{"id":415,"date":"2020-08-11T15:44:04","date_gmt":"2020-08-11T19:44:04","guid":{"rendered":"https:\/\/web.uri.edu\/materialslab\/?page_id=415"},"modified":"2020-08-16T11:41:51","modified_gmt":"2020-08-16T15:41:51","slug":"journal-publications","status":"publish","type":"page","link":"https:\/\/web.uri.edu\/materialslab\/journal-publications\/","title":{"rendered":"Journal Publications"},"content":{"rendered":"

D. Spader, K. Maciejewski, H. Ghonem, Distribution of Grain Boundary Carbides in Inconel 617 Subjected to Creep at 900\u00b0C and 950\u00b0C<\/em>, <\/strong> Metallurgical and Materials Transactions, A, 10.1007\/s11661-020-05798-x, 2020, 1-15.<\/em><\/p>\n

M. Lapera, D. Spader, H. Ghonem, A Coupled, Physic-Based Matrix-Grain Boundary Model for Creep of Carbide Strengthened Nickel-Based Superalloys – I. Concepts and Formulations.<\/b> Journal of Materials Science and Engineering<\/i>, A 769, 2020, 138421.<\/i><\/em><\/em><\/p>\n

D. Spader, M. Lapera, H. Ghonem, A Coupled, Physic-Based Matrix-Grain Boundary Model for Creep of Carbide Strengthened Nickel-Based \u2013 II. Experimental Results and Model Application. <\/b> Journal of Materials Science and Engineering<\/i>, A 769, 2020, 138355.<\/i><\/em><\/p>\n

W. Visser, H. Ghonem<\/span>, Dynamic Flo<\/strong>w Stress<\/strong> of Shock Loaded Low Carbon Steel<\/strong>, <\/span><\/b> Accepted in <\/b>Journal of Materials Science and Engineering<\/i>, A 753, 2019, 317-330.<\/p>\n

J. Spirdione, H. Ghonem<\/span>, Dynamic Flow Stress of Fine Grain material Processed Using Equal Channel Angular Pressing<\/strong><\/span>, <\/span><\/b> <\/b>Journal of Materials Science and Engineering<\/i>, A 698, 2017, 256-267.<\/p>\n

W. Visser, H. Ghonem, Twin Nucleation in Cold Rolled Low Carbon Steel, <\/b>Journal of Materials Science and Engineering<\/em>, A 687, 2017, 28-38.<\/i><\/p>\n

J. Spirdione, W. Visser, K. Maciejewski and H. Ghonem<\/span>, Role of Pearlite Colonies on Dynamic Flow Stress of Low Carbon Steel, <\/span><\/b> <\/b>Journal of Materials Science and Engineering<\/i>, A 679, 2017, 446-454.<\/p>\n

K. Maciejewski, H. Ghonem, Isotropic and Kinematic Hardening as Explicit Functions of Gamma Prime Precipitates in a Nickel-Based Superalloy, <\/b>International Journal of Fatigue<\/i>, Volume 68, November 2014, 123-135.<\/p>\n

K. Maciejewski, J. Dahal, Y. Sun, H. Ghonem, Creep-Environment Interactions in Dwell-Fatigue Crack Growth of Nickel Based Superalloys, <\/b>Metallurgical and Materials Transactions A<\/i>, DOI 10.1007\/s11661-014-2199-z, February 2014<\/p>\n

K. Maciejewski, M. Jouiad, H. Ghonem, Dislocation\/Precipitate Interactions in IN100 at 650\u00b0C, <\/b>Materials Science and Engineering A<\/i>, 582, 2013, 47-54<\/p>\n

Y. Sun, K. Maciejewski, H. Ghonem, A Damage Based Cohesive Zone Model of Intergranular Crack Growth in a Nickel-Based Superalloy, <\/b>International Journal of Damage Mechanics, <\/i>22(6), 2013, 905-923<\/p>\n

J. Dahal, K. Maciejewski, H. Ghonem, Loading Frequency and Microstructure Interactions in Intergranular Fatigue Crack Growth in a Disk Ni-Based Superalloy, <\/b>International Journal of Fatigue<\/i>, 57, 2013, 93-102<\/p>\n

K. Maciejewski, H. Ghonem, Influence of Continuum Precipitates on Intergranular Fatigue Crack Growth of a P\/M Nickel-Based Superalloy, <\/b>Materials Science and Engineering A<\/i>, 560, January 2013, 439-449<\/p>\n

Y. Sun, K. Maciejewski, H. Ghonem, Simulation of Viscoplastic Deformation of Low Carbon Steel Structures at Elevated Temperatures, <\/b>Journal of Materials Engineering and Performance<\/i>, 21(7), 2012, 1151-1159<\/p>\n

K. Maciejewski, Y. Sun, O. Gregory, H. Ghonem, Time-Dependent Deformation of Low Carbon Steel at Elevated Temperatures, <\/b>Materials Science and Engineering A<\/i>, 534, 2012, 147-156<\/p>\n

J. Dahal, K. Maciejewski, H. Ghonem, Grain Boundary Deformation and Damage Mechanisms in Dwell Fatigue Crack Growth in Turbine Disk Superalloy ME3, <\/b>Superalloys 2012<\/i>, ed. E.S. Huron et al., The Minerals, Metals and Materials Society, 2012, 2012, 149-158.<\/p>\n

K. Maciejewski, H. Ghonem, Relative Contributions of Secondary and Tertiary \u03b3<\/b>\u2019 Precipitates to Intergranular Crack Growth Resistance in IN100 Alloy, <\/b>Superalloys 2012<\/i>, ed. E.S. Huron et al., The Minerals, Metals and Materials Society, 2012, 421-430.<\/p>\n

W. Visser, Y. Sun, O. Gregory, G. Plume, C-E. Rousseau, H. Ghonem, Deformation Characteristics of Low Carbon Steel Subjected to Dynamic Impact Loading, <\/b>Material Science and Engineering A<\/i>, 528(27), October 2011, 7857-7866<\/p>\n

H. Ghonem, Microstructure and Fatigue Crack Growth Mechanisms in High Temperature Titanium Alloys, <\/b>Int. J. Fatigue<\/i>, 32, 2010, 1448-1460<\/p>\n

O. Gregory, J. Oxley, J. Smith, M. Platek, J. Smith, M. Downey, C. Cummiskey, E. Bernier , H. Ghonem, Microstructural Characterization of Pipe Bomb Fragments, <\/b>Materials Characterization<\/i>, 61(3), March 2010, 347-354<\/p>\n

F. Sansoz, M. Almesalamy and H. Ghonem, Effects of High Temperature Exposure on the Tensile Ductility of an Aged Beta Titanium, <\/b>Metallurgical and Materials<\/i> Transactions A<\/i>, 35, 2004, 3113-3129<\/p>\n

F. Sansoz and H. Ghonem, Fatigue Crack Growth Mechanisms in Ti6242 Lamellar Microstructures: Influence of Loading Frequency and Temperature, <\/b>Metallurgical and Materials<\/i> Transactions A<\/i>, 34, 2003, 2565-2577<\/p>\n

F. Sansoz and H. Ghonem, Effects of Loading Frequency on Fatigue Crack Growth Mechanisms in \u03b1<\/b>\/\u03b2<\/b> Ti Microstructure with Large Colony Size, <\/b>Materials Science and Engineering A<\/i>, 356(1-2), 2003, 81-92<\/p>\n

N. Chandra, H. Li, C. Shet and H. Ghonem, Some Issues in the Application of Cohesive Zone Models for Metal\u2013Ceramic Interfaces, <\/b>Journal of Solids and Structures<\/i>, 39(10), 2002, 2827-2855<\/p>\n

A. Zaki and H. Ghonem, A Model for Fatigue Crack Initiation from Notches, <\/b>ASME- NDE<\/i>, 21, 2001, 49<\/p>\n

N. Chandra and H. Ghonem, Interfacial Mechanics of Push-Out Tests: Theory and Experiments, <\/b>Composites Part A: Applied Science and Manufacturing<\/i>, 32(3-4), 2001, 575-584<\/p>\n

D. Osborne, N. Chandra and H. Ghonem, Elevated Temperature Interphase Properties of Titanium Matrix Composites, <\/b>Composites Part A: Applied Science and Manufacturing<\/i>, 32(3-4), 2001, 545-553<\/p>\n

M. N. Tamin and H. Ghonem, Fatigue Damage Mechanisms of Bridging Fibers in Titanium Metal Matrix Composites, <\/b>Engineering Materials and Technology<\/i>, 122(4), 2000, 370<\/p>\n

H. Ghonem, Fiber Fracture Criterion in Titanium Metal Matrix Composites at Elevated Temperature, <\/b>Advancing with Composites<\/i>, AMME-CANICA<\/i>, 2000, 37<\/p>\n

H. Ghonem, Model for Fracture of Bridging Fibers in Titanium Metal Matrix Composites, <\/b>ASME- MD<\/i>, 86, 1999, 87-93<\/p>\n

M. N. Tamin, D. J. Osborne and H. Ghonem, A Processing Related Interface Properties in Titanium Metal Matrix Composites, <\/b>Ceramic and Metal Matrix Composites<\/i>, Part 1, 1997, 639-650<\/p>\n

M. N. Tamin, and H. Ghonem, Fiber Damage Mechanisms in Titanium Metal Matrix Composites<\/strong>, <\/b>ASME-Materials Division Publication MD 74, 1996, 115<\/em><\/p>\n

H. Ghonem, IBridging Fiber Stress in Metal Matrix Composites \u2013 An Analytical Model, <\/b>ASME- Aerospace Division Publication AD 51, 1996, 489<\/em><\/p>\n

M. N. Tamin, D. J. Osborne and H. Ghonem, Interphase Shear Strength of Titanium Metal Matrix Composites at elevated Temperature, <\/b>ASME- Aerospace Division Publication AD 51, 1996, 241<\/em><\/p>\n

M. N. Tamin, D. J. Osborne and H. Ghonem, Influence of Interfacial Properties on Fiber Debonding in Titanium Metal Matrix Composites, <\/b>Fatigue and Fracture at Elevated Temperature, <\/i>ASME-AD, 50, 1996, 121-134<\/p>\n

M. N. Tamin and H. Ghonem, Evolution of Bridging Fiber Stress in Titanium Metal Matrix Composites at Elevated Temperature, <\/b>Advances in Fatigue Lifetime Predictive Techniques<\/i>, ASTM STP 1292, 1996, 24-38<\/p>\n

D. Zheng and H. Ghonem, High Temperature\/High Frequency Fatigue Crack Growth Damage Mechanisms in Titanium Metal Matrix Composites, <\/b>ASTM STP 1253<\/i>, 1996, 137-163<\/p>\n

T. Zhang and H. Ghonem, Time-Dependent Fatigue Crack Growth of Titanium Metal Matrix Composites, <\/b>Fatigue and Fracture of Engineering Materials<\/i>, 18(11), 1995, 1231-1366<\/p>\n

A. Madsen, and H. Ghonem, Separating the Effects of Aluminide and Silicide Precipitation on the Tensile and Crack Growth Behavior at Room Temperature and 593o<\/sup>C in a Near-\u03b1 Titanium Alloy, <\/b>J of Materials Performance and Technology<\/i>, 4(3), 1995, 301-308<\/p>\n

A. H. Rosenberger and H. Ghonem, Influence of Creep-Fatigue Interaction on High Temperature Fatigue Crack Growth Behavior of Ti-1100, <\/b>Journal of Fatigue<\/i>, 17(6), 1995, 449<\/p>\n

A.H. Rosenberger, A. Madsen and H. Ghonem, Aging Effects on the Creep Behavior of the Near-Alpha Titanium Alloy Ti-1100, <\/b>Journal of Materials Performance and Technology<\/i>, 4(2), 1995, 182-188<\/p>\n

D. Zheng and H. Ghonem, High Temperature Fatigue Crack Growth in \u03c31240\/Timetal-21S Composite, <\/b>Metallurgical Transactions A<\/i>, 26A(9), 1995, 2193-2488<\/p>\n

M. Tamin, D. Zheng and H. Ghonem, Time-Dependent Stress Analysis in Fiber-Reinforced Metal Matrix Composites -Modeling and Applications, <\/b>J. Comp. Technology and Research<\/i>, V. 16, No. 4, pp. 314-322, 1994<\/p>\n

A. H. Rosenberger and H. Ghonem, High Temperature Elastic-Plastic Small Crack Growth Behavior in a Nickel-Base Superalloy, <\/b>Fatigue and Fracture of Engrg Materials & Structures<\/i>, 17(5), 1994, 509-522<\/p>\n

A. H. Rosenberger and H. Ghonem, Influence of Creep-Fatigue Interaction on High Temperature Fatigue Crack Growth of Ti-1100, <\/b>Fatigue and Fracture of Engrg Materials & Structures<\/i>, 17(4), 1994, 397-410<\/p>\n

H. Ghonem, Y. Wen and D. Zheng, An Interactive Simulation Technique to Determine the Internal Stress States in Fiber Reinforced Titanium Metal Matrix Composites, <\/b>Materials Science and Engineering<\/i>, A177, 1994, 125-134<\/p>\n

A. Madsen and H. Ghonem, Effects of Aging on the Tensile and Fatigue Behavior of the Near-\u03b1 Ti-1100 at both Room Temperature and 593o<\/sup>C, <\/b>Material Science and Engineering<\/i>, A177, 1994, 63-77<\/p>\n

H. Ghonem, Y. Wen and D. Zheng, Fatigue Crack Growth Characteristics of Ti-\u03b221S Neat Laminate, <\/b>in \u201cDamage in Composite Materials\u201d, ed. G. Z. Voyiadjis, Studies in Applied Mechanics 34<\/i>, Elsevier Science Publishers Ltd., New York, 1993, 161-180<\/p>\n

A. Madsen, E. Andrieu and H. Ghonem, Microstructural Changes During Aging of a Silicon Containing Near-\u03b1 Titanium Alloy, <\/b>Materials Science and Engineering<\/i>, A171, 1993, 191-197<\/p>\n

R. Foerch, A. Madsen and H. Ghonem, Environmental Interactions in High Temperature Fatigue Crack Growth of Ti-1100, <\/b>Metallurgical Transaction<\/i>, 24A, 1993, 1321-1332<\/p>\n

H. Ghonem, T. Nicholas and A. Pineau, Elevated Temperature Fatigue Crack Growth in Alloy 718 \u2013 Part II: Effects of Environmental and Material Variables, <\/b>Fatigue and Fracture of Engrg Materials & Structures<\/i>, 16(6), 1993, 577-591<\/p>\n

H. Ghonem, T. Nicholas and A. Pineau, Elevated Temperature Fatigue Crack Growth in Alloy 718 \u2013 Part I: Effects of Mechanical Variables, <\/b>Fatigue and Fracture of Engrg Materials & Structures<\/i>, 16(5), 1993, 565-577<\/p>\n

D. Zheng, A. Rosenberger and H. Ghonem, Role of Pre-Deformation in the Modification of Crack Tip Oxidation Resistance, <\/b>American Society of Mechanical Engineers International Gas turbine and Aero-engine Congress and Exposition<\/i>, 1993, 3C<\/p>\n

D. Zheng, A. Rosenberger and H. Ghonem, Influence of Pre-straining on High Temperature Low Frequency Fatigue Crack Growth in Superalloys, <\/b>Materials Science and Engineering<\/i>, A161, 1993, 13-21<\/p>\n

H. Ghonem, Y. Wen, M. Thompson and G. Linsey, Effects of Temperature and Frequency on Fatigue Crack Growth in Ti-\u03b221S Monolithic Laminate, <\/b>Materials Science and Engineering<\/i>, A161, 1993, 45-53<\/p>\n

D. Zheng and H. Ghonem, Influence of Prolonged Thermal Exposure at 650o<\/sup>C on Intergranular Fatigue Crack Growth Behavior in Alloy 718, <\/b>Metallurgical Transactions<\/i>, 23A, 1992, 3169-3171<\/p>\n

H. Ghonem and D. Zheng, Frequency Interaction on High Temperature Fatigue Crack Growth in Alloy 718, <\/b>Metallurgical Transactions<\/i>, 23A, 1992, 3067-3072<\/p>\n

A. H. Rosenberger and H. Ghonem, Effect of Cycle Mean Strain on Small Crack Growth in Alloy 718 at Elevated Temperatures, <\/b>Fatigue and Fracture of Engrg Materials & Structures<\/i>, 11(15), 1992, 1125-1139<\/p>\n

E. Andrieu, R. Mollins, H. Ghonem and A. Pineau, Intergranular Crack Tip Oxidation Mechanisms in A Nickel-Based Superalloy, <\/b>Materials Science and Engineering<\/i>, A154, 1992, 21-28<\/p>\n

H. Ghonem and D. Zheng, Depth of Intergranular Oxygen Diffusion During Environment-Dependent Fatigue Crack Growth in Alloy 718, <\/b>Materials Science and Engineering<\/i>, A150, 1992, 151-160<\/p>\n

H. Ghonem A. Pineau and T. Nicholas, Analysis of Elevated Temperature Fatigue Crack Growth Mechanisms in Alloy 718,<\/strong> American Society of Mechanical Engineers, Materials Division, Publication MD 21<\/em>, 1991, 1<\/p>\n

H. Ghonem and R. Foerch, Environmental Effects on Elevated Temperature Fatigue Crack Growth in a Near-\u03b1 Ti-1100 Alloy, <\/b>Material Science and Engineering<\/i>, A138, 1991, 69-81<\/p>\n

H. Ghonem and M. Zheng, Prediction of Fatigue Crack Growth Under Single Overload Application in Ti-6Al-4V, <\/b>Fatigue and Fracture of Engrg Materials & Structures<\/i>, 4(8), 1991, 805-814<\/p>\n

D. Zheng and H. Ghonem, Oxidation-Assisted Fatigue Crack Growth Behavior in Alloy 718 \u2013 Part II: Application, <\/b>Fatigue and Fracture of Engrg Materials & Structures<\/i>, 14(7), 1991, 761-768<\/p>\n

H. Ghonem and D. Zheng, Oxidation-Assisted Fatigue Crack Growth Behavior in Alloy 718 \u2013 Part I: Quantitative Modeling, <\/b>Fatigue and Fracture of Engrg Materials & Structures<\/i>, 14(7), 1991, 749-761<\/p>\n

E. Andrieu, H. Ghonem and A. Pineau, Two-Stage Crack Tiop Oxidation Mechanism in Alloy 718,<\/strong> American Society of Mechanical Engineers, Materials Division, Publication MD 18<\/em>, 1990, 25<\/p>\n

H. Ghonem and R. Foerch, Frequency Effects on Fatigue Crack Growth Behavior in a Near-a Titanium Alloy,<\/b> American Society of Mechanical Engineers, Materials Division, Publication MD 18<\/em>, 1990, 93<\/p>\n

H. Ghonem, Constant-Probability Crack Growth Curves, <\/b>Engrg Fracture Mechanics<\/i>, 30(5), 1988, 685-699<\/p>\n

H. Ghonem and J. Kalousek, Study of Surface Crack Initiation Due to Biaxial Compression\/Shear Loading, <\/b>Engrg Fracture Mechanics<\/i>, 30(5), 1988, 667-683<\/p>\n

H. Ghonem and S. Dore, Experimental Study of the Constant Probability Crack Growth Curves Under Constant Amplitude Loading, <\/b>Engrg Fracture Mechanics<\/i>, 27(1), 1987, 1-25<\/p>\n

H. Ghonem and S. Dore, Probabilistic Description of Fatigue Crack Growth in Polycrystalline Solids, <\/b>Engrg Fracture Mechanics<\/i>, 21(6), 1985, 1151-1168<\/p>\n

H. Ghonem and J. Kalousek, Quantitative Model to Estimate Rail Surface Failure, <\/b>Wear<\/i>, 97, 1984, 65-81<\/p>\n

D. Parsons, J. Kalousek and H. Ghonem, Effects of Streaks on Fracture Toughness of Steel, <\/b>Canadian Metallurgical Quarterly<\/i>, 21(1), 1982, 25-30<\/p>\n

H. Ghonem, Fatigue Life Estimation of the Longitudinal Crack in Rail Stee<\/strong>l, Canadian Congress of Applied Mechanics<\/em>, 1981, 439<\/p>\n

H. Ghonem and J. W. Provan, Micromechanics Theory of Fatigue Crack Initiation and Propagation, <\/b>Engrg Fracture Mechanics<\/i>, 13(4), 1981, 963-977<\/p>\n

H. Ghonem, R. Gonsalves, and G. Bartley, Comparative Performance of Type II Designs, <\/b>ASME Transactions<\/i>, 80-RT-8, March 1979, 1-16<\/p>\n

H. Ghonem and J. W. Provan, Microstress Distributions in Single Silicon Crystals, <\/b>Canadian Metallurgical Quarterly<\/i>, 16(3), 1977, 319-326<\/p>\n\n\n

(go to top<\/a>)<\/a><\/p>\n","protected":false},"excerpt":{"rendered":"

D. Spader, K. Maciejewski, H. Ghonem, Distribution of Grain Boundary Carbides in Inconel 617 Subjected to Creep at 900\u00b0C and 950\u00b0C, Metallurgical and Materials Transactions, A, 10.1007\/s11661-020-05798-x, 2020, 1-15. M. Lapera, D. Spader, H. Ghonem, A Coupled, Physic-Based Matrix-Grain Boundary Model for Creep of Carbide Strengthened Nickel-Based Superalloys – I. Concepts and Formulations. Journal of […]<\/p>\n","protected":false},"author":3750,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"_acf_changed":false,"footnotes":"","_links_to":"","_links_to_target":""},"class_list":["post-415","page","type-page","status-publish","hentry"],"acf":[],"_links":{"self":[{"href":"https:\/\/web.uri.edu\/materialslab\/wp-json\/wp\/v2\/pages\/415","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/web.uri.edu\/materialslab\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/web.uri.edu\/materialslab\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/web.uri.edu\/materialslab\/wp-json\/wp\/v2\/users\/3750"}],"replies":[{"embeddable":true,"href":"https:\/\/web.uri.edu\/materialslab\/wp-json\/wp\/v2\/comments?post=415"}],"version-history":[{"count":5,"href":"https:\/\/web.uri.edu\/materialslab\/wp-json\/wp\/v2\/pages\/415\/revisions"}],"predecessor-version":[{"id":757,"href":"https:\/\/web.uri.edu\/materialslab\/wp-json\/wp\/v2\/pages\/415\/revisions\/757"}],"wp:attachment":[{"href":"https:\/\/web.uri.edu\/materialslab\/wp-json\/wp\/v2\/media?parent=415"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}