Uzma Amin | Engineering | Best Researcher Award

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Dr. Uzma Amin | Engineering | Best Researcher Award

Lecturer at Curtin University, Australia.

Dr. Uzma Amin πŸŽ“ is a passionate Lecturer in Electrical Engineering ⚑, with a Ph.D. in the field and over a decade of commitment to academia and applied research. She actively contributes to education through curriculum development and international teaching collaborations 🌍. As a member of IEEE, WIE, and the Young Professional Engineers network πŸ‘©β€πŸ’», she also plays a key role in professional communities. Her work bridges academia and industry through hands-on supervision of student-industry projects πŸ”§. In addition to her technical contributions, she is a committed reviewer and volunteer, driving innovation and empowerment in engineering education πŸš€.

Professional Profile:

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Suitability For Best Researcher award – Dr. Uzma Amin

Dr. Uzma Amin exemplifies the ideal candidate for the Best Researcher Award through her balanced contributions in research, academia, industrial collaboration, and international teaching. With a Ph.D. in Electrical Engineering, she maintains a strong publication record, participates actively in global professional networks (IEEE, WIE), and has shown leadership and innovation in curriculum design and engineering education. Her research, which aligns with sustainable and impactful themes like renewable energy integration, electrical power systems, and smart grids, is both applied and interdisciplinary, reinforcing her significance in today’s technological landscape.

πŸ“˜ Education & Experience

  • πŸŽ“ Ph.D. in Electrical Engineering

  • πŸ‘©β€πŸ« Lecturer in Electrical Engineering

  • 🌐 Taught postgraduate units at Curtin and Yanshan University under international collaboration

  • πŸ“š Developed and redesigned undergraduate and postgraduate engineering curricula

  • πŸ”¬ 23 research publications in indexed journals

  • 🀝 Supervised industrial projects with Regen Pvt Ltd, Rio Tinto, Partum Engineering, and EPC Australia

  • 🌍 Member of IEEE, WIE, and Young Professional Engineers

πŸ“ˆ Professional Development

Dr. Uzma Amin’s professional development reflects her proactive pursuit of excellence in engineering education and practice 🌟. She received the prestigious FHEA fellowship in 2022 πŸŽ–οΈ, recognizing her pedagogical innovation. As a vice-chair of IEEE WIE WA section in 2023, she actively organized workshops and networking events 🀝. Her consistent role as a reviewer for top-tier journals like IEEE Access and Elsevier’s Applied Energy πŸ“‘ illustrates her influence in academic circles. Her teaching, curriculum innovation, and industrial partnerships exemplify a progressive career dedicated to both research impact and engineering education transformation πŸ’‘.

πŸ”¬ Research Focus Category

Dr. Uzma Amin’s research lies primarily in Electrical Power Systems and Renewable Energy Integration ⚑🌱. Her work addresses real-world engineering problems through applied research, with a strong emphasis on renewable power generation systems, electrical machines, and energy systems optimization πŸ”‹. With 23 publications, she contributes to fields intersecting smart grids, clean energy, and sustainable power infrastructure 🌍. Her industry collaborations with companies like Rio Tinto and Electric Power Conversions Australia underscore the applied nature of her research πŸ› οΈ. She also reviews work in computational energy analysis and advanced electrical systems, reflecting a technically diverse focus πŸ“˜.

πŸ… Awards and Honors

  • πŸŽ–οΈ FHEA Fellowship, 2022 – Recognized for excellence in higher education teaching

  • πŸ‘©β€πŸ’Ό Vice-Chair, IEEE Women in Engineering (WIE), WA Section, 2023

  • πŸ“ Regular Reviewer for top journals (IEEE Access, Elsevier, MDPI, etc.)

Publication Top Notes

1. Optimal price based control of HVAC systems in multizone office buildings for demand response

  • Authors: U. Amin, M. J. Hossain, E. Fernandez

  • Journal: Journal of Cleaner Production

  • Volume: 270

  • Article No.: 122059

  • Cited by: 67

  • Year: 2020

  • Summary: This paper proposes a price-based control strategy for HVAC systems in multizone office buildings to enhance energy efficiency and responsiveness in demand-side management under smart grid settings.

2. Computational tools for design, analysis, and management of residential energy systems

  • Authors: K. Mahmud, U. Amin, M. J. Hossain, J. Ravishankar

  • Journal: Applied Energy

  • Volume: 221

  • Pages: 535–556

  • Cited by: 52

  • Year: 2018

  • Summary: The article surveys and evaluates various computational tools that assist in designing and managing residential energy systems, particularly under the influence of emerging distributed energy resources.

3. Integration of renewable energy resources in microgrid

  • Authors: M. Ahmed, U. Amin, S. Aftab, Z. Ahmed

  • Journal: Energy and Power Engineering

  • Volume: 7 (1)

  • Pages: 12–29

  • Cited by: 44

  • Year: 2015

  • Summary: This study discusses the integration strategies of renewable energy sources in microgrids and addresses the associated challenges and opportunities from technical and economic perspectives.

4. Design, construction and study of small scale vertical axis wind turbine based on a magnetically levitated axial flux permanent magnet generator

  • Authors: G. Ahmad, U. Amin

  • Journal: Renewable Energy

  • Volume: 101

  • Pages: 286–292

  • Cited by: 39

  • Year: 2017

  • Summary: This work presents a detailed design and performance analysis of a small-scale vertical axis wind turbine, incorporating a magnetically levitated generator to reduce friction and improve energy efficiency.

5. Energy trading in local electricity market with renewablesβ€”A contract theoretic approach

  • Authors: U. Amin, M. J. Hossain, W. Tushar, K. Mahmud

  • Journal: IEEE Transactions on Industrial Informatics

  • Volume: 17 (6)

  • Pages: 3717–3730

  • Cited by: 37

  • Year: 2020

  • Summary: The paper develops a contract-theoretic framework for local energy trading in a renewable-integrated smart grid setting, ensuring fair pricing and demand satisfaction.

6. Performance analysis of an experimental smart building: Expectations and outcomes

  • Authors: U. Amin, M. J. Hossain, J. Lu, E. Fernandez

  • Journal: Energy

  • Volume: 135

  • Pages: 740–753

  • Cited by: 34

  • Year: 2017

  • Summary: This study presents real-time data and performance evaluation of an experimental smart building, highlighting discrepancies between expected and actual outcomes in energy consumption and management.

🧾 Conclusion

In conclusion, Dr. Uzma Amin’s career trajectory, research excellence, and international impact make her an outstanding contender for the Best Researcher Award. Her ability to merge technical depth with practical relevance, academic influence, and community engagement embodies the spirit of a researcher committed not just to discovery but also to societal and industrial transformation. Recognizing her with this award would celebrate a truly multidimensional and forward-thinking scholar. πŸ†

Li Wang | Engineering | Best Scholar Award

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Li Wang | Engineering | Best Scholar Award

PHD Candiate at chongqing university, China.

Li Wang is a dedicated Ph.D. candidate at Chongqing University, specializing in electrical engineering with a focus on ice prevention and mitigation for power grids. His journey began with a B.S. in electrical engineering from Qilu University of Technology, followed by an M.S. from Sichuan University. His current research is embedded within the prestigious State Key Laboratory of Power Transmission Equipment and System Security and New Technology at Chongqing University. Li has completed three research projects, with his work published in respected journals such as Applied Thermal Engineering and Polymers. His research aims to improve power system resilience by addressing ice accumulation and insulator flashover issues. With practical experience in a State Grid Zhejiang Electric Power Co. project and a citation index of 28.5, he is emerging as a promising scholar in electrical engineering and insulation technology, with plans to continue advancing research to address industry challenges.

ProfileπŸ‘€

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Education πŸŽ“

Li Wang completed his B.S. degree in electrical engineering from Qilu University of Technology in 2016, where he developed foundational knowledge in power systems and insulation technology. Pursuing further specialization, he earned his M.S. in electrical engineering from Sichuan University in 2019, deepening his understanding of energy transmission and system reliability. His educational background is characterized by a blend of theoretical and practical learning, equipping him to handle the challenges of power grid reliability and insulation in extreme conditions. Currently, he is a Ph.D. candidate at Chongqing University, where he is engaged with the State Key Laboratory, recognized for advancing research in power transmission security. His academic journey reflects a commitment to excellence in electrical engineering and energy infrastructure, with each step laying a foundation for his research into ice prevention and system safety.

ExperienceπŸ’Ό

Li Wang’s professional and academic experience is rooted in electrical engineering, with a focus on developing solutions to protect power systems from extreme weather. As a Ph.D. candidate at Chongqing University, he has contributed to three significant research projects, each aimed at enhancing the resilience of electrical insulation in ice-prone environments. He has also gained practical experience through his involvement in an industry project with State Grid Zhejiang Electric Power Co., which provided real-world insights into the application of his research. This blend of research and industry experience has allowed Li to apply theoretical knowledge to practical problems, particularly in addressing challenges related to ice formation on power infrastructure. His work has been featured in leading journals, showcasing his ability to contribute valuable insights to the field.

Research Interests πŸ”¬

Li Wang’s research interests lie at the intersection of electrical engineering, material science, and environmental sustainability. He is particularly focused on developing innovative solutions for ice prevention and mitigation in power systems, which are critical for ensuring system reliability in regions prone to freezing temperatures. His work involves analyzing and improving the performance of insulators and power transmission equipment under icy conditions, with the goal of minimizing system failures and enhancing the durability of electrical infrastructure. Li is also interested in advancing knowledge on how environmental factors affect insulation performance, with implications for the future of power grid maintenance and resilience. His research is driven by a commitment to both scientific discovery and practical application, aiming to support the energy sector in adapting to increasingly challenging environmental conditions.

Awards and Honors πŸ†

Li Wang has achieved notable academic milestones, underscored by a citation index of 28.5, demonstrating the impact of his research in electrical engineering. Although early in his career, his publications in esteemed journals like Applied Thermal Engineering, Plant Methods, and Polymers have established him as a promising researcher in insulation technology. His work on ice prevention for energy equipment addresses critical challenges faced by the power industry, and his contributions to three research projects have been well-recognized within his academic community. Additionally, his involvement in an industry project with State Grid Zhejiang Electric Power Co. highlights his ability to translate research into real-world applications. Li’s academic achievements and professional contributions underscore his potential as an emerging leader in the field of power grid safety and resilience.

Conclusion πŸ”šΒ 

Li Wang’s research in preventing and mitigating ice damage in power grids has potential for real-world impact, making him a promising candidate for the Best Scholar Award. With future growth in collaborations and publications, he has a strong foundation to contribute significantly to his field.

Publications Top NotesΒ πŸ“š

Title: “Mechanism of self-recovery of hydrophobicity after surface damage of lotus leaf”
Authors: L. Wang, L. Shu, Q. Hu, X. Jiang, H. Yang, H. Wang, L. Rao
Journal: Plant Methods
Year: 2024
Citation Count: 3

Title: “Ultra-efficient and thermally-controlled atmospheric structure deicing strategy based on the Peltier effect”
Authors: L. Wang, L. Shu, Y. Lv, Q. Hu, L. Ma, X. Jiang
Journal: Applied Thermal Engineering
Year: 2024
Citation Count: 1