Dr. Archisman Dasgupta: Senior Research Fellow at National Institute of Technology Agartala, India
Title / Designation: Dr
Name: Archisman Dasgupta
Current Role / Designation: Senior Research Fellow
Organization / Institution Details: National Institute of Technology Agartala
Country: India
Subject Track: Engineering
Award Categories: Best Innovator Award
Archisman Dasgupta is an emerging leader in the field of sustainable engineering and additive manufacturing. With a Ph.D. currently underway at the National Institute of Technology (NIT) Agartala, his research aims to revolutionize the 3D printing industry by developing biodegradable filaments derived from waste plastic and used tyre rubber. Drawing from his strong academic foundation in Mechanical and Production Engineering, Archisman’s work merges sustainability with innovation, with a vision of reducing plastic waste through the development of eco-friendly materials for industrial applications. His research not only contributes to the circular economy but also offers practical solutions to the global problem of plastic waste management.
Online Profiles
Archisman maintains an active professional presence on both LinkedIn and ResearchGate, which serve as platforms to share his work, collaborate with other researchers, and engage with the academic and industrial communities. His LinkedIn profile is a reflection of his extensive experience in mechanical engineering, research, and teaching, while his ResearchGate profile provides access to his growing body of work in sustainable materials science.
Education
Archisman’s educational journey has been marked by a consistent pursuit of excellence in engineering. He earned his Bachelor of Technology (B.Tech) in Mechanical and Automation Engineering from Guru Gobind Singh Indraprastha University (GGSIPU) in New Delhi, followed by a Master of Technology (M.Tech) in Production Engineering from NIT Agartala, where he specialized in Computer Integrated Manufacturing. His M.Tech research on optimizing machining costs for Inconel 800 using wire-cut EDM laid the groundwork for his deep interest in materials science and manufacturing optimization. Currently, as a Ph.D. candidate at NIT Agartala, his research is focused on the development of sustainable 3D printing filaments, demonstrating his commitment to addressing environmental challenges through engineering innovation.
Research Focus
Archisman’s research is centered around the development and optimization of biodegradable 3D printing materials, specifically those derived from waste plastic reinforced with used tyre rubber. His primary goal is to create filaments that are not only environmentally friendly but also possess the necessary mechanical properties for industrial-scale 3D printing. By exploring the interaction between waste materials and their potential for biodegradation, he aims to provide viable alternatives to petroleum-based polymers, which are widely used in the 3D printing industry. His work aligns with the growing global demand for sustainable manufacturing practices and contributes to the circular economy by utilizing waste materials in a productive and eco-friendly way.
Experience
Archisman’s professional journey as an educator has allowed him to make substantial contributions to the academic community. He worked as a Lecturer in the Mechanical Engineering Department at TTAADC Polytechnic Institute, where he taught courses in manufacturing processes, materials engineering, and workshop technology. During his tenure, Archisman also engaged in curriculum development, fostering an environment of continuous learning. In addition, he worked as a Faculty at the educational society of the Government of Tripura, where he contributed to the training of faculty and students on various engineering and technical topics. These roles allowed him to share his technical expertise and research insights, while also staying abreast of new developments in the fields of additive manufacturing and sustainable materials.
Research Timeline & Activities
Archisman’s research career has evolved steadily, beginning with his M.Tech thesis on optimizing machining costs for Inconel 800. This project laid the foundation for his passion for materials science and process optimization. His current Ph.D. research, started in February 2021, is focused on developing biodegradable 3D printing filaments from waste plastic and used tyre rubber. In addition to his academic research, Archisman has been actively involved in publishing research papers in high-impact, peer-reviewed journals and presenting his findings at international conferences. His research activities are characterized by a strong interdisciplinary approach, combining material science, waste management, and manufacturing technology to address environmental sustainability challenges.
Awards & Honors
Throughout his academic and professional career, Archisman has received multiple recognitions for his outstanding contributions to research and education. Notably, he has been a life-time associate member of the Institution of Engineers (IEI) India since 2017, demonstrating his commitment to the advancement of engineering knowledge and practices. In 2025, he was appointed as an academic board member for Global Open Share Publishing (GOSP Science), further solidifying his position as an emerging leader in sustainable engineering. These accolades reflect his dedication to fostering innovation in the field of sustainable manufacturing and reinforcing the importance of interdisciplinary collaboration for addressing global challenges.
Top Noted Publication
One of Archisman’s top publications is titled “Ground tyre rubber as an enhancer for waste plastic biodegradation: microscopic, kinetic, and thermodynamic insights,” published in the Journal of Rubber Research. This paper is significant because it explores the innovative use of ground tyre rubber to enhance the biodegradation process of waste plastics, a critical area in the fight against plastic pollution. The publication has been widely recognized for its novel approach to using waste materials in a sustainable manner and is frequently cited in studies focused on waste management, recycling, and biodegradable materials. Archisman’s contributions to this research represent a key advancement in sustainable polymer composites and additive manufacturing, aligning with his overarching goal to develop environmentally responsible materials for future industrial applications.
Entropy-TOPSIS-based material selection for sustainable polymer composite: An MCDM framework promoting circular economy
Journal of Elastomers & Plastics (2025-08)
DOI: 10.1177/00952443251331171
Contributors: Archisman Dasgupta, Binayak Sen, Prasenjit Dutta, Nikunj Rachchh, Nagaraj Patil, Abinash Mahapatro, A. Karthikeyan
This paper presents a novel entropy-based TOPSIS (Technique for Order of Preference by Similarity to Ideal Solution) method for the selection of sustainable polymer composites, focusing on promoting a circular economy by integrating multi-criteria decision-making (MCDM) techniques. The framework aids in optimizing material selection for eco-friendly manufacturing.Ground tyre rubber as an enhancer for waste plastic biodegradation: microscopic, kinetic and thermodynamic insights
Journal of Rubber Research (2025-05)
DOI: 10.1007/s42464-025-00304-7
Contributors: Archisman Dasgupta, Prasenjit Dutta, Biswanath Bhunia
This article investigates the role of ground tyre rubber as an enhancer for the biodegradation of waste plastic. The study provides microscopic, kinetic, and thermodynamic insights into how incorporating ground tyre rubber can accelerate plastic degradation, offering an innovative approach to tackling plastic waste.Development of a sustainable polymer composite: enhancing properties of waste plastic with ground tire rubber reinforcement
Physica Scripta (2024-09-01)
DOI: 10.1088/1402-4896/ad6bf8
Contributors: Archisman Dasgupta, Binayak Sen, Prasenjit Dutta
This research focuses on the development of a sustainable polymer composite by reinforcing waste plastic with ground tire rubber. The study explores the enhanced physical, mechanical, and thermal properties of the composite, paving the way for its potential use in various industrial applications, including in the automotive and construction sectors.Reinforcing effects of ground tyre rubber on physical, mechanical, and thermal properties of polyethylene terephthalate
Journal of Elastomers & Plastics (2024-08)
DOI: 10.1177/00952443241254934
Contributors: Archisman Dasgupta, Prasenjit Dutta
This paper delves into how ground tyre rubber reinforcement can improve the physical, mechanical, and thermal properties of polyethylene terephthalate (PET), a widely used plastic. The findings highlight the potential of ground tyre rubber to enhance the performance of PET in various industrial applications, especially in packaging and textiles.Printability of elastomer as a 3D printing material for additive manufacturing
Journal of Rubber Research (2024-02)
DOI: 10.1007/s42464-024-00241-x
Contributors: Archisman Dasgupta, Prasenjit Dutta
This article examines the suitability of elastomeric materials for 3D printing, focusing on their printability and performance in additive manufacturing. The study addresses key challenges and proposes solutions to improve the usability of elastomers in the rapidly growing field of 3D printing.A Study of Additive Manufacturing Using 3D Printing Machines and Pens
Book Chapter (2024-01-16)
DOI: 10.4018/979-8-3693-2647-3.ch005
Contributors: Archisman Dasgupta, Prasenjit Dutta
This book chapter provides a comprehensive overview of additive manufacturing techniques, particularly focusing on the use of 3D printing machines and pens. It explores the diverse applications of 3D printing and its impact on modern manufacturing processes, while also highlighting the challenges and advancements in the field.