Chawla Research Group

Publications

Textbooks (2)

  1. N. Chawla and K.K. Chawla, Metal Matrix Composites – 2nd Edition, (2013), Springer, New York, ISBN-13: 978-1461495475.
  2. N. Chawla and K.K. Chawla, Metal Matrix Composites, (2006), Springer, New York, ISBN 0387233067.

Edited Books (1)

  1. K.K. Chawla and N. Chawla, Mechanics of Materials – Measurements and Applications (Vol. 4), Springer, (2015) in preparation.

Encyclopedia/book chapters (10)

  1. K.K. Chawla and N. Chawla, “Metal Matrix Composites,” Encyclopedia of Automotive Engineering, (R. Dashwood, ed.), (2013), John Wiley & Sons, in press.
  2. N. Chawla and J.J. Williams, “Chapter 16: Fracture and Fatigue of Powder Metallurgy Steels,” Advances in Powder Metallurgy, (I. Chang and Y.Y. Zhao, eds.), (2013), Woodhead, pp. 455-490.
  3. K.K. Chawla and N. Chawla, “Thermal Shock of Ceramic Matrix Composites,” Encyclopedia of Thermal Stresses, (R. Hetnarsky, ed.), (2012), Springer.
  4. K.K. Chawla and N. Chawla, “Automotive Composites,” Encyclopedia of Composites (G. Nicolais, ed.), (2012), John Wiley & Sons, Hoboken, New Jersey, ISBN  978-0-470-12828-2.
  5. G.A. Crawford and N. Chawla, “Bioactive TiO2 Nanotube and Hierarchical Coatings on Ti by Anodic Oxidation,” Recent Developments in Advanced Medical and Dental Materials Using Electrochemistry, (2009), Research Signpost, Kerala, India, pp. 177-199.
  6. K.K. Chawla and N. Chawla, “Metal Matrix Composites,” Encyclopedia of Chemical Technology, (2007), 5th Edition, John-Wiley and Sons.
  7. N. Chawla and J.E. Allison, “Fatigue of Particle Reinforced Light Metals,” Concise Encyclopedia of Composite Materials, (A. Mortensen, ed.), (2006), Elsevier Science.
  8. K.K. Chawla and N. Chawla, “Metal Matrix Composites,” Kirk-Othmer Encyclopedia, (2004), John-Wiley and Sons.
  9. K.K. Chawla and N. Chawla, “Processing of Ceramic Matrix Composites,” ASM Handbook: Composites, vol. 21, (2001), ASM International, 2nd Edition, Materials Park, OH, pp. 589-599.
  10. N. Chawla and J.E. Allison, “Fatigue of Particle Reinforced Light Metals,” Encyclopedia of Materials: Science and Technology, vol. 3, (B. Ilschner and P. Lukas, eds.), (2001), Elsevier Science, pp. 2969-2974.

Refereed Journal Publications (182)

  1. C.R. Mayer, N. Li, N. Mara, and N. Chawla, “In situ Shear Testing of Al-SiC Nanolaminate Composites in a Transmission Electron Microscope (TEM),” Mater. Sci. Eng. A, (2014) in preparation.
  2. H. Li, N. Chawla, and Y. Jiao, “X-ray Tomography Reconstructions via Stochastic Optimization of Limited Tomographic Data,” Scripta Mater., (2014) submitted.
  3. N.C. Chapman, J. Silva, J.J. Williams, N. Chawla, and X. Xiao, “Characterization of Thermal Cycling-Induced Cavitation in Particle Reinforced Metal Matrix Composites by Three Dimensional (3D) X-ray Synchrotron Tomography,” Mater. Sci. Tech., (2014) submitted.
  4. J.C.E. Mertens, J.J. Williams, and N. Chawla, “Methods for Noise and Artifact Reduction in High-Energy, Polychromatic, X-ray Computed Tomography,” IEEE Trans. Imaging, (2014) submitted.
  5. P. Hruby, S.S. Singh, J.J. Williams, X. Xiao, F. De Carlo, and N. Chawla, “Fatigue Crack Growth in SiC Particle Reinforced Al Alloy Matrix Composites at High and Low R-ratios by In Situ X-Ray Synchrotron Tomography,” Int. J. Fatigue, (2014) in revision.
  6. S. Lotfian, C. Mayer, N. Chawla, J. LLorca, A. Misra, and J.M. Molina-Aldareguia, “Effect of Layer Thickness on the High Temperature Mechanical Properties of Al/SiC Nanolaminates,” Thin Solid Films, (2014) in revision.
  7. S.S. Singh, J.J. Williams, M.F. Lin, X. Xiao, F. De Carlo, and N. Chawla, “In situ Investigation of High Humidity Stress Corrosion Cracking of 7075 Aluminum Alloy by Three Dimensional (3D) X-ray Synchrotron Tomography,” Mater. Res. Lett., (2014) in press.
  8. E.Y. Guo, S.S. Singh, H. Xie, J.J. Williams, T. Jing, and N. Chawla, “Microstructure-based Modeling of Austenitic-Ferritic Steels based on Constitutive Behavior Obtained by Micropillar Compression,” Steel Res. Int., (2014) in press.
  9. J.J. Williams and N. Chawla, “Fractography of a Neck Failure in a Double-Modular Hip Implant,” Case Studies Engin. Fail. Anal., (2014) 2 45-50.
  10. M.Y. Wang, Y.J. Xu, Q.W. Zheng, S.J. Wu, T. Jing, and N. Chawla, “Dendritic Growth in Mg-based Alloys: Phase Field Simulations and Experimental Verification by X-ray Synchrotron Tomography,” Metall. Mater. Trans., (2014) 45A 2562-2574.
  11. R. Yuan, S.S. Singh, N. Chawla, and J. Oswald, “Efficient Methods for Implicit Geometrical Representation of Complex Material Microstructures,” Int. J. Numer. Meth. Eng., (2014) 98 79-91.
  12. S.S. Singh, R. Sarkar, H.-X. Xie, C. Mayer, J. Rajagopalan, and N. Chawla, “Tensile Behavior of Single Crystal Tin Whiskers,” J. Electr. Mater., (2014) 43 978-982.
  13. S.S. Singh, J.J. Williams, P. Hruby, X. Xiao, F. De Carlo, and N. Chawla, “In situ Experimental Techniques to Study Mechanical Behavior of Materials using X-ray Synchrotron Tomography,” Integr. Mater. Manufac. Innov., (2014) 3 9.
  14. Y. Jiao and N. Chawla, “Three Dimensional (3D) Modeling of Complex Heterogeneous Materials via Statistical Microstructural Descriptors,” Integr. Mater. Manufac. Innov., (2014) 3 3.
  15. S.S. Singh, C. Schwartzstein, J.J. Williams, X. Xiao, F. De Carlo, and N. Chawla, “3D Microstructural Characterization and Mechanical Properties of Constituents Particles in Al 7075 Alloys using X-ray Synchrotron Tomography and Nanoindentation,” J. Alloys Compd., (2014) 602 163-174.
  16. J.C.E. Mertens, J.J. Williams, and N. Chawla, “Development of a Lab-scale, High-Resolution, Tube-Generated X-Ray Computed-Tomography System for Three-Dimensional (3D) Materials Characterization,” Mater. Charac., (2014) 92 36-48.
  17. Y. Jiao and N. Chawla, “Modeling and characterizing anisotropic inclusion orientation in heterogeneous materials via directional cluster functions and stochastic microstructure reconstruction,” J. Appl. Phys., (2014) 115 093511.
  18. E.Y. Guo, N. Chawla, T. Jing, S. Torquato, and Y. Jiao, “Three-Dimensional Reconstruction of Percolating Filamentary Microstructures from Two-Dimensional Micrographs via Dilation-Erosion Method,” Mater. Charac., (2014) 89 33–42.
  19. E.Y. Guo, H.X. Xie, S.S. Singh, A. Kirubanandham, T. Jing, and N. Chawla, “Mechanical Characterization of Microconstituents in a Cast Duplex Stainless Steel by Micropillar Compression,” Mater. Sci. Eng. A, (2014) A598 98-105.
  20. H.X. Xie, D. Friedman, K. Mirpuri, and N. Chawla, “Electromigration Damage Characterization in Sn-3.9Ag-0.7Cu and Sn-3.9Ag-0.7Cu-0.5Ce Solder Joints by Three Dimensional (3D) X-ray Tomography and Scanning Electron Microscopy (SEM),” J. Electron. Mater., (2014) 43 33-42.
  21. J.C.E. Mertens, J.J. Williams, and N. Chawla, “Note: Design and Construction of a Multi-Scale, High-Resolution, Tube-Generated X-Ray Computed-Tomography System for Three-Dimensional (3D) Imaging,” Rev. Sci. Instr., (2014) 85 16103-1—16103-3.
  22. J.J. Williams, K.E. Yazzie, E. Padilla, N. Chawla, X. Xiao, and F. De Carlo, “Understanding Fatigue Crack Growth in Aluminum Alloys by in situ X-ray Synchrotron Tomography,” Int. J. Fatigue, (2013) 57 79-85.
  23. H.X. Xie, L. Jiang, and N. Chawla, “Effect of Cerium Addition on Wetting, Undercooling, and Mechanical Properties of Sn-3.9Ag-0.7Cu Pb-Free Solder Alloys,” J. Mater. Sci.: Mater. Elec., (2013) 24 3456–3466.
  24. E. Padilla, N. Chawla, L.F. Silva, V.R. dos Santos, and S. Paciornik, “Image Analysis of Cracks in the Weld of a Wet Welded Steel Joint by Three Dimensional (3D) X-ray Tomography,” Mater. Charac., (2013) 83 139-144.
  25. E.Y. Guo, M.Y. Wang, T. Jing, and N. Chawla, “Temperature-dependent tensile properties of an austenitic-ferritic stainless steel studied by in situ scanning electron microscopy (SEM),” Mater. Sci. Eng. A, (2013) 580 159–168.
  26. S. Lotfian, M. Rodríguez, K.E. Yazzie, J.M. Molina-Aldareguía, N. Chawla, and J. LLorca, “High Temperature Micropillar Compression of Al/SiC Nanolaminates,” Acta Mater., (2013) 61 4439-4451.
  27. S. Lotfian, J.M. Molina-Aldareguia, K.E. Yazzie, J. LLorca, and N. Chawla, “Mechanical Characterization of Pb-Free Solder and Cu-Sn Intermetallics by High Temperature Nanoindentation,” J. Electron. Mater., (2013) 42 1085-1091.
  28. H.X. Xie and N. Chawla, “Mechanical Shock Behavior of Sn-3.9Ag-0.7Cu and Sn-3.9Ag-0.7Cu-0.5Ce Solder joints,” Microelectro. Reliab., (2013) 53 733–740.
  29. Y. Jiao, E. Padilla, and N. Chawla, “Modeling and Predicting Microstructure Evolution in Lead/Tin Alloy via Correlation Functions and Stochastic Material Reconstruction,” Acta Mater., (2013) 61 3370–3377.
  30. N. Chawla, S.H. Venkatesh, D.R.P. Singh, and T.L. Alford, “Characterization and Adhesion in Cu/Ru/SiO2/Si Multilayered Nanoscale Structure for Cu Metallization,” J. Mater. Eng. Perf., (2013) 22 1085-1090.
  31. H.X. Xie and N. Chawla, “Enhancing the Ductility of Sn-Ag-Cu Pb-Free Solder Joints by the Addition of Compliant Intermetallics,” J. Electron. Mater., (2013) 42 527-536.
  32. T.D. Prichard, B.D. Vogt, S.S. Singh, and N. Chawla, “Flocculated Surfactant Dispersed Carbon Nanotubes to Reduce Solvent Swelling of Soft Templated Microfeatures,” Polymer, (2013) 54 1130-1135.
  33. J.J. Williams, J.L. Walters, M.Y. Wang, N. Chawla, and A. Rohatgi, “Extracting Constitutive Stress-Strain Behavior of Microscopic Phases by Micropillar Compression,” JOM, (2013) 65 226-233.
  34. J.J. Williams, N.C. Chapman, and N. Chawla, “Mechanisms of Sn-Hillock Growth in Vacuum by in situ Nanoindentation in a Scanning Electron Microscope (SEM),” J. Electron. Mater., (2013) 42 224-229.
  35. H. Fei, A. Abraham, N. Chawla, and H. Jiang, “Evaluation of Micro-Pillar Compression Tests for Accurate Determination of Elastic-Plastic Constitutive Relations,” J. Appl. Mech., (2012) 79 061011-1- 061011-9.
  36. K.E. Yazzie, H. Fei, H. Jiang, and N. Chawla, “A Self-Consistent Approach for Necking Correction in Tensile Specimens with Rectangular Cross-section,” Metall. Mater. Trans., (2012) 43 5058-5066.
  37. H.X. Xie, N. Chawla, and K. Mirpuri, “Thermal and Mechanical Stability of Ce-containing Sn-3.9Ag-0.7Cu Solder Alloy on Cu and Electroless Ni-P Metallization,” J. Electron. Mater., (2012) 41 3249-3258.
  38. S.S. Singh, J.J. Williams, Y. Jiao, and N. Chawla, “Modeling Anisotropic Multiphase Heterogeneous Materials via Directional Correlation Functions: Simulations and Experimental Verification,” Metall. Mater. Trans., (2012) 43A 4470-4474.
  39. K.E. Yazzie, J. Topliff, and N. Chawla, “On The Asymmetric Growth Behavior of Intermetallic Compound Layers During Extended Reflow of Sn-rich Alloy on Cu,” Metall. Mater. Trans., (2012) 43 3442-3446.
  40. N. Chawla, P.K. Liaw, E. Lara-Curzio, M.K. Ferber, and R.A. Lowden, “Effect of Fiber Fabric Orientation on the Tensile and Fatigue Behavior of Two Dimensional (2D) Woven Ceramic Matrix Composites,” Mater. Sci. Eng. A, (2012) 557 77–83.
  41. J.J. Williams, J. Segurado, J. LLorca, and N. Chawla, “Three dimensional (3D) Microstructure-Based Modeling of Interfacial Decohesion in Particle Reinforced Metal Matrix Composites (MMCs),” Mater. Sci. Eng. A, (2012) 557 113–118.
  42. Y.-L. Shen, C.B. Blada, J.J. Williams, and N. Chawla, “Cyclic Indentation Behavior of Metal-Ceramic Nanolayered Composites,” Mater. Sci. Eng. A, (2012) 557 119-125.
  43. M.Y. Wang, Y.J. Xu, T. Jing, G.Y. Peng, Y.N. Fu, and N. Chawla, “Three Dimensional (3D) Quantification of Growth Orientations and Morphologies of a-Mg dendrites in Mg–Zn alloys by Combined X-ray Tomography and Electron Backscatter Diffraction,” Scripta Mater., (2012) 67 629–632.
  44. K.E. Yazzie, J.J. Williams, and N. Chawla, “Fracture Behavior of Sn-3.5Ag-0.7Cu and Pure Sn Solders as a Function of Applied Strain Rate,” J. Electron. Mater., (2012) 41 2519-2526.
  45. J. Zhang, Y. An, K.E. Yazzie, N. Chawla, and H. Jiang, “Finite Element Simulation of Swelling-Induced Crack Healing in Gels,” Soft Matter, (2012) 31 8107-8112.
  46. S. Lotfian, J.M. Molina-Aldareguia, K.E. Yazzie, J. LLorca, and N. Chawla, “High Temperature Nanoindentation Behavior of Al/SiC Multilayers,” Phil. Mag. Lett., (2012) 92 362-367.
  47. H. Fei, K.E. Yazzie, N. Chawla, and H. Jiang, “Modeling Fracture of Sn-rich (Pb-free) Solder Joints under Mechanical Shock Conditions,” J. Electron. Mater., (2012) 41 2089-2099.
  48. L. Jiang, H. Jiang, and N. Chawla, “Effect of Crystallographic Orientation on the Mechanical Behavior of Cu6Sn5 Intermetallic by Micropillar Compression,” J. Electron. Mater., (2012) 41 2083-2088.
  49. A. Bonakdar, F. Wang, J.J. Williams, and N. Chawla, “Environmental Effects on Fatigue Crack Growth in 7075 Aluminum Alloy,” Metall. Mater. Trans. A, (2012) 43 2799-2809.
  50. K.E. Yazzie, J.J. Williams, N.C. Phillips, F. De Carlo, and N. Chawla, “Multiscale Microstructural Characterization of Sn-rich Alloys by Three Dimensional (3D) X-ray Synchrotron Tomography and Focused Ion Beam (FIB) Tomography,” Mater. Charac., (2012) 70 33-41.
  51. K.E. Yazzie, H. Fei, H. Jiang, and N. Chawla, “Rate Dependent Behavior of Sn Alloy-Cu Couples: Effects of Microstructure and Composition on Mechanical Shock Resistance,” Acta Mater., (2012) 60 4336–4348.
  52. E. Padilla, V. Jakkali, L. Jiang, and N. Chawla, “Quantifying the Effect of Porosity on the Evolution of Deformation and Damage in Sn-based Solder Joints by X-ray Microtomography and Microstructure-based Finite Element Modeling,” Acta Mater., (2012) 60 4017–4026.
  53. M.Y. Wang, J.J. Williams, L. Jiang, F. De Carlo, T. Jing, and N. Chawla, “Three dimensional (3D) Microstructural Characterization and Quantitative Analysis of Solidified Microstructures in Magnesium Alloys by X-ray Synchrotron Tomography,” Metallography, Microstructure, and Analysis, (2012) 1 7-13 (selected for inclusion in inaugural issue).
  54. K.E. Yazzie, H.X. Xie, J.J. Williams, and N. Chawla, “On the Relationship Between Solder-controlled and Intermetallic Compound (IMC)-controlled Fracture in Sn-Based Solder Joints,” Scripta Mater., (2012) 66 586–589.
  55. K.E. Yazzie, J.J. Williams, and N. Chawla, “Quantifying Necking of Rectangular Tensile Specimens Using a Mirror-based Image Analysis System,” Mater. Lett., (2012) 74 243–246.
  56. J.L. Walters, L. Jiang, J.J. Williams, and N. Chawla, “Prediction of Bulk Tensile Behavior of Dual Phase Stainless Steels Using Constituent Behavior from Micropillar Compression Experiments,” Mater. Sci. Eng. A, (2012) A534 220–227.
  57. H. Fei, K.E. Yazzie, N. Chawla, and H. Jiang, “The Effect of Random Voids in the Modified Gurson Model,” J. Electron. Mater., (2012) 41 177-183 (selected for open access by editor).
  58. D.R.P. Singh and N. Chawla, “Scratch Resistance of Al/SiC Nanolaminates,” J. Mater. Res., (2012) 27 278-283.
  59. J.L. Walters, J.J. Williams, and N. Chawla, “Influence of Thermal Aging on the Microstructure and Mechanical Behavior of Sintered Dual Phase Stainless Steels,” Metall. Mater. Trans., (2012) 43 124-135.
  60. A. Bonakdar, B. Mobasher, and N. Chawla, “Diffusivity and Micro-hardness of Blended Cement Materials Exposed to External Sulfate Attack,” Cement Concrete Compos., (2012) 34 76–85.
  61. J.J. Williams, K.E. Yazzie, N.C. Phillips, N. Chawla, X. Xiao, F. De Carlo, N. Iyyer, and M. Kittur, “On the Correlation Between Fatigue Striation Spacing and Crack Growth Rate: A 3D X-ray Synchrotron Tomography Study,” Metall. Mater. Trans., (2011) 42 3845-3848.
  62. M.Y. Wang, J.J. Williams, L. Jiang, F. De Carlo, T. Jing, and N. Chawla, “Dendritic Morphology of α-Mg in Mg-based alloys: Three dimensional (3D) Experimental Characterization by X-ray Synchrotron Tomography and Phase-field Simulations,” Scripta Mater., (2011) 65 855-858.
  63. J.J. Williams, N.C. Chapman, V. Jakkali, V.A. Tanna, N. Chawla, X. Xiao, and F. De Carlo, “Characterization of Damage Evolution in SiC Particle Reinforced Al Alloy Matrix Composites by in situ X-Ray Synchrotron Tomography,” Metall. Mater. Trans., (2011) 42A 2999-3005.
  64. L. Jiang, N. Chawla, M. Pacheco, and V. Noveski, “Three Dimensional (3D) Microstructural Characterization and Quantification of Reflow Porosity in Sn-rich Alloy Solder Joints by X-ray Tomography,” Mater. Charac., (2011) 62 970-975.
  65. H.X. Xie, N. Chawla, and Y.-L. Shen, “Mechanisms of Deformation in High-Ductility Ce-Containing Sn-Ag-Cu Solder Alloys,” Microelec. Reliab., (2011) 51 1142–1147.
  66. F.E. Danaher, J.J. Williams, D.R.P. Singh, L. Jiang, and N. Chawla, “Tensile and Fatigue Behavior of Al-1Si Wire Used in Wirebonding,” J. Electron. Mater., (2011) 40 1422-1427.
  67. D.R.P. Singh, N. Chawla, G. Tang, and Y.-L. Shen, “Anomalous Viscoplasticity During Nanoindentation of Al/SiC Nanolaminated Composites,” Mater. Sci. Eng. A, (2011) A528 4608–4614.
  68. R. Govindarajan, M. Keswani, S. Siddiqui, S. Raghavan, D.R.P. Singh, and N. Chawla, “Electrochemical Mechanical Removal of Ta Films in Dihydroxybenzene Sulfonic Acid Solutions containing Potassium Iodate,” Electrochem. Solid State Lett., (2011) 14 H156-H160.
  69. H. Fei, K.E. Yazzie, J.J. Williams, N. Chawla, and H. Jiang, “Multiscale Modeling of the Interfacial Fracture Behavior in the Sn-Cu6Sn5-Cu System,” J. Computat. Theor. Nanosci., (2011) 8 873-880.
  70. X. Li, A.B. Larson, L. Jiang, L. Song, T. Prichard, N. Chawla, and B.D. Vogt, “Evolution of mechanical, optical and electrical properties of self-assembled mesostructured phenolic resins during carbonization,” Micropor. Mesopor. Mater., (2011) 138 86-93.
  71. D.R.P. Singh, X. Deng, N. Chawla, J. Bai, C.R. Hubbard, G. Tang, and Y.-L. Shen, “Residual Stress Characterization of Al/SiC Multilayers using X-ray Synchrotron Radiation,” Thin Solid Films, (2010) 519 759-765.
  72. D.R.P. Singh, N. Chawla, G. Tang, and Y.-L. Shen, “Micropillar Compression of Al/SiC Nanolaminated Composites,” Acta Mater., (2010) 58 6628–6636.
  73. F.A. Silva, R.D. Toledo Filho, B. Mobasher, and N. Chawla, “A Multi-scale Investigation of the Mechanical Behavior of Durable Sisal Fiber Cement Composites,” Revista Matéria, (2010) 15 338-344.
  74. J.J. Williams, Z. Flom, A.A. Amell, N. Chawla, X. Xiao, and F. De Carlo, “Damage Evolution in SiC Particle Reinforced Al Alloy Matrix Composites by X-Ray Synchrotron Tomography,” Acta Mater., (2010) 58 6194–6205.
  75. L. Jiang and N. Chawla, “Mechanical Properties of Cu6Sn5 Intermetallic by Micropillar Compression Testing,” Scripta Mater., (2010) 63 480-483.
  76. F.A. Silva, J.J. Williams, B.R. Mueller, M.P. Hentschel, P.D. Portella, and N. Chawla, “3D Microstructure Visualization of Inclusions and Porosity in SiC Particle Reinforced Al Matrix Composites by X-Ray Synchrotron Tomography,” Metall. Mater. Trans., (2010) 41A 2121-2128.
  77. K.E. Yazzie, J.J. Williams, D. Kingsbury, P. Peralta, H. Jiang, and N. Chawla, “Analysis of the Deformation Behavior of Pb-free Solders at Intermediate Strain Rates by Digital Image Correlation (DIC),” JOM, (2010) 62 [7] 18-23.
  78. F.A. Silva, N. Chawla, and R.D. Toledo Filho, “Mechanical Behavior of Natural Sisal Fibers,” J. Biobased Mater. Bioenergy, (2010) 4 106–113.
  79. M.A. Dudek and N. Chawla, “Nanoindentation of Rare Earth-Sn Intermetallics in Pb-Free Solders,” Intermetall., (2010) 18 1016-1020.
  80. D.R.P. Singh, N. Chawla, and Y.-L. Shen, “Focused Ion Beam (FIB) Tomography of Nanoindentation Damage in Nanoscale Metal/Ceramic Multilayers,” Mater. Charac., (2010) 61 481–488.
  81. M.A. Dudek, L. Hunter, S. Kranz, J.J. Williams, S.H. Lau, and N. Chawla, “Three-Dimensional (3D) Visualization of Reflow Porosity by X-Ray Tomography and Image-Based Finite Element Modeling of Deformation in Pb-free Solder Joints,” Mater. Charac., (2010) 61 433–439.
  82. M.A. Dudek and N. Chawla, “The Effect of Rare Earth (La, Ce, and Y) Additions on the Microstructure and Mechanical Behavior of Sn-3.9Ag-0.7Cu Solder Alloy,” Metall. Mater. Trans., (2010) 41A 610-620.
  83. P.L. Sun, J.P. Chu, T.Y. Lin, Y.-L. Shen, and N. Chawla, “Characterization of Nanoindentation Damage in Metal/Ceramic Nanolaminate Composites by Transmission Electron Microscopy (TEM),” Mater. Sci. Eng. A, (2010) A527 2985–2992.
  84. G. Tang, Y.-L. Shen, D.R.P. Singh, and N. Chawla, “Indentation Analysis of Metal-Ceramic Multilayers at the Nanoscale: Numerical Analysis and Experimental Verification,” Acta Mater., (2010) 58 2033–2044.
  85. N. Chawla and V.V. Ganesh, “Fatigue Crack Growth Behavior of SiC Particle Reinforced Metal Matrix Composites,” Int. J. Fatigue, (2010) 32 856–863.
  86. K.E. Yazzie, H. Fei, J.J. Williams, H. Jiang, and N. Chawla, “Mechanical Shock Behavior of Bulk Pure Sn Solder,” J. Electron. Mater., (2009) 38 2746-2755.
  87. N. Chawla, “Thermomechanical Behaviour of Environmentally-Benign Pb-free Solders,” Int. Mater. Rev. (commissioned review article), (2009) 54 368-384.
  88. G.A. Crawford, N. Chawla, and J.E. Houston, “Nanomechanics of Biocompatible TiO2 Nanotubes by Interfacial Force Microscopy (IFM),” J. Mech. Behav. Biomed. Mater., (2009) 2 580-587.
  89. M.A. Dudek and N. Chawla, “Mechanisms of Sn Whisker Growth in Rare-Earth (RE) Containing Pb-free Solders,” Acta Mater., (2009) 57 4588-4599.
  90. F.A. Silva, N. Chawla, and R.D. Toledo Filho, “An Experimental Investigation of the Fatigue Behavior of Sisal Fibers,” Mater. Sci. Eng. A, (2009) A516 90–95.
  91. G.A. Crawford, N. Chawla, and J. Ringnalda, “Processing and Microstructure Characterization of a Novel Porous Hierarchical TiO2 Nanostructure,” J. Mater. Res., (2009) 24 1683-1687.
  92. N. Chawla, J.J. Williams, X. Deng, C. McClimon, L. Hunter, and S.H. Lau, “Three Dimensional (3D) Characterization and Modeling of Porosity in Powder Metallurgy (P/M) Steels,” Int. J. Powder Metall., (2009) 45 19-27.
  93. A. Goel, K.K. Chawla, U.K. Vaidya, N. Chawla, and M. Koopman, “Fatigue Behavior of Long Fiber Reinforced Thermoplastic (LFT) Composites,” Mater. Charac., (2009) 60 537–544.
  94. G.A. Crawford and N. Chawla, “Tailoring TiO2 Nanotube Growth during Anodic Oxidation by Crystallographic Orientation of Ti,” Scripta Mater., (2009) 60 874–877.
  95. S.M. Hayes, N. Chawla, and D.R. Frear, “Interfacial Fracture Toughness of Sn-Rich Solder Joints,” Microelec. Reliab., (2009) 49 269–287.
  96. A. Rinaldi, P. Peralta, C. Friesen, N. Chawla, E. Traversa, and K. Sieradzki, “Localized Compression and Shear Tests on Nanotargets with a Berkovitch Tip and a Novel Multifunctional Tip,” J. Mater. Res., (2009) 24 768-775.
  97. G.A. Crawford, N. Chawla, M. Koopman, K. Carlisle, and K.K. Chawla, “Effect of Mounting Material Compliance on Nanoindentation Response of Metallic Materials,” Adv. Eng. Mater., (2009) 11 45-51.
  98. J.P. Coughlin, J.J. Williams, and N. Chawla, “Mechanical Behavior of NiTi Shape Memory Alloy Fiber Reinforced Sn Matrix ‘Smart’ Composites,” J. Mater. Sci., (2009) 44 700-707.
  99. G. Tang, D.R.P. Singh, Y.-L. Shen, and N. Chawla, “Analysis of Elastic Behavior of Metal-Ceramic Multilayered Composites by Nanoindentation,” Mater. Sci. Eng. A, (2009) A502 79-84.
  100. M.A. Dudek and N. Chawla, “Oxidation Behavior of Rare-Earth Containing Sn-rich Solders,” J. Electron. Mater., (2009) 38 210-220 (selected for open access by editors).
  101. G.A. Crawford and N. Chawla, “Porous Hierarchical TiO2 Nanostructures: Processing and Microstructure Relationships,” Acta Mater., (2009) 57 854–867.
  102. J.P. Coughlin, J.J. Williams, G.A. Crawford, and N. Chawla, “Interfacial Reactions in Model NiTi Shape Memory Alloy Fiber Reinforced Sn Matrix ‘Smart’ Composites,” Metall. Mater. Trans., (2009) 40 176-184 (selected for open access by editors).
  103. G. Tang, Y.-L. Shen, D.R.P. Singh, and N. Chawla, “Analysis of Indentation-Derived Effective Elastic Modulus of Metal-Ceramic Multilayers,” Int. J. Mech. Mater. Design, (2008) 391-398.
  104. G. Tang, Y.-L. Shen, and N. Chawla, “Plastic Deformation During Indentation Unloading of Layered Materials at the Nanoscale,” J. Appl. Phys., (2008) 104 116102-1—116102-3.
  105. F.A. Silva, N. Chawla, and R.D. Toledo Filho, “Tensile Behavior of High Performance Natural (Sisal) Fibers,” Compos. Sci. Tech., (2008) 68 3438-3443.
  106. A. Ayyar, G.A. Crawford, J.J. Williams, and N. Chawla, “Numerical simulation of the effect of particle spatial distribution and strength on tensile behavior of particle reinforced composites,” Computat. Mater. Sci., (2008) 44 496-506.
  107. X. Deng and N. Chawla, “Three Dimensional (3D) Modeling of the Thermoelastic Behavior of Woven Glass Fiber Reinforced Resin Matrix Composites,” J. Mater. Sci., (2008) 43 6468-6472.
  108. A. Goel, K.K. Chawla, U.K. Vaidya, N. Chawla, and M. Koopman, “Two Dimensional Microstructure-based Modeling of Young’s Modulus of a Long Fiber Thermoplastic Composite,” Mater. Sci. Tech., (2008) 24 864-869.
  109. M.A. Dudek and N. Chawla, “Three-dimensional (3D) Microstructure Visualization of LaSn3 Intermetallics in a Novel Sn-rich Rare-Earth Containing Solder,” Mater. Charac., (2008) 59 1364-1368.
  110. X. Deng, G.B. Piotrowski, N. Chawla, and K.S. Narasimhan, “Fatigue Crack Growth Behavior of Hybrid and Prealloyed Sintered Steels, Part I: Microstructure Characterization,” Mater. Sci. Eng. A, (2008) A491 19-27.
  111. X. Deng, G.B. Piotrowski, N. Chawla, and K.S. Narasimhan, “Fatigue Crack Growth Behavior of Hybrid and Prealloyed Sintered Steels, Part II: Fatigue Behavior,” Mater. Sci. Eng. A, (2008) A491 28-38.
  112. N. Chawla, D.R.P. Singh, Y.-L. Shen, G. Tang, and K.K. Chawla, “Indentation Mechanics and Fracture Behavior of Metal/Ceramic Nanolaminate Composites,” J. Mater. Sci., (2008) 43 4383-4390.
  113. R.S. Sidhu and N. Chawla, “Thermal Fatigue Behavior of Sn-Rich (Pb-free) Solders,” Metall. Mater. Trans., (2008) 39A 799-810.
  114. R.S. Sidhu and N. Chawla, “Microstructure Characterization and Creep Behavior of Sn-rich Solder Alloys, Part I: Microstructure Characterization,” Metall. Mater. Trans., (2008) 39A 340-348.
  115. R.S. Sidhu, X. Deng, and N. Chawla, “Microstructure Characterization and Creep Behavior of Sn-rich Solder Alloys, Part II: Creep Behavior,” Metall. Mater. Trans., (2008) 39A 349-362.
  116. R.S. Sidhu, S.V. Madge, X. Deng, and N. Chawla, “On the Nature of the Interface Between Ag3Sn Intermetallics and Sn in Sn-3.5Ag Solder Alloys,” J. Electron. Mater., (2007) 36 1615-1620.
  117. A. Ayyar and N. Chawla, “Microstructure-Based Modeling of the Influence of Particle Spatial Distribution and Fracture on Crack Growth in Particle Reinforced Composites,” Acta Mater., (2007) 55 6064-6073.
  118. A. Ayyar and N. Chawla, “Three-dimensional (3D) microstructure-based modeling of crack growth in particle reinforced composites,” J. Mater. Sci., (2007) 42 9125-9129.
  119. J.J. Williams, X. Deng, and N. Chawla, “Effect of Residual Surface Stress on the Fatigue Behavior of a Low-Alloy Powder Metallurgy Steel,” Int. J. Fatigue, (2007) 29 1978–1984.
  120. G.A. Crawford, N. Chawla, K. Das, S. Bose, and A. Bandyopadhyay, “Microstructure and Deformation Behavior of Bioactive TiO2 Coatings,” Acta Biomater., (2007) 3 359-367.
  121. N. Chawla and R.S. Sidhu, “Microstructure-Based Modeling of Deformation in Pb-free Solders,” J. Mater. Sci. – Materials in Electronics, Special Issue on Pb-free Solders, (2007) 18 175-189.
  122. M.A. Dudek, R.S. Sidhu, N. Chawla, and M. Renavikar, “Microstructure and Mechanical Behavior of Novel Rare Earth-Containing Pb-free Solders,” J. Electron. Mater., (2006) 35 2088-2097.
  123. N. Chawla and K.K. Chawla, “Metal Matrix Composites in Ground Transportation,” JOM, (2006) 11 65-68.
  124. X. Deng and N. Chawla, “Modeling the Effect of Particle Clustering on the Mechanical Behavior of SiC Particle Reinforced Al Matrix Composites,” J. Mater. Sci., (2006) 41 5731-5734.
  125. A. Ayyar and N. Chawla, “Microstructure-based Modeling of Crack Growth in Particle Reinforced Composites,” Compos. Sci. Tech., (2006) 66 1980-1994.
  126. N. Chawla, “Metal Matrix Composites in Automotive Applications,” Adv. Mater. & Processes, July, (2006) 29-31.
  127. N. Chawla, X. Deng, and D.R.M. Schnell, “Thermal Expansion Anisotropy of Extruded SiC Particle Reinforced 2080 Aluminum Matrix Composites,” Mater. Sci. Eng., (2006) 426A 314-322.
  128. M.A. Dudek, R.S. Sidhu, and N. Chawla, “Novel Rare-Earth Containing Pb-free Solders with Enhanced Ductility,” JOM, (2006) 6 57-62.
  129. R.S. Sidhu and N. Chawla, “Three-Dimensional (3D) Visualization and Microstructure-Based Modeling of Deformation in a Sn-rich Solder,” Scripta Mater., (2006) 54 1627-1631.
  130. N. Chawla and K.K. Chawla, “Microstructure-Based Modeling of Deformation in Particle Reinforced Metal Matrix Composites,” J. Mater. Sci. – 40th Anniversary Issue (1966-2006), (2006) 41 913-925.
  131. N. Chawla, R.S. Sidhu, and V.V. Ganesh, “Three Dimensional (3D) Visualization and Microstructure-Based Finite Element Modeling of Particle Reinforced Composites,” Acta Mater., (2006) 54 1541-1548.
  132. X. Deng, N. Chawla, K.K. Chawla, M. Koopman, and J.P. Chu, “Mechanical Behavior of Multilayered Nanoscale Metal-Ceramic Composites,” Adv. Eng. Mater., (2005) 7 1099-1108.
  133. X. Deng, G.B. Piotrowski, J.J. Williams, and N. Chawla, “Effect of Porosity and Tension-Compression Asymmetry on the Bauschinger Effect in Porous Sintered Steels,” Int. J. Fatigue, (2005) 27 1233-1243.
  134. X. Deng, C. Cleveland, T. Karcher, M. Koopman, N. Chawla, and K.K. Chawla, “Nanoindentation of Nanolayered Metal-Ceramic Composites,” J. Mater. Eng. Perf., (2005) 14 417-423.
  135. Y.-L. Shen, N. Chawla, E.S. Ege, and X. Deng, “Deformation Analysis of Lap Shear Testing of Solder Joints,” Acta Mater., (2005) 53 2633-2642.
  136. M. Kerr, N. Chawla, and K.K. Chawla, “Cyclic Fatigue of High Performance Fibers,” JOM, (2005) 2 67-70.
  137. N. Chawla, G.B. Piotrowski, X. Deng, K.S. Narasimhan, and M.L. Marucci, “Fatigue crack growth of Fe-0.85Mo-2Ni-0.6C steels with a heterogeneous microstructure,” Int. J. Powder Metall., (2005) 41 31-41.
  138. N. Chawla, M. Kerr, and K.K. Chawla, “Monotonic and Cyclic Fatigue Behavior of High Performance Ceramic Fibers,” J. Am. Ceram. Soc., (2005) 88 101-108.
  139. X. Deng, R.S. Sidhu, P. Johnson, and N. Chawla, “Influence of Reflow and Thermal Aging on the Shear Strength and Fracture Behavior of Sn-3.5Ag Solder/Cu Joints,” Metall. Mater. Trans., (2005) 36A 55-64.
  140. V.V. Ganesh and N. Chawla, “Effect of Particle Orientation Anisotropy on the Tensile Behavior of Metal Matrix Composites: Experiments and Microstructure-Based Simulation,” Mater. Sci. Eng., (2005) A391 342-353.
  141. N. Chawla and X. Deng, “Microstructure and Mechanical Behavior of Porous Sintered Steels,” Mater. Sci. Eng., (2005) A390 98-112.
  142. F. Ochoa, X. Deng, and N. Chawla, “Effects of Cooling Rate on Creep Behavior of a Sn-3.5Ag Alloy,” J. Electron. Mater., (2004) 33 1596-1607.
  143. N. Chawla, Y.-L. Shen, X. Deng, and E.S. Ege, “An Evaluation of the Lap-Shear Test for Sn-rich Solder/Cu Couples: Experiments and Simulation,” J. Electron. Mater., (2004) 33 1589-1595.
  144. M. Kerr and N. Chawla, “Creep Deformation Behavior of a Sn-3.5Ag Solder/Cu Couple at Small Length Scales,” Acta Mater., (2004) 52 4527-4535.
  145. X. Deng, G. Piotrowski, N. Chawla, and K.S. Narasimhan, “Effect of Pore Clustering on the Mechanical Behavior of Powder Metallurgy (P/M) Steels,” P/M Sci. Tech. Briefs, (2004) 6 5-9.
  146. R.S. Sidhu and N. Chawla, “Three-Dimensional (3D) Microstructure Characterization of Ag3Sn Intermetallics in Sn-rich Solder by Serial Sectioning,” Mater. Charac., (2004) 52 225-230.
  147. X. Deng, N. Chawla, K.K. Chawla, and M. Koopman, “Deformation Behavior of (Cu, Ag)-Sn Intermetallics by Nanoindentation,” Acta Mater., (2004) 52 4291-4303.
  148. N. Chawla, V.V. Ganesh, and B. Wunsch, “Three-Dimensional (3D) Microstructure Visualization and Finite Element Modeling of the Mechanical Behavior of SiC Particle Reinforced Aluminum Composites,” Scripta Mater., (2004) 51 161-165.
  149. M. Kerr and N. Chawla, “Creep Deformation Behavior of a Sn-3.5Ag Solder at Small-Length Scale,” JOM, (2004) 56 50-54.
  150. N. Chawla, F. Ochoa, V.V. Ganesh, X. Deng, M. Koopman, K.K. Chawla, and S. Scarritt, “Measurement and Prediction of Young’s Modulus of a Pb-free Solder,” J. Mater. Sci.-  Mater. Elect., (2004) 15 385-388.
  151. X. Deng, M. Koopman, N. Chawla, and K.K. Chawla, “Young’s Modulus of (Cu, Ag)-Sn Intermetallics Measured by Nanoindentation,” Mater. Sci. Eng., (2004) 364 240-243.
  152. V.V. Ganesh and N. Chawla, “Effect of Particle Orientation Anisotropy on the Tensile and Fatigue Behavior of Metal Matrix Composites,” Metall. Mater. Trans., (2004) 35A 53-62.
  153. F. Ochoa, J.J. Williams, and N. Chawla, “Effects of Cooling Rate on the Microstructure and Tensile Behavior of a Sn-3.5wt.% Ag Solder,” J. Electron. Mater., (2003) 32 1414-1420.
  154. X. Deng, G. Piotrowski, J.J. Williams, and N. Chawla, “Influence of Initial Morphology and Thickness on Growth and Evolution of Cu6Sn5 and Cu3Sn Intermetallics During Thermal Aging of Sn-Ag Solder/Cu Joints,” J. Electron. Mater., (2003) 32 1403-1413.
  155. N. Chawla, B.V. Patel, M. Koopman, K.K. Chawla, R. Saha, B.R. Patterson, E.R. Fuller, and S.A. Langer, “Microstructure-Based Simulation of Thermomechanical Behavior of Composite Materials by Object Oriented Finite (OOF) Element Analysis,” Mater. Charac., (2003) 49 395-407.
  156. F. Ochoa, J.J. Williams, and N. Chawla, “Effect of Cooling Rates on Microstructure and Mechanical Behavior of Sn-3.5Ag Solder,” JOM, (2003) 55 56-60.
  157. N. Chawla, B. Jester, and D.T. Vonk, “Bauschinger Effect in Porous Sintered Steels,” Mater. Sci. Eng. A, (2003) A346 266-272.
  158. J.J. Williams, G. Piotrowski, R. Saha, and N. Chawla, “Effect of Over-aging and Particle Size on Tensile Deformation and Fracture of Particle Reinforced Aluminum Matrix Composites,” Metall. Mater.Trans., (2002) 33A 3861-3869.
  159. N. Chawla, J.J. Williams, and R. Saha, “Mechanical Behavior and Microstructure Characterization of Sinter-Forged SiC Particle Reinforced Aluminum Matrix Composites,” J. Light Metals, (2002) 2 215-227.
  160. R. Saha, E. Morris, N. Chawla, and S.M. Pickard, “Hybrid and Conventional Particle Reinforced Metal Matrix Composites by Squeeze Infiltration Casting,” J. Mater. Sci. Lett., (2002) 21 337-339.
  161. S.J. Polasik, J.J. Williams, and N. Chawla, “Fatigue Crack Initiation and Propagation in Binder-treated Powder Metallurgy Steels,” Metall. Mater. Trans., (2002) 33A 73-81.
  162. N. Chawla, K.K. Chawla, M. Koopman, B. Patel, C.C. Coffin, and J.I. Eldridge, “Thermal-Shock Behavior of a Nicalon-Fiber-Reinforced Hybrid Glass-Ceramic Composite,” Comp. Sci. Tech., (2001) 61 1923-1930.
  163. Y.-L. Shen, J.J. Williams, G. Piotrowski, N. Chawla, and Y.L. Guo, “Correlation between Tensile and Indentation Behavior of Particle-Reinforced Metal Matrix Composites: an Experimental and Numerical Study,” Acta Mater., (2001) 49 3219-3229.
  164. N. Chawla and Y.-L. Shen, “Mechanical Behavior of Particle Reinforced Metal Matrix Composites,” Adv. Eng. Mater., (2001) 3 357-370.
  165. N. Chawla, S. Polasik, K.S. Narasimhan, T. Murphy, M. Koopman, and K.K. Chawla, “Fatigue Behavior of Binder-Treated Powder Metallurgy Steels,” Int. J. Powder Metall., (2001) 37 49-57.
  166. N. Chawla, T.F. Murphy, K.S. Narasimhan, M. Koopman, and K.K. Chawla, “Axial Fatigue Behavior of Binder-treated versus Diffusion Alloyed Powder Metallurgy Steels,” Mater. Sci. Eng. A, (2001) A308 180-188.
  167. E. Carreno-Morelli, N. Chawla, and R. Schaller, “Thermo-mechanical Characterization of 2080 Al/SiCp Composites by Mechanical Spectroscopy Technique,” J. Mater. Sci. Lett., (2001) 20 163-165.
  168. Y.-L. Shen and N. Chawla, “On the Correlation Between Hardness and Tensile Strength in Particle Reinforced Metal Matrix Composites,” Mater. Sci. Eng. A, (2001) A297 44-47.
  169. N. Chawla, L.C. Davis, C. Andres, J.E. Allison, J.W. Jones, “The Interactive Role of Inclusions and SiC Reinforcement on the High Cycle Fatigue Resistance of Particle Reinforced Metal Matrix Composites,” Metall. Mater. Trans., (2000) 31A 951-957.
  170. N. Chawla, U. Habel, Y.-L. Shen, C. Andres, J.W. Jones, and J.E. Allison, “Effect of Matrix Microstructure on the Fatigue Behavior of SiC Particle Reinforced 2080 Al Matrix Composites,” Metall. Mater. Trans., (2000) 31A 531-540.
  171. Y.-L. Shen, E. Fishencord, and N. Chawla, “Correlating Macrohardness and Tensile Behavior in Discontinuously Reinforced Metal Matrix Composites,” Scripta Mater., (2000) 42 427-432.
  172. A.B. Pandey and N. Chawla, “Fracture Toughness and Fatigue of Discontinuously Reinforced Aluminum (DRA),” JOM, (1999) 51 69-72.
  173. N. Chawla, C. Andres, J.W. Jones, and J.E. Allison, “The Effect of Reinforcement Volume Fraction and Particle Size on the Fatigue Behavior of an Aluminum Alloy/SiC Composite,” Ind. Heating, (1999) 66 61.
  174. N. Chawla, C. Andres, J.W. Jones, and J.E. Allison, “Effect of Reinforcement Volume Fraction and Particle Size on the Fatigue Behavior of SiC Particle Reinforced Al 2080 Matrix Composites,” Metall. Mater. Trans., (1998) 29A 2843.
  175. N. Chawla, C. Andres, J.W. Jones, and J.E. Allison, “Cyclic Stress-Strain Behavior of Discontinuously Reinforced Metal Matrix Composites,” Scripta Mater., (1998) 38 1595-1600.
  176. N. Chawla, Y.K. Tur, J.W. Holmes, J.R. Barber, and A. Szweda, “The High Frequency Fatigue Behavior of a Woven Fiber Fabric Reinforced Polymer-Derived Ceramic Matrix Composite,” J. Am. Ceram. Soc., (1998) 81 [5] 1221.
  177. N. Chawla, “Effect of Laminate Stacking Sequence on the High Frequency Fatigue Behavior of SCS-6 Fiber Reinforced Si3N4 Matrix Composites,” Metall. Mater. Trans., (1997) 28A 2423.
  178. N. Chawla, J.W. Holmes, and R.A. Lowden, “The Role of Interfacial Coatings on the High Frequency Fatigue Behavior of Nicalon/C/SiC Composites,” Scripta Mater., (1996) 35 1411.
  179. N. Chawla, J.W. Holmes, and J.F. Mansfield, “Surface Roughness Characterization of NicalonTM and HI-NicalonTM Ceramic Fibers by Atomic Force Microscopy,” Mater. Charac., (1995) 35 199.
  180. Z.R. Xu, K.K. Chawla, A. Wolfenden, A. Neuman, G.M. Liggett, and N. Chawla, “Stiffness Loss and Density Decrease due to Thermal Cycling in an Alumina Fiber/Magnesium Alloy Composite,” Mater. Sci. Eng. A, (1995) A203 75.
  181. N.N. Thadhani, N. Chawla, and W. Kibbe, “Explosive Shock Consolidation of Titanium Aluminides,” J. Mater. Sci., (1991) 26 231.
  182. Z. Iqbal, N.N. Thadhani, N. Chawla, B.L. Ramakrishna, R. Sharma, K.V. Rao, F. Reindinger, and H. Eckhardt,  “Shock‑wave Synthesis of a Thallium‑Based Superconductor with a Novel Defect Microstructure,” App. Phys. Lett., (1989) 55 1553.

Conference Proceedings (45)

  1. F. De Carlo, X. Xiao, K. Fezzaa, S. Wang, N. Chawla, C. Jacobsen, F. Fusseis, “Challenges in Data Intensive Science at Synchrotron Based 3D X-Ray Imaging Facilities,” TMS 2013 Conf. Prof., (2013).
  2. S.S. Singh, J.J. Williams, X. Xiao, F. De Carlo, and N. Chawla, “In situ Three Dimensional (3D) X-ray Synchrotron Tomography of Corrosion-Fatigue in Al 7075 Alloy,” Fatigue of Materials: Advances and Emergences in Understanding II, T.S. Srivatsan, M.A. Imam, eds., (2012), Wiley pp. 17-25.
  3. H. Xie, N. Chawla, Y.-L. Shen, K. Mirpuri, and A. Aleksov, “Rare Earth-containing Solders with Enhanced Ductility and Mechanical Shock Resistance,” TECHCON, Semiconductor Research Corporation, (2011).
  4. F. Wang, J.J. Williams, and N. Chawla, “Environmental Effects on Fatigue Crack Growth in 7075 Aluminum Alloy,” Fatigue of Materials: Advances and Emergences in Understanding, T.S. Srivatsan and M.A. Imam, eds., (2010), Wiley, 29-41.
  5. F. De Carlo, X. Xiao, F. Fusseis, and N. Chawla, “In-situ dynamics at the Advanced Photon Source X-ray Imaging beamlines,” 31st Risø International Symposium on Materials Science: Challenges in materials science and possibilities in 3D and 4D characterization techniques, Risø National Laboratory, (2010).
  6. J.L. Walters, J.J. Williams, N. Chawla, C. Schade, T. Murphy, and K.N. Narasimhan, “Influence of Aging on the Microstructure and Mechanical Properties of a Dual Phase Powder Metallurgy (P/M) Steel,” Powdermet 2009, (2009), MPIF, Princeton, NJ, 1-6.
  7. F.A. Silva, J.J. Williams, N. Chawla, B.R. Mueller, M.P. Hentschel, and P.D. Portella, “3D Microstructure Visualization of SiC Particle Reinforced Al Matrix Composites by X-Ray Synchrotron Tomography,” Proc. of International Conference on Composite Materials (ICCM-17), (2009), IOM, London, England.
  8. K.K. Chawla, P.-L. Sun, T.-Y. Lin, J.P. Chu, D.R.P. Singh, N. Chawla, and Y.-L. Shen, “Deformation Mechanisms During Indentation of Nanoscale Metallic/Ceramic Laminated Composites,” Proc. of International Conference on Composite Materials (ICCM-17), (2009), IOM, London, England.
  9. N. Chawla and D.R.P. Singh, “Three Dimensional (3D) Visualization of Damage in Metal-Ceramic Nanolayers by Focused Ion Beam (FIB) Serial Sectioning,” Microscopy and Microanalysis 2008, vol. 14, Cambridge University Press, (2008) 140-141.
  10. N. Chawla and K.K. Chawla, “Microstructure-Based Finite Element Modeling of Particle Reinforced Metal Matrix Composites,” International Conference on Composite Materials, ICCM-16, (2007).
  11. A. Goel, K.K. Chawla, U.K. Vaidya, and N. Chawla, “Fatigue Behavior of Long Fiber Reinforced Thermoplastic (LFT) Composites,” Global Advances in Material and Process Engineering, (2007), SAMPE.
  12. N. Chawla and K.K. Chawla, “Modeling of Particle Reinforced Metal Matrix Composites Using Actual Microstructures,” Global Advances in Material and Process Engineering, (2006), SAMPE.
  13. R.S. Gorur, N. Chawla, J. Hunt, and M. Dyer, “Mechanical and electrical issues concerning the use of composite materials for the supporting core in transmission line conductors,” IEEE Conference on Electrical Insulation and Dielectric Phenomena, (2006).
  14. J.J. Williams, X. Deng, N. Chawla, B. Lindsley, P. King, and K.S. Narasimhan, “Effects of Residual Surface Stress and Tempering on the Fatigue Behavior of Ancorsteel 4300,” Powdermet 2006, (2006), Metal Powder Industries Federation, 1-9.
  15. N. Chawla and K.K. Chawla, “What’s New in Finite Element Modeling of Particle Reinforced Metal Matrix Composites?,” Proc. Rohatgi Honorary Symposium, (2006), TMS, Warrendale, PA.
  16. X. Deng, N. Chawla, F. Tang, I.E. Anderson, and B. Glesson, “Effect of Particle Clustering on the Fatigue Behavior of SiC Particle Reinforced Al Matrix Composites,” Proc. of Materials Science and Technology 2005, (2005), TMS, Warrendale, PA.
  17. N. Chawla and M. Kerr, “Elevated Temperature Cyclic Fatigue of High Performance Al2O3 Fibers,” Proc. of Materials Science and Technology 2005, (2005), TMS, Warrendale, PA.
  18. N. Chawla and V.V. Ganesh, “Three-Dimensional (3D) Microstructure Visualization and Finite Element Modeling of the Mechanical Behavior of Heterogeneous Materials,” International Congress on Fracture, (2005) 1-6.
  19. X. Deng, G.B. Piotrowski, N. Chawla, K.S. Narasimhan, and M. Marucci, “Fatigue Crack Growth of Prealloy Fe-0.85Mo-2Ni-0.6C Steels with a Homogeneous Microstructure,” Adv. Powder Metall. Part. Mater., (2005), Metal Powder Industries Federation, 1-13.
  20. N. Chawla, K.K. Chawla, and B. Turcic, “An Evaluation of Fatigue Behavior of High Performance Ceramic Fibers,” Proc. of Reinforced Plastics XXIII, (2005), pp. 199-204.
  21. G. Piotrowski, X. Deng, N. Chawla, and K.S. Narasimhan, “Fatigue crack growth of sintered steels with a heterogeneous microstructure,” World Powder Metallurgy Congress, (2004), European Powder Metallurgy Association, 1-6.
  22. G. Piotrowski, X. Deng, N. Chawla, K.S. Narasimhan, and M. Marucci, “Fatigue crack growth of Fe-0.85Mo-2Ni-0.6C steels with a heterogeneous microstructure,” Adv. Powder Metall. Part. Mater., (2004), Metal Powder Industries Federation, 1-12.
  23. B. Wunsch, X. Deng, and N. Chawla, “3D Microstructure Visualization and Modeling of the Mechanical Behavior of SiC Particle Reinforced Aluminum Composites,” Computational Methods in Materials Characterisation, (A.A. Mammoli and C.A. Brebbia, eds.), (2004), WIT Press, Boston, pp. 175-184.
  24. N. Chawla, X. Deng, M. Marucci, and K.S. Narasimhan, “Effect of Porosity on the Microstructure and Mechanical Properties of Powder Metallurgy Fe-Mo-Ni Steels,” in Automotive Fatigue Design & Applications, (2003), Metal Powder Industries Federation, pp. 177-189.
  25. M.L. Marucci, K.S. Narasimhan, G. Fillari, N. Chawla, and V.V. Ganesh, “Axial Fatigue Properties of Silicon Containing P/M Steels,” in Automotive Fatigue Design & Applications, (2003), Metal Powder Industries Federation, pp. 68-76.
  26. N. Chawla, X. Deng, M. Marucci, and K.S. Narasimhan, “Effect of Porosity on the Microstructure and Mechanical Behavior of Powder Metallurgy Fe-Mo-Ni Steels,” Adv. Powder Metall. Part. Mater., (2003), Metal Powder Industries Federation.
  27. N. Chawla, M. Kerr, and K.K. Chawla, “Tensile and Fatigue Behavior of High Performance Ceramic Fibers,” International Conference on Composite Materials (ICCM-14), (2003), Society of Manufacturing Engineers.
  28. N. Chawla, “Fatigue and Durability of Particle Reinforced Metal Matrix Composites,” Adv. Powder Metall. Part. Mater., (2002), vol. 5, Metal Powder Industries Federation, p. 82.
  29. N. Chawla, D. Babic, J.J. Williams, S.J. Polasik, M. Marucci, and K.S. Narasimhan,  “Effect of Ni and Cu Alloying Additions on the Tensile and Fatigue Behavior of Sintered Steels,” Adv. Powder Metall. Part. Mater., (2002), vol. 5, Metal Powder Industries Federation, p. 104.
  30. M. Kerr, J.J. Williams, N. Chawla, and K.K. Chawla, “Monotonic and Cyclic Fatigue Behavior of a High Performance Ceramic Fiber,” Advanced Fibers, Plastics, Laminates and Composites, (F.T. Wallanberger, N. Weston, K.K. Chawla, R. Ford, and R.P. Wool, eds.), vol. 702, Materials Research Society, Boston, MA, (2002), pp. 223-228.
  31. N. Chawla, J.J. Williams, G. Piotrowski, and R. Saha, “Tensile and Fatigue Fracture of Discontinuously Reinforced Aluminum (DRA),” Advances in Fracture Research, (K. Ravi-Chandar, B.L. Karihaloo, T. Kishi, R.O. Ritchie, A.T. Yokobori, and T. Yokobori, eds.), (2001) 1-6.
  32. E. Carreño-Morelli, R. Schaller, N. Chawla, and O. Beffort, “Damping Evolution During Thermal Cycling of SiC Particle Reinforced Metal Matrix Composites,” Euromat 2001, (2001).
  33. S.J. Polasik, J.J. Williams, N. Chawla, and K.S. Narasimhan, “Fatigue Crack Initiation and Propagation in Ferrous Powder Metallurgy Alloys,” Adv. Powder Metall. Part. Mater., (W. Eisen and S. Kassam, eds.), (2001), vol. 10, Metal Powder Industries Federation, pp. 172-187.
  34. N. Chawla, S. Wu, R.J. Fields, and G.T. Campbell, “Processing Effects on Mechanical Behavior of High Performance Powder Metallurgy Al Alloys,” Powder Metallurgy Aluminum & Light Alloys for Automotive Applications, (W. Jandeska and R. Chernekoff, eds.), (2000), Metal Powder Industries Federation,pp. 69-76.
  35. M.C. Baran, N. Chawla, T.F. Murphy, and K.S. Narasimhan, “New High Performance P/M Alloys for Replacing Ductile Cast Irons,” Adv. Powder Metall. Part. Mater., (H. Ferguson and D.T. Whychell, eds.), (2000), vol. 13, Metal Powder Industries Federation, pp. 133-140.
  36. F.J. Semel, N. Chawla, and K.S. Narasimhan, “Binder Treated Analogs of Diffusion Alloyed Compositions based on Ancorsteel 150 HP,” Adv. Powder Metall. Part. Mater., (H. Ferguson and D.T. Whychell, eds.), (2000), vol. 6, Metal Powder Industries Federation, pp. 123-138.
  37. N. Chawla, T.F. Murphy, K.S. Narasimhan, M. Koopman, and K.K. Chawla, “Axial Fatigue Behavior of Binder-Treated versus Diffusion Alloyed Powder Metallurgy Steels,” Adv. Powder Metall. Part. Mater., (H. Ferguson and D.T. Whychell, eds.), (2000), vol. 6, Metal Powder Industries Federation, pp. 139-154.
  38. N. Chawla, G. Fillari, and K.S. Narasimhan, “Recent Advances in Ferrous Powder Metallurgy,” Powder Materials: Current Research and Industrial Practices (F.D.S. Marquis, ed.), TMS, Warrendale, PA (1999), p. 247.
  39. N. Chawla, J.W. Jones, and J.E. Allison, “Elevated Temperature Tensile and Fatigue Behavior of Particle Reinforced Metal Matrix Composites,” Fatigue ’99 (X.R. Wu and Z.G. Wang, eds.), EMAS/HEP, (1999).
  40. N. Chawla and J.W. Holmes, “High Frequency Fatigue of Continuous Fiber Ceramic Matrix Composites,” Processing and Design of High Temperature Materials (N.S. Stoloff and R. Jones, eds.), TMS, Warrendale, PA (1997), p.281.
  41. N. Chawla, P.K. Liaw, E. Lara-Curzio, R.A. Lowden, and M.K. Ferber, “Effect of Fiber Fabric Orientation on the Mechanical Behavior of a Continuous Fiber Ceramic Composite,” High Performance Composites – Commonalty of Phenomena (K.K. Chawla, P.K. Liaw, and S.G. Fishman, eds.), TMS, Warrendale, PA (1994), p. 291.
  42. A.S. Wagh, D. Singh, W. Subhan, and N. Chawla, “Processing and Mechanical Properties of Chemically Bonded Ceramics for the Containment of Radioactive Waste,” Proceedings of American. Ceramic Society Annual Meeting, (1993).
  43. A.S. Wagh, J.C. Cunnane, D. Singh, D.D. Reed, S. Armstrong, W. Subhan, and N. Chawla, “Chemically Bonded Phosphate Ceramics for Radioactive and Mixed-Waste Solidification and Stabilization,” Waste Management 1993, (1993).
  44. R. Sharma, B.L. Ramakrishna, Z. Iqbal, N.N. Thadhani, and N. Chawla, “Structure and Defects of Shock-Processed Tl and Y-Based Copper Oxide Superconductors,” Proceedings of Materials Research Society, (1990), vol. 183, pp. 67.
  45. Z. Iqbal, N.N. Thadhani, N. Chawla, K.V. Rao, S. Skumryev, B.L. Ramakrishna, R. Sharma, H. Eckhardt, and F.J. Owens, “Shock Synthesis and Processing of High Temperature Superconductors,” APS Topical Conf. on Shock Compression of Condensed Matter, Albuquerque, 1989 (S.C. Schmidt et al., eds.), Elsevier Press, pp. 45.

Commentaries/book reviews/forewords/corrigenda (8)

  1. K.E. Yazzie, H. Fei, H. Jiang, and N. Chawla, Corrigendum to: “Rate-dependent behavior of Sn alloy–Cu couples: Effects of microstructure and composition on mechanical shock resistance [Acta Mater Mater. 60 (2012) 4336–4348],” (2014) 72 262.
  2. N. Chawla, A. Boccaccini, G. Gladysz, and P. Portella, “Preface: A Celebration of Prof. K.K. Chawla’s Distinguished Contributions: Fibers, Foams, and Composites,” Mater. Sci. Eng. A, (2012) 557 1.
  3. S. K. Kang, I. Anderson, S. Chada, J.-G. Duh, L.J. Turbini, A. Wu, C.R. Kao, F. Hua, K.N. Subramanian, D. Frear, C. Handwerker, F. Guo, N. Chawla, and K. Zeng, “Lead-free solder implementation: Reliability, alloy development, new technology – Foreword,” J. Electron. Mater., (2009) 38 2427-2428.
  4. N. Chawla, C. Boehlert, K.K. Chawla, and E. Lara-Curzio, “Preface to Special Section on Composite Materials,” J. Mater. Sci., (2008) 43 4353-4355.
  5. N. Chawla, “Multiscale Modeling of Composite Materials,” JOM, (2008) 60 38.
  6. N. Chawla, S. Chada, S.K. Kang, C.R. Kao, K.-L. Lin, J. Lucas, and L. Turbini, “Lead-free solder implementation: Reliability, alloy development, new technology – Foreword,” J. Electron. Mater., (2006) 35 2073.
  7. N. Chawla, “Book Review: ‘Fatigue Testing and Analysis,’” MRS Bulletin, (2005) 30 785.
  8. N. Chawla, “Guest Editorial: Fatigue of Light Metals,” Metall. Mater. Trans., (2004) 35A 5.