Deep Choudhuri
Assistant Professor
Materials and Metallurgical Engineering
- deep.choudhuri@chinaqinyu.com
- 575-835-5465
- 116 Jones Hall
Research Areas
- Non-classical nucleation; Crystallization; Phase trasformations; Dislocation plasticity
- Metallic alloys; Hybrid inorganic-organic materials
- Classical Molecular Dynamics and Monte Carlo simulations; Density functional theory & Ab initio Molecular Dynamics; Phase-field modelling; Machine learning
Education
Ph.D. Materials Science and Engineering, Michigan State University, 2009
Bachelor’s in Technology (B Tech) in Materials Science and Engineering, Indian Institute of Technology (IIT), Kharagpur, 2002
Computational Microstructure Physics Group
Our mission is to computationally discover atomic-scale phenomena that will help in engineering materials for targeted applications. For this pupose, we employ concepts at the intersection of Materials Science, Condensed Matter Physics, Quantum Chemisty & Micro-mechanics.
Currently, we are focussed on understanding: (A) non-classical nucleation pathways during solidification; (B) chemical reactivity and properties of hybrid inorganic-organic materials like Si-based polyhedral oligomeric silsesquioxnes and metal-organic frameworks; and, (C) defect arrangements in high-temperature alloys. Our recent findings are as follows:
(A) By coupling ab initio Molecular Dynamics and unsupervised learning algorithms, we have discovered two transformation pathways during the solidification of binary Al-Sc allloys: (i)Sc−centered-polyhedrons→L12−Al3Sc→liquid−Al/L12−Al3Sc-interfacial-ordering→fcc−Al; and (ii) Sc−centered-polyhedrons→hcp−Al→bcc−Al→fcc−Al. These pathways open doors for engineering alloy solidification - starting from the liquid state.(Physical Review Materials, 6(10), p.103406)
(B) Trisilanol polyhedral oligomeric silsesquioxane (POSS) are a category of inorganic–organic
material that comprise an inorganic open cage silica structure, organic attachments,
and silanol (SiOH) groups. Recently, trisilanol POSS was added to Al-based alloys, and found to promote
substantial microstructural refinement, and improved mechanical strength and fatigue
life compared to conventional compositions. To better understand the interaction between
liquid-Al atoms and POSS, we have used ab initio molecular dynamics simulations at 1500 K. We found that that Al atoms modified the silanol groups to
form, two energetically favorable coordinate complexes: monodentate SiOAl and bidentate (SiO)2Al. Such complexes were formed by Al atoms attracting electrons towards themselves
from the POSS molecule. This bonding mechanism allowed trisilanol POSS to organize
the neighboring Al atoms into geometric motifs that can potentially serve as nucleation
sites within liquid-Al, and facilitate microstructural refinement. (Computational Materials Science, 139, p.112985)
(C) Several high-temperature body-centered cubic (bcc) structural materials such as Nb-, Zr- and Ti-based alloys undergo phase separation, which is a second-order phase transformation, whereby the host lattice decomposes into distinct bcc domains with different compositions. Using hybrid Monte Carlo/Molecular Dynamics simulations, we studied the high-strain-rate response of bcc-forming Nb–xZr (x = 0, 25, 50 at.%) alloys at 1000 K. Our investigation shows that softening of bcc alloys can result from a coupling of mechanisms involving local solute segregation, displacive phase transformation and twinning occurring across multiple slip planes. (Journal of Materials Science, p.1-20)
- NSF CAREER: Emergence of in-liquid structures in metallic alloys by nucleation and growth (PI)
- American Chemical Society, Petroleum Research Fund: Correlation between bond dynamics and thermodynamic factors in negative thermal expansion materials (PI)
- Sandia National Laboratory - LDRD: Ab initio MD simulation of gas entrapment in metal-organic-frameworks (PI)
- NSF MRI: Track I - Acquisition of a High Performace Computing System at New Mexico Tech (Co-PI)
- Army Research Laboratory: Atomistic Modeling: Engineer Liquid Phase Structure and Composition for a High Density of Nucleation Sites (Co-PI)
- NMT Sophomore research program
-
NMT-Hoonify NMSBA project - Completed (Co-PI)
*Undergraduate student co-author, **Graduate student co-author, “ ” corresponding author
Independent career publications @NMT (Fall'19 - present)
- Choudhuri, D., Rinehart. A.J., (2024),"Interaction between water and point defects inside volume-constrained α-quartz: An ab initio molecular dynamics study at 300K", Journal of Applied Physics - accepted
- Choudhuri, D., Lee, A., (2024),"Ab initio molecular dynamics study of interactions between isolated polyhedral oligomeric silsesquioxane trisilanols and aluminum", Computational Materials Science - accepted
- [Invited Article] Hasan, M.M.**, Srinivasan, S.G., Choudhuri, D., (2023) "Transformation and twinning induced plasticity in phase separated bcc Nb-Zr alloys: An atomistic study", Journal of Materials Science, 59, p.4728–4747
- Wilkinson, H.*, Boyd, B.*, O’Connell, J.M.**, Knox, R., Rinehart, A.J., Majumdar, B.S. and Choudhuri, D., (2023). "Factors controlling heteroepitaxial phase formation at intermetallic-Al3Sc/liquid interfaces". Journal of Applied Physics, 133(12), p.124902.
- Choudhuri, D., Majumdar, B.S. and Wilkinson, H*., (2022). “Investigation of in-liquid ordering mediated transformations in Al-Sc via ab initio molecular dynamics and unsupervised learning”. Physical Review Materials, 6(10), p.103406.
- Eshed, E., Choudhuri, D. and Osovski, S., (2022). “M7C3: The story of a misunderstood carbide”. Acta Materialia, p.117985.
- Choudhuri, D. and Blake, L.**, (2021). “Particle curvature effects on microstructural evolution during solid-state sintering: phenomenological insights from phase-field simulations”. Journal of Materials Science, 56(12), pp.7474-7493. (Article was a finalist for the prestigious Robert Wolfgang Cahn award.)
- Choudhuri, D., Matteson, S*. and Knox, R*., (2021). “Nucleation of coupled body-centered-cubic and closed-packed structures in liquid Ni-Cr alloys”. Scripta Materialia, 199, p.113857.
- Choudhuri, D., (2021).“Local structure and bonding environment of intermetallic β1 precipitate phase nucleus in binary Mg-Nd”. Computational Materials Science,187, p.110111.
- Paranjape, P.**, Srinivasan, S.G. and Choudhuri, D.*, (2020). "Correlation between bonding, vacancy migration mechanisms, and creep in model binary and ternary hcp-Mg solid solutions". Journal of Applied Physics, 128(14), p.145103. (Student was my PhD advisee from UNT)
- Choudhuri, D. and Majumdar, B.S., (2020). "Structural changes during crystallization and vitrification of dilute FCC-based binary alloys". Materialia, 12, p.100816.
- Choudhuri, D. and CampBell, A.**, (2020). "Interface dominated deformation mechanisms in two-phase fcc/B2 nanostructures: Nishiyama-Wasserman vs. Kurdjumov-Sachs interfaces". Computational Materials Science, 177, p.109577.
- Reynolds, C.R., Herl, Z., Ley, N.A., Choudhuri, D., Lloyd, J.T. and Young, M.L., (2020). "Comparing CALPHAD predictions with high energy synchrotron radiation X-ray diffraction measurements during in situ annealing of Al3CoCrFeNi high entropy alloy". Materialia, 12, p.100784.
- Choudhuri, D, Srinivasan, S.G. and Mishra, R.S., (2020). “Deformation of lamellar FCC-B2 nanostructures containing Kurdjumov-Sachs interfaces: Relation between interfacial structure and plasticity”. International Journal of Plasticity, 125, pp.191-209
Selected computational publications from postdoctoral research
- Choudhuri, D. and Srinivasan, S.G., (2019). "Density functional theory-based investigations of solute kinetics and precipitate formation in binary magnesium-rare earth alloys: A review". Computational Materials Science, 159, pp.235-256. (Invited paper in special issue – “Rising Stars in Computational Materials Science”)
- Choudhuri, D., Gwalani, B., Gorsse, S., Komarasamy, M., Mantri, S.A., Srinivasan, S.G., Mishra, R.S. and Banerjee, R., (2019). "Enhancing strength and strain hardenability via deformation twinning in fcc-based high entropy alloys reinforced with intermetallic compounds." Acta Materialia, 165, pp.420-430.
- Choudhuri, D., Shukla, S., Gwalani, B., Banerjee, R. and Mishra, R.S., (2019). "Deformation induced intermediate metastable lattice structures facilitate ordered B2 nucleation in a fcc-based high entropy alloy". Materials Research Letters, 7(1), pp.40-46.
- Choudhuri, D., Banerjee, R. and Srinivasan, S.G., (2018). "Uniaxial deformation of face-centered-cubic (Ni)-ordered B2 (NiAl) bicrystals: atomistic mechanisms near a Kurdjumov–Sachs interface." Journal of Materials Science, 53(8), pp.5684-5695.
- Choudhuri, D., Srinivasan, S.G., Gibson, M.A., Zheng, Y., Jaeger, D.L., Fraser, H.L. and Banerjee, R., (2017). "Exceptional increase in the creep life of magnesium rare-earth alloys due to localized bond stiffening." Nature Communications, 8(1), pp.1-9.
- Choudhuri, D., Zheng, Y., Alam, T., Shi, R., Hendrickson, M., Banerjee, S., Wang, Y., Srinivasan, S.G., Fraser, H. and Banerjee, R., (2017). "Coupled experimental and computational investigation of omega phase evolution in a high misfit titanium-vanadium alloy." Acta Materialia, 130, pp.215-228.
- Choudhuri, D., Banerjee, R. and Srinivasan, S.G., (2017). "Interfacial structures and energetics of the strengthening precipitate phase in creep-resistant Mg-Nd-based alloys." NPG Scientific Reports, 7(1), pp.1-8.
- Choudhuri, D., Srinivasan, S.G., Gibson, M.A. and Banerjee, R., 2017. Bonding environments in a creep–resistant Mg–RE–Zn alloy. In Magnesium Technology 2017 (pp. 471-475). Cham: Springer International Publishing.
- Choudhuri, D., Alam, T., Borkar, T., Gwalani, B., Mantri, A.S., Srinivasan, S.G., Gibson, M.A. and Banerjee, R., (2015). "Formation of a Huesler-like L21 phase in a CoCrCuFeNiAlTi high-entropy alloy." Scripta Materialia, 100, pp.36-39.
- Choudhuri, D., Dendge, N., Nag, S., Gibson, M.A. and Banerjee, R., (2014). "Role of applied uniaxial stress during creep testing on precipitation in Mg–Nd alloys." Materials Science and Engineering: A, 612, pp.140-152.
- Choudhuri, D., Dendge, N., Nag, S., Meher, S., Alam, T., Gibson, M.A. and Banerjee, R., (2014). "Homogeneous and heterogeneous precipitation mechanisms in a binary Mg–Nd alloy." Journal of Materials Science, 49, pp.6986-7003.
- A. CampBell, "Strength and mechanical response of Dual-phase Ni/Al bicrystals: A comparison between Kurdjumov-Sachs and Nishiyama Wasserman interfaces", Masters Thesis, New Mexico Institute of Mining and Technology, 2021
- P. Paranjape, "First principles study of the effect of local bonding on the diffusion mechanisms in alloys", PhD Dissertation, University of North Texas, 2021 (Co-advised from NMT)
Graduate:
- Md. Mahmmudul Hasan (Masters program)
- Brianne Boyd (Accelerated Masters program)
- Rashedul Chowhury (Masters program)
Undergraduate:
- Gavin Fillip
- Andrew Hubbard
Former students:
- Audrey CampBell, MS (pursuing PhD at Arizona State University)
- Reilly Knox, BS (pursuing PhD at Pennsylvania State University)
- Hunter Wilkinson, BS (3D Glass Solutions)
- Skyler Matteson, BS (Department of Transportation)
- Logan Blake, ME (Intel)
- Joseph Liu (former Sophomore Research Program grant recipient)
- Erica Pape
- Github: Few in-house programs (and forks) used in my group
- A student-friendly guide to running ab initio MD simulations using VASP - prepared by Brianne Boyd
- Lectures on Computational Materials Science
Courses Taught
MTLS 202 &202L Materials Engineering 1
MTLS 235 Materials Engineering 2
MTLS 3010 Microstructure and processing
MTLS 3027/3207D Physical Metallurgy
MTLS 4046/4046D Survey of Computer Methods in Materials Science
MTLS 5091 Thesis
MTLS 5000 Directed Study
MTLS 580/580D Dislocation theory