Fadila Djouadi | Wastewater treatment | Best Researcher Award

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Dr. Fadila Djouadi | Wastewater treatment | Best Researcher Award

Doctorate at Belkada CRTSE, Algeria

Dr. Fadila Djouadi Belkada is a distinguished researcher at the Research Center in Semi-conductor Technology for the Energetic (CRTSE) in Algiers, Algeria. Born on June 3, 1970, in Algiers, she holds extensive experience in environmental engineering, particularly focusing on semiconductor waste management, water treatment, and renewable energy applications. Her expertise spans across various international institutions, including Kyoto Institute of Technology, Kyoto University, and Osaka University. With a notable h-index of 5 and a solid publication record, she is recognized for her contributions to the field of environmental engineering and waste management.

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Scopus Profile

ORCID Profile

Dr. Belkada’s research impact is evidenced by her h-index of 5, reflecting her influence in the field through citations of her published work. Her Scopus Researcher ID is 55901382300, Web of Science Researcher ID is KHY-4570-2024, and she maintains an ORCID ID. These metrics highlight her significant contributions to scientific literature and her active engagement in research.

  • Citations: 303 citations across 298 documents
  • Documents: 7
  • h-index: 5

Education

Dr. Belkadaā€™s educational background is robust and diverse. She earned her Doctorate in Environmental Engineering from the National Polytechnic School (ENP) in Algiers in 2019. Prior to this, she obtained a Master of Engineering in Environmental Engineering from Osaka University in 2001. Her academic journey includes specialization in phyto-pharmacy from the University of Montpellier, France, in 1996, and a degree in Chemical Engineering from the University of Science and Technology Houari Boumediene (USTHB) in Algiers in 1992. This comprehensive education has laid a strong foundation for her research career.

Research Focus

Dr. Belkadaā€™s research primarily revolves around environmental engineering with a focus on the management and treatment of semiconductor waste, water purification, and renewable energy systems. Her work includes innovative approaches such as the use of electrodialysis for wastewater treatment, the development of bioadsorbents, and the integration of solar energy with desalination technologies. Her research contributes to sustainable development and addresses key environmental challenges.

Professional Journey

Dr. Belkadaā€™s professional trajectory showcases a blend of academic and practical experience. She has held various positions at CRTSE, including roles as a Research Associate and a Researcher. Her international experience includes stints at Kyoto Institute of Technology, Kyoto University, and Osaka University, where she engaged in cutting-edge research projects. Additionally, she has been involved in teaching and administrative responsibilities, reflecting her multifaceted expertise and leadership in her field.

Honors & Awards

Dr. Belkada has been recognized for her contributions to environmental engineering and research. Notable honors include her role as Chair of a session at the ICCESEN international conference and her leadership in organizing significant scientific events, such as the two-day intensive course on solar-driven desalination and water purification. Her achievements underline her commitment to advancing scientific knowledge and fostering collaborative research.

Publications Noted & Contributions

Dr. Belkadaā€™s publication record includes influential papers in reputable journals such as Chemical Engineering Research and Design, Desalination and Water Treatment, and Nature/Polymer Journal. Her notable contributions include research on fluoride and nitrate removal from wastewater, the development of dendrimers for novel battery devices, and the synthesis of aerogel capsules. Her work is widely cited and has significantly impacted the field of environmental engineering.

Electrodialysis for Fluoride and Nitrate Removal from Synthesized Photovoltaic Industry Wastewater: Toward High Performance Experimental Parameters

  • Journal: Chemical Engineering Research and Design
  • Date: March 7, 2024
  • DOI: 10.1016/j.cherd.2024.03.008
  • ISSN: 0263-8762
  • Contributors: Fadila Djouadi Belkada, Ouiza Kitous, Ouahiba Bouchelaghem, Nadjib Drouiche, Mouna Hecini, Nabil Mameri

This publication presents a study on optimizing electrodialysis parameters for effectively removing fluoride and nitrate ions from wastewater generated by the photovoltaic industry. The research emphasizes improving the performance of electrodialysis systems through experimental adjustments and provides detailed insights into achieving high efficiency in wastewater treatment.

Activated Alumina as Adsorbent for Fluoride and Nitrate Ions Removal from Synthesized Photovoltaic Cells Manufacturing Effluents

  • Journal: Desalination and Water Treatment
  • Date: 2023
  • DOI: 10.5004/DWT.2023.30003
  • WOSUID: WOS:001118564900008
  • Contributors: Fadila Djouadi Belkada, Ouiza Kitous, Ouahiba Bouchelaghem, Nadjib Drouiche, Mouna Hecini, Nabil Mameri

In this article, the use of activated alumina as an adsorbent for removing fluoride and nitrate ions from effluents produced during photovoltaic cell manufacturing is explored. The study investigates the effectiveness of activated alumina and provides practical solutions for handling these specific pollutants in industrial wastewater.

Electrodialysis for Fluoride and Nitrate Removal from Synthesized Photovoltaic Industry Wastewater

  • Journal: Separation and Purification Technology
  • Date: 2018
  • DOI: 10.1016/J.SEPPUR.2018.04.068
  • WOSUID: WOS:000436651000013
  • Contributors: Fadila Djouadi Belkada, Ouiza Kitous, Nadjib Drouiche, Salaheddine Aoudj, Ouahiba Bouchelaghem, Nadia Abdi, Hocine Grib, Nabil Mameri

This research focuses on the application of electrodialysis technology for the removal of fluoride and nitrate from wastewater associated with the photovoltaic industry. The paper evaluates the performance and efficiency of the electrodialysis process, contributing to advancements in wastewater treatment technologies.

Synthesis of Imidazolium Salt-Terminated Poly(amidoamine)-Typed POSS-Core Dendrimers and Their Solution and Bulk Properties

  • Journal: Polymer Journal
  • Date: 2014
  • DOI: 10.1038/pj.2013.60
  • ISSN: 0032-3896, 1349-0540
  • Contributors: K. Naka, R. Shinke, M. Yamada, Fadila Djouadi Belkada, Y. Aijo, Y. Irie, S. Ram Shankar, K. Sai Smaran, N. Matsumi, S. Tomita, et al.

This article details the synthesis and characterization of a new class of dendrimers, specifically imidazolium salt-terminated poly(amidoamine) dendrimers with a POSS core. The study explores both the solution and bulk properties of these materials, offering insights into their potential applications in various fields.

Photovoltaic Solar Cells Industry Wastewater Treatment

  • Journal: Desalination and Water Treatment
  • Date: 2013
  • DOI: 10.1080/19443994.2012.763217
  • WOSUID: WOS:000325921700008
  • Contributors: Nadjib Drouiche, Fadila Djouadi-Belkada, Tarik Ouslimane, Aissa Kefaifi, Jihane Fathi, Emina Ahmetovic

Research Timeline

Dr. Belkadaā€™s research timeline illustrates her ongoing commitment to addressing environmental issues. From her early research on pesticide behavior in soil to her current projects on innovative membrane materials for desalination, her work has evolved to address pressing global challenges. Key research phases include her projects on semiconductor waste management, photovoltaic industry wastewater treatment, and the development of new materials and techniques for environmental applications.

Collaborations and Projects

Dr. Belkada has collaborated with numerous esteemed researchers and institutions on various projects. Current collaborations include work on innovative membrane materials with Dr. Nadjib Drouiche and treatment of semiconductor waste with Dr. Mouna Hecini. Her past projects have involved international research teams in Japan, focusing on dendrimer synthesis, ionic liquids, and capsule materials. These collaborations enhance the scope and impact of her research, contributing to advancements in environmental engineering and renewable energy technologies.

Strengths of the Best Researcher Award for Dr. Fadila Djouadi Belkada

Innovative Research Focus: Dr. Belkadaā€™s work on semiconductor waste management, electrodialysis for wastewater treatment, and renewable energy applications demonstrates a strong focus on innovative and pressing environmental issues. Her research contributes significantly to advancing sustainable technologies and solutions.

Diverse Expertise and Background: Her broad educational background in environmental engineering, chemical engineering, and related fields from prestigious institutions adds depth and versatility to her research capabilities. This multidisciplinary approach enhances her ability to tackle complex environmental challenges.

International Collaboration: Dr. Belkadaā€™s experience working with renowned institutions like Kyoto University and Osaka University showcases her ability to engage in high-impact, global research projects. These collaborations enrich her work with diverse perspectives and advanced methodologies.

Publication Record: With publications in reputable journals such as Chemical Engineering Research and Design, Desalination and Water Treatment, and Nature/Polymer Journal, Dr. Belkada has a solid track record of impactful research. Her work is well-cited, reflecting its significance in the field.

Recognition and Leadership: Receiving accolades such as the Best Researcher Award and playing leadership roles in international conferences highlight Dr. Belkadaā€™s prominence and influence in environmental engineering. Her involvement in organizing scientific events further underscores her commitment to advancing the field.

Areas for Improvement

h-Index Growth: While an h-index of 5 reflects her influence, it also indicates potential for further growth. Increasing the number of highly cited publications could enhance her research impact and recognition in the field.

Broader Research Scope: Expanding research topics to include emerging areas in environmental engineering, such as circular economy practices or advanced materials for environmental remediation, could enhance the relevance and applicability of her work.

Increased Funding and Grants: Securing additional funding and research grants could support larger-scale projects and further innovative research. Diversifying funding sources may also provide more opportunities for groundbreaking work.

Public Engagement and Outreach: Enhancing efforts to communicate research findings to the general public and stakeholders could improve the societal impact of her work. Engaging in science communication and public education initiatives could broaden the reach and influence of her research.

Collaborative Publications: Increasing the number of collaborative publications with other leading researchers could boost her visibility and impact. This approach may also facilitate the exploration of new research areas and methodologies.

Conclusion

Dr. Fadila Djouadi Belkadaā€™s recognition as a Best Researcher highlights her significant contributions to environmental engineering, particularly in wastewater treatment and semiconductor waste management. Her strong international collaborations, diverse expertise, and impactful publications demonstrate her leadership and innovation in the field. However, there are areas for growth, such as expanding her research scope, increasing her h-index, and enhancing public engagement. Addressing these areas can further elevate her impact and continue to drive advancements in environmental engineering and sustainable technologies.

Kaushik Kundu | Waste to Energy | Chemical Environmental Award

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Mr. Kaushik Kundu | Waste to Energy | Chemical Environmental Award

Kaushik Kundu at IIT Delhi, India

Kaushik Kundu is a doctoral candidate in Chemical Engineering at IIT Delhi, with a focus on advancing clean energy technologies through innovative research. With a solid foundation in chemical engineering from both IIT (ISM) Dhanbad and Maulana Abul Kalam Azad University of Technology, he has developed a strong expertise in hydrogen economy, biomass conversion, and reaction engineering.

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Scopus Profile

ORCID Profile

Kaushik Kundu has made significant contributions to the field of chemical engineering, particularly in the areas of biomass conversion and catalyst development. His work is recognized through publications in reputable journals and presentations at major conferences. His research metrics reflect a growing impact in his field, evidenced by his published articles and their relevance to current scientific discussions.

  • Citations: 11 citations across 11 documents
  • Documents: 2 published documents
  • h-index: 2

Education

Kaushik Kundu pursued his Ph.D. in Chemical Engineering at IIT Delhi, where he has maintained a CGPA of 8.45. He completed his M.Tech in Fuel Engineering at IIT (ISM), Dhanbad with an impressive CGPA of 9.45, and earned his B.Tech in Chemical Engineering from Maulana Abul Kalam Azad University of Technology, Calcutta Institute of Technology with a CGPA of 8.35. His educational journey showcases a consistent track record of academic excellence.

Research Focus

Kaushik’s research is centered on the hydrogen economy, including the thermochemical and catalytic conversion of biomass to clean energy. His interests extend to kinetic modeling, machine learning applications in chemical engineering, and process optimization using ASPEN modeling. This diverse focus allows him to tackle complex challenges in sustainable energy solutions.

Professional Journey

Kaushik’s professional journey includes notable projects and roles that highlight his expertise and commitment to advancing chemical engineering. He has worked on a significant project sponsored by IIT Delhi and GAIL, focusing on catalyst development for methanol and DME production via CO2 hydrogenation. His M.Tech dissertation involved research on the characterization and production of bio-coke from agricultural wastes, underscoring his dedication to sustainable energy.

Honors & Awards

Kaushik received the Best Poster Award at IIChE-CHEMCON 2023 for his work on predicting and optimizing syngas yield from biomass using Multivariate LSTM. This recognition highlights his innovative approach and contributions to the field of chemical engineering.

Publications Noted & Contributions

Obtaining High H2-Rich Syngas Yield and Carbon Conversion Efficiency from Biomass Gasification: From Characterization to Process Optimization Using Machine Learning with Experimental Validation

Published in: Fuel
Date: December 15, 2024
DOI: 10.1016/j.fuel.2024.132931
ISSN: 0016-2361
Contributors: Kaushik Kundu, Avan Kumar, Hariprasad Kodamana, Kamal K. Pant

This paper presents a comprehensive study on optimizing the production of hydrogen-rich syngas from biomass gasification. It covers the entire process from the initial characterization of biomass to the optimization of the gasification process using machine learning techniques. The study includes experimental validation to ensure the accuracy and effectiveness of the proposed optimization methods. This research contributes to improving the efficiency of biomass conversion technologies, which is critical for advancing sustainable energy solutions.

CO2 Hydrogenation to Methanol over Cu-ZnO-CeO2 Catalyst: Reaction Structureā€“Activity Relationship, Optimizing Ce and Zn Ratio, and Kinetic Study

Published in: Chemical Engineering Journal
Date: January 1, 2024
DOI: 10.1016/j.cej.2023.147783
ISSN: 1385-8947
Contributors: Rajan Singh, Kaushik Kundu, Kamal K. Pant

This article explores the reaction structureā€“activity relationship for CO2 hydrogenation to methanol using a Cu-ZnO-CeO2 catalyst. The study focuses on optimizing the ratios of Cerium (Ce) and Zinc (Zn) in the catalyst to enhance the reaction efficiency. Additionally, it includes a detailed kinetic study to understand the reaction dynamics. The findings offer valuable insights into catalyst design and optimization for CO2 conversion processes, contributing to the development of more efficient and sustainable methods for methanol production.

Bio-Coke: A Sustainable Solution to Indian Metallurgical Coal Crisis

Published in: Journal of Analytical and Applied Pyrolysis
Date: May 2023
DOI: 10.1016/j.jaap.2023.105977
ISSN: 0165-2370
Contributors: Amrit Anand, Shalini Gautam, Kaushik Kundu, Lal Chand Ram

This paper addresses the metallurgical coal crisis in India by proposing bio-coke as a sustainable alternative. The research discusses the production and characterization of bio-coke derived from agricultural wastes and its potential to replace traditional metallurgical coal. By highlighting the benefits of bio-coke, this study aims to contribute to more sustainable and eco-friendly practices in the steel industry, offering a viable solution to the coal supply challenges faced in India.

Research Timeline

Kaushikā€™s research timeline includes his Ph.D. studies at IIT Delhi (2022-present), his M.Tech research (2018-2019), and various projects and workshops. His research has progressed from bio-coke production to advanced catalyst development and optimization, demonstrating a trajectory of increasing depth and impact in his field.

Collaborations and Projects

Kaushik has collaborated with institutions such as IIT Delhi and GAIL on high-impact projects like catalyst development for CO2 hydrogenation. He has also participated in workshops and short-term courses, including one on finite volume methods in computational fluid dynamics and another on solid fuel processing, enhancing his skills and broadening his research network.

Strengths of the Chemical Environmental Award

Innovative Research Focus: Kaushik Kunduā€™s work in the hydrogen economy and biomass conversion is highly relevant to contemporary challenges in clean energy. His research on optimizing syngas yield from biomass and CO2 hydrogenation to methanol demonstrates a commitment to developing sustainable and efficient energy solutions.

Strong Academic Background: Kaushik has a solid educational foundation with impressive CGPAs at both the M.Tech and B.Tech levels, showcasing his academic excellence and capability in chemical engineering. His doctoral studies at IIT Delhi further solidify his expertise in the field.

Notable Publications and Citations: The publications highlighted, including those in Fuel and the Chemical Engineering Journal, indicate a high level of scholarly contribution. Despite having a modest number of citations and documents, the impact of his work is growing, reflecting its relevance and potential influence.

Recognition and Awards: The Best Poster Award at IIChE-CHEMCON 2023 signifies recognition from peers and experts in the field, underscoring the innovative nature of Kaushikā€™s research and his ability to effectively communicate his findings.

Diverse Research Applications: Kaushikā€™s research spans several critical areas, including biomass gasification, catalyst optimization, and sustainable alternatives to metallurgical coal. This broad focus not only enhances the applicability of his work but also contributes to various aspects of environmental sustainability.

Areas for Improvement

Citation Impact: Although Kaushik has 11 citations, his h-index of 2 suggests that his work is still gaining traction. Increasing the visibility and impact of his research through more publications, collaborations, and conference presentations could help boost his citation metrics.

Publication Volume: With only 2 published documents, expanding his research output and publishing in high-impact journals could enhance his academic profile and influence within the field of chemical engineering.

Research Collaboration: While Kaushik has engaged in significant projects with IIT Delhi and GAIL, further expanding his network through additional collaborations with international institutions and industry partners could enrich his research perspectives and opportunities.

Grant and Funding Opportunities: Securing additional funding and grants for research projects could provide Kaushik with the resources needed to explore more ambitious research goals and increase the scope of his investigations.

Outreach and Dissemination: Enhancing outreach efforts, including public lectures, workshops, and media engagement, could help raise awareness of his research and its potential impact, attracting more attention from both the academic community and industry stakeholders.

Conclusion

Kaushik Kunduā€™s candidacy for the Chemical Environmental Award is well-supported by his innovative research, strong academic background, and notable contributions to the field of chemical engineering. His work addresses critical challenges in clean energy and sustainability, demonstrating a high level of expertise and commitment. However, to further strengthen his candidacy, Kaushik could benefit from increasing his publication volume, enhancing research visibility, expanding collaborations, and securing additional funding. By addressing these areas, he can continue to make significant strides in advancing sustainable energy technologies and solidify his standing as a leading researcher in his field.