Wafa Abdelmalek | Green Finance | Best Researcher Award

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Assoc. Prof. Dr. Wafa Abdelmalek | Green Finance | Best Researcher Award

Associate professor | Institute of Higher Business Studies of Sfax | Tunisia

Dr. Wafa Abdelmalek is an accomplished academic and researcher specializing in finance, econometrics, and financial technology, with expertise spanning asset pricing, volatility forecasting, behavioral finance, green finance, cryptocurrencies, and energy–commodity interlinkages. Currently serving as an Associate Professor at the Institute of High Business Studies of Sfax, University of Sfax (Tunisia), she has made notable contributions to understanding market dynamics, risk management, and the integration of artificial intelligence into economic modeling. Her research employs advanced computational methods such as machine learning, neural networks, genetic algorithms, and time-varying models to explore financial interconnections and systemic risks across global markets. Dr. Abdelmalek’s publications in leading journals, including International Journal of Finance & Economics, Studies in Economics and Finance, Eurasian Economic Review, EuroMed Journal of Business, and Review of Behavioral Finance, are recognized for advancing knowledge in sustainable finance and portfolio diversification. Through her collaborative and interdisciplinary work, she continues to bridge traditional finance with emerging technologies, contributing to more resilient and sustainable financial systems. Dr. Abdelmalek’s academic excellence and research influence are reflected in her growing recognition, with 50 citations, 8 publications, and an h-index of 5, underscoring her impactful contributions to the advancement of financial innovation and green finance.

Profiles: Google Scholar | Scopus | ORCID | ResearchGate

Brenda Yanin Azcárraga Salinas | Bioenergy | Best Researcher Award

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Prof. Brenda Yanin Azcárraga Salinas | Bioenergy | Best Researcher Award

PhD student | Instituto Politécnico Nacional | Mexico

Dr. Brenda Yanin Azcárraga Salinas is a distinguished biotechnology researcher specializing in microalgal bioprocesses, environmental biotechnology, and the circular bioeconomy. Her work focuses on transforming agro-industrial and livestock residues into biodiesel, bioactive compounds, and biostimulants, contributing to sustainable energy production and waste valorization. With a strong foundation in analytical chemistry and applied biotechnology, she combines precision in techniques such as HPLC, GC-MS, FTIR, and UV-Vis spectroscopy with innovative approaches to green process design. Her research explores the production of value-added compounds from Scenedesmus obliquus and Chlorella vulgaris cultivated in organic waste-based media, the generation of phytohormones through anaerobic digestion, and the development of biofertilizers derived from microalgal biomass. She has authored and co-authored multiple peer-reviewed publications on renewable bioenergy, green chemistry, and sustainable agriculture, collaborating with national and institutional research networks to advance environmental biotechnology and clean energy innovations. Through her interdisciplinary work, she promotes the development of circular, low-carbon solutions aligned with global sustainability goals. Dr. Azcárraga’s academic excellence and research influence are reflected in her growing global recognition, with 1,117 citations, 33 publications, and an h-index of 9, underscoring her impactful contributions to the advancement of environmental biotechnology and circular bioeconomy.

Profiles: Google Scholar | Scopus | ORCID | ResearchGate 

Featured Publications

1. Solís, M., Solís, A., Pérez, H. I., Manjarrez, N., & Flores, M. (2012). Microbial decolouration of azo dyes: A review. Process Biochemistry, 47(12), 1723–1748. Cited by: 1,026

2. Butrón, E., Juárez, M. E., Solis, M., Teutli, M., González, I., & Nava, J. L. (2007). Electrochemical incineration of indigo textile dye in filter-press-type FM01-LC electrochemical cell using BDD electrodes. Electrochimica Acta, 52(24), 6888–6894. Cited by: 101

3. Solís-Oba, M., Ugalde-Saldívar, V. M., González, I., & Viniegra-González, G. (2005). An electrochemical–spectrophotometrical study of the oxidized forms of the mediator 2,2′-azino-bis-(3-ethylbenzothiazoline-6-sulfonic acid) produced by immobilized laccase. Journal of Electroanalytical Chemistry, 579(1), 59–66. Cited by: 97

4. Solís-Oba, M., Teniza-García, O., Rojas-López, M., & Delgado-Macuil, R. (2011). Application of infrared spectroscopy to the monitoring of lactose and protein from whey after ultra and nano filtration process. Journal of the Mexican Chemical Society, 55(3), 190–193. Cited by: 37

5. Castro Rivera, R., Solís Oba, M. M., Chicatto Gasperín, V., & Solís Oba, A. (2020). Producción de biogás mediante codigestión de estiércol bovino y residuos de cosecha de tomate (Solanum lycopersicum L.). Revista Internacional de Contaminación Ambiental, 36(3), 529–539. Cited by: 34

Dr. Brenda Yanin Azcárraga Salinas advances sustainable biotechnology by transforming organic waste into renewable energy and high-value bioproducts, fostering circular bioeconomy solutions that mitigate environmental impact. Her research bridges science and industry, driving global innovation in green technologies and sustainable resource management.

Wanxuan Yao | Climate change mitigation technologies | Best Researcher Award

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Dr. Wanxuan Yao | Climate change mitigation technologies | Best Researcher Award

Researcher | GEOMAR Helmholtz Centre for Ocean Research Kiel | Germany

Dr. Ben Wanxuan Yao is an accomplished climate scientist specializing in biogeochemical modelling, carbon dioxide removal (CDR), and carbon capture and storage (CCS). His research integrates modelling, data analysis, and environmental assessment to evaluate the technical feasibility, effectiveness, and societal implications of carbon mitigation technologies. With extensive experience in developing CDR evaluation frameworks, he has advanced the global understanding of marine-based carbon removal and its integration within policy and sustainability contexts. He has led multidisciplinary research initiatives focused on site-specific CDR and CCS portfolio development, aligning scientific innovation with national and international climate goals. His work encompasses quantitative modelling of oceanic carbon and nutrient cycles, AI-based parameter calibration on high-performance computing systems, and holistic assessments of carbon sequestration techniques. His findings have been published in leading international journals, including Geophysical Research Letters, Earth’s Future, Environmental Research Letters, and Global Change Biology, providing critical insights into the environmental, economic, and ethical dimensions of marine carbon removal technologies. Beyond research, he has played a key role in facilitating collaboration between scientists, policymakers, and industry through workshops, think tanks, and conferences, strengthening the interface between science and decision-making in the field of climate solutions. His expertise in geospatial data analysis, system modelling, and sustainable innovation has positioned him as a valuable contributor to the evolving landscape of carbon management and environmental strategy. Dr. Yao’s academic excellence and research influence are reflected in his growing global recognition, with 67 citations, 8 publications, and an h-index of 5, underscoring his impactful contributions to the advancement of climate modelling and carbon removal science.

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

Featured Publications

1. Somes, C. J., Dale, A. W., Wallmann, K., Scholz, F., Yao, W., Oschlies, A., Muglia, J., & Achterberg, E. P. (2021). Constraining global marine iron sources and ligand‐mediated scavenging fluxes with GEOTRACES dissolved iron measurements in an ocean biogeochemical model. Global Biogeochemical Cycles, 35(8), e2021GB006948. Cited by: 30

2. Frenger, I., Landolfi, A., Kvale, K., Somes, C. J., Oschlies, A., Yao, W., & Koeve, W. (2024). Misconceptions of the marine biological carbon pump in a changing climate: Thinking outside the “export” box. Global Change Biology, 30(1), e17124. Cited by: 27

3. Yao, W., Kvale, K. F., Achterberg, E., Koeve, W., & Oschlies, A. (2019). Hierarchy of calibrated global models reveals improved distributions and fluxes of biogeochemical tracers in models with explicit representation of iron. Environmental Research Letters, 14(11), 114009. Cited by: 15

4. Kvale, K., Keller, D. P., Koeve, W., Meissner, K. J., Somes, C. J., Yao, W., & Oschlies, A. (2020). Explicit silicate cycling in the Kiel Marine Biogeochemistry Model, version 3 (KMBM3) embedded in the UVic ESCM version 2.9. Geoscientific Model Development Discussions, 1–46.Cited by: 10

5. Yao, W., Kvale, K. F., Koeve, W., Landolfi, A., Achterberg, E., Bertrand, E. M., & Oschlies, A. (2022). Simulated future trends in marine nitrogen fixation are sensitive to model iron implementation. Global Biogeochemical Cycles, 36(3), e2020GB006851. Cited by: 6

Dr. Wanxuan Yao’s work advances global climate solutions by integrating biogeochemical modelling with carbon removal science, enhancing the precision of Earth system projections and guiding sustainable carbon management strategies for policymakers and industry. His research bridges scientific innovation and environmental governance, driving impactful progress toward a low-carbon, resilient future.

Fauzan Djamaluddin | Clean Transportation | Best Researcher Award

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Assist. Prof. Dr. Fauzan Djamaluddin | Clean Transportation | Best Researcher Award

Lecturer | Hasanuddin University | Indonesia

Dr. Fauzan, ST, MT, PhD, is a prominent scholar and researcher in mechanical and materials engineering, widely recognized for his expertise in impact engineering, finite element analysis, crashworthiness, and solid mechanics. His research primarily focuses on the design, analysis, and optimization of lightweight and energy-absorbing structures, particularly those utilizing aluminum foams and composite materials for advanced safety applications in automotive, marine, and rail transport systems. Through his innovative work, he has contributed significantly to improving energy absorption efficiency, structural resilience, and passenger safety while supporting the global transition toward sustainable engineering solutions. He has successfully led multiple funded research projects centered on the development and optimization of advanced materials and structural systems aimed at enhancing vehicle safety and energy efficiency. His research findings have been published in leading international journals, including Ocean Engineering, International Journal of Crashworthiness, Results in Materials, and Latin American Journal of Solids and Structures, reflecting the high scientific rigor and impact of his work. His studies combine experimental and computational approaches, employing advanced simulation tools such as MATLAB, Abaqus, and SolidWorks to model, validate, and optimize complex mechanical systems under various loading conditions. In addition to his strong research profile, Dr. Fauzan actively contributes to academic development through mentoring, interdisciplinary collaboration, and the dissemination of applied engineering knowledge. His work not only advances theoretical understanding but also delivers tangible benefits to society through safer, lighter, and more efficient mechanical systems. Dr. Fauzan’s academic excellence and research influence are reflected in his growing global recognition, with 311 citations, 36 publications, and an h-index of 10, underscoring his meaningful contributions to the fields of mechanical design and materials innovation.

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

Featured Publications

1. Djamaluddin, F., Abdullah, S., Ariffin, A. K., & Nopiah, Z. M. (2015). Optimization of foam-filled double circular tubes under axial and oblique impact loading conditions. Thin-Walled Structures, 87, 1–11. Cited by: 137

2. Djamaluddin, F., Abdullah, S., Ariffin, A. K., & Nopiah, Z. M. (2015). Non-linear finite element analysis of bitubal circular tubes for progressive and bending collapses. International Journal of Mechanical Sciences, 99, 228–236. Cited by: 35

3. Djamaluddin, F., Abdullah, S., Ariffin, A. K., & Nopiah, Z. M. (2015). Multi-objective optimization of foam-filled circular tubes for quasi-static and dynamic responses. Latin American Journal of Solids and Structures, 12(6), 1126–1143. Cited by: 35

4. Djamaluddin, F., Abdullah, S., Ariffin, A. K., & Nopiah, Z. M. (2016). Finite element analysis and crashworthiness optimization of foam-filled double circular under oblique loading. Latin American Journal of Solids and Structures, 13, 2176–2189. Cited by: 21

5. Djamaluddin, F., Abdullah, S., Ariffin, A. K., & Nopiah, Z. M. (2019). Optimisation and validation of full and half foam filled double circular tube under multiple load cases. International Journal of Crashworthiness. Cited by: 16

Dr. Fauzan Djamaluddin’s research advances global innovation in mechanical and materials engineering by developing lightweight, energy-absorbing structures that enhance vehicle safety, energy efficiency, and structural sustainability. His pioneering work in finite element modeling and crashworthiness design contributes to safer, greener, and more efficient transportation systems, bridging the gap between scientific discovery and real-world industrial applications.

Tao Sun | Renewable Energy Systems | Best Researcher Award

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Prof. Tao Sun | Renewable Energy Systems | Best Researcher Award

Professor | Northwest University | China

Dr. Tao Sun is a distinguished Professor at the School of Chemical Engineering, Northwest University, China, widely recognized for his pioneering contributions to the fields of energy conversion and environmental catalysis. His research focuses on the rational design and synthesis of nanostructured and single-atom materials for electrocatalysis, photocatalysis, water splitting, fuel cells, metal–air batteries, and CO₂ reduction. By integrating advanced concepts in atomic-level engineering, heterojunction construction, and defect chemistry, he has developed highly efficient and durable materials that address pressing global challenges in clean energy generation and pollutant degradation. Dr. Sun has authored more than ninety peer-reviewed publications, including numerous papers as first or corresponding author in internationally renowned journals such as Nature Nanotechnology, Advanced Materials, Advanced Functional Materials, ACS Nano, ACS Catalysis, and Advanced Science. His research has achieved substantial global recognition, reflected by thousands of citations and a strong h-index, underscoring his scientific influence and leadership in catalysis and materials chemistry. In addition to his prolific research output, Dr. Sun serves as a reviewer for over fifty leading international journals and contributes to the scholarly community as a youth editor for EcoEnergy, Advanced Powder Materials, and Carbon Energy. His work bridges fundamental science and applied technology, offering innovative strategies for sustainable energy conversion, carbon-neutral pathways, and environmental protection. Through his commitment to advancing catalyst design and clean energy technologies, Dr. Tao Sun continues to make impactful contributions that shape the future of green chemistry and sustainable materials engineering. Dr. Tao Sun’s academic excellence is reflected in his global research influence, with 6,780 citations, 94 publications, and an h-index of 38, highlighting his leading role in the field of materials and energy science.

Profiles: Scopus | ORCID

Featured Publications

1. Sun, T., et al. (2025). Photocatalytic H₂ evolution over Ni₃(PO₄)₂/twinned-Cd₀.₅Zn₀.₅S S-scheme homo-heterojunction using degradable plastics as electron donors. Journal of Materials Science and Technology. Citations: 8

2. Sun, T., et al. (2025). Efficient hydrogen production coupled with polylactic acid plastic electro-treatment over a CoFe LDH/MoSe₂/NixSey/NF heterostructure electrocatalyst. ACS Sustainable Chemistry & Engineering. Citations: 4

3. Sun, T., et al. (2025). Co₃S₄/MnS p–p heterojunction as a highly efficient electrocatalyst for water splitting and electrochemical oxidation of organic molecules. Journal of Colloid and Interface Science. Citations: 10

4. Sun, T., et al. (2025). Efficient photocatalytic H₂ evolution over SnS₂/twinned Mn₀.₅Cd₀.₅S hetero-homojunction with double S-scheme charge transfer routes. Journal of Materials Science and Technology. Citations: 31

5. Sun, T., et al. (2025). Tuning interfacial charge transfer for efficient photodegradation of tetracycline hydrochloride over Ti₃C₂/Bi₁₂O₁₇Cl₂ Schottky heterojunction and theoretical calculations. Applied Surface Science. Citations: 16

Dr. Tao Sun’s pioneering research in photocatalysis and electrocatalysis advances sustainable hydrogen production and plastic waste valorization, bridging clean energy generation with environmental remediation. His innovative heterostructure designs drive global progress toward carbon-neutral technologies and circular energy systems, fostering transformative impact across science, industry, and society.

Alessandro De Oliveira Rios | Climate Change | Excellence in Research Award

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Dr. Alessandro De Oliveira Rios | Climate Change | Excellence in Research Award

Full Professor | Federal University of Rio Grande do Sul | Brazil

Dr. Alessandro de Oliveira Rios is a distinguished researcher affiliated with the University Federal do Rio Grande do Sul (UFRGS), Porto Alegre, Brazil. With an exceptional academic record, he has authored over 160 scientific publications and received more than 6,600 citations, reflecting his significant impact in food science, biotechnology, and sustainable materials, supported by an h-index of 47 that highlights his sustained research excellence. His work focuses on biodegradable materials, natural bioactive compounds, food packaging innovations, and plant-based product development, exploring advances such as microencapsulation of Amazonian buriti fruit oil for oxidative stability in meat products, biodegradable sodium alginate films enriched with carotenoids, and intelligent nonwoven indicators for food spoilage detection. By integrating green chemistry, food engineering, and material science, his research emphasizes circular economy principles and eco-innovative strategies that minimize environmental impact. Beyond materials innovation, Dr. Rios contributes to functional foods and nutrition science, studying the stability of phenolic and carotenoid compounds in regional fruits like Caryocar brasiliense and developing plant-based and hybrid burger formulations aligned with global sustainability goals. Collaborating with over 350 international co-authors across Latin America, Europe, and Asia, he has established a strong global research network, publishing in leading journals such as Food Hydrocolloids, Food Research International, and Biomass. Through his pioneering, interdisciplinary contributions, Dr. Rios advances sustainable food systems, environmental protection, and public health, reinforcing his reputation as one of Brazil’s leading scientific voices in food innovation and sustainability, while actively supporting the United Nations Sustainable Development Goals (SDGs) through impactful, real-world applications of biotechnological research.

Profiles: Google Scholar | Scopus | ORCID | ResearchGate

Featured Publications

1. Rios, A. de O., et al. (2025). Microcapsules with Amazonian buriti fruit oil (Mauritia flexuosa L.) on maintaining oxidative stability of ground beef. Food Hydrocolloids. Citations: 7

2. Rios, A. de O., et al. (2025). Biodegradable sodium alginate films incorporated with lycopene and β-carotene for food packaging purposes. Food Science and Technology International. Citations: 11

3. Rios, A. de O., et al. (2025). Hybrid and plant-based burgers: Trends, challenges, and physicochemical and sensory qualities. [Open Access Review]. Citations: 6

4. Rios, A. de O., et al. (2024). Unlocking the potential of pequi (Caryocar brasiliense Camb.): Stability of phenolic compounds, carotenoid profile, and vitamin A after drying. Food Research International. Citations: 6

5. Rios, A. de O., et al. (2024). Efficient and sustainable production of intelligent nonwovens as indicators of food spoilage through solution blow spinning of proteins and natural pigments from agri-food waste. Food Control.
Citations: 11

Dr. Alessandro de Oliveira Rios’s pioneering research advances sustainable food systems and green technologies, bridging science, industry, and environmental innovation. His work transforms biodegradable materials and natural bioactives into practical solutions that reduce waste, enhance food security, and support global sustainability goals.

Zhenghao Yang | Carbon Neutral Technologies | Young Scientist Award

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Dr. Zhenghao Yang | Carbon Neutral Technologies | Young Scientist Award

Doctor | Air Force Engineering University | China

Dr. Zhenghao Yang is a distinguished researcher at the Air Force Engineering University, Xi’an, China, specializing in advanced combustion systems, energy conversion efficiency, and sustainable propulsion technologies. With 16 publications, 113 citations, and an h-index of 6, he has established a growing academic presence in renewable and green energy research. His work focuses on optimizing combustion and energy conversion mechanisms under specialized and extreme operating conditions, particularly for high-altitude applications in aerospace systems. A notable example of his research is the study titled “Optimization research of combustion and energy conversion efficiency of elliptical rotary engine at high altitude using green hydrogen fuel” (Renewable Energy, 2026), which exemplifies his innovative efforts in integrating hydrogen-based propulsion technologies as sustainable alternatives to traditional fossil-fuel engines. His expertise encompasses computational fluid dynamics (CFD), thermodynamic modeling, performance optimization, and hybrid energy system integration, contributing to advancements in energy efficiency and emission reduction. Collaborating with 18 co-authors across various institutions, Dr. Yang demonstrates strong interdisciplinary engagement that connects mechanical engineering, renewable energy, and environmental sustainability. His research holds significant relevance for both aviation and defense sectors, addressing global challenges related to clean energy utilization, decarbonization, and eco-efficient propulsion. Through his continued exploration of hydrogen-fueled engines and high-performance energy systems, Dr. Zhenghao Yang contributes meaningfully to the worldwide transition toward sustainable energy technologies and low-carbon innovation, positioning himself as a promising leader in the field of green propulsion research.

Profile: Scopus | ORCID | ResearchGate

Featured Publications

1. Yang, Z., Jia, G., Fang, Z., Du, Y., He, G., & Wang, Z. (2026). Optimization research of combustion and energy conversion efficiency of elliptical rotary engine at high altitude using green hydrogen fuel. Renewable Energy.

2. Yang, Z., Du, Y., Jia, G., Gao, X., Fang, Z., He, G., & Wang, Z. (2025). Clean combustion of a hydrogen-doped elliptical rotary engine based on turbulent jet ignition: Synergistic enhancement of thermodynamic and emission performance via flow field coupling. Energy Conversion and Management.

3. Yang, Z., Du, Y., Jia, G., Gao, X., He, G., & Wang, Z. (2025). Effect of multi-hole passive jet ignition on thermodynamic and combustion characteristics of hydrogen-doping elliptical rotary engine in high-altitude environment. Energy.

4. Yang, Z., Jia, G., Du, Y., Fang, Z., Gao, X., He, G., & Wang, Z. (2025). Investigation of high-tumble chamber of ammonia-hydrogen fueled elliptical rotary engine based on turbulence and combustion characteristics. Fuel.

5. Du, Y., Yang, Z., Zhang, Z., Wang, Z., He, G., Wang, J., & Zhao, P. (2024). Control strategy optimization exploration of a novel hydrogen-fed high-efficiency X-type rotary engine hybrid power system by coupling with recuperative organic Rankine cycle. Energy.

Dr. Zhenghao Yang’s research advances the development of clean, high-efficiency hydrogen-fueled rotary engines, contributing to global decarbonization, sustainable aviation, and next-generation propulsion technologies. His innovative work bridges energy science and engineering, fostering breakthroughs that support a greener and more energy-efficient future for society and industry alike.

Mahdi Jahami | Green Hydrogen | Green Hydrogen Production Award

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Dr. Mahdi Jahami | Green Hydrogen | Green Hydrogen Production Award

Professor | The University of Alabama | United States

Dr. Mahdi Jahami is a dedicated researcher in the Department of Mechanical Engineering, Tuscaloosa, United States, whose work focuses on renewable energy systems, sustainable hydrogen production, and life cycle assessment (LCA). His research aims to develop environmentally responsible energy conversion technologies by integrating renewable resources with innovative modeling and optimization frameworks. Dr. Jahami’s scholarly contributions emphasize reducing greenhouse gas emissions through cleaner production pathways and advancing the global transition toward a low-carbon, sustainable energy future. His notable publication, “Life cycle assessment of SMR and Electrified-SMR with renewable energy systems: Projecting emissions and optimizing hydrogen production for California’s goals,” provides a comprehensive assessment of hydrogen generation via Steam Methane Reforming (SMR) and Electrified-SMR systems powered by renewable energy. The study delivers significant insights into optimizing hydrogen production efficiency while aligning with ambitious environmental and policy objectives. With 9 citations, 1 publication, and a Scopus h-index of 1, Dr. Jahami’s research demonstrates growing academic recognition and influence in the fields of clean energy and carbon mitigation. Through collaboration with international co-authors, he applies an interdisciplinary approach combining techno-economic analysis, emissions modeling, and renewable energy integration to design efficient, sustainable hydrogen systems. Beyond academic contributions, his work holds strong societal impact by supporting global initiatives for carbon neutrality, clean technology advancement, and sustainable industrial transformation. Through rigorous research and innovation, Dr. Jahami continues to contribute to the evolution of green engineering solutions, reinforcing the vital role of hydrogen technologies in achieving net-zero emissions and driving global energy sustainability.

Profiles: Scopus | ResearchGate | LinkedIn

Featured Publications

1. Jahami, M. (2025). Life cycle assessment of SMR and Electrified-SMR with renewable energy systems: Projecting emissions and optimizing hydrogen production for California’s 2035 goals. Renewable Energy. Cited by 9.

Dr. Mahdi Jahami’s research advances the global transition toward sustainable hydrogen production and renewable energy integration, providing innovative life cycle–based solutions that reduce emissions and support carbon-neutral industrial systems. His work bridges engineering innovation and environmental responsibility, driving progress toward a cleaner, more resilient energy future.

Mohsin Raza | Renewable Energy | Innovation Research Award

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Dr. Mohsin Raza | Renewable Energy | Innovation Research Award

Post Doctoral Research Associate | University of Sharjah | United Arab Emirates

Dr. Mohsin Raza, Ph.D., is a distinguished researcher specializing in biomass valorization, bioenergy, green chemistry, and nanocellulose production. He is currently advancing research in sustainable material science and bio-based innovations as a Postdoctoral Research Associate at a leading research institute. His academic background and scientific expertise center on transforming agricultural and lignocellulosic wastes into high-value materials through green and energy-efficient processes. Dr. Raza’s work integrates biomass conversion technologies, lignin recovery, nanocellulose extraction, and bio-based thermal insulation development, emphasizing environmental sustainability and circular economy principles. His core research skills include thermochemical processing, biopolymer synthesis, pyrolysis kinetics, and the use of natural deep eutectic solvents for eco-friendly material synthesis. Highly skilled in advanced analytical techniques such as TGA, DSC, XRD, FTIR, GC-MS, SEM, and TEM, he also demonstrates excellence in intellectual property development, holding multiple granted U.S. patents and additional applications in the fields of biomass valorization and green solvent technologies. As a prolific author with extensive publications in high-impact Q1 journals from leading publishers, Dr. Raza’s research contributions have significantly advanced understanding in renewable energy systems, sustainable chemistry, and nanomaterial engineering. His work has been recognized through multiple innovation and sustainability awards, reflecting his leadership and creativity in promoting clean technologies. Through collaborative research and continuous innovation, Dr. Raza continues to shape the future of renewable materials and sustainable energy, contributing to global progress toward a circular bioeconomy, with a documented record of 994 citations, 28 publications, and an h-index of 14.

Profile: Google Scholar | Scopus | ORCID

Featured Publications

1. Inayat, A., & Raza, M. (2019). District cooling system via renewable energy sources: A review. Renewable and Sustainable Energy Reviews, 107, 360–373. Cited by: 221

2. Raza, M., Abu-Jdayil, B., Al-Marzouqi, A. H., & Inayat, A. (2022). Kinetic and thermodynamic analyses of date palm surface fibers pyrolysis using Coats–Redfern method. Renewable Energy, 183, 67–77. Cited by: 161

3. Raza, M., Inayat, A., Ahmed, A., Jamil, F., Ghenai, C., Naqvi, S. R., Shanableh, A., & Park, Y. K. (2021). Progress of the pyrolyzer reactors and advanced technologies for biomass pyrolysis processing. Sustainability, 13(19), 11061. Cited by: 148

4. Raza, M., Abu-Jdayil, B., Banat, F., & Al-Marzouqi, A. H. (2022). Isolation and characterization of cellulose nanocrystals from date palm waste. ACS Omega, 7(29), 25366–25379. Cited by: 102

5. Raza, M., & Abu-Jdayil, B. (2022). Cellulose nanocrystals from lignocellulosic feedstock: A review of production technology and surface chemistry modification. Cellulose, 29(2), 685–722. Cited by: 77

 

Ao Wang | Biomass | Best Researcher Award

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Dr. Ao Wang | Biomass | Best Researcher Award

Institute of Chemical Industry of Forest Products, Chinese Academy of Forestry | China

Dr. Ao Wang is an Associate Research Fellow at the Institute of Chemical Industry of Forest Products, Chinese Academy of Forestry (CAF) and currently serves as a visiting scholar at Nanyang Technological University, fostering international research collaborations. His professional expertise centers on the preparation and application of advanced functional carbon materials derived from biomass, with a particular focus on electrochemical energy storage. He has led major research projects, including national key programs and fundamental research initiatives at CAF. Dr. Wang’s contributions include elucidating the evolution mechanism of carbon microcrystals during lignin and cellulose pyrolysis, demonstrating that the isotropy of carbon crystal seeds drives the ordered growth of graphite-like microcrystals, and revealing the critical influence of catalyst-induced pore sizes on the formation of closed pore structures in energy storage carbon materials. He has published over 30 articles in high-impact journals such as Progress in Materials Science, Advanced Functional Materials, and Carbon Energy, and has been granted 8 invention patents. His research skills encompass biomass carbon material synthesis, catalytic carbonization, pore structure engineering, and electrochemical characterization for lithium-ion and sodium-ion batteries, as well as supercapacitors. Dr. Wang continues to advance the field of biomass-derived carbon materials for energy storage, demonstrating a strong commitment to sustainable energy solutions and functional material innovation, with a documented record of 1,899 citations, 99 documents, and an h-index of 24.

Profiles: Google Scholar | Scopus | ORCID

Featured Publications

1. Fan, M., Yuan, Q., Zhao, Y., Wang, Z., Wang, A., Liu, Y., Sun, K., Wu, J., Wang, L., … (2022). A facile “double‐catalysts” approach to directionally fabricate pyridinic N–B‐pair‐doped crystal graphene nanoribbons/amorphous carbon hybrid electrocatalysts for efficient … Advanced Materials, 34(13), 2107040. Cited by 163.

2. Fan, M., Wang, Z., Sun, K., Wang, A., Zhao, Y., Yuan, Q., Wang, R., Raj, J., Wu, J., … (2023). N–B–OH site-activated graphene quantum dots for boosting electrochemical hydrogen peroxide production. Advanced Materials, 35(17), 2209086. Cited by 150.

3. Wang, A., Sun, K., Xu, R., Sun, Y., Jiang, J. (2021). Cleanly synthesizing rotten potato-based activated carbon for supercapacitor by self-catalytic activation. Journal of Cleaner Production, 283, 125385. Cited by 118.

4. Chen, C., Sun, K., Huang, C., Yang, M., Fan, M., Wang, A., Zhang, G., Li, B., Jiang, J., … (2023). Investigation on the mechanism of structural reconstruction of biochars derived from lignin and cellulose during graphitization under high temperature. Biochar, 5(1), 51. Cited by 66.

5. Cao, M., Liu, Y., Sun, K., Li, H., Lin, X., Zhang, P., Zhou, L., Wang, A., Mehdi, S., … (2022). Coupling Fe3C nanoparticles and N‐doping on wood-derived carbon to construct reversible cathode for Zn–Air batteries. Small, 18(26), 2202014. Cited by 58.