Meisam Ansarpour | Chemical Engineering | Best Researcher Award

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Mr. Meisam Ansarpour | Chemical Engineering | Best Researcher Award

Mr. Meisam Ansarpour | University of Wolverhampton | United Kingdom

Mr. Meisam Ansarpour is a dedicated chemical engineering researcher specializing in computational fluid dynamics (CFD), nanotechnology, and advanced CO₂ capture processes. His career reflects a strong integration of theoretical modeling, experimental design, and industrial applications. He has contributed significantly to advancing nanofluid-based heat and mass transfer techniques, with applications in energy efficiency and environmental sustainability. Throughout his academic and professional journey, he has collaborated with multidisciplinary teams to address climate change challenges through innovative CO₂ absorption methods and optimization strategies. His publications in reputable international journals and contributions to book chapters showcase his commitment to generating impactful research that bridges scientific knowledge and industrial solutions. In addition to research, he has served as a lecturer and mentor, guiding students in mastering engineering principles and simulation tools. His forward-looking vision is focused on delivering innovative, practical, and sustainable solutions to complex engineering problems worldwide.

Profile

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Education

Mr. Meisam Ansarpour’s academic pathway has been rooted in excellence and progressive specialization. He pursued his bachelor’s studies in chemical engineering with a strong focus on thermodynamics and process operations. Building on this foundation, he completed a master’s degree where he conducted pioneering experimental work on nanofluids and their effect on mass transfer phenomena, supported by advanced modeling using COMSOL and MATLAB. His research combined laboratory precision with computational accuracy, setting the stage for his current doctoral studies. At the PhD level, his focus is on optimizing CO₂ absorption-desorption systems through innovative system configurations. His learning approach is interdisciplinary, integrating fluid mechanics, reaction engineering, and environmental technology. Alongside formal studies, he has engaged in specialized training in simulation platforms like ANSYS Fluent, Aspen HYSYS, and Materials Studio, enabling him to model and predict process behavior under complex operational conditions. His academic achievements are supported by high performance in coursework, research output, and practical application.

Experience

Mr. Meisam Ansarpour’s professional journey combines academia, research, and industry engagement. As a visiting lecturer, he has taught subjects such as fluid mechanics, thermodynamics, and process simulation, demonstrating both technical expertise and strong communication skills. His role as a laboratory supervisor enhanced his leadership in overseeing experimental safety, managing advanced equipment, and guiding student projects. Industrially, he has worked on ethane diffusivity measurement in composite pipelines, bridging theoretical research with real-world operational demands. His research has involved both independent investigations and collaborative projects with leading academics, resulting in innovative process designs for CO₂ capture and heat transfer enhancement. Beyond research, he has been actively involved in technical skill development, delivering training on software tools like MATLAB, ASPEN Plus, and MINITAB. His combined teaching and research experience showcases his capability to translate scientific advancements into applied engineering solutions, making him a versatile contributor in both academic and industrial chemical engineering landscapes.

Research Interest

Mr. Meisam Ansarpour’s research interests focus on integrating nanotechnology with chemical process engineering to address global environmental and energy challenges. He specializes in computational fluid dynamics (CFD) modeling, exploring the heat and mass transfer performance of nanofluids in industrial applications. His work particularly emphasizes the enhancement of CO₂ capture efficiency through modified absorption and regeneration processes. He investigates system reconfiguration, solvent optimization, and advanced reactor designs to reduce energy consumption and improve scalability. His interests also extend to the experimental validation of CFD models, ensuring real-world applicability of theoretical findings. By combining simulation, laboratory experimentation, and industrial process knowledge, his research aims to develop sustainable, high-performance solutions for carbon mitigation. The ultimate goal is to provide industries with cost-effective, environmentally friendly technologies that contribute to achieving net-zero emission targets while maintaining operational efficiency and process reliability across multiple chemical engineering domains.

Awards

Mr. Meisam Ansarpour has been recognized for his academic excellence, research productivity, and technical leadership in chemical engineering. He was honored as a talented student for his innovative contributions to nanofluid research and process optimization. His designation as a top researcher reflects his high-impact publications and successful collaborations in cutting-edge CO₂ capture technologies. Representing his university in prestigious scientific competitions, he has demonstrated both technical competence and the ability to communicate complex research to diverse audiences. These distinctions acknowledge not only his academic performance but also his capacity to drive advancements that align with sustainability goals. His awards are a testament to his consistent dedication, creative problem-solving skills, and ability to bridge the gap between theoretical research and practical implementation. Through his achievements, he has built a strong foundation for future contributions to chemical engineering innovation and international scientific collaboration.

Publication Top Notes

Biomass and Wind-Based Cogeneration Technologies

Reference Module in Earth Systems and Environmental Sciences – Meisam Ansarpour, Masoud Mofarahi

Carbon Capture by Swing Adsorption Processes

 Reference Module in Earth Systems and Environmental Sciences – Meisam Ansarpour, Masoud Mofarahi

Increasing Mass Transfer in Absorption and Regeneration Processes via Nanofluids

Nanofluids and Mass Transfer – Meisam Ansarpour, Masoud Mofarahi

Numerical Study on the Convective Heat Transfer Performance of a Developed MXene IoNanofluid in a Horizontal Tube by Considering Temperature-Dependent Properties

Journal of Thermal Analysis and Calorimetry – Meisam Ansarpour, Navid Aslfattahi, Masoud Mofarahi, R. Saidur

Increasing Mass Transfer in Absorption and Regeneration Processes via Nanofluids

 Nanofluids and Mass Transfer – Meisam Ansarpour, Masoud Mofarahi

Conclusion

Mr. Meisam Ansarpour is a forward-thinking chemical engineer whose career embodies a balance between research excellence, teaching, and practical industry engagement. His contributions to CO₂ capture, nanofluid applications, and heat and mass transfer modeling are paving the way for more efficient and sustainable chemical processes. By integrating computational modeling with experimental validation, he ensures that his research delivers both scientific depth and industrial applicability. His international collaborations and diverse research portfolio demonstrate adaptability and a global perspective on engineering challenges. With a commitment to sustainability, innovation, and knowledge transfer, he is poised to make further breakthroughs that support climate change mitigation and process optimization. His combination of academic rigor, hands-on experimentation, and visionary approach positions him as a valuable leader in advancing chemical engineering solutions for the future.

Samira Farjaminejad | Engineering | Best Researcher Award

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Dr. Samira Farjaminejad | Engineering | Best Researcher Award

Dr. Samira Farjaminejad | City university of London | United Kingdom

Dr. Samira Farjaminejad is an accomplished biomedical engineer based in London, UK, with a strong academic and professional background in tissue engineering and regenerative medicine. She specializes in the synthesis and characterization of novel polymer-based biomaterials aimed at advancing medical therapies. Her expertise spans advanced laboratory techniques including PCR, cell culture, 3D printing, flow cytometry, and polymer characterization methods such as SEM, XRD, DSC, and DMTA. Dr. Farjaminejad’s work integrates nanotechnology and scaffold development, making significant contributions to bone regeneration and drug delivery systems. In addition to her research, she has held academic positions, supervised over 500 students, and participated in high-impact interdisciplinary projects with international organizations like the WHO. Her combination of technical knowledge, teaching, and real-world clinical applications demonstrates her commitment to advancing the future of biomedical sciences.

Profile

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Education

Dr. Farjaminejad holds a PhD in Biomedical Engineering from Azad University, Tehran Central Branch, where she completed a distinguished thesis on polymer nanocomposites for bone tissue engineering. Her academic foundation includes an MSc in Biomedical Engineering and a second MSc in Research and Health Management from City University of London, achieving Merit-level performance. Her doctoral research showcased advanced competencies in biomaterial synthesis and scaffold development, while her second master’s degree focused on digital health innovations like tele-mental health in the UK. She also earned her bachelor’s degree in Biomedical Engineering (Bioelectric) from Azad University, equipping her with an early and solid understanding of bio-signals and biomedical systems. This diverse academic journey has enriched her interdisciplinary approach and enabled her to bridge engineering principles with health science innovations in both research and practice.

Experience

Dr. Farjaminejad’s experience reflects a strong blend of academic, clinical, and industry-focused expertise. She has served as a Research Intern at the International Agency for Research on Cancer (WHO), where she analyzed genomic data governance and ethical frameworks across Sub-Saharan Africa. As a researcher at Amirkabir University of Technology, she developed novel bio-rubbers and nanocomposites for tissue regeneration. In academia, she held a faculty position at Azad University, mentoring over 500 students in biomedical engineering and leading practical lab sessions. Her clinical experience includes work as a clinical trainer and biomedical engineer at Rasool Akram Hospitals, where she trained staff in the use of diagnostic and therapeutic medical equipment. Additionally, she was the Head of R&D at Noyan Teb Dental Material Company, where she led the development of innovative dental biomaterials. This rich mix of responsibilities underlines her multidimensional contributions to biomedical engineering.

Research Interests

Dr. Farjaminejad’s research primarily focuses on tissue engineering and regenerative medicine, particularly the use of polymer-based biomaterials for bone repair and drug delivery. She is deeply involved in the development and testing of nanocomposites, scaffolds, and bio-rubbers with enhanced mechanical and biological properties. Her interest extends into the exploration of nanoparticles in regenerative applications and the integration of 3D printing in scaffold fabrication. She is also exploring the impact of electrical stimulation in bone healing and the non-invasive imaging of tissue-engineered constructs. In public health, she has contributed to international research on genomic data protection and tele-mental health systems. Her interdisciplinary approach enables her to investigate complex problems from the molecular to the systems level, contributing to both therapeutic innovation and policy development in healthcare technologies.

Awards & Nominations

Dr. Farjaminejad’s body of work and interdisciplinary impact make her a strong candidate for numerous prestigious awards in biomedical engineering. Her recent collaborations with WHO-IARC on ethical frameworks in genomic research, combined with her extensive publication record in high-impact journals such as Polymers and Carbohydrate Polymer and Applications, demonstrate her thought leadership in global biomedical research. She has guided over 500 students, developed innovative biomaterials for both academic and commercial use, and contributed to cutting-edge advances in tissue regeneration. Her nomination for awards in innovation, translational research, or early-career excellence is well supported by her academic distinction, including two MSc degrees and a PhD with distinction. Her cross-sector experience—ranging from hospitals to industry—adds further value to her candidacy.

Publication Top Notes

Advances and Challenges in Polymer-Based Scaffolds for Bone Tissue Engineering: A Path Towards Personalized Regenerative Medicine

Nanoparticles in bone regeneration: a narrative review of current advances and future directions in tissue engineering

Tuning properties of bio-rubbers and its nanocomposites with addition of succinic acid and ɛ-caprolactone monomers to poly(glycerol sebacic acid) as main platform for …

3D Printing Approach in Maxillofacial Surgery in Iran: An Evaluation Using the Non-Adoption, Abandonment, Scale-Up, Spread, and Sustainability (NASSS) Framework

The critical role of nano-hydroxyapatites as an advanced scaffold in drug delivery towards efficient bone regeneration: Recent progress and challenges

Hydroxyapatites and nano-hydroxyapatites as scaffolds in drug delivery towards efficient bone regeneration: A review

The Role of Tissue Engineering in Orthodontic and Orthognathic Treatment: A Narrative Review

Regenerative Endodontic Therapies: Harnessing Stem Cells, Scaffolds, and Growth Factors

Surgical orthodontics in a patient with β-thalassaemia major. A case report

Conclusion

Dr. Samira Farjaminejad exemplifies a new generation of interdisciplinary biomedical engineers whose work bridges research, clinical application, and policy. Her accomplishments in developing advanced scaffolds, her collaborations with global health organizations, and her dual expertise in engineering and health management uniquely position her to make lasting contributions in regenerative medicine. Her publication portfolio reflects both depth and breadth, covering experimental studies, systematic reviews, and policy evaluations. She continues to lead and innovate in polymer science, tissue engineering, and health systems research. As a mentor, researcher, and engineer, she represents the epitome of translational science—taking ideas from lab bench to bedside with rigor and vision. Her trajectory suggests she is not only a leader in her field today but also a critical voice for the future of biomedical innovation.