Abdelhamid Errachid | Analytical Chemistry | Research Excellence Award

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Prof. Dr. Abdelhamid Errachid | Analytical Chemistry | Research Excellence Award

Distinguished Professor |Institute of Analytical Sciences | France

Dr. Abdelhamid Errachid is a distinguished researcher recognized for his impactful contributions to analytical chemistry, biosensor engineering, and advanced electrochemical diagnostics. With 354 published documents, over 7,934 citations, and an h-index of 46, his work reflects exceptional scientific productivity, global research influence, and sustained excellence. His expertise spans molecular imprinting, microfabrication, nanomaterial-based biosensing, aptasensors, wearable diagnostics, and point-of-care analytical systems, with applications addressing medical diagnostics, environmental monitoring, and emerging public health needs. His research focuses heavily on the development of label-free electrochemical biosensors, flexible sensing platforms, nanoparticle-assisted detection systems, and microcontact-printed analytical devices, enabling highly sensitive detection of clinically relevant biomarkers, antibiotics, oncogenes, inflammatory markers, and illicit substances. His scholarly portfolio demonstrates strong interdisciplinary collaboration, with more than 600 co-authors, reflecting an extensive global network and sustained engagement in high-impact scientific partnerships. His work is widely disseminated in leading journals and open-access research platforms, supporting innovations that advance healthcare technology, real-time disease monitoring, and next-generation analytical tools. Through his commitment to scientific innovation, translational research, and emerging sensing technologies, Dr. Errachid continues to drive progress in precision diagnostics and modern analytical science, contributing significantly to global scientific and societal advancement.

Profiles : Scopus | ORCID

Featured Publications 

Ben Halima, H., Zine, N., Nemeir, I. A., Pfeiffer, N., Heuberger, A., Bausells, J., Elaissari, A., Jaffrezic-Renault, N., & Errachid, A. (2024). An immunoFET coupled with an immunomagnetic preconcentration technique for the sensitive EIS detection of HF biomarkers. Micromachines, 15(3).

Elouerghi, A., Bellarbi, L., Errachid, A., & Yaakoubi, N. (2024). An IoMT-based wearable thermography system for early breast cancer detection. IEEE Transactions on Instrumentation and Measurement.

Techakasikornpanich, M., Jangpatarapongsa, K., Polpanich, D., Zine, N., Errachid, A., & Elaissari, A. (2024). Biosensor technologies: DNA-based approaches for foodborne pathogen detection. TrAC – Trends in Analytical Chemistry.

Achmamad, A., M’Hammedi, T., Yaakoubi, N., Errachid, A., Fezazi, M. E., Jbari, A., & Bellarbi, L. (2024). Degree of stenosis quantification from phonoangiography signal analysis for diagnosing carotid artery disease. IEEE Sensors Journal.

Suwannin, P., Jangpatarapongsa, K., Frías, I. A. M., Polpanich, D., Techakasikornpanich, M., Elaissari, A., & Errachid, A. (2024). Development of ultrasensitive genosensor targeting pathogenic Leptospira DNA detection in urine sample. SSRN Electronic Journal.

Hamid Rehman | Environmental Chemistry | Research Excellence Award

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Dr. Hamid Rehman | Environmental Chemistry | Research Excellence Award

Postdoctoral Research Fellow | Yildiz Technical University | Turkey

Dr. Hamid Rehman is an emerging interdisciplinary researcher whose work focuses on environmental biotechnology, waste valorization, and the sustainable recovery of rare earth elements, with growing recognition for his contributions to circular economy solutions and eco-efficient material extraction strategies. His research demonstrates a strong integration of experimental bioleaching, microbial process engineering, predictive analytics, and meta-analysis, reflecting a modern scientific approach that bridges laboratory methods with scalable industrial applications. With 8 indexed publications, 44 citations, and an h-index of 4, his scholarly record shows a steadily increasing impact within the scientific community. His engagement in large, multi-author and cross-disciplinary projects, including collaborations with more than 50 co-authors, illustrates his commitment to global scientific cooperation and knowledge exchange. One of his most prominent works applies an integrated framework to the bioleaching of waste-derived rare earth elements, combining experimental data with computational forecasting to support process scale-up, positioning his research within urgent global discussions on c ritical material supply, clean energy technologies, and sustainable resource management. Beyond technical advancement, his scientific vision aligns with broader societal goals, emphasizing responsible waste utilization, reduction of environmental pollution, and replacement of resource-intensive mining processes with biologically driven alternatives. His contributions are not only relevant to academic research but also show strong potential for industrial translation, particularly in sectors developing green manufacturing, cleaner extraction pathways, and next-generation materials. As his publication profile and citation influence continue to expand, Dr. Rehman remains committed to advancing innovative research, strengthening international collaborations, and contributing to scientific progress that supports environmental stewardship, technological resilience, and global sustainability.

Profiles : Google Scholar | Scopus | ORCID | ResearchGate | LinkedIn

Featured Publications

Rehman, H., Debik, E., Ulucan-Altuntas, K., Manav-Demir, N., Canci, B., Iqbal, M., Barros, R., ur Rehman, W., Mohanty, S. K., & Khan, A. H. A. (2025). Bioleaching of waste-derived rare earth elements: An integrated approach with meta-analysis and predictive analytics for scale-up. Results in Engineering.

Wasif ur Rehman, W., Ma, Y., Khan, Z., Ait Laaskri, F. Z., Xu, J., Farooq, U., Ghani, A., Rehman, H., & Xu, Y. (2025). Biomass-derived carbon materials for batteries: Navigating challenges, structural diversities, and future perspective. Next Materials.

Wasif ur Rehman, W., Ma, Y., Khan, Z., Ait Laaskri, F. Z., Xu, J., Xu, Y., Rehman, H., Farooq, U., Altalbe, A., & Li, J. (2025). Bioinspired materials for batteries: Structural design, challenges and future perspective. Results in Chemistry.

Rehman, H., Rehman, Z., Das, T. K., Rehman, M., Khan, B. A., Nandi, S., Ahmad, K., Mohanty, S. K., Wasif ur Rehman, W., Naeem, R., et al. (2024). Toxicity evaluation and degradation of cypermethrin-contaminated soil using biochar and Bacillus cereus amendments. Scientific Reports.

Rehman, H., Khan, A. H. A., Butt, T. A., Toqeer, M., Bilal, M., Ahmad, M., Al-Naghi, A. A. A., Latifee, E. R., Algassem, O. A. S., & Iqbal, M. (2024). Synergistic biochar and Serratia marcescens tackle toxic metal contamination: A multifaceted machine learning approach. Journal of Environmental Management.

Dr. Hamid Rehman is advancing the field of environmental biotechnology through innovative bioleaching and data-driven sustainable recovery methods. His research promotes cleaner scientific practices and supports the global transition toward circular resource utilization.

Tamer Saleh | Green Chemistry | Chemical Scientist Award

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Prof. Dr. Tamer Saleh | Green Chemistry | Chemical Scientist Award

Professor | University of Jeddah | Saudi Arabia

Dr. Tamer S. Saleh is a distinguished researcher recognized for substantial contributions to sustainable chemistry, advanced catalysis, green synthesis, nanomaterials, and biotechnology, with a strong publication record exceeding 96 peer-reviewed articles, 1,928 citations, and an h-index of 27. His research integrates innovative catalytic methodologies with environmentally responsible chemical processes, demonstrating expertise in developing supramolecular coordination polymers, metal-decorated biopolymers, layered double hydroxide systems, and novel organocatalysts that enable greener approaches for heterocycle construction, CH-functionalization, and cycloaddition reactions. He has advanced modern synthetic chemistry through sonophotocatalysis, pressure-assisted reactors, and hybrid catalytic platforms that improve efficiency, selectivity, and sustainability across diverse transformations. In analytical and materials chemistry, he has contributed significantly to the design of carbon dot–gold nanoparticle composites, fluorescence-based sensing probes, and SERS-enabled biosensors with enhanced sensitivity for detecting neurotransmitters and microbial metabolites, enabling progress in diagnostics, environmental monitoring, and chemical safety. His interdisciplinary work further includes biotechnological innovations such as optimized bioreactor fermentation, valorization of agricultural waste, and microbial lipid production using oleaginous yeasts, highlighting impactful pathways toward sustainable resource utilization and microbial engineering. Research on oxidative stress regulation in pathogenic fungi, metabolite profiling, and the development of novel bioactive compounds adds to his broad scientific portfolio with relevance to public health and drug discovery. With more than 160 collaborative co-authors worldwide, his scholarship is marked by strong scientific partnerships and global visibility. Through his commitment to methodological rigor, innovation, and sustainability-driven solutions, Dr. Saleh continues to contribute meaningfully to advancements in green chemistry, catalysis, materials science, and biotechnology, reinforcing the societal relevance of modern chemical research.

Profiles : Scopus | ORCID | ResearchGate

Featured Publications

Saleh, T. S., Al-Bogami, A. S., Aqlan, F. M., & Akhdhar, A. (2026). Exploring the molecular structure of green-synthesized aza-Michael addition products: 2D NMR confirms novel pyrazoles. Journal of Molecular Structure.

El-Said, W. A., Akhdhar, A., Al-Bogami, A. S., & Saleh, T. S. (2025). Design and green synthesis of carbon dots/gold nanoparticle composites and their applications for neurotransmitter sensing based on emission spectroscopy. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy.

Saleh, T. S., & Al-Bogami, A. S. (2025, November 4). Straightforward synthesis of thiophene bioisosteres of the pyrrolo[3,2-c]quinoline framework from Martinelline alkaloids. Molbank. El-bendary, M. M., Akhdhar, A., Davaasuren, B., Al-Bogami, A. S., & Saleh, T. S. (2025, October 10). Unveiling silver catalysis to access 5-substituted tetrazole through [3+2] cycloaddition reaction, utilizing a novel silver supramolecular coordination polymer–based catalyst: A new green horizon. Catalysts.

Al-Romaizan, A. N., Altuna, I. A., Larruskain, M. G., Alghamdi, K. S., Alzhrani, G., Saleh, T. S., … & Hillenbrand, R. (2025, September). Copper-decorated chitosan organocatalyst for sonophotocatalytic C–H arylation of pyrazoles: Mechanistic insights and eco-friendly perspective. Carbohydrate Polymer Technologies and Applications.

Dr. Tamer S. Saleh’s research advances sustainable chemical innovation by developing green catalytic systems, eco-friendly synthesis pathways, and high-performance sensing materials that address critical scientific and industrial challenges. His work supports cleaner technologies, enhances analytical capabilities, and contributes to global efforts toward environmentally responsible chemical manufacturing.

Yanhe Han | Environmental Chemistry | Editorial Board Member

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Prof. Yanhe Han | Environmental Chemistry | Editorial Board Member

Dean | Beijing Institute of Petrochemical Technology | China

Han Yanhe is a highly cited researcher known for influential contributions in environmental engineering, catalytic materials development, advanced oxidation processes, and innovative wastewater treatment technologies. With a substantial record of 68 peer-reviewed publications, over 1,602 citations, and an h-index of 20, Han has established a strong global research presence characterized by consistent scientific impact and extensive multidisciplinary engagement. His work spans the design of integrated nitrogen and sulfur removal systems, including synergistic approaches combining sulfate reduction, sulfur-autotrophic denitrification, and micro-electrolytic pathways to achieve efficient treatment of complex and sulfate-rich wastewaters. Han has advanced understanding of the mechanistic interplay between sulfur-based electron donors and iron–carbon micro-electrolysis, contributing engineering strategies that enhance pollutant degradation and support scalable, sustainable water-treatment solutions. In the field of catalysis, he has contributed to the development of high-performance materials such as CeO₂/GO-co-doped MoS₂ composites, improving electrocatalytic hydrogen evolution and offering practical, cost-effective alternatives to noble-metal-based systems. His research portfolio further encompasses low-temperature plasma-driven oxidation for the mitigation of pharmaceutical and personal-care contaminants, environmental impact assessments of analytical detection methods, and intensified micro-electrolysis techniques tailored for highly toxic industrial waste streams. With collaborations spanning over 140 co-authors, Han has demonstrated a strong commitment to interdisciplinary research and scientific integration across chemistry, materials science, and environmental systems engineering. Many of his publications continue to accumulate significant citations, underscoring the relevance and applicability of his findings to both academic research and industrial practice. Through a combination of mechanistic insight, engineering innovation, and sustainability-focused design, Han Yanhe’s body of work contributes substantially to global efforts aimed at advancing clean-water technologies, enhancing catalytic efficiency, reducing environmental burdens, and supporting sustainable chemical engineering practices.

Profiles : Scopus

Featured Pulications

  1. Han, Y., Xu, H., Zhang, L., Ma, X., Man, Y., Su, Z., & Wang, J. (2023). An internal circulation iron–carbon micro-electrolysis reactor for aniline wastewater treatment: Parameter optimization, degradation pathways and mechanism. Chinese Journal of Chemical Engineering, 63(11), 96–107.

  2. Han, Y., Zhang, S., Zhang, X., Wu, C., & An, R. (2020). Optimization of the conditions for degradation of hydrolyzed polyacrylamide using electro-coagulation. Desalination and Water Treatment, 179, 148–159.

  3. Han, Y., Zhang, S., Xiaofei, Z., & Chen, J. (2020). Electrochemical oxidation of Hydrolyzed Polyacrylamide (HPAM) at Ti/SnO₂-Sb₂O₃/β-PbO₂ anode: Degradation kinetics and mechanisms. International Journal of Electrochemical Science, 15(4), 3382–3399.

  4. Han, Y., Wang, H., Wei, M., … Ma, X. (2025). Advanced low-temperature plasma-driven oxidation for mitigating pharmaceutical and personal care products in wastewater: Mechanisms, influencing factors, and reactor configurations.

    Prof. Yanhe Han advances sustainable environmental engineering through innovative electrochemical and micro-electrolysis technologies for efficient pollutant removal. His work delivers practical solutions for industry while contributing to global efforts toward cleaner water systems and a healthier environment.

Shraddha Yadav | Green Chemistry | Women Researcher Award

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Dr. Shraddha Yadav | Green Chemistry | Women Researcher Award

Postdoctoral Fellow |Indian Institute of Technology Bombay | India

Dr. Shraddha Yadav is a distinguished researcher known for her impactful work in environmental catalysis, electrochemical remediation, and sustainable materials engineering. With 21 publications, 263 citations, and an h-index of 8, her research demonstrates strong scientific productivity and interdisciplinary significance. Her recent studies, published in high-impact journals such as Chemical Engineering Journal and Electrochimica Acta, explore advanced nanostructured catalyst systems, including Fe₃C-infused hydrochar-based cathodes and MIL-53(Fe)-derived Fe₃O₄ MWCNT composites, for the efficient degradation of persistent organic pollutants. By integrating green chemistry, nanomaterial synthesis, and electrochemical process optimization, she contributes to developing sustainable wastewater treatment and pollution control technologies. Her comparative analyses of bio-electro-Fenton and bio-electro-peroxone systems provide key insights into improving catalytic efficiency and environmental compatibility. Through collaborations with more than 25 co-authors from diverse scientific backgrounds, she advances interdisciplinary approaches to address global environmental challenges. Collectively, her work supports the advancement of catalytic and electrochemical pathways for pollutant degradation, aligning with sustainable development goals on clean water, responsible production, and climate action while reinforcing the role of scientific innovation in promoting a cleaner, greener future.

Profiles : Google Scholar | Scopus | ORCID | ResearchGate | LinkedIn

Featured Publications

Sabyasachi Sarkar | Bioinorganic Chemistry | Best Researcher Award

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Prof. Dr. Sabyasachi Sarkar | Bioinorganic Chemistry | Best Researcher Award 

Honorary Distinguished Professor | Ramakrishna Mission Vidyamandira | India

Prof. Dr. Sabyasachi Sarkar is a distinguished chemist whose pioneering work bridges fundamental and applied research, combining enzymatic and nanocarbon innovations to create transformative solutions for science and society. He has led and contributed to advanced research in bioinorganic chemistry, catalysis, and nanomaterial systems, with a focus on enzyme-inspired catalysis, sustainable chemical processes, and nanocarbon-based energy conversion. His interdisciplinary research integrates biochemical principles with material science, resulting in significant advancements in metalloenzyme modeling, biomimetic catalyst development, and functional nanomaterials. Prof. Sarkar’s contributions are further exemplified by multiple groundbreaking patents in drug delivery, ambient energy conversion, and catalytic ammonia synthesis, demonstrating both innovation and real-world applicability. His academic influence extends through the training and mentoring of scientists, fostering collaborations across chemistry, biology, and materials science. Prof. Sarkar has received numerous honors and recognitions for his excellence in research and education, reflecting his role as a global leader in advancing sustainable chemistry. His scholarly impact is evident in his 6,444 citations, 229 documents, and an h-index of 39, underscoring the enduring significance and reach of his work in chemical sciences.

Profiles : Google Scholar | Scopus | ORCID | ResearchGate | LinkedIn

 

Featured Publications

Müller, A., Sarkar, S., Shah, S. Q. N., Bögge, H., Schmidtmann, M., & Sarkar, S., et al. (1999). Archimedean synthesis and magic numbers: “Sizing” giant molybdenum‐oxide‐based molecular spheres of the keplerate type. Angewandte Chemie International Edition, 38(21), 3238–3241. Cited by: 503.

Tripathi, S., Sonkar, S. K., & Sarkar, S. (2011). Growth stimulation of gram (Cicer arietinum) plant by water soluble carbon nanotubes. Nanoscale, 3(3), 1176–1181. Cited by: 358.

Goswami, S., Das, S., Aich, K., Pakhira, B., Panja, S., Mukherjee, S. K., & Sarkar, S. (2013). A chemodosimeter for the ratiometric detection of hydrazine based on return of ESIPT and its application in live-cell imaging. Organic Letters, 15(21), 5412–5415. Cited by: 263.

Das, S. K., Chaudhury, P. K., Biswas, D., & Sarkar, S. (1994). Modeling for the active site of sulfite oxidase: Synthesis, characterization, and reactivity of [MoVIO₂(mnt)₂]²⁻ (mnt²⁻ = 1,2-dicyanoethylenedithiolate). Journal of the American Chemical Society, 116(20), 9061–9070. Cited by: 217.

Tripathi, S., & Sarkar, S. (2015). Influence of water soluble carbon dots on the growth of wheat plant. Applied Nanoscience, 5(5), 609–616. Cited by: 200.

Matias Cardenas | Analytical Chemistry | Young Scientist Award

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Dr. Matias Cardenas | Analytical Chemistry | Young Scientist Award

Universidad Nacional de Río Cuarto | Argentina

Dr. Matias Alberto Cardenas is an emerging leader in analytical chemistry whose academic journey began with a degree in Microbiology from the Universidad Nacional de Río Cuarto, eventually culminating in a Doctorate in Chemical Sciences (Ph.D., Universidad Nacional de Río Cuarto, 2025) with a thesis on electroanalytical detection of neonicotinoids in honey. Over the course of his academic and professional trajectory, he has built a strong profile combining teaching, research, and project leadership: he has served as a teaching assistant in microbiology and chemistry courses, evaluated faculty competitions, and held administrative roles such as departmental counselor and evaluator of socio-community practices. His professional experience includes directing and collaborating in multiple research projects funded by national agencies (FONCYT, CONICET, SECyT), including leading the “ApisLoq” nanoparticle-based biopesticide project, and contributing to interdisciplinary programs aiming at sustainable contaminant analysis in agro-food systems. His research interests lie in electrochemical sensor technology, nanomaterials, chemometric data analysis, and food and environmental contaminant detection, and he is skilled in applying electroanalytical techniques, multivariate statistics, sensor fabrication, separation methods, and method validation. Notably, his publications include articles such as Chemometric-assisted electrochemical sensor for simultaneous determination of neonicotinoids imidacloprid and thiamethoxam in honey (Analytical Methods) and Reduction of Fusarium proliferatum growth and fumonisin accumulation by ZnO nanoparticles (International Journal of Food Microbiology). His leadership in research projects, conference presentations across Latin America and Europe, and service in academic governance reflect strong dedication to community and science. In recognition of his contributions, he has earned awards such as “Best Poster” and “Best Work” in electroanalytical chemistry at national conferences. In summary, Dr. Cardenas combines solid educational credentials, relevant professional experience, advanced technical skills, a growing record of impactful publications, and formal honors — making him a promising researcher with significant potential to contribute to global analytical chemistry. Dr. Cardenas’s academic impact is further reflected in his growing recognition with 1 citation, 2 documents, and an h-index of 1.

Profiles: scopus | ORCID

Featured Publications

1. Cardenas, M. A., Vignati, M., Pierini, G. D., Robledo, S. N., Moressi, M. B., & D’Eramo, F. (2025). Chemometric-assisted electrochemical sensor for simultaneous determination of neonicotinoids imidacloprid and thiamethoxam in honey samples. Analytical Methods.

2. Cardenas, M. A., Alaníz, R. D., Crapnell, R., Robledo, S. N., Fernández, H., Arévalo, F. J., Granero, A. M., Banks, C. E., & Pierini, G. D. (2025, August 13). Electrochemically activated screen-printed graphene electrochemical sensor for daidzein determination in edible peanut oils. Chemosensors.

3. Pena, G. A., Cardenas, M. A., Monge, M. P., Yerkovich, N., Planes, G. A., & Chulze, S. N. (2022). Reduction of Fusarium proliferatum growth and fumonisin accumulation by ZnO nanoparticles both on a maize based medium and irradiated maize grains. International Journal of Food Microbiology.

Jeffrey Amelse | Environmental Chemistry | Best Researcher Award

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Dr. Jeffrey Amelse | Environmental Chemistry | Best Researcher Award

Invited Contributor at University of Aveiro, Portugal

Dr. Jeffrey A. Amelse is an accomplished chemical engineer, researcher, and educator with a distinguished career spanning academia and industry. He earned his Ph.D. in Chemical Engineering from Northwestern University and went on to make significant contributions to catalysis, molecular sieves, petrochemical process design, and carbon sequestration technologies. With over three decades at BP Amoco Chemical Company, he played a pivotal role in developing and commercializing advanced paraxylene technologies, molecular sieve catalysts, and innovative process designs that remain influential in the petrochemical sector. Following his industrial career, he transitioned to academia as an Invited Teaching Professor at the University of Aveiro in Portugal, where he continues to shape the future of energy, catalysis, and sustainability through teaching and research. Currently, as Lead Scientist at Carbon Sequestration, Inc., he pioneers low-cost, natural methods for carbon dioxide removal. His legacy reflects a rare blend of industrial leadership, academic excellence, and innovation.

Professional Profile 

Dr. Amelse’s academic foundation in chemical engineering is marked by rigorous training and a passion for applied research. He earned his Bachelor of Science in Chemical Engineering from the University of Illinois at Urbana-Champaign. He then pursued graduate studies at Northwestern University, obtaining his Master of Science in Chemical Engineering followed by a Ph.D. His doctoral research, under Professors John Butt and Lyle Schwartz, focused on “Silica Supported Iron Bimetallic Catalysts for the Fischer-Tropsch Synthesis,” combining catalyst characterization with performance evaluation—a project that reflected his early interest in bridging fundamental chemistry with industrial applications. Beyond formal degrees, he pursued numerous continuing education courses throughout his career, covering refining, petrochemicals, and biofuels. This extensive educational background not only equipped him with technical expertise but also laid the groundwork for his later innovations in catalysis, petrochemical processes, and sustainable energy technologies, enabling him to contribute across academia and industry.

Experience 

Dr. Amelse’s professional journey integrates high-level industrial leadership, academic teaching, and cutting-edge research. At BP Amoco Chemical Company, he was a core team member in designing world-scale paraxylene crystallization units, developing next-generation catalysts, and leading U.S. Department of Energy–sponsored projects on ammonia absorption refrigeration. He also guided international collaborations, including projects in Belgium, India, Portugal, and the UK, making significant contributions to global petrochemical technology. After retiring from BP Amoco, he joined the University of Aveiro as an Invited Teaching Professor, lecturing on biofuels, refining, and petrochemicals while contributing to molecular sieve research using solid-state NMR. Currently, he serves as Lead Scientist at Carbon Sequestration, Inc., leading commercialization of woody biomass burial for carbon dioxide removal. His experience highlights a career that bridges innovation, teaching, and sustainability, demonstrating his ability to drive transformative advances across both industrial and academic landscapes.

Professional Development

Throughout his career, Dr. Amelse actively pursued professional development to remain at the forefront of chemical engineering and energy research. At BP Amoco, he became a trained leader in HAZOP and LOPA safety analysis techniques, guiding critical plant safety design studies. He also served as an instructor for internal technical courses on paraxylene catalysis and process technologies, reflecting his commitment to knowledge transfer within industry. His collaborations with leading universities, including Cambridge University and the University of Aveiro, provided opportunities to mentor graduate students and postdoctoral researchers, strengthening academia-industry ties. More recently, he expanded his expertise into renewable energy and climate solutions, developing a micro-module on Global Warming, Renewable Energy, and Decarbonization for the European Consortium of Innovative Universities. His continual engagement with new technologies, from biofuels to biomass carbon sequestration, exemplifies lifelong learning and adaptation. This pursuit of professional growth underscores his leadership in advancing energy innovation and sustainability.

Skills & Expertise

Dr. Amelse possesses a rare combination of technical, analytical, and leadership skills in catalysis, process design, and sustainable energy solutions. He is recognized as an expert in molecular sieve synthesis and characterization, having applied advanced techniques such as solid-state NMR to study catalytic materials. His proficiency in ASPEN process simulation and HTRI heat exchanger design software enabled him to lead complex petrochemical process designs with strong economic and technical insight. He also has deep expertise in the aromatics marketplace, including paraxylene process technologies, competitive benchmarking, and licensing strategies. In addition to technical mastery, he is skilled in safety leadership through HAZOP and LOPA methodologies, ensuring safe and efficient operations. His teaching and mentoring roles highlight his ability to translate complex scientific concepts into practical applications. Today, his expertise extends into biomass burial technologies for carbon sequestration, making him a versatile innovator in both conventional petrochemicals and emerging sustainable energy fields.

Resarch Focus

Dr. Amelse’s research has consistently advanced the frontiers of catalysis, petrochemicals, and sustainable energy. His early work focused on catalyst development and reactor modeling for xylene isomerization and paraxylene production, where he pioneered molecular sieve catalyst characterization and design methodologies still in use today. He contributed to the development of novel catalysts for dehydrogenation, transalkylation, and isomerization processes, resulting in patents that improved energy efficiency and selectivity in petrochemical operations. In academia, his research shifted toward renewable energy, exploring biofuels from cellulosic biomass and molecular sieve applications in green chemistry. Currently, his focus lies in carbon sequestration, specifically the commercialization of woody biomass burial as a low-cost and natural method for carbon dioxide removal. His work also explores catalytic oxidation of biomethane and novel bio-aromatic conversion processes. By integrating catalysis, process design, and climate solutions, his research exemplifies innovation at the intersection of chemical engineering and sustainability.

Awards & Recognitions

Dr. Amelse’s career achievements have been recognized through numerous grants, patents, and scholarly contributions. While at BP Amoco, he received special grants from the Head of Technology and the Distributed Research Laboratory to sponsor advanced academic collaborations at the University of Aveiro and Cambridge University. His patents—spanning paraxylene recovery, catalyst design, refrigeration systems, and biomass conversion—demonstrate his innovation and impact, with technologies implemented at industrial scale. His process for recovering germanium from optical fiber effluents, developed at Bell Labs, was notable enough to be featured in The New York Times. In academia, his contributions to climate education were recognized through his development of a European Consortium module on global warming and sustainability. His publications in leading journals, chapters in Industrial Arene Chemistry, and invited lectures further highlight his influence. Collectively, these recognitions underscore his reputation as a pioneering researcher, mentor, and innovator in chemical engineering and sustainability.

Publication Top Notes 

Title: A European Consortium of Innovative Universities Micromodule on Global Warming, Renewable Energy, and Decarbonization
Authors: J.A. Amelse
Year: 2025

Title: Terrestrial Storage of Biomass (Biomass Burial): A Natural, Carbon-Efficient, and Low-Cost Method for Removing CO₂ from Air
Authors: J.A. Amelse
Year: 2025

Title: BP/Amoco Paraxylene Crystallization Technology
Authors: J.A. Amelse
Year: 2023

Title: Reactions and Mechanisms of Xylene Isomerization and Related Processes
Authors: J.A. Amelse
Year: 2023

Title: Sequestering Biomass for Natural, Carbon Efficient, and Low-Cost Direct Air Capture of Carbon Dioxide
Authors: J.A. Amelse, P.K. Behrens
Year: 2022

Dr. Amelse is a highly deserving candidate for the Best Researcher Award. His lifelong contributions to catalysis, petrochemicals, renewable energy, and carbon sequestration reflect both depth and breadth of expertise. His patents and publications demonstrate originality and industrial impact, while his teaching and mentoring underscore his role in shaping future scientists. Although further visibility of his research impact metrics (citations, h-index) and a stronger articulation of future directions could enhance his case, his record already places him among the leading researchers globally.

Patrycja Żak | Environmental Chemistry | Women Researcher Award

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Assoc. Prof. Dr. Patrycja Żak | Environmental Chemistry | Women Researcher Award

Associate Professor, UAM Poznań, Poland.

Dr. Patrycja Żak is an Associate Professor in the Department of Organometallic Chemistry at Adam Mickiewicz University in Poznań, Poland. She holds a distinguished academic and research career focused on green chemistry, organometallic synthesis, and functional nanomaterials. With over 47 peer-reviewed publications and 16 patents, her contributions span catalysis, silsesquioxane chemistry, and environmentally friendly synthetic methodologies. A highly respected scientist, she has led multiple national and European research projects and mentored doctoral candidates. Her scientific work emphasizes sustainable practices through the use of organocatalysis and mechanochemistry. Dr. Żak is a collaborative researcher, partnering with international and national institutions to expand the frontiers of materials and inorganic chemistry. Her dedication has earned her a place in prestigious scientific networks and journals as a reviewer and contributing author. Through her innovative and impactful work, Dr. Żak exemplifies excellence in chemical research and its practical application.

Professional Profile 

Dr. Patrycja Żak completed her entire academic education at Adam Mickiewicz University in Poznań, Poland, where she laid the foundation for her scientific journey. She earned her Master of Science degree in Chemistry under the supervision of Prof. Marciniec. Continuing under the same mentor, she pursued and successfully defended her Ph.D. in Chemistry , focusing on advanced organometallic systems. Demonstrating a consistent trajectory of academic growth, she achieved her habilitation at the same institution, a significant milestone in European academia reflecting her independent research capabilities and teaching qualifications. Her educational path reflects a deep commitment to chemical sciences, and her studies were grounded in synthetic and structural chemistry, particularly relating to silicon-based compounds and catalysts. This solid academic base has underpinned her research excellence, enabling her to contribute meaningfully to interdisciplinary fields, particularly in developing green and sustainable chemical methods.

Experience 

Dr. Żak has accumulated over 15 years of academic and research experience at Adam Mickiewicz University. She began her professional career as an adjunct faculty member and was promoted to Associate Professor. Her work has been briefly paused due to maternity leaves and a short health-related hiatus, but she returned to academia with renewed vigor. During her tenure, she has taken on roles beyond teaching and research, including supervising doctoral projects and serving on selection commissions for post-doc and master’s program candidates. She has actively contributed to collaborative research with international scientists and led industry-related projects, such as the development of efficient synthesis methods at AdvaChemLab. Her extensive project portfolio includes national grants like OPUS, SONATA, and MAESTRO, where she served as both investigator and principal investigator. These experiences have shaped her as a leader in her field, merging academic excellence with research innovation and mentorship.

Professional Development

Throughout her career, Dr. Żak has consistently engaged in professional development activities to enhance her academic and research contributions. She is a member of the Polish Chemical Society and has served as a reviewer for prestigious journals such as ChemSusChem, Inorganic Chemistry, and ChemCatChem. She also acted as a tutor in Environmental and Material Chemistry and served on several selection commissions for post-doc and master’s program candidates. Dr. Żak participated as an organizing committee member for the 8th European Silicon Days Conference. Internationally, she broadened her expertise through a six-month research exchange under the Socrates-Erasmus Program in Belgium. She continually refines her skills through leading-edge research projects and supervising doctoral candidates. These roles reflect her commitment to staying at the forefront of chemical science, emphasizing collaborative growth, academic integrity, and leadership in research dissemination, all of which have significantly contributed to her development as an esteemed scientist in organometallic and green chemistry.

Skills & Expertise

Dr. Patrycja Żak possesses an extensive skill set that bridges experimental chemistry, project leadership, and academic mentorship. She is highly proficient in organometallic synthesis, catalysis (particularly organocatalysis), and mechanochemical methods, enabling the development of green and efficient chemical transformations. Her expertise includes the design and functionalization of silicon-based nanomaterials such as silsesquioxanes. She has demonstrated strong abilities in analytical characterization techniques, photophysical studies, and collaborative interdisciplinary research. She effectively manages national and European research grants, showcasing organizational and leadership capabilities. In academia, she is skilled in curriculum development, supervising postgraduate students, and contributing to peer review and academic publishing. Furthermore, her role in organizing international conferences and reviewing for high-impact journals highlights her communication and evaluative skills. Her ability to innovate while adhering to sustainability principles marks her as a skilled and future-ready researcher in both academic and applied chemical sciences.

Resarch Focus

Dr. Patrycja Żak’s primary research focus lies at the intersection of Green Chemistry, Organometallic Chemistry, and Material Chemistry. Her work emphasizes the design of environmentally friendly and sustainable synthetic methods using organocatalysis and mechanochemistry. She is particularly focused on eliminating hazardous solvents and toxic metal-based catalysts by developing N-heterocyclic carbene-catalyzed transformations. Her research also targets the synthesis and functionalization of silsesquioxanes and nanomaterials with well-defined thermal and photochemical properties. Additionally, she explores thioester and heterocycle synthesis from unsaturated aldehydes and other functionalized compounds, contributing to the growing demand for sustainable, efficient chemical pathways. The research she leads aligns with cutting-edge themes in chemical sustainability, structure-property relationships in hybrid materials, and catalyst design for selective transformations. Her projects consistently follow the principles of atom economy and eco-compatibility, placing her work firmly within the green and sustainable chemistry category, with wide applications in pharmaceuticals, materials science, and nanotechnology.

Awards & Recognitions

Dr. Żak’s scientific excellence is reflected in her numerous achievements and recognitions. She has published 47 papers in Scopus-indexed journals, with an additional paper accepted and one under minor revision, showcasing consistent high-quality output. Her work has received over 662 citations in Scopus and 527 in Web of Science, with an h-index of 14, signifying both productivity and scholarly impact. She has authored chapters in scientific books and contributed to academic handbooks, such as the “Laboratory Experiments in Basic Inorganic Chemistry.” Moreover, her innovation has led to 16 patents across multiple jurisdictions including the US, EU, China, and Poland. She has also served as project manager and principal investigator for prestigious national projects including SONATA, POMOST, and OPUS. In addition, she plays a pivotal role in guiding doctoral candidates under Poland’s “Initiative of Excellence” programs. These distinctions underline her commitment to impactful, innovative, and globally relevant chemical research.

Publication Top Notes 

Conclusion:

Overall, Dr. Patrycja Żak is an exceptionally strong candidate for the Women Researcher Award. Her impressive academic productivity, innovation in sustainable chemistry, mentorship record, and project leadership clearly match the criteria for recognizing excellence among women in science. Minor enhancements, such as expanding industrial collaborations and increasing policy outreach, could further amplify her profile in the future. Nonetheless, she fully deserves acknowledgment as a role model inspiring future generations of women scientists working toward a greener and more sustainable world.

RAJESWARAN | PHOTOCATALYSIS | Best Researcher Award

Published on by Chemical Scientist

Dr. P.RAJESWARAN | PHOTOCATALYSIS | Best Researcher Award

ASSOCIATE PROFESSOR at VEL TECH HIGH TECH Dr.RANGARAJAN Dr,SAKUNTHALA ENGINEERING COLLEGE,CHENNAI,TAMILNADU,India.

🔬 Short Biography 🌿💊📚

Dr. P. Rajeswaran 🎓 is an accomplished academician and researcher in the field of chemistry, with over 14 years of teaching experience in reputed institutions across Tamil Nadu, India 🇮🇳. Holding a Ph.D. in Chemistry with a specialization in Nanoscience and Nanotechnology 🧪 from Bharathiar University, his academic journey began with B.Sc. and M.Sc. degrees in Chemistry followed by an M.Phil. He is currently serving as Associate Professor of Chemistry at Vel Tech High Tech Engineering College, Chennai 🏫. His passion for research is reflected in over 28 SCI/Scopus-indexed publications 📄, spanning topics like photocatalysis, nanomaterials, and environmental remediation. A dedicated mentor and active R&D coordinator, Dr. Rajeswaran continues to shape the next generation of scientists while driving innovation through sustainable chemistry solutions 🌱🔬.

PROFILE 

GOOGLE SCHOLAR 

🔍 Summary of Suitability:

Dr. P. Rajeswaran is a highly accomplished researcher with over 14 years of academic experience and an exceptional track record in the fields of nanoscience, nanotechnology, and environmental chemistry. Holding a Ph.D. in Chemistry, his scholarly excellence is reflected through his prolific publication record—28 SCI/Scopus-indexed journal papers, over 323 citations, an h-index of 12, and consistent involvement in cutting-edge research. He has also supervised Ph.D. scholars, contributed to institutional research development, and secured internal research funding, underscoring his dedication to both discovery and mentorship.

🔹 Education & Experience 

Dr. Rajeswaran’s academic path is steeped in chemical sciences 🧪. He completed his Ph.D. in Chemistry (Nanoscience and Nanotechnology) from Bharathiar University in 2018 🎓, with earlier degrees including an M.Phil. from Vinayaga Missions University and M.Sc./B.Sc. from NMS.S.V.N. College, Madurai 🎒. With 14.7 years of teaching experience 👨‍🏫, he has served in progressive academic roles—from Assistant Professor at institutions like King College of Technology and Mahendra Engineering College, to Associate Professor at Vel Tech High Tech Engineering College, Chennai 🏢. His practical experience in curriculum delivery, departmental leadership, and research supervision has been instrumental in advancing institutional and student success. As a recognized Ph.D. supervisor under Anna University, his teaching is deeply integrated with ongoing research in nanotechnology and materials science 🧬.

🔹 Professional Development 

Dr. Rajeswaran is consistently engaged in professional development, participating in over 14 national and international conferences, workshops, and training sessions 🧑‍🏫🌍. He has presented and published on advanced topics including photocatalytic nanomaterials, dye-sensitized solar cells ☀️, and eco-friendly synthesis techniques for environmental remediation 🌿. Beyond participation, he has contributed as a coordinator of R&D initiatives and held leadership roles such as Head of Department and Discipline Committee Member 🏅. His dedication to evolving with scientific advancements is evident through his diverse academic collaborations and his role in organizing academic events at Vel Tech High Tech. Additionally, he secured research seed funding 💰 and published a patent on eco-friendly coconut soap formulation 🧼. Dr. Rajeswaran remains at the forefront of academic enrichment through sustained learning and institutional development 📚🔍.

🏅 Awards and Recognitions

  • 🏆 Ph.D. Thesis Highly Commended – Bharathiar University (2018)

  • 🎖️ Institute Seed Money Grant – ₹1,10,000 for DSSC project (2024)

  • 📜 Published Patent – Eco-friendly coconut soap formulation (2022)

  • 🧑‍🏫 Ph.D. Supervisorship – Recognized by Anna University

  • 📈 Citations: 323 | h-index: 12 | i10-index: 14 – Google Scholar Metrics

  • 📝 28 International Journal Publications – SCI/Scopus/WoS indexed

  • 🗣️ Presented at 7+ International/National Conferences – Including on nanomaterials and smart chemistry

  • 🧪 R&D Coordinator – Vel Tech High Tech Engineering College

🔬 Research Focus

Dr. Rajeswaran’s research focus lies primarily in Nanoscience and Nanotechnology 🔬, with applications in environmental remediation, photocatalysis, and energy storage devices 🔋. His doctoral and postdoctoral work centers around the synthesis of pure and doped SnO₂ nanoparticles using microwave-assisted techniques, exploring their structural, optical, and catalytic properties 🌈🧪. He has made notable contributions to green chemistry and sustainable solutions by developing nanomaterials for the degradation of toxic dyes and organic pollutants in wastewater 🌍💧. His work extends to graphene-based hybrid materials for supercapacitors and dye-sensitized solar cells, reflecting his interest in renewable energy systems ☀️⚡. Dr. Rajeswaran’s approach blends experimental chemistry with materials engineering to address pressing environmental and energy challenges through nanotechnology, making his research impactful across both academic and industrial domains 🧠⚙️.

Publications & Citations 📚

  1. 📘 Influence of Mn doping on SnO₂ nanoparticles (gas sensing)43 citations, 🗓️ 2015

  2. 🧪 Chitosan–CeO₂–CuO composites for dye degradation & microbial study38 citations, 🗓️ 2024

  3. 🧫 Mn-doped SnO₂ nanoparticles for Congo red degradation29 citations, 🗓️ 2023

  4. WO₃/Graphene hybrid for solar cells22 citations, 🗓️ 2021

  5. 🔋 NiMoO₄@rGO for asymmetric supercapacitors21 citations, 🗓️ 2023

  6. 💧 Chitosan–ZrO₂–CeO₂ for water remediation20 citations, 🗓️ 2023

  7. 🌞 SnO₂–ZnO heterojunctions for dye & Cr(VI) degradation19 citations, 🗓️ 2024

  8. 💡 SnO₂/CoFe₂O₄ nanocomposite for wastewater treatment19 citations, 🗓️ 2024

  9. 🧬 W⁶⁺ doped SnO₂ nanoparticles (photocatalysis)16 citations, 🗓️ 2016

  10. ☀️ Graphene-modified CeO₂ for DSSCs15 citations, 🗓️ 2020

  11. 🔆 Zn-doped SnO₂ nanoparticles (photocatalytic activity)14 citations, 🗓️ 2015

  12. 🌿 Gelatin–Alginate–CeO₂ hydrogel for biological use13 citations, 🗓️ 2024

  13. 🔋 NiCoP@rGO for asymmetric supercapacitors12 citations, 🗓️ 2023

  14. 🌞 Al₂O₃/Graphene for solar cells via microwave12 citations, 🗓️ 2020

  15. 🔋 NiMn₂O₄@rGO hybrids for supercapacitors10 citations, 🗓️ 2023

🔍 Conclusion:

✅ Dr. P. Rajeswaran is highly suitable for the Best Researcher Award. His sustained contributions to applied nanoscience, environmental remediation, and energy materials, paired with leadership in academia and innovation, make him an exemplary candidate who embodies the spirit of research excellence and societal impact.