2023

1.   Sharma A., Emmanuel B., Kulasegaram S., Smooth particle hydrodynamics modelling of AFM nano-scratching of single crystal Copper , Nanomanufacturing and Metrology 6(1), 2022, Springer (I.F.: 3.78)

 2022

2.      Sharma A., Dubey D.K., Atomic insights into shock wave interactions with solid and porous   structures, Mechanics of Materials 177 (2022). Elsevier (I.F.: 4.137) https://doi.org/10.1016/j.mechmat.2022.104535

3.      Shinde A., Owhal A., Sharma A., Ranjan P., Roy T., Balasubramaniam R., Comparative analysis of mechanical properties for mono and poly-crystalline copper under nanoindentation - Insights from molecular dynamics simulations, Material Chemistry and Physics 277 (2022). Elsevier (I.F.: 4.778) https://doi.org/10.1016/j.matchemphys.2021.125559

 

2021 

4.      Roy T., Sharma A., Ranjan P., Balasubramaniam R., Modeling the Nano Indentation Behavior of Recast Layer and Heat Affected Zone on Reverse Micro EDMed Hemispherical Feature, Journal of Manufacturing Science and Engineering (ASME)143 (10), 101009. ASME (I.F.:3.033)

5.      Ranjan P., Sharma A., Roy T., Balasubramaniam R., Improvement in surface quality of diamond- turned aluminium substrate by using hydrogen peroxide: a molecular dynamics simulation study, Journal of Micromanufacturing, (2021), 27-35, https://doi.org/10.1177/2516598420963996

6.      Sharma A., Datta D., Balasubramaniam R., Prediction of tool wear constants for diamond turn machining of CuBe, Journal of Micromanufacturing. (2021) DOI: 10.1177/2516598420930992

2020

7.      Sharma A., Joshi S. S., Datta D., Balasubramaniam R., Investigation of tool and workpiece interaction on surface quality while diamond turning of CuBe alloy, Journal of Manufacturing Science and Engineering, 2020, Vol. 142 (2), 1-15 (ASME: I.F.-3.033). https://doi.org/10.1115/1.4045721

8.      Sharma A., Joshi S. S., Datta D., Balasubramaniam R., Modelling Tool Wear Mechanisms in Diamond Turning of Copper Beryllium, Journal of manufacturing processes, 2020/ Vol. 56, 439-450.. {Elsevier: I.F.- 5.01}. https://doi.org/10.1016/j.jmapro.2020.04.053

9.      Sharma A., Ranjan P., Balsubramaniam R., Investigation of effect of uncut chip thickness to edge radius ratio on nanoscale cutting behavior of single crystal copper: MD simulation approach, Journal of Micromanufacturing, (2020)  https://doi.org/10.1177/2516598420937638

10. Sharma A., as co-author, Micromachining- A review (Part I), Journal of micro-manufacturing (SAGE) /2020/ 1-17. https://doi.org/10.1177/2516598419895828

2019

11. Sharma A., Datta D., Balasubramaniam R., A molecular dynamics simulation of wear mechanism of diamond tool in nanoscale cutting of copper beryllium, International Journal of Advanced Manufacturing Technology, (2019), Vol. 102, 731-745. {Springer: I.F.- 3.226}   https://doi.org/10.1080/08927022.2019.1626988

12. Sharma A., Roy T., Ranjan P., Datta D., Balasubramaniam, R., “Investigation of tool-workpiece interaction in nanoscale cutting: A Molecular Dynamics study”,  International Journal of Precision Technology, (2019) Vol. 8, 411 - 428. 10.1504/IJPTECH.2019.100940

13. Roy T., Sharma A., Datta D., Balasubramaniam R., Molecular dynamics simulation of single   discharge and dimensionless correlation with actual material removal in micro-EDM, Molecular simulation, 2019, Vol. 45 (13), 1-11 (I.F.-2.178). https://doi.org/10.1080/08927022.2019.1626988

14. Ranjan P., Sharma A., Roy T., Balasubramaniam R., Jain V. K., “Molecular Dynamics Simulation of Mechanical Polishing”, International Journal of Precision Technology, 2019 / Vol.  8(2-4), 335-353. https://doi.org/10.1504/IJPTECH.2019.100932

2018

15. Sharma A., Datta D., Balasubramaniam R., An investigation of tool and hard particle interaction in nanoscale cutting of copper beryllium, Computational materials science (2018) 145 (2018) 208–223. (I.F.-3.3) https://doi.org/10.1016/j.commatsci.2018.01.011

16. Sharma A., Datta D., Balasubramaniam R., Molecular dynamics simulation to investigate the orientation effects on nanoscale cutting of single crystal Copper, Computational materials science (2018), 153, 241-250. (I.F.- 3.3)  https://doi.org/10.1016/j.commatsci.2018.07.002

17. Roy T., Sharma A., Datta D., Balasubramaniam R., Molecular dynamics study on the effect of discharge on adjacent craters on micro EDMed surface, Precision Engineering, Vol. 52, pp. 469-476, 2018.  https://doi.org/10.1016/j.precisioneng.2018.02.005 (I.F.-3.156)   

 

1.      Sharma, A., Datta, D., Balasubramaniam R., MD simulation study to investigate nanocutting process in Cu and CuBe, EUSPEN’s 18th International Conference  & Exhibition, Venice (ITALY) -2018.

2.      Ranjan, P., Sharma, A., Roy, T., Balasubramaniam R., Jain, V.K., Molecular Dynamics Simulation of Mechanical Polishing, COPEN, IIT Madras, December 2017.

3.      Sharma, A., Roy, T., Ranjan, P., Datta, D., Balasubramaniam R., Investigation of tool-workpiece interaction in nanoscale cutting: A Molecular Dynamics study, COPEN, IIT Madras, December 2017.

4.      Sharma, A., Ranjan, P., Balasubramaniam R., A comparative study on the reflectivity of metallic mirrors finished by deterministic and random processes, All India Manufacturing Technology, Design and Research Conference (AIMTDR 2014), IIT Guwahati, December 2014.

5.      Ranjan, P., Sharma, A., Balasubramaniam R., Suri V.K., Nano-Groove Generation by Diamond Turn Machining and Chemical Processing, All India Manufacturing Technology, Design and Research Conference (AIMTDR 2014), IIT Guwahati, December 2014.

6.    Saxena, R.K., Sharma, A., Application of a new friction model in Circular Cup Drawing, All India Manufacturing Technology, Design and Research Conference/ IIT Guwahati / December 12-14, 2014/ 808 (1-6)

7.      Ranjan, P., Sharma, A., Roy, T., Mechanism of material removal on stainless steel through diamond abrasion – a molecular dynamics simulation study, COPEN, IIT Kanpur, 2022