Pavan Gupta | Heterogeneous catalysis | Best Researcher Award

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Dr. Pavan Gupta | Heterogeneous catalysis | Best Researcher Award

Doctorate at CSIR-Central Institute of Mining and Fuel Research, India

Pavan Kumar Gupta is a distinguished chemical engineer with extensive experience in catalysis and process development. With a background in Chemical Engineering from prestigious institutions including HIT, Haldia, IIT-BHU, and IIT-ISM, he has built a strong reputation in the field of chemical engineering. His expertise spans various domains such as heterogeneous catalysis, syngas conversion, and the utilization of coal fly ash in catalytic processes. Gupta’s work contributes significantly to advancing sustainable technologies and resource utilization in the chemical industry.

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Pavan Kumar Gupta has published extensively in high-impact scientific journals, with several papers in prestigious SCI journals. His research has garnered significant attention, as evidenced by his numerous citations and the high visibility of his work in the field of chemical engineering. His author metrics reflect a strong impact on both academic research and practical applications, showcasing his contributions to advancements in catalysis and sustainable technologies.

  • Citations: 162 citations accumulated across 154 documents, highlighting the impact and relevance of his research.
  • Documents: A total of 18 published documents, showcasing a substantial body of work.
  • h-index: 6, indicating that Gupta has at least 6 papers each cited at least 6 times, reflecting a balanced combination of productivity and citation impact.

Education

Pavan Kumar Gupta’s academic journey began with a B.Tech in Chemical Engineering from HIT, Haldia in 2013. He furthered his studies with an M.Tech in Chemical Engineering from IIT-BHU in 2015. His dedication to the field culminated in a PhD in Chemical Engineering from IIT-ISM in 2024. His educational background provided him with a solid foundation in both theoretical and practical aspects of chemical engineering, shaping his expertise in catalysis and process development.

Research Focus

Gupta’s research primarily focuses on heterogeneous catalysis, specifically in areas such as syngas conversion, CO2 absorption, and the development of advanced catalytic materials. He is particularly interested in the utilization of waste materials, like coal fly ash, to create valuable catalysts for processes such as Fischer-Tropsch synthesis. His work aims to advance sustainable technologies and improve the efficiency and environmental impact of industrial chemical processes.

Professional Journey

Pavan Kumar Gupta’s professional journey is marked by significant contributions to both research and industry. He has been involved in various projects related to coal-to-liquid (CTL) technologies, catalyst development, and resource utilization from waste materials. His role in the CSIR-CIMFR includes leading research projects and developing innovative solutions for energy and chemical industries. His experience reflects a commitment to addressing both scientific and practical challenges in chemical engineering.

Honors & Awards

Throughout his career, Pavan Kumar Gupta has received recognition for his contributions to chemical engineering and catalysis. His awards and honors reflect his dedication to advancing scientific knowledge and his impact on sustainable technological solutions. These accolades underscore his role as a leading researcher and innovator in his field.

Publications Noted & Contributions

Gupta’s notable publications span various high-impact journals, highlighting his contributions to the field of chemical engineering. His work includes influential papers on catalysis, waste utilization, and renewable fuels. Key publications include studies on Fischer-Tropsch synthesis using coal fly ash-derived catalysts, and reviews on biomass conversion. His contributions are widely recognized for advancing both theoretical knowledge and practical applications in catalysis.

Enhanced CO2 Methanation over Nickel‐Based Unsupported Catalyst Synthesized by Chemical Precipitation Method

  • Journal: ChemistrySelect
  • Date: August 12, 2024
  • DOI: 10.1002/slct.202400572
  • Contributors: Abhay Kumar Choudhary, Sudeep Yadav, Pavan Kumar Gupta
  • Summary: This study explores the synthesis of a nickel-based unsupported catalyst using a chemical precipitation method and its application in CO2 methanation. The research highlights advancements in catalytic performance and efficiency for CO2 conversion, contributing to sustainable energy solutions.

Significance and Influence of Various Promoters on Cu‐Based Catalyst for Synthesizing Methanol from Syngas: A Critical Review

  • Journal: Journal of Chemical Technology & Biotechnology
  • Date: May 2023
  • DOI: 10.1002/jctb.7331
  • Contributors: Shiva Kumar Saw, Sudipta Datta, PD Chavan, Pavan K Gupta, Shweta Kumari, Gajanan Sahu, Vishal Chauhan
  • Summary: This critical review examines the role of various promoters in enhancing the performance of Cu-based catalysts for methanol synthesis from syngas. The paper provides a comprehensive analysis of promoter effects, offering valuable insights for optimizing catalytic processes in industrial applications.

Comparative Studies of Co/SBA‐15 Catalysts Synthesized with Different Silica Sources Including Coal Fly Ash for Fischer‐Tropsch Synthesis

  • Journal: ChemistrySelect
  • Date: March 20, 2023
  • DOI: 10.1002/slct.202204962
  • Contributors: Pavan K. Gupta, Vineet Kumar, Sudip Maity, Goutam Kishore Gupta, Sudipta Datta, Arvind Singh, Siddhartha Sengupta
  • Summary: This research investigates the performance of Co/SBA-15 catalysts synthesized from various silica sources, including coal fly ash, in Fischer-Tropsch synthesis. The study emphasizes the potential of using waste materials as silica sources for catalyst preparation, contributing to more sustainable catalytic processes.

Effect of Char Temperature on CO2 Gasification of High Ash Coal and Biomass

  • Journal: ChemistrySelect
  • Date: 2022
  • DOI: 10.1002/SLCT.202201551
  • WOSUID: WOS:000863629400001
  • Contributors: Neelam Kumari, Sudipta Datta, Gajanan Sahu, Pinaki Sarkar, Sujan Saha, Prakash D. Chavan, Vishal Chauhan, Pavan Kumar Gupta
  • Summary: This article examines the impact of char temperature on the CO2 gasification process of high ash coal and biomass. The findings provide insights into optimizing gasification conditions for improved efficiency and resource utilization in energy production.

Heterogeneous Nanocatalyst for Biodiesel Synthesis

  • Journal: ChemistrySelect
  • Date: 2022
  • DOI: 10.1002/SLCT.202201671
  • WOSUID: WOS:000828851400001
  • Contributors: Deshal Yadav, Sudipta Datta, Sujan Saha, Subhalaxmi Pradhan, Shweta Kumari, Pavan Kumar Gupta, Vishal Chauhan, Shiva Kumar Saw, Gajanan Sahu
  • Summary: This research focuses on the development of a heterogeneous nanocatalyst for biodiesel synthesis. The study highlights advancements in catalyst design and performance for efficient biodiesel production, addressing key challenges in sustainable fuel generation.

Research Timeline

Pavan Kumar Gupta’s research timeline illustrates a trajectory of increasing specialization and impact. Starting with foundational research during his B.Tech and M.Tech studies, his focus evolved towards advanced catalysis and sustainable processes during his PhD. Over the years, he has managed and participated in numerous research projects, contributing to significant advancements in chemical engineering. His timeline reflects a consistent commitment to addressing complex challenges in catalysis and resource utilization.

Collaborations and Projects

Gupta’s work involves extensive collaborations with national and international research institutions. His projects span diverse areas, including the development of catalysts for syngas conversion, utilization of coal fly ash, and quality monitoring in energy production. Notable collaborations include projects with CSIR-CIMFR and CMPDI Ranchi, where he has played key roles in various research initiatives. His collaborative efforts underscore his ability to work effectively across different teams and contribute to multidisciplinary research projects.

Strengths of the Best Researcher Award

  1. Innovative Research Contributions: Dr. Pavan Kumar Gupta’s work in heterogeneous catalysis and sustainable technologies, such as utilizing coal fly ash in catalytic processes and advancing CO2 methanation, demonstrates a strong commitment to innovation in the field. His contributions to enhancing catalytic performance and resource utilization have significant practical implications.
  2. High Citation Impact: With 162 citations across 154 documents, Gupta’s research has had a notable impact on the scientific community. His work is highly regarded and frequently referenced, reflecting its relevance and influence in advancing catalysis and chemical engineering.
  3. Diverse Research Topics: Gupta’s research spans various crucial areas, including syngas conversion, CO2 absorption, and the development of advanced catalytic materials. His ability to address multiple facets of chemical engineering showcases his broad expertise and adaptability.
  4. Recognition in Prestigious Journals: Gupta’s publications in high-impact journals such as ChemistrySelect and the Journal of Chemical Technology & Biotechnology underscore the quality and significance of his research. His ability to publish in top-tier journals highlights his position as a leading researcher in his field.
  5. Successful Utilization of Waste Materials: Gupta’s focus on utilizing coal fly ash and other waste materials for catalytic processes is a significant strength. This approach not only advances sustainable technologies but also addresses environmental challenges by repurposing waste materials.

Areas for Improvement

  1. Broader Research Scope: While Gupta’s research is highly specialized, expanding his focus to include emerging areas such as renewable energy technologies or advanced materials could further enhance the breadth and impact of his work.
  2. Collaborative Networks: Although Gupta has engaged in extensive collaborations, increasing partnerships with international research institutions and industry leaders could broaden the scope of his research and enhance its practical applications.
  3. Public Engagement and Outreach: Enhancing efforts in public science communication and outreach could help disseminate his research findings to a broader audience, including policymakers, industry professionals, and the general public.
  4. Research Funding: Securing additional funding for large-scale or interdisciplinary projects could support more ambitious research initiatives and enable the development of innovative solutions to complex problems in catalysis and sustainability.
  5. Diversification of Publication Venues: Expanding publication efforts to include interdisciplinary journals or those focusing on applied research could help reach new audiences and increase the practical impact of his findings.

Conclusion

Dr. Pavan Kumar Gupta’s recognition as the Best Researcher reflects his exceptional contributions to the field of chemical engineering, particularly in heterogeneous catalysis and sustainable technologies. His innovative research, high citation impact, and diverse publication record underscore his significant role in advancing scientific knowledge and practical applications. While there are opportunities for further growth, such as expanding research scope and increasing public engagement, Gupta’s achievements highlight his dedication and expertise. His work continues to drive advancements in catalysis and resource utilization, reinforcing his position as a leading researcher in his field.

Zain Ul Abideen | Catalysis | Best Researcher Award

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Dr. Zain Ul Abideen | Catalysis | Best Researcher Award

Doctorate at Central South University, China

Dr. ZainUl Abideen is a post-doctoral research fellow at Central South University, China, specializing in materials chemistry, environmental chemistry, and electro-catalysis. With a PhD in Environmental Science and Engineering from Nanjing University of Information Science and Technology, his research focuses on synthesizing semiconductor nanomaterials through various methods such as solid-state, co-precipitation, and hydrothermal techniques. His work aims to advance green energy production and environmental remediation by enhancing photocatalytic and electrocatalytic processes. He has a strong background in water management, supported by both master’s and bachelor’s degrees in the field from The University of Agriculture Peshawar, Pakistan.

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ORCID Profile

Dr. ZainUl Abideen’s author metrics reflect his substantial impact and contributions to the field of materials chemistry and environmental science.

  • Citations: Dr. Abideen has accumulated 435 citations on Google Scholar and 429 on ResearchGate. These citations indicate the influence and relevance of his research in the scientific community, showcasing how his work has been recognized and referenced by other researchers.
  • h-index: His h-index stands at 14 on Google Scholar and 13 on ResearchGate. The h-index measures both the productivity and citation impact of his publications. An h-index of 14 means that he has at least 14 publications that have each been cited at least 14 times, highlighting his consistent contributions to impactful research.
  • i10-index: Dr. Abideen has an i10-index of 15 on both Google Scholar and ResearchGate. This index indicates the number of his publications that have received at least 10 citations each, further emphasizing the breadth and recognition of his research contributions.

These metrics collectively reflect Dr. Abideen’s successful and influential career in research, underscoring the significant impact of his work in his field.

Education

Dr. Abideen holds a PhD in Environmental Science and Engineering from Nanjing University of Information Science and Technology, China, where his thesis focused on the effects of alkaline treatment on ZnS and Zn0.3Cd0.7S solid solution photochemical activities. He also earned a Master’s degree in Water Management from The University of Agriculture Peshawar, Pakistan, with a thesis on crop water productivity. His academic foundation is further supported by a Bachelor’s degree in Water Management from the same institution. This educational background provides him with a robust understanding of both environmental science and water management.

Research Focus

Dr. Abideen’s research is centered on the synthesis and application of semiconductor nanomaterials for electro-photocatalysis. His work involves exploring solid-state, co-precipitation, and hydrothermal methods to develop materials for hydrogen and oxygen evolution reactions. His focus extends to green energy production, energy storage, and environmental remediation, aiming to create efficient and sustainable solutions for energy and environmental challenges. Recent projects involve advanced electrocatalysts for hydrogen and oxygen evolution reactions, which are crucial for renewable energy technologies.

Professional Journey

Dr. Abideen’s professional journey includes roles as a post-doctoral research fellow at Central South University, China, where he focuses on advanced materials for electrocatalysis. Prior to this, he completed a PhD at Nanjing University of Information Science and Technology, China, where he investigated photocatalytic materials. His career began with academic roles and research positions in Pakistan, where he also supervised graduate students. His international experience and academic positions highlight his dedication to advancing research in materials chemistry and environmental science.

Honors & Awards

Dr. Abideen has received several honors recognizing his academic excellence and research contributions. He was awarded the Best Thesis Award and the Award of Outstanding International Graduate from Nanjing University of Information Science and Technology in 2019. Additionally, he was a recipient of the Chinese Government Scholarship during his doctoral studies, which supported his research and academic pursuits. These accolades reflect his significant achievements and impact in his field of study.

Publications Noted & Contributions

Dr. Abideen has published numerous influential papers in reputable journals, contributing to the fields of materials chemistry and environmental science. Notable publications include articles on the photocatalytic activity of semiconductor materials and advancements in electrochemical properties. His research on materials like CeO2@Zn0.5Cd0.5S and Fe2O3@Zn0.3Cd0.7S highlights his work in enhancing photocatalytic and electrochemical processes. These contributions underscore his role in advancing knowledge and technology in his research areas.

One-Step Hydrothermal Synthesis of ZnO Microtubes with Efficient Photocatalytic Activity

  • Journal: Micro & Nano Letters
  • Publication Date: December 29, 2020
  • DOI: 10.1049/mna2.12024
  • ISSN: 1750-0443
  • Summary: This study presents a one-step hydrothermal method to synthesize ZnO microtubes, which exhibit high photocatalytic activity. The work demonstrates the effectiveness of this approach in creating nanostructures with enhanced photocatalytic properties, suitable for various environmental applications.

Fe2O3-Promoted Interface Charge Separation and Visible-Light Activity of Fe2O3@Zn0.3Cd0.7S

  • Journal: Materials Chemistry and Physics
  • Publication Date: May 2020
  • DOI: 10.1016/j.matchemphys.2020.122811
  • ISSN: 0254-0584
  • Summary: This article explores the role of Fe2O3 in enhancing the interface charge separation and visible-light photocatalytic activity of Fe2O3@Zn0.3Cd0.7S. The study provides insights into how Fe2O3 can promote effective charge transfer and improve the photocatalytic performance of composite materials.

Enhanced Visible Light Photocatalytic Activity of CeO2@Zn0.5Cd0.5S by Facile Ce(IV)/Ce(III) Cycle

  • Journal: Arabian Journal of Chemistry
  • Publication Date: February 2020
  • DOI: 10.1016/j.arabjc.2019.06.013
  • ISSN: 1878-5352
  • Summary: This publication details the improvement of visible light photocatalytic activity in CeO2@Zn0.5Cd0.5S through a simple Ce(IV)/Ce(III) redox cycle. The study highlights the effectiveness of this method in enhancing photocatalytic performance under visible light, which has implications for environmental remediation and energy conversion.

Hydrological Appraisal of Rainfall Estimates from Radar, Satellite, Raingauge, and Satellite–Gauge Combination on the Qinhuai River Basin, China

  • Journal: Hydrological Sciences Journal
  • Publication Date: December 10, 2019
  • DOI: 10.1080/02626667.2018.1557335
  • ISSN: 0262-6667, 2150-3435
  • Summary: This study assesses the accuracy of various rainfall estimation methods, including radar, satellite, and raingauge measurements, in the Qinhuai River Basin, China. It provides valuable insights into the effectiveness of different estimation techniques and their combined use for hydrological studies.

Highly Uniform MnCo2O4 Hollow Spheres-Based All-Solid-State Asymmetric Micro-Supercapacitor via a Simple Metal-Glycerate Precursor Approach

  • Journal: Energy Technology
  • Publication Date: September 2019
  • DOI: 10.1002/ente.201900314
  • ISSN: 2194-4288, 2194-4296
  • Summary: This publication describes the synthesis of highly uniform MnCo2O4 hollow spheres and their application in an all-solid-state asymmetric micro-supercapacitor. The research demonstrates a straightforward precursor approach and the potential for high-performance energy storage devices.

Research Timeline

Dr. Abideen’s research timeline spans from his early studies in water management to his current focus on semiconductor nanomaterials. His doctoral research on photocatalytic materials laid the foundation for his subsequent work in materials chemistry. His post-doctoral research at Central South University involves developing advanced electrocatalysts for renewable energy applications. This timeline illustrates his progression from foundational studies to cutting-edge research in energy and environmental technologies.

Strengths of Dr. Zain Ul Abideen’s Research

  1. Innovative Research Contributions: Dr. Abideen has significantly advanced the field of materials chemistry and environmental science through innovative research. His work on synthesizing semiconductor nanomaterials and enhancing their photocatalytic and electrocatalytic properties demonstrates a high level of creativity and technical expertise.
  2. High Citation Impact: With 435 citations on Google Scholar and 429 on ResearchGate, Dr. Abideen’s research has made a substantial impact in his field. His h-index of 14 and i10-index of 15 further emphasize the influence and reach of his publications, highlighting the recognition his work has received from the scientific community.
  3. Focused Research on Green Energy and Environmental Remediation: Dr. Abideen’s research is centered on critical global challenges, including green energy production and environmental remediation. His work on photocatalytic and electrocatalytic processes aligns well with the current needs for sustainable solutions, making his research highly relevant and impactful.
  4. Strong Academic Background and Awards: His educational background in environmental science and water management, combined with awards such as the Best Thesis Award and the Award of Outstanding International Graduate, reflects a solid academic foundation and recognition of his excellence in research.
  5. Diverse and High-Quality Publications: Dr. Abideen has published influential papers in reputable journals, covering various aspects of materials chemistry and environmental science. Notable publications include research on photocatalytic activity and electrochemical properties, showcasing the breadth and depth of his expertise.

Areas for Improvement

  1. Broadening Research Horizons: While Dr. Abideen’s focus on semiconductor nanomaterials and photocatalytic processes is strong, expanding his research to include other emerging areas such as nanomedicine or advanced materials for electronic applications could further enhance his research impact and applicability.
  2. Increasing Collaboration with Industry: Strengthening collaborations with industry partners could facilitate the translation of his research into practical applications and commercialization. Engaging with industrial stakeholders may also provide additional resources and perspectives that could benefit his research.
  3. Diversifying Research Methodologies: Incorporating a broader range of research methodologies, including computational modeling or machine learning approaches, could complement his experimental work and provide new insights into the behavior and optimization of materials.
  4. Enhancing Public Engagement: Increasing efforts to communicate his research findings to a broader audience, including the general public and policymakers, could enhance the societal impact of his work. Public engagement can help raise awareness of the importance of his research and its potential benefits.
  5. Expanding Geographical and Cultural Scope: Expanding his research to address environmental and energy challenges in different geographical and cultural contexts could increase the global relevance of his work. This could involve collaborations with researchers and institutions in various regions to address region-specific issues.

Conclusion

Dr. Zain Ul Abideen is a distinguished researcher whose contributions to materials chemistry and environmental science are noteworthy. His innovative approach to synthesizing semiconductor nanomaterials and advancing photocatalytic and electrocatalytic processes highlights his expertise and commitment to addressing critical global challenges. His high citation impact and recognition through awards further underscore the significance of his work.

However, to build upon his already impressive career, Dr. Abideen could consider broadening his research scope, strengthening industry collaborations, diversifying methodologies, enhancing public engagement, and expanding his research to different geographical and cultural contexts. These improvements could amplify the impact of his research and contribute to solving a wider range of environmental and energy challenges.