{"id":195,"date":"2018-08-05T21:52:09","date_gmt":"2018-08-06T01:52:09","guid":{"rendered":"https:\/\/cecas.clemson.edu\/mat2sim\/?page_id=195"},"modified":"2022-12-29T11:27:46","modified_gmt":"2022-12-29T16:27:46","slug":"publications","status":"publish","type":"page","link":"https:\/\/cecas.clemson.edu\/mat2sim\/publications\/","title":{"rendered":"Publications"},"content":{"rendered":"\t\t
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O. Hussein, D. Coffman, K. Hattar, E. Lang, S. Dillon, F. Abdeljawad<\/strong>, \u00a0“Plateau\u2013Rayleigh instability with a grain boundary twist.”\u00a0Applied Physics Letters<\/i>, 121<\/i>(14), 141601 (2022).<\/a><\/p><\/header><\/div>

Y. Mahmood, M. Alghalayini, E. Martinez, C. Paredis, F. Abdeljawad<\/strong>, “Atomistic and machine learning studies of solute segregation in metastable grain boundaries.”\u00a0Sci Rep<\/i> 12<\/b>, 6673 (2022).<\/a><\/p>

M. Alkayyali, F. Abdeljawad<\/strong>, \u201cGrain Boundary Solute Drag Model in Regular Solution Alloys,\u201d Physical Review Letters, 127, 175503 (2021)<\/a><\/p>

C. Barr, S. Foiles, M. Alkayyali, Y. Mahmood, P. Price, D. Adams, B. Boyce, F. Abdeljawad<\/strong>, K. Hattar, \u201cThe role of grain boundary character in solute segregation and thermal stability of nanocrystalline Pt-Au,\u201d Nanoscale, 13, 3552 (2021) Featured on the Cover.<\/strong><\/a><\/p>

R. D. Moore, T. Beecroft, G. S. Rohrer, C. Barr, E. Homer, K. Hattar, B. L. Boyce, F. Abdeljawad<\/strong>, \u201cThe grain boundary stiffness and its impact on equilibrium shapes and boundary migration: Analysis of the \u03a35, 7, 9, and 11 boundaries in Ni,\u201d Acta Materialia, 218, 117220 (2021).<\/a><\/p>

O. Hussein, S. J. Dillon, F. Abdeljawad<\/strong>, \u201cUnraveling the Role of Grain Boundary Anisotropy in Sintering: Implications for Nanoscale Manufacturing,\u201d ACS Applied Nano Materials, 4, 8039 (2021).<\/a><\/p>

H. Lee, M. Shabani, G. Pataky, F. Abdeljawad<\/strong>, \u201cTensile Deformation Behavior of Twist Grain Boundaries in CoCrFeMnNi High Entropy Alloy Bicrystals,\u201d Nature Scientific Reports, 11, 428 (2021)<\/a><\/p>

T. Rodgers, D. Moser, F. Abdeljawad<\/strong>, O. Underwood, J. Carroll, B. Jared, D. Bolintineanu, J. Mitchell, J. Madison, \u201cSimulation of powder bed metal additive manufacturing microstructures with coupled finite difference-Monte Carlo method,\u201d Additive Manufacturing 41, 101953 (2021).<\/a><\/p>

S. Kadambi, F. Abdeljawad<\/strong>, S. Patala, \u201cInterphase boundary segregation and pre- cipitate coarsening resistance in ternary alloys: An analytic phase-field model de- scribing chemical effects,\u201d Acta Materialia, 197, 283 (2020)<\/a><\/p>

S. Kadambi, F. Abdeljawad<\/strong>, S. Patala, \u201cA phase-field approach for modeling equilibrium solute segregation at the interphase boundary in binary alloys,\u201d Comp. Mater. Sci., 175, 109533 (2020)<\/a><\/p>

F. Abdeljawad<\/span>, D. Bolintineanu, A. Cook, H. Brown-Shaklee, C. DiAntonio, D. Kammler, A. Roach, “Sintering processes in direct ink write additive manufacturing processes: A mesoscopic modeling approach”, Acta Mater. 169 (2019) 60-75<\/span><\/a><\/p>

J. Sestito, <\/span>F. Abdeljawad<\/strong>, T. A. Harris, Y. Wang, A. Roach, “An atomistic simulation study of nanoscale sintering: the role of\u00a0grain boundary misorientation , Computational Materials Science 165 (2019) 180-189<\/a><\/p>

P. Lu, F. Abdeljawad<\/strong>, M. Rodriguez, M. Chandross, D. Adams, B. L. Boyce, B. G. Clark, N. Argibay, “On the thermal stability and grain boundary segregation in nanocrystalline PtAu alloys”, Materialia 6 (2019) 100298<\/span><\/a><\/p>

S. M. Foiles,\u00a0<\/span>F. Abdeljawad<\/span>, A. Moore, B. L. Boyce,\u00a0<\/span>“<\/span>Fatigue-driven acceleration of abnormal grain growth in nanocrystalline wires”,\u00a0Modelling Simul. Mater. Sci. Eng. 27 (2019) 025008<\/span><\/a><\/p>

F. Abdeljawad<\/span>, S. M. Foiles, A. Moore, A. R. Hinkle, C. Barr, N. Heckman, K. Hattar, B. L. Boyce, “The role of the interface stiffness tensor on grain boundary dynamics”, Acta Mater. 158 (2018) 440-453<\/span><\/a><\/p>

\u00a0<\/span>D. de Oca Zapiain, E. Popova,\u00a0<\/span>F. Abdeljawad<\/span>, J. Foulk, S. Kalidindi, H. Lim, “Reduced-Order Microstructure-Sensitive Models for Damage Initiation in Two-Phase Composites”, Integ. Mater. Manuf. Innov. (IMMI) 7, 1 (2018)<\/span><\/a><\/p>

M. Francois, A. Sun, W. King, N. Henson, D. Tourret, C. Bronkhorst, N. Carlson, C. Newman, T. Haut, J. Bakosi, J. Gibbs, V. Livescu, S. Vander Wiel, A. Clarke, M. Schraad, T. Blacker, H. Lim, T. Rodgers, S. Owen,\u00a0F. Abdeljawad<\/span>, J. Madison, A. Anderson, J.-L. Fattebert, R. Ferencz, N. Hodge, S. Khairallah, O. Walton, “Modeling of additive manufacturing processes for metals: Challenges and opportunities”, Curr. Opin. Solid State Mater. Sci. 21, 198 (2017)<\/span><\/a><\/p>

F. Abdeljawad<\/span>, P. Lu, N. Argibay, B. G. Clark, B. Boyce, S. M. Foiles, “Grain boundary segregation in immiscible nanocrystalline alloys”, Acta Mater. 126, 528 (2017)<\/span><\/a><\/p>

D. L. Medlin, J. A. Zimmerman,\u00a0F. Abdeljawad<\/span>, K. Hattar, S. M. Foiles, “Defect character at grain boundary facet junctions: \u00a0Analysis of an asymmetric\u00a0\u03a3=<\/span>\u00a05 grain boundary in Fe”, Acta Mater. 124, 383 (2017)<\/span><\/a><\/p>

J. Gruber, H. Lim,\u00a0F. Abdeljawad<\/span>, S. M. Foiles, G. J. Tucker “ Development of physically based atomistic microstructures: The effect on the mechanical response of polycrystals”, Comp. Mater. Sci. 128, 29 (2017) (Editor’s choice)<\/span><\/a><\/p>

F. Abdeljawad<\/span>, S. M. Foiles, “Interface-driven phenomena in solids: Thermodynamics, kinetics and chemistry”, J. Materials (JOM) 68, 1594 (2016)<\/span><\/a><\/p>

F. Abdeljawad<\/span>, D. L. Medlin, J. A. Zimmerman, K. Hattar, S. M. Foiles, “A Diffuse interface model of grain boundary faceting”, \u00a0J. App. Phys. 119, 235306 (2016)<\/span><\/a><\/p>

H. Lim,\u00a0F. Abdeljawad<\/span>, S. Owen, B. Hanks, C. C. Battaile, “Incorporating physically-based microstructures in materials modeling: Bridging phase field and crystal plasticity frameworks”, Mod. Sim. Mat. Sci. Eng. 24, 045016 (2016)<\/span><\/a><\/p>

D. C. Bufford,\u00a0F. Abdeljawad<\/span>, K. Hattar, S. M. Foiles, “Unraveling irradiation induced grain growth with in situ TEM and coordinated modeling”, App. Phys. Lett. 107, (2015)<\/span><\/a><\/p>

F. Abdeljawad<\/span>, S. M. Foiles, “Stabilization of nanocrystalline alloys via grain boundary segregation: A diffuse interface model”, Acta Mater. 101, 159 (2015)<\/span><\/a><\/p>

F.\u00a0Abdeljawad<\/span>, B. Voelker, R. Davis, R. M. McMeeking, M. Haataja, “Connecting microstructural coarsening processes to electrochemical performance in solid oxide fuel cells: An integrated modeling approach”, J. Power Sources 250, 319 (2014)<\/span><\/a><\/p>

R. Davis,\u00a0F. Abdeljawad<\/span>, J. Lillibridge, M. Haataja, “Phase wettability and microstructural evolution in solid oxide fuel cell anode materials”, Acta Mater. 78, 271 (2014)<\/span><\/a><\/p>

A. Zaheri,\u00a0F. Abdeljawad<\/span>, M. Haataja, “Simulation study of mechanical properties of bulk metallic glass systems: Martensitic inclusions and twinned precipitates”, Model. Simu. Mater. Sci. Eng. 22, 085008 (2014)<\/span><\/a><\/p>

F. Abdeljawad<\/span>, M. Haataja, “Microstructural coarsening effects on redox instability and mechanical damage in solid oxide fuel cell anodes”, J. App. Phys. 114, 183519 (2013)<\/span><\/a>
<\/span><\/p>

F. Abdeljawad<\/span>, G. Nelson, W. Chiu, M. Haataja, \u00a0“Redox instability, mechanical deformation, and heterogeneous damage accumulation in solid oxide fuel cell anodes”, J. App. Phys. 112, 036102 (2012)<\/span><\/a>
<\/span><\/p>

F. Abdeljawad<\/span>, M. Fontus, M. Haataja, “Ductility of bulk metallic glass composites:\u00a0Microstructures effects”, App. Phys. Lett. 98 (2011) 031909<\/a>
<\/span><\/p>

F. Abdeljawad<\/span>, M. Haataja, “Continuum modeling of bulk metallic glasses and composites”, Phys. Rev. Lett. 105 (2010) 125503<\/span><\/a><\/p>

F. Abdeljawad<\/span>, M. Zikry, “The effects of grain boundary orientations on failure behavior in F.C.C. polycrystalline systems”, Int. J. Damage Mechanics 18, 341 (2009)<\/span><\/a>
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Peer-reviewed articles O. Hussein, D. Coffman, K. Hattar, E. Lang, S. Dillon, F. Abdeljawad, \u00a0“Plateau\u2013Rayleigh instability with a grain boundary twist.”\u00a0Applied Physics Letters, 121(14), 141601 (2022). Y. Mahmood, M. Alghalayini, E. Martinez, C. Paredis, F. Abdeljawad, “Atomistic and machine learning studies of solute segregation in metastable grain boundaries.”\u00a0Sci Rep 12, 6673 (2022). M. Alkayyali, F. […]<\/p>\n","protected":false},"author":9,"featured_media":0,"parent":0,"menu_order":3,"comment_status":"closed","ping_status":"closed","template":"","meta":{"ocean_post_layout":"","ocean_both_sidebars_style":"","ocean_both_sidebars_content_width":0,"ocean_both_sidebars_sidebars_width":0,"ocean_sidebar":"","ocean_second_sidebar":"","ocean_disable_margins":"enable","ocean_add_body_class":"","ocean_shortcode_before_top_bar":"","ocean_shortcode_after_top_bar":"","ocean_shortcode_before_header":"","ocean_shortcode_after_header":"","ocean_has_shortcode":"","ocean_shortcode_after_title":"","ocean_shortcode_before_footer_widgets":"","ocean_shortcode_after_footer_widgets":"","ocean_shortcode_before_footer_bottom":"","ocean_shortcode_after_footer_bottom":"","ocean_display_top_bar":"default","ocean_display_header":"default","ocean_header_style":"","ocean_center_header_left_menu":"","ocean_custom_header_template":"","ocean_custom_logo":0,"ocean_custom_retina_logo":0,"ocean_custom_logo_max_width":0,"ocean_custom_logo_tablet_max_width":0,"ocean_custom_logo_mobile_max_width":0,"ocean_custom_logo_max_height":0,"ocean_custom_logo_tablet_max_height":0,"ocean_custom_logo_mobile_max_height":0,"ocean_header_custom_menu":"","ocean_menu_typo_font_family":"","ocean_menu_typo_font_subset":"","ocean_menu_typo_font_size":0,"ocean_menu_typo_font_size_tablet":0,"ocean_menu_typo_font_size_mobile":0,"ocean_menu_typo_font_size_unit":"px","ocean_menu_typo_font_weight":"","ocean_menu_typo_font_weight_tablet":"","ocean_menu_typo_font_weight_mobile":"","ocean_menu_typo_transform":"","ocean_menu_typo_transform_tablet":"","ocean_menu_typo_transform_mobile":"","ocean_menu_typo_line_height":0,"ocean_menu_typo_line_height_tablet":0,"ocean_menu_typo_line_height_mobile":0,"ocean_menu_typo_line_height_unit":"","ocean_menu_typo_spacing":0,"ocean_menu_typo_spacing_tablet":0,"ocean_menu_typo_spacing_mobile":0,"ocean_menu_typo_spacing_unit":"","ocean_menu_link_color":"","ocean_menu_link_color_hover":"","ocean_menu_link_color_active":"","ocean_menu_link_background":"","ocean_menu_link_hover_background":"","ocean_menu_link_active_background":"","ocean_menu_social_links_bg":"","ocean_menu_social_hover_links_bg":"","ocean_menu_social_links_color":"","ocean_menu_social_hover_links_color":"","ocean_disable_title":"default","ocean_disable_heading":"default","ocean_post_title":"","ocean_post_subheading":"","ocean_post_title_style":"","ocean_post_title_background_color":"","ocean_post_title_background":0,"ocean_post_title_bg_image_position":"","ocean_post_title_bg_image_attachment":"","ocean_post_title_bg_image_repeat":"","ocean_post_title_bg_image_size":"","ocean_post_title_height":0,"ocean_post_title_bg_overlay":0.5,"ocean_post_title_bg_overlay_color":"","ocean_disable_breadcrumbs":"default","ocean_breadcrumbs_color":"","ocean_breadcrumbs_separator_color":"","ocean_breadcrumbs_links_color":"","ocean_breadcrumbs_links_hover_color":"","ocean_display_footer_widgets":"default","ocean_display_footer_bottom":"default","ocean_custom_footer_template":"","footnotes":""},"class_list":["post-195","page","type-page","status-publish","hentry","entry"],"_links":{"self":[{"href":"https:\/\/cecas.clemson.edu\/mat2sim\/wp-json\/wp\/v2\/pages\/195","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/cecas.clemson.edu\/mat2sim\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/cecas.clemson.edu\/mat2sim\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/cecas.clemson.edu\/mat2sim\/wp-json\/wp\/v2\/users\/9"}],"replies":[{"embeddable":true,"href":"https:\/\/cecas.clemson.edu\/mat2sim\/wp-json\/wp\/v2\/comments?post=195"}],"version-history":[{"count":52,"href":"https:\/\/cecas.clemson.edu\/mat2sim\/wp-json\/wp\/v2\/pages\/195\/revisions"}],"predecessor-version":[{"id":2012,"href":"https:\/\/cecas.clemson.edu\/mat2sim\/wp-json\/wp\/v2\/pages\/195\/revisions\/2012"}],"wp:attachment":[{"href":"https:\/\/cecas.clemson.edu\/mat2sim\/wp-json\/wp\/v2\/media?parent=195"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}