Ms. Haitong Yang | Renewable Energy | Women Researcher Award

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Ms. Haitong Yang | Renewable Energy | Women Researcher Award

Ms. Haitong Yang | China university of geosciences | China

Ms. Haitong Yang is a joint Ph.D. student at the China University of Geosciences (Beijing) specializing in Oil and Gas Engineering, with research focusing on advanced interpretation methods for production profiling based on microbial DNA sequencing. His academic background includes a Master’s degree in Oil and Gas Engineering from the China University of Petroleum (Beijing), where his work centered on production dynamic monitoring using microbial DNA sequencing, and a Bachelor’s degree in Oil and Gas Storage and Transportation Engineering from Northeast Petroleum University. Haitong has been recognized with multiple national and international awards, including the National Scholarship for Chinese Graduate Students, first prizes in the China Doctoral Academic Forum and the Asia Pacific Cup in Mathematical Modeling, as well as honors in innovation and entrepreneurship competitions. His technical expertise encompasses DNA extraction experiments, Mothur, CMG, Petrel, and MATLAB, applied to major projects in Shengli and Changqing Oilfields, where his work integrates microbial genomics with petroleum engineering to optimize reservoir evaluation, water flow path tracking, and fluid biomarker analysis. His contributions have resulted in 9 published documents, 51 citations by 47 documents, and an h-index of 3, reflecting his growing impact in the field of intelligent oil and gas engineering and reservoir characterization.

Profile: Scopus

Featured Publication

Yang, H., Kang, Z., Wang, S., & Jiang, H. (2025). DNA-sequencing method maps subsurface fluid flow paths for enhanced monitoring. Communications Earth and Environment.

 

Dr. Nisha Dagade | Renewable Energy | Best Researcher Award

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Dr. Nisha Dagade | Renewable Energy | Best Researcher Award

Dr. Nisha Dagade | Sinhgad Institutes | India

Dr. Nisha R. Dagade  is an accomplished Assistant Professor at Sinhgad Institutes, Pune, India, specializing in electrical power systems with a particular focus on Distributed Generation  and Reliability Analysis. Her research emphasizes the optimal integration of renewable DG sources into modern distribution networks, addressing both technical and economic challenges through heuristic and metaheuristic optimization approaches such as Ant Colony Optimization (ACO). Dr. Dagade’s scholarly contributions explore multi-objective frameworks that aim to reduce power losses, improve voltage profiles, and enhance the overall reliability and cost-effectiveness of distribution systems. Her notable work, “Ant colony optimization technique for integrating renewable DG in distribution system with techno-economic objectives,” published in Evolving Systems (2022), has gained significant academic recognition. With a strong research portfolio comprising 10 completed and ongoing projects, 7 Scopus-indexed journal publications, and one published book, and maintains an active research profile with 61 citations, an h-index of 5, and an i10-index of 2 , she continues to advance innovation in the domain of sustainable power systems. She has also collaborated with IIT Bombay on research initiatives that bridge academic insights with real-world applications. Her professional memberships in IAENG and I2OR reflect her active engagement in the global engineering research community. Dr. Dagade’s work embodies the integration of renewable energy technologies for efficient, reliable, and environmentally responsible power system development.

Profile: Google Scholar

Featured Publications

  • Godha, N. R., Bapat, V. N., & Korachagaon, I. (2022). Ant colony optimization technique for integrating renewable DG in distribution system with techno-economic objectives. Evolving Systems, 13(3), 485–498.

  • Godha, N. R., Deshmukh, S. R., & Dagade, R. V. (2011). Application of Monte Carlo simulation for reliability cost/worth analysis of distribution system. In 2011 International Conference on Power and Energy Systems (pp. 1–6).

  • Godha, N. R., Deshmukh, S. R., & Dagade, R. V. (2012). Time sequential Monte Carlo simulation for evaluation of reliability indices of power distribution system. In Proceedings of the 2012 IEEE Symposium on Computers and Informatics (ISCI 2012).

  • Godha, N. R., Bapat, V. N., & Korachagaon, I. (2019). Placement of distributed generation in distribution networks: A survey on different heuristic methods. In Techno-Societal 2018: Proceedings of the 2nd International Conference on Techno-Societal.

  • Dagade, N. R. G., Bapat, V. N., & Korachagaon, I. (2020). Improved ACO for planning and performance analysis of multiple distributed generations in distribution system for various load models. In 2020 Second International Sustainability and Resilience Conference.

 

 

Assist. Prof. Dr. Mostafa Wageh lotfy Mohamed | Renewable Energy | Best Researcher Award

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Assist. Prof. Dr. Mostafa Wageh lotfy Mohamed | Renewable Energy | Best Researcher Award

Assist. Prof. Dr. Mostafa Wageh lotfy Mohamed | Beni-Suef University | Egypt

Dr. Mostafa Wageh Lotfy Mohamed is an Assistant Professor in the Department of Process Control Technology at the Faculty of Technology and Education, Beni-Suef University, Egypt. He earned his PhD in Electrical Power and Machines from Beni-Suef University, where his doctoral research focused on the control of Split-Source Inverters for renewable energy applications. His academic foundation also includes an M.Sc. degree on the performance analysis of high-gain DC-DC converters for distributed generation systems, and a B.Sc. in Automatic Control with an excellent grade. Dr. Mohamed has extensive expertise in power electronics, control systems, and renewable energy technologies, particularly in DC/DC and DC/AC converters, transformer-less Split-Source Inverters, and intelligent control strategies for energy systems. He has successfully led multiple funded research projects, including the design and implementation of three-phase Split-Source Inverters for renewable energy applications and an innovative 3D-printed small wind turbine for low-speed regions. His scholarly impact is reflected in 75 citations , an h-index of 5, and an i10-index of 4. Through his research and innovation, Dr. Mohamed continues to contribute to advancing renewable energy integration, sustainable system design, and technological progress in Egypt and globally.

Profile: Google Scholar

Featured Publications

  1. Lotfy, M. W., Dabour, S. M., Mostafa, R. M., Almakhles, D. J., & Elmorshedy, M. F. (2023). Modeling and control of a voltage-lift cell split-source inverter with MPPT for photovoltaic systems. IEEE Access.

  2. Shehata, E. G., Thomas, J., Brisha, A. M., & Wageh, M. (2017). Design and analysis of a quasi Y-source impedance network DC–DC converter. Proceedings of the 2017 Nineteenth International Middle East Power Systems Conference (MEPCON), 1-6. IEEE.

  3. Wageh, M., Dabour, S. M., & Mostafa, R. M. (2021). A high gain split-source inverter with reduced input current ripple. Proceedings of the 2021 22nd International Middle East Power Systems Conference (MEPCON), 383-388. IEEE.

  4. Wageh, M., Dabour, S. M., Mostafa, R. M., & Ghalib, M. A. (2021). Space vector PWM of three-phase inverter with MPPT for photovoltaic system. Australian Journal of Electrical and Electronics Engineering, 18(4), 310-318.

  5. Wageh, M., Dabour, S. M., & Mostafa, R. M. (2022). A new four-switch split-source boosting inverter: Analysis and modulation. Proceedings of the 2022 23rd International Middle East Power Systems Conference (MEPCON), 1-7. IEEE.

  6. Ali, M. M., Elmorshedy, M. F., Gabr, M. A., Ramadan, H. S., & Lotfy, M. W. (2023). An enhanced finite-set model predictive control based super twisting sliding mode speed controller for linear metro applications. Proceedings of the 2023 24th International Middle East Power System Conference (MEPCON), 1-6. IEEE.

 

 

Dr. Qinglu Fan | Renewable Energy | Best Researcher Award

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Dr. Qinglu Fan | Renewable Energy | Best Researcher Award

Dr. Qinglu Fan | YiBin Vocational And Technical College | China

Dr. Qinglu Fan is a lecturer at YiBin Vocational and Technical College, specializing in materials science and engineering with a research focus on nickel-based layered cathode materials for lithium-ion batteries. She earned her doctoral degree at Guangdong University of Technology from 2016 to 2021 and conducted research as a visiting Ph.D. student at Binghamton University from 2019 to 2021. Her work centers on interface and bulk regulation of Ni-rich layered cathode materials to enhance their electrochemical performance, stability, and efficiency. She has published more than ten papers as the first author in international journals, including Journal of Power Sources, ACS Applied Materials & Interfaces, and Applied Materials Today, and authored the book “Lithium-ion Battery Nickel-based Layered Cathode Materials and Its Modifications.” Her research is supported by multiple ongoing projects, including participation in the National Natural Science Foundation of China, as principal investigator of the Ph.D. Startup Fund at Yibin Vocational and Technical College, and leadership of the Academician Ouyang Minggao Workstation Youth Talent Development Fund. With an h-index of ten, she continues to contribute to the advancement of sustainable energy storage materials and innovative solutions for next-generation lithium-ion batteries.

Profile: Scopus | Orcid

Featured Publications

  • Fan, Q., Li, X., Cheng, Y., Hu, Y., Ma, W., & Chen, Z. (2025). Enhanced cycling stability of nickel-rich single-crystal LiNi0.83Co0.12Mn0.05O2 at high voltage via low-temperature epitaxial rock-salt interface engineering. Journal of Materials Science.

  • Fan, Q., Li, X., Cheng, Y., Hu, Y., Ma, W., Almuqrin, A. H., Alodhayb, A. N., Chen, Z., & Shi, Z. (2025). Comprehensive investigation of the impact of calcination temperature-induced Li/Ni mixing on LiNi0.8Mn0.1Co0.1O2. Materials Today Energy.

  • Fan, Q., Chen, Z., Ma, W., & Shi, Z. (2025). Examining the collaborative impact of a heterojunction TiO2 coating and Ti substitution on LiNi0.8Co0.1Mn0.1O2 via a single-step modification approach. Applied Materials Today.

  • Fan, Q. (2021). Heterojunction TiO2@TiOF2 nanosheets as superior anode materials for sodium-ion batteries. Journal of Materials Chemistry A.

  • Fan, Q., Lin, K., Guan, S., Chen, J., Feng, S., Liu, L., & Shi, Z. (2021). Constructing high conductive composite coating with TiN and polypyrrole to improve the performance of LiNi0.8Co0.1Mn0.1O2 at high cutoff voltage of 4.5 V. ACS Applied Energy Materials.

  • Fan, Q. (2021). Can greener Cyrene replace NMP for electrode preparation of NMC 811 cathodes? Journal of The Electrochemical Society.

 

 

 

Dr. Guangxing Guo | Renewable Energy | Best Academic Researcher Award

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Dr. Guangxing Guo | Renewable Energy | Best Academic Researcher Award

Dr. Guangxing Guo | Yangzhou University | China

Dr. Guangxing Guo is a dedicated researcher in the field of wind energy with strong academic training and impactful contributions. He is pursuing a Doctor of Engineering degree at Yangzhou University, focusing on the application of artificial intelligence in wind energy, and also gained international academic exposure as a guest student at Aalborg University, Denmark. He earned a Master of Engineering degree from the Institute of Engineering Thermophysics, Chinese Academy of Sciences, where his research centered on the structural performance of wind turbine blades, and a Bachelor of Engineering in New Energy Science and Engineering from Lanzhou University of Technology. His expertise covers aerodynamics, aeroelastic dynamics, structural dynamics, and computational fluid dynamics. To date, he has published 8 documents, including SCI-indexed works in Composite Structures, Sustainable Energy Technologies and Assessments, and Energies. His research has received 90 citations by 75 documents, with an h-index of 5, demonstrating growing academic recognition. He has also presented his work at international conferences, highlighting contributions to wind turbine blade design, wind farm noise reduction, and machine learning-based performance evaluation.

Profile: Scopus | Orcid

Featured Publications

Guo, G., Zhu, W., Sun, Z., Fu, S., Shen, W., & Hua, Y. (2025). Large wind turbine blade design with mould sharing concept based on deep neural networks. Sustainable Energy Technologies and Assessments, 73, 104131.

Guo, G., Zhu, W., Zhang, Z., Shen, W., & Chen, Z. (2025). Achieving power-noise balance in wind farms by fine-tuning the layout with reinforcement learning. Energies, 18(18), 5019.

Guo, G., Zhu, W., Sun, Z., Fu, S., Shen, W., & Cao, J. (2024). An aero-structure-acoustics evaluation framework of wind turbine blade cross-section based on gradient boosting regression tree. Composite Structures, 337, 118055.

Guo, G., Zhu, W., Sun, Z., Shen, W., Cao, J., & Fu, S. (2023). Drag reducer design of wind turbine blade under flap-wise fatigue testing. Composite Structures, 318, 117094.

Zhu, W., Liu, J., Sun, Z., Cao, J., Guo, G., & Shen, W. (2022). Numerical study on flow and noise characteristics of an NACA0018 airfoil with a porous trailing edge. Sustainability, 15(1), 275.

Li, S., Zhang, L., Xu, J., Yang, K., Song, J., & Guo, G. (2020). Experimental investigation of a pitch-oscillating wind turbine airfoil with vortex generators. Journal of Renewable and Sustainable Energy, 12(6), 063304.

Mr. Yohannes Shuka Jara | Renewable Energy | Best Researcher Award

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Mr. Yohannes Shuka Jara | Renewable Energy | Best Researcher Award

Mr. Yohannes Shuka Jara | Borana University | Ethiopia

Mr. Yohannes Shuka Jara is a dedicated lecturer and researcher in the Department of Chemistry at Borana University, Ethiopia, with a strong academic and professional trajectory in physical chemistry and sustainable nanotechnology. Currently pursuing a PhD at the University of Messina, Italy, he holds an MSc in Physical Chemistry from Hawassa University and a BSc in Chemistry from Dilla University. His professional experience includes serving as Lecturer of Physical Chemistry at Borana University, Chief-in Laboratory Chemist, and Senior Lab Technical Assistant at Madda Walabu University, where he contributed significantly to research and laboratory management. His research primarily focuses on the green synthesis of nanoparticles and metal oxide semiconductors for sustainable applications, including green energy conversion, electrochemical and bio-nano sensors, catalysis design, and environmental remediation. Notable projects include biosynthesized N-Zn co-doped CuO nanoparticles for photocatalytic dye degradation, polyaniline-coated nanocomposites for enhanced microbial fuel cell efficiency, and activated carbon from Vernonia amygdalina for water purification. With 50 citations across 49 documents and an h-index of 2, Mr. Jara actively engages with the scientific community through platforms such as ORCID, ResearchGate, Scopus, and LinkedIn, demonstrating a strong commitment to advancing sustainable chemistry and nanotechnology solutions.

Profile: Scopus | Orcid

Featured Publications

Jara, Y. S., Mohammed, E. T., & Mekiso, T. T. (2025). Biosynthesized pure CuO, N-CuO, Zn-CuO, and N-Zn-CuO nanoparticles for photocatalytic activity: Enhanced optical properties through bandgap engineering. Next Materials.

Shuka, Y. (2025). Investigation of energy efficiency in a zeolite-water adsorption solar cooling system utilizing locally sourced materials for the conservation chamber. Physical Science International Journal.

Eyoel, T., Shuka, Y., Tadesse, S., Tesfaye, T., Mengesha, M., & Mert, S. O. (2025). Green energy: Power generation improvement in microbial fuel cells using bio-synthesized polyaniline-coated Co3O4 nanocomposite. International Journal of Energy Research.

Tesfaye, T., Shuka, Y., Tadesse, S., Eyoel, T., & Mengesha, M. (2025). Improving the power production efficiency of microbial fuel cell by using biosynthesized polyaniline-coated Fe3O4 as pencil graphite anode modifier. Scientific Reports.

Jara, Y. S., Mekiso, T. T., & Washe, A. P. (2024). Highly efficient catalytic degradation of organic dyes using iron nanoparticles synthesized with Vernonia amygdalina leaf extract. Scientific Reports.

Mengesha, M., Shuka, Y., Eyoel, T., & Tesfaye, T. (2024). Novel biomaterial-derived activated carbon from Lippia adoensis (Var. Koseret) leaf for efficient organic pollutant dye removal from water solution. American Journal of Applied Chemistry, 12(2), 11.

Jara, Y. S., & Gari, A. N. (2023). The impact of land use types on soil physicochemical properties and agricultural productivity: A case of Gojera Kebele, Dinsho District, South Eastern Ethiopia. Research Square.

Mr. Ivo Yotov | Renewable Energy | Best Researcher Award

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Mr. Ivo Yotov | Renewable Energy | Best Researcher Award

Mr. Ivo Yotov | Technical University of Sofia | Bulgaria

Mr. Ivo Yotov Yotov is a highly skilled mechanical engineer with extensive experience in the space industry, automotive environmental testing, and heavy machinery maintenance. He is currently contributing to advanced satellite projects as an AIT Mechanical Engineer at Endurosat EAD, where he is involved in the precise assembly, integration, and testing of satellite systems. Previously, he worked as an Environmental Test Technician at Visteon Electronics Bulgaria, focusing on climatic and mechanical testing for automotive platforms, and as a Service Engineer at EUROMARKET Group, specializing in diagnostics, maintenance, and optimization of heavy machinery. His career is characterized by a strong focus on quality assurance, adherence to industry standards, and the application of innovative engineering solutions. With both advanced academic training and practical expertise, Ivo blends theoretical knowledge with hands-on problem-solving to deliver results in complex and technologically demanding environments.

Professional Profile 

Google Scholar | Scopus

Education and Experience

Mr. Ivo Yotov Yotov is pursuing a doctoral degree at the Technical University of Sofia in the field of Theory of Mechanisms, Machines, and Automatic Lines. His research examines the modelling and study of energy conversion systems based on shape memory alloys, supported by specialized studies in MEMS technology, mathematical modelling, and actuator design. He also holds a master’s degree in Mechanical Engineering from the same institution, specializing in Computer-aided Design and Manufacturing Technology. His thesis focused on the design and analysis of a bistable pump driven by shape memory alloys, incorporating an energy recovery system. His professional experience spans several engineering domains, including his current role as an AIT Mechanical Engineer in the space industry, previous work as an Environmental Test Technician in the automotive sector, and earlier service as a heavy machinery Service Engineer. This academic and professional blend gives him a solid foundation for tackling complex mechanical and technological challenges.

Summary Suitability

Mr. Ivo Yotov Yotov is an outstanding candidate for the Best Researcher Award, demonstrating a rare combination of academic depth, cross-industry engineering expertise, and impactful research in the field of applied mechanical and aerospace engineering. His work bridges theoretical innovation with practical application, particularly in the study and utilization of shape memory alloys for energy conversion, vibration harvesting, and high-reliability mechanical systems. With a strong foundation in satellite system integration, environmental testing for the automotive industry, and diagnostics for heavy machinery, Ivo has consistently applied rigorous methodologies to solve complex engineering problems. His academic research, supported by high-quality publications in peer-reviewed journals, reflects a commitment to advancing knowledge in smart material applications and energy systems.

Professional Development

Mr. Ivo Yotov Yotov’s professional development reflects a steady progression through increasingly sophisticated areas of engineering. His early work in heavy machinery diagnostics and maintenance allowed him to build a strong technical foundation in mechanical systems, safety, and reliability. Moving into the automotive sector, he advanced his skills in environmental testing, developing test programs, ensuring compliance with industry standards, and mastering the interpretation of performance data under various climatic and mechanical conditions. In the space industry, his focus has expanded to high-precision assembly and integration of satellite systems, combining advanced mechanical engineering with rigorous quality control and testing methodologies. Throughout his career, he has consistently sought opportunities to expand his technical expertise, deepen his understanding of innovative materials such as shape memory alloys, and apply modern design and manufacturing tools. His journey demonstrates adaptability, commitment to excellence, and the ability to integrate theoretical and practical knowledge in cutting-edge engineering projects.

Research Focus

Mr. Ivo Yotov Yotov’s research and technical work align with the category of Applied Mechanical and Aerospace Engineering, with a particular emphasis on smart materials and precision systems. His doctoral studies investigate energy conversion systems based on shape memory alloys, exploring their potential in actuation, energy recovery, and absorption technologies. His expertise extends to MEMS-based applications, mathematical modelling, and the design of systems capable of performing reliably in challenging operational environments. In his current space industry role, he applies these principles to satellite integration and testing, ensuring structural, mechanical, and functional integrity. His background in automotive environmental testing also supports research into material durability, system resilience, and performance optimization under extreme climatic and mechanical stress. This combination of academic inquiry and industrial application positions him to contribute to advancements in smart material utilization, satellite technology, and high-reliability engineering systems.

Awards and Honors

Mr. Ivo Yotov Yotov has been recognized for his professional excellence through respected certifications, specialized training, and impactful contributions to engineering research and practice. He holds internationally acknowledged certifications in ISO/IEC standards, demonstrating a strong commitment to quality management, laboratory competence, and adherence to globally accepted engineering requirements. Throughout his career, he has been trusted to lead maintenance and repair teams for high-priority projects in the aerospace, automotive, and heavy machinery sectors. His reputation for delivering results under challenging conditions is matched by his ability to integrate leadership, technical precision, and innovative problem-solving. Proficiency in advanced engineering software, including SolidWorks, Comsol, Ansys, and PTC Creo, further enhances his capacity to create and implement effective solutions. These honors reflect his dedication to advancing engineering practices, maintaining professional integrity, and contributing to projects with lasting technical and industrial impact.

Publication Top Notes

  • Title: Study of Self-Excited Thermomechanical Oscillator with Shape Memory Alloys
    Year: 2024
    Citation: 4

  • Title: Dynamics of a Self-Excited Vibrating Thermal Energy Harvester with Shape Memory Alloys and PVDF Cantilevers
    Year: 2024
    Citation: 3

  • Title: Magnetic Frequency Tuning of a Shape Memory Alloy Thermoelectric Vibration Energy Harvester
    Year: 2025

Conclusion

Mr. Ivo Yotov Yotov stands out as an exceptional researcher whose academic achievements, innovative contributions, and practical engineering applications position him as a leading figure in his field. His commitment to advancing knowledge, coupled with his ability to translate research into real-world technological solutions, makes him highly deserving of the Best Researcher Award.

 

Ms. Mohadeseh Naderi | Renewable Energy | Best Researcher Award

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Ms. Mohadeseh Naderi | Renewable Energy | Best Researcher Award

Ms. Mohadeseh Naderi, Dundalk Institute of technology, Ireland.

Ms. Mohadeseh Naderi is a dedicated researcher at Dundalk Institute of Technology with a strong focus on renewable energy and biomass conversion. She holds a Master’s degree in Chemical Engineering and is currently pursuing her PhD in the field of sustainable energy. Her academic research has been published in reputable journals including Biomass Conversion and Biorefinery and the International Journal of Thermofluids. She is an active member of Engineers Ireland and is known for her technical knowledge and research excellence. In recognition of her work, she was awarded the Best Paper Award at the SEEP 2024 Conference.

Professional Profile

Google Scholar
Orcid

Education and Experience

Ms. Mohadeseh Naderi completed her Master’s degree in Chemical Engineering and is currently engaged in doctoral research in the field of renewable energy. She is affiliated with Dundalk Institute of Technology as a researcher. Throughout her academic journey, she has contributed to several scholarly publications including articles in Biomass Conversion and Biorefinery and the International Journal of Thermofluids. Her experience includes extensive work in biomass conversion and thermofluid systems, combining theoretical knowledge with practical application in sustainable energy development.

Summary Suitability

Ms. Mohadeseh Naderi is a highly deserving candidate for the Best Researcher Award based on her sustained academic dedication, impactful research outputs, and contributions to the renewable energy sector. Currently a PhD researcher at Dundalk Institute of Technology, she holds an MSc in Chemical Engineering and specializes in biomass conversion and sustainable energy systems. Her work aligns with global environmental goals and demonstrates both scientific excellence and practical relevance.

Professional Development

Ms. Mohadeseh Naderi has shown consistent growth in her professional journey through academic advancement and active research. With a foundation in chemical engineering, she has expanded her expertise to include renewable energy systems and sustainable technology. She has authored peer-reviewed articles in high-impact journals and maintains active participation in professional organizations such as Engineers Ireland. Her work is not only academic but also aimed at real-world applications that contribute to environmental sustainability. Through ongoing research and collaborations, she continues to enhance her knowledge and impact in the energy and engineering sectors.

Research Focus 

Ms. Mohadeseh Naderi’s research is centered on advancing technologies in renewable energy, with a particular emphasis on biomass conversion. Her work explores innovative thermochemical and biochemical pathways for transforming organic waste into clean, sustainable energy sources. By integrating principles of chemical engineering and thermofluid dynamics, she develops efficient systems that optimize energy recovery while minimizing environmental impact. Her research contributes to addressing global energy challenges by promoting alternatives to fossil fuels and supporting the transition to low-carbon economies. With both scientific rigor and practical relevance, her studies offer scalable solutions for energy sustainability in academic, industrial, and environmental contexts.

Awards and Honors

Ms. Mohadeseh Naderi received the Best Paper Award at the Sustainable Energy and Environmental Protection (SEEP) Conference held in September 2024. She also obtained a Certificate of Merit from the event organizers in recognition of her presentation. Her citation index currently stands at one, reflecting her early but impactful contributions to academic research.

Publication Top Notes

  1. Naderi, M., & Vesali-Naseh, M. (2021). Hydrochar-derived fuels from waste walnut shell through hydrothermal carbonization: Characterization and effect of processing parameters. Biomass Conversion and Biorefinery, 11(5), 1443–1451.
    [Cited by: 40 | Published: October 12, 2019 | Indexed: SCI/Scopus]

  2. Naderi, M., Rashidi, H., Reynolds, A., & Doherty, W. (2024). Aspen Plus modelling of the MILENA dual fluidised bed biomass gasifier technology. SEEP Conference 2024, 7.
    [Presented: September 2024 | Awarded Best Paper]

  3. Naderi, M., & Vesali-Naseh, M. (2017). Production of Hydrochar from Biomass by Hydrothermal Carbonization. 4th International Conference on Applied Research in Chemistry, Science, and Biology, October 19, 2017.

Conclusion

Ms. Mohadeseh Naderi’s contributions in advancing renewable energy technologies, particularly through novel biomass utilization strategies, make her a strong candidate for the Best Researcher Award. Her work has already started influencing both academic and applied sectors, with promising potential for further impact.