inclusions,” Theoretical and Applied Fracture Mechanics, 37, 29-38, 2001.
  39. Z. Suo and W. Lu, “Forces that Drive Self-Assembly on Solid Surfaces,” Journal of Nanoparticle Research, 2, 333-344, 2000.
  40. Z. Suo and W. Lu, “Composition Modulation and Nanophase Separation in a Binary Epilayer,” Journal of the Mechanics and Physics of Solids, 48, 211-232, 2000.
  41. W. Lu and Z. Suo, “Coarsening, Refining, and Pattern Emergence in Binary Epilayers,” Zeitschrift fur Metallkunde, 90, 956-960, 1999.
  42. D.N Fang, W. Lu, and K.C. Hwang, “Pseudoelastic Behavior of a CuAlNi Single Crystal under Uniaxial Loading,” Metallurgical and Materials Transactions A - Physical Metallurgy and Materials Science, 30, 1933-1943, 1999.
  43. W. Lu, D.N. Fang, C. Q. Li, and K.C. Hwang, “Nonlinear Electric-Mechanical Behavior and Micromechanics Modeling of Ferroelectric Domain Evolution,” Acta Materialia, 47, 2913-2926, 1999.
  44. D.N. Fang, W. Lu, W.Y. Yan, T. Inoue, and K.C. Hwang, “Stress-Strain Relation of CuAlNi SMA Single Crystal under Biaxial Loading-Constitutive Model and Experiments,” Acta Materialia, 47, 269-280, 1998.
  45. W. Lu, D.N. Fang, and K.C. Hwang, “A Macroscopic-Microscopic Constitutive Model for Ferroelectric Ceramics,” Acta Mechanica Sinica, 30, 540-551, 1998.
  46. D.N. Fang, W. Lu, and K.C. Hwang, “Pseudoelastic Behavior of CuAlNi Single Crystal under Biaxial Loading,” Metals and Materials, 4, 702-706, 1998.
  47. W. Lu, D.N. Fang, and K.C. Hwang, “A Constitutive Theory for Ferroelectric Ceramics,” Key Engineering Materials, 145, 983-988, 1998.
  48. W. Lu, D.N. Fang, and K.C.Hwang, “Numerical Analysis of Ferroelectric/Ferroelastic Domain Switching in Ferroelectric Ceramics,” Computational Materials Science, 8, 291-308, 1997.
  49. W. Lu, D.N. Fang, and K.C. Hwang, “Nonlinear Evolution of Ferroelectric Domains,” Communications in Nonlinear Science and Numerical Simulation, 2, 30-35, 1997.
  50. M.D. Xue, K.C.Hwang, W. Lu, and W. Chen, “Reinforcement Design Method Based on Analysis of Large Openings in Cylindrical Pressure Vessels,” Journal of Pressure Vessel Technology-Transactions of the ASME, 118, 502-506, 1996.