Dr. Sudeshna Roy | Granular Matter | Best Researcher Award 

Friedrich Alexander University Erlangen | Germany  

AUTHOR PROFILE

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EARLY ACADEMIC PURSUITS

Dr. Sudeshna Roy's academic journey began with a Bachelor of Engineering (B.Eng.) in Chemical Engineering from Jadavpur University, Kolkata, completed in 2006 with Honours and a Grade Point Average of 8.35 out of 10.0. She pursued her Master of Technology (M.Tech.) in Steel Technology, Metallurgical Engineering, and Materials Science at the Indian Institute of Technology (IIT), Mumbai, from 2010 to 2012, where she achieved a Grade Point Average of 9.28 out of 10.0. Her M.Tech. project focused on the "Modeling of the Reduction Zone of MIDREX Shaft Furnace." Dr. Roy then completed her Ph.D. in Multiscale Mechanics at the University of Twente (UTwente), Netherlands, from 2013 to 2018, with a dissertation titled "Hydrodynamic Theory of Wet Particle Systems," under the supervision of Prof. Stefan Luding and Dr. Thomas Weinhart.

PROFESSIONAL ENDEAVORS

Dr. Roy's professional career encompasses extensive research and teaching roles. Currently, she serves as the Manager of Process Simulation at Formulation Technology Research Laboratories, Daiichi-Sankyo Europe GmbH, since March 2024. Her previous positions include Postdoctoral Researcher roles at the Institute for Multiscale Simulation (Friedrich-Alexander-Universität, Germany), Heriot-Watt University (UK), Syracuse University (NY, US), and Pennsylvania State University (PA, US). She has also worked in various capacities at Essar Steel Ltd., including Deputy Manager in Research and Development, Assistant Manager in Environment, and Assistant Manager in HBI Technical Services.

CONTRIBUTIONS AND RESEARCH FOCUS

Dr. Roy's research interests lie in granular matter, the Discrete Element Method, particle interactions, wet and cohesive granular materials, non-Newtonian flow rheology, and constitutive relations. She has made significant contributions to the study of the Rheology of Granular Matter, focusing on active matter, sheared amorphous solids, avalanche, yielding behavior, plasticity, and collective motion. Her research on Granular Matter has been pivotal in understanding the complex behavior of these systems under various conditions, leading to advancements in both theoretical and applied mechanics.

CITATIONS

• Citations   415
• h-index     009
• i10-index  009

IMPACT AND INFLUENCE

Dr. Roy's work has had a substantial impact on the field of multiscale mechanics, particularly in the study of Granular Matter. Her contributions have been recognized with several awards and fellowships, including the Alexander von Humboldt Research Fellowship for postdocs (2021-2023), the Emerging Talents Initiative (ETI) grant at FAU (2021), and the FFL Habilitation Fellowship for postdocs (2023-2024). She has also been a guest editor for the Journal "Granular Matter" and served on the local scientific and organizing committee of DEM9, enhancing her visibility and influence in the international scientific community.

ACADEMIC CITATIONS

Dr. Roy's research has been widely cited, reflecting the significant impact of her work on the scientific community. Her studies on Granular Matter and the rheology of granular systems have been referenced in numerous academic publications, demonstrating the relevance and importance of her contributions to the field.

LEGACY AND FUTURE CONTRIBUTIONS

Dr. Roy's legacy is marked by her dedication to advancing the understanding of Granular Matter and its applications in various fields. Her future contributions are expected to further explore the complexities of granular systems, potentially leading to new insights and innovations in process simulation and materials science. As a manager, researcher, and educator, Dr. Roy continues to influence the field through her ongoing research, teaching, and mentorship of emerging talents in the scientific community.

GRANULAR MATTER 

Dr. Roy's research prominently features the keywords Granular Matter, Discrete Element Method, and non-Newtonian flow rheology. Her work in Granular Matter explores the fundamental and applied aspects of particle interactions and the behavior of granular systems under various conditions. The integration of these keywords in her research underscores the innovative and cutting-edge nature of her academic and professional pursuits, solidifying her contributions to the advancement of multiscale mechanics and materials science.

NOTABLE PUBLICATION

• SPIRAL: An efficient algorithm for the integration of the equation of rotational motion

  Citation: 03       Year: 2024

• Structural fluctuations in thin cohesive particle layers in powder-based additive manufacturing

  Citation: 01       Year: 2024

• Effect of cohesion on structure of powder layers in additive manufacturing

  Citation: 03       Year: 2023

• A direct link between active matter and sheared granular systems

  Citation: 48       Year: 2021

• Fast, flexible particle simulations — An introduction to MercuryDPM

  Citation: 88       Year: 2020