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Haribabu, G.N. and Jegadeesan, J.T. and Bhattacharya, C. and Basu, B. (2023) A deep adversarial approach for the generation of synthetic titanium alloy microstructures with limited training data. In: Computational Materials Science, 230 .
Mukherjee, R and Abinandanan, TA (2022) Grain boundary grooving in a polycrystalline thin film: A phase-field study. In: Computational Materials Science, 203 .
Das, P and Dutta, P (2020) Three-dimensional phase field simulation of spheroidal grain formation during semi solid processing of Al-7Si-0.3 Mg alloy. In: Computational Materials Science, 184 .
Narendar, S and Ravinder, S and Gopalakrishnan, S (2012) Study of non-local wave properties of nanotubes with surface effects. In: Computational Materials Science, 56 . pp. 179-184.
Datta, A and Srirangarajan, A and Waghmare, UV and Ramamurty, U and To, AC (2011) Surface effects on stacking fault and twin formation in fcc nanofilms: A first-principles study. In: Computational Materials Science, 50 (12). pp. 3342-3345.
Narendar, S and Mahapatra, Roy D and Gopalakrishnan, S (2010) Investigation of the effect of nonlocal scale on ultrasonic wave dispersion characteristics of a monolayer graphene. In: Computational Materials Science, 49 (4). pp. 734-742.
Narendar, S and Gopalakrishnan, S (2009) Nonlocal scale effects on wave propagation in multi-walled carbon nanotubes. In: Computational Materials Science, 47 (2). pp. 526-538.
Malvade, I and Deb, A and Biswas, P and Kumar, A (2009) Numerical prediction of load-displacement behaviors of adhesively bonded joints at different extension rates and temperatures. In: Computational Materials Science, 44 (4). pp. 1208-1217.
Abhilash, V and Balu, R and Balaji, S and Nathan, Senthil S and Mohan, S (2004) Monte Carlo simulation of transport process of the sputtered species in the facing target sputtering technique. In: Computational Materials Science, 30 (3-4). pp. 523-529.
