Publications & Patents

Monographs/Thesis

Selected Papers

  1. The origin of the boundary strengthening in polycrystal-like architected materials, Nature Communications, (2021), C. Liu, J. Lertthernasarn, M.S. Pham

  2. The role of side-branching in microstructure development in laser powder-bed fusion, Nature Communications 11, 749 (2020), MS Pham, B Dovgyy, P Hooper, C. Gourlay, A. Piglione (Highly cited paper according to WoS)

  3. Damage-tolerant architected materials inspired by crystal microstructure, Nature, 565, 305-311 (2019), M.S. Pham, C. Liu, I. Todd, J. Lertthanasarn (Highly cited paper according to WoS)

  4. Cyclic plasticity and fatigue damage of CrMnFeCoNi high entropy alloy fabricated by laser powder-bed fusion, Additive Manufacturing, 36, 101584 (2020), M.S. Jin, A. Piglione, B. Dovgyy, E. Hosseini, P. A. Hooper, S. R. Holdsworth, M. S. Pham

  5. Comprehensive assessment of the printability of CoNiCrFeMn in Laser Powder Bed Fusion, Materials & Design, 194, 108845 (2020), B Dovgyy, A. Piglione, P Hooper, M.S. Pham,

  6. Thermally-activated constitutive model includingdislocation interactions, aging and recovery for strain path dependence of solidsolution strengthened alloys: Application to AA5754, M.S. Pham,M. Iadicola, A. Creuziger, L. Hu and A. D. Rollett, Int. J. Plasticity, December (2015), 75, pp. 226-243.

  7. Cyclic deformation response of AISI 316L at room temperature: mechanical behaviour, microstructural evolution, physically-based evolutionary constitutive modelling, M.S. Pham, S.R. Holdsworth, K.G.F. Janssens, E. Mazza, Int. J. of Plasticity 47 (2013) 143-164.

  8. Role of microstructural condition on fatigue damage development of AISI 316L at 20 and 300°C, M.S. Pham & S.R. Holdsworth, Int. J. Fatigue 51 (2013) 36-48.

Patents

  1. Polycrystals-inspired lattice structures (Application No. GB 1712114.6)

Peer-reviewed papers (updated July 2021)

  1. The origin of the boundary strengthening in polycrystal-like architected materials, Nature Communications, (2021), C. Liu, J. Lertthernasarn, M.S. Pham,

  2. Synergistic effects of crystalline microstructure, architected mesostructure, and processing defects on the mechanical behaviour of Ti6Al4V meta-crystals, MSE A (2021), 141436, J. Lertthernasarn, C. Liu, M.S. Pham,

  3. Alloy design against the solidification cracking in fusion additive manufacturing: an application to a FeCrAl alloy, Materials Research Letters (2021), 9 (8), 350-357, B. Dovgyy, M Simonelli, M.S. Pham,

  4. Micro-cracking, microstructure and mechanical properties of Hastelloy-X alloy printed by laser powder bed fusion: as-built, annealed and hot-isostatic pressed, Additive Manufacturing, 101853 (2021), H Wang, L Chen, B Dovgyy, W Xu, A Sha, X Li, H Tang, Y Liu, H Wu, M.S. Pham,

  5. Creep deformation and failure properties of 316L stainless steel manufactured by laser powder bed fusion under multiaxial loading conditions, Additive Manufacturing, 101706 (2020), R. Williams, J. Al-Lami, P.A. Hooper, M.S. Pham,C.M. Davies,

  6. Cyclic plasticity and fatigue damage of CrMnFeCoNi high entropy alloy fabricated by laser powder-bed fusion, Additive Manufacturing, 36, 101584 (2020), M.S. Jin, A. Piglione, B. Dovgyy, E. Hosseini, P. A. Hooper, S. R. Holdsworth, M. S. Pham

  7. The role of microstructure on wear mechanisms and anisotropy of additively manufactured 316L stainless steel in dry sliding, Materials & Design, 196, 109076 (2020), M. Bahshwan, C. W. Myant, T. Reddyhoff, M. S. Pham

  8. Comprehensive assessment of the printability of CoNiCrFeMn in Laser Powder Bed Fusion, Materials & Design, 194, 108845 (2020), B Dovgyy, A. Piglione, P Hooper, M.S. Pham,

  9. Micro-mechanisms of Cyclic Plasticity at Stress Concentrations in a Ni-Based Single-Crystal Superalloy, Superalloys 2020, 333-340, A Piglione, J Yu, J Zhao, C Xiao, F Dunne, MS Pham,

  10. The role of side-branching in microstructure development in laser powder-bed fusion, Nature Communications 11, 749, 2020, MS Pham, B Dovgyy, P Hooper, C. Gourlay, A. Piglione (highly cited paper according to WoS)

  11. In-situ thermography for laser powder bed fusion: effects of layer temperature on porosity, microstructure and mechanical properties, Additive Manufacturing, 30, 100880, Williams R, Ronneberg T, Piglione A, Jones C, Pham M-S, Davies C, Hooper P

  12. Crystal plasticity analysis of deformation anisotropy of lamellar TiAl alloy: 3D microstructure-based modelling and in-situ micro-compression, International Journal of Plasticity 119, 344-360, L Chen, TEJ Edwards, F Di Gioacchino, WJ Clegg, FPE Dunne, MS Pham

  13. Damage-tolerant architected materials inspired by crystal microstructure, Nature, 565, 305-311 (2019), M.S. Pham, C. Liu, I. Todd, J. Lerttharnasarn (highly cited paper according to WoS)

  14. Epitaxial growth in 316L steel and CoCrFeMnNi high entropy alloy made by powder-bed laser melting, B. Dovgyy, M.S. Pham, 2018

  15. Printability and microstructure of the CoCrFeMnNi high-entropy alloy fabricated by laser powder bed fusion, A.Piglione, B.Dovgyy, C.Liu, C.M.Gourlay, P.A.Hooper, M.S.Pham, Materials Letters, 2018

  16. Creep deformation mechanisms and CPFE modelling of a nickel-based superalloy, M.Z. Li, M.S. Pham, Z. Peng, G. Tian, B.A. Shollock, MSE A, 2018

  17. Twinning-induced plasticity in austenitic stainless steel 316L made by additive manufacturing, M.S. Pham, B. Dovvgy, P. Hooper, (MSE A, 2017).

  18. Roles of texture and latent hardening on plastic anisotropy of face-centered-cubic materials during multi-axial loading, M.S. Pham, A. Creuziger, M. Iadicola, T. Foecke, A.D. Rollett (Journal of Mechanics and Physics of Solids)

  19. Forminglimit prediction using a self-consistent crystal plasticity framework: a casestudy for body-centered cubic materials (Modelling and Simulation in MSE, 5, Vol 24, 2016), 2016, Y.G. Jeong, M.S. Pham, M. Iadicola, A. Creuziger. T. Foecke

  20. Thermally-activated constitutive model includingdislocation interactions, aging and recovery for strain path dependence of solidsolution strengthened alloys: Application to AA5754, M.S. Pham,M. Iadicola, A. Creuziger, L. Hu and A. D. Rollett, Int. J. Plasticity, December (2015), 75, pp. 226-243.

  21. Constitutive Modeling based on Evolutionary Multi-junctionsof Dislocations, Minh-Son Pham, Anthony D. Rollett, Adam Crueziger,Mark A. Iadicola and Timothy Foecke, Key Engineering Materials, 2014, Vol 611, p1771-1776.

  22. Evolution of dislocation microstructures and internal stresses of AISI 316L during cyclic loading at 293 and 573K, M.S. Pham, S.R. Holdsworth, Metal. and Mat. Trans. A 45 (2014), 2, pp. 738-751, Springer.

  23. Microscopic analysis of the influence of ratcheting on the evolution of dislocation structures observed in AISI 316L stainless steel during low cycle fatigue, G. Facheris, M.S. Pham, K.G.F. Janssens & S.R. Holdsworth, MSEA 587 (2013), 1-11, Elsevier

  24. Cyclic deformation response of AISI 316L at room temperature: mechanical behaviour, microstructural evolution, physically-based evolutionary constitutive modelling, M.S. Pham, S.R. Holdsworth, K.G.F. Janssens, E. Mazza, Int. J. of Plasticity 47 (2013) 143-164.

  25. Role of microstructural condition on fatigue damage development of AISI 316L at 20 and 300°C, M.S. Pham & S.R. Holdsworth, Int. J. Fatigue 51 (2013) 36-48.

  26. Dynamic strain ageing of AISI 316L during cyclic loading at 300°C: Mechanism, evolution, and its effects, M.S. Pham & S.R. Holdsworth, MSE A 556 (2012) 122–133.

  27. Dislocation structures evolution and its effect on cyclic deformation behavior of AISI 316L steel,M.S. Pham, C. Solenthaler, K.G.F. Janssens & S.R. Holdsworth, MSE A 528 (2011) 3261-3269, Elsevier.

  28. Change of stress-strain hysteresis loop and its links with microstructural evolution in AISI 316L during cyclic loading, M.S. Pham & S.R. Holdsworth, Procedia Engineering, 10, 2011, 1069-1074, Elsevier.

  29. Plasticity improvement of amorphous alloy via skim cold rolling, M.S. Pham, K.W. Park, B.G. Yoo, J.I. Jang & J.C. Lee, Met. Mater. Int., Vol. 15, No. 2 (2009), pp. 209~214, Springer

Under review/Submitted/In preparation

  1. Criteria for selecting printable alloys for metal 3D printing and additive manufacturing

  2. Scanning strategy-Microstructure-Property relationship of CoNiCrFeMn high entropy alloy made by selective laser melting

  3. A constitutive model based on dislocation interactions from self to higher order interactions,

Conference Talks

(> 40 talks including more than 15 invited lectures). Some are given below (updated Dec 2020):

  1. Programmable meta-crystals (Invited), International Conference on Programmable Materials, Berlin, Germany, 2020

  2. Invited lecture, International Conference on Processing and Manufacturing of Advanced Materials - Thermec 2020, Vienna, Austria, 2020.

  3. Invited lecture, 3D Printing and Beyond: State-of-the-art and New Paradigms for Additive Manufacturing Technologies, CIMTEC - Congress, Italy, 2020

  4. Invited talk, Multi-material Additive Manufacturing: Processing and Heterogeneous Materials Design, Materials Science & Technology 2020, Pittsburgh, USA

  5. Additive Manufacturing for Aerospace and Defense - Panel member (Invited), Birmingham, UK, Feb 2020.

  6. Meta-crystals: Damage tolerance and progammability (Invited lecture), Winter School in Additive Manufacturing, IMDEA, Spain, 2020.

  7. Metacrystals – Lightweight and Damage-tolerant Architected Materials (Invited), Additive Manufacturing Internationl Summit, Nottingham, UK, July 2019.

  8. Crystal-inspired meta-materials (Invited), ICMAT 2019, Singapore, June 2019.

  9. Criteria for selecting alloys for powder-bed additive manufacturing (Invited), International Conference on Processing and Manufacturing of Advanced Materials, M.S. Pham, Paris, France, 2018

  10. High entropy alloys for Additive manufacturing, TMS2018, Phoenix, AZ, USA

  11. Crystal growth in face-centred-cubic alloys made by additive manufacturing: Epitaxial growth, branching and splitting, TMS2018, Phoenix, AZ, USA

  12. Epitaxial Growth and Evolution of Grains in 316L Steel and NiCoCrFeMn High Entropy Alloy Made by Powder-bed Laser Melting, ESAFORM 2018, Italy

  13. Grain growth in Rapid cooling and Recrystallisation, and Twinning-induced plasticity of AM 316L, Alloys for Additive Manufacturing, 2017, Switzerland

  14. Crystal growth and the development of new alloys for additive manufacturing, Powder-based Additive manufacturing, Coventry, Oct. 2017

  15. Roles of Microstructures on the Uniaxial Deformation Response of 316 Stainless Steel Made by Powder-bed Laser 3D printing, ESAFORM 2017, Dublin, Ireland

  16. Material characterisation and modelling for additive manufacturing of metals and alloys (Invited), International Conference on Plasticity, Damage and Fracture, Mexico, 2017

  17. Crystal plasticity-based modelling for predicting anisotropic behaviour and formability of metallic materials, NUMISHEET 2016, 4-9 September 2016, Bristol, UK

  18. Material Characterisation and Modelling in Manufacturing, University of Birmingham, 26.02.2016

  19. Crystal Plasticity Analysis of Constitutive Behavior of 5754 Aluminum Sheet, M.S. Pham, A. Rollett, A. Creuziger, M. Iadicola, T. Foecke, ESAFORM 2016, 27-29 April, Nantes, France

  20. The strain path dependence of plastic deformation response in AA5754: Experiment and Modeling (Invited), M.S. Pham, L. Hu, A. Creuziger, M. Iadicola, T. Foecke, A. Rollett, America's Conference on Al Alloys, Aug. 23-26, 2015, Toronto.

  21. Crystal Plasticity-Based Constitutive Modeling for Forming and Service Duties of Metallic Materials (Travel Award), M.S. Pham, A. Rollett, S. Holdsworth, A. Creuziger, M. Iadicola, Y. Jeong, J. Guyer, T. Foecke, 13th US National Congress on Computational Mechanics, July 26-30 2015, San Diego, CA.

  22. Roles of texture and latent hardening on plastic anisotropy of face-centered-cubic materials during multi-axial loading, M.S. Pham, A. Creuzinger, M. Iadicola, T. Foeke, A. Rollett, Gordon Research conference-Physical Metallurgy, July 19-24, Main 2015

  23. Synergistic roles of texture and dislocation interactions on plastic anisotropy and formability of face-centered-cubic materials, M.S. Pham, Y. Jeong, A. Creuzinger, M. Iadicola, A. Rollett, T. Foeke, Mach Conference, April 08-10, Annapolis, MD

  24. Crystal Plasticity Analysis of Constitutive Behavior of 5754 Aluminum Sheet (Invited), Minh-Son Pham, Anthony Rollett, Adam Creuziger, Mark Iadicola, Tim Foecke, TMS 2015

  25. Plastic anisotropy of face-centered-cubic materials: Roles of textures and dislocation interactions, Minh-Son Pham, Adam Creuziger, Mark Iadicola, Timothy Foecke, Anthony D. Rollett, TMS 2015

  26. A study on forming limit diagram using a self-consistent crystal plasticity model, Youngung Jeong, Minh-Son Pham, Mark Iadicola, Adam Creuziger, TMS 2015

  27. Forming limit diagram predictions using a self-consistent crystal plasticity model: a parametric study, YG Jeong, MS Pham, M Iadicola, A Creuziger, Key Engineering Materials 651, 193-198, 2015

  28. Dislocation-based constitutive model including latent hardening, aging and recovery for strain path dependence, Minh-Son Pham, Anthony D. Rollett, Adam Crueziger,Mark A. Iadicola and Timothy Foecke, MS&T 2014, Pittsburgh, PA, USA

  29. Crystal plasticity-based constitutive modelling (Invited), COLLOQUIA of the Computational Materials Science Center, George Mason University, Mar. 03 2014.

  30. Constitutive Modeling based on Evolutionary Multi-junctionsof Dislocations (Invited), Minh-Son Pham, Anthony D. Rollett, Adam Crueziger,Mark A. Iadicola and Timothy Foecke, ESAFORM 2014, Finland

  31. Crystal Plasticity Analysis of Constitutive Behavior of 5754 Aluminum Sheet, Minh-Son Pham, Anthony D. Rollett, Adam Crueziger,Mark A. Iadicola and Timothy Foecke, ICAA2014, Norway

  32. The strain path dependence of plastic deformation response of AA5754:Experiment and modelling, M.S. Pham, L. Hu, M. Iadicola, A. Creuziger, and A. D. Rollett, NUMISHEET 2014, Australia.

  33. Evolutionary constitutive modelling based on multi-scale interactions of dislocation (Invited), M.S. Pham, K.G.F. Janssens, E. Mazza, & S.R. Holdsworth, Symposium on Integrated computational modeling of materials for nuclear energy, TMS Annual Meeting 2013, 03-07thMar. 2013, San Antonio Texas, US.

  34. Constitutive model for cyclic deformation response of AISI 316L based on relationships between internal stress and dislocation microstructure. M.S. Pham, S.R. Holdsworth, 1st Int. Workshop on Physics based modelling ofmaterial Properties and Experimental Observations, 22-23.10.2012, Ankara Turkey. (Travel Grant Award)

  35. Relation of microstructural condition to the evolution of internal stresses during cyclic loading of AISI 316L, M.S. Pham & S. R. Holdsworth, 8th European Solid Mechanics Conference, 9-13 Jul. 2012, Graz-Austria.

  36. Microstructural evolution and cyclic deformation response of AISI 316L, at Max-Planck Institute for Iron Research, MPIE, Duesseldorf, 04.04.2012, Germany

  37. Change of stress-strain hysteresis loop and its links with microstructural evolution in AISI 316L during cyclic loading, M.S. Pham & S.R. Holdsworth, ICM11- Int. Conf. on Mechanical Behaviour of Materials, Como-Italy, 05-09/06/2011.

  38. TEM investigation of microstructural evolution during cyclic loading, at Electron Microscopy Center (ZEM, EMPA), 2010, Switzerland.

  39. The Effect of sub-grain formation and development on cyclic response in engineering steels. T. Mayer, M.S. Pham, C. Solenthaler, K.G.F.Janssens & S.R. Holdsworth, Proc. 18th European Conf. on Fracture, DVM, Dresden, 30/8-03/9/2010.