Alia Al-Ghosoun | Engineering and Technology | Best Researcher Award

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Dr Alia Al-Ghosoun | Engineering and Technology | Best Researcher Award

Assistant professor, Philadephia University, Jordan

Dr. Alia Radwan Al-Ghosoun is an Assistant Professor in the Mechatronics Engineering Department at Philadelphia University, Jordan. With a deep passion for advanced engineering research, she holds a DPhil in Engineering from Durham University, UK, where her work focused on shallow water dynamics and adaptive control methods for hydrodynamic systems. Dr. Al-Ghosoun’s research spans fluid mechanics, computational modeling, and the application of artificial intelligence in engineering problems. She has worked as a post-doctoral researcher at Durham University and has held multiple academic positions at the University of Jordan, where she contributed to the development of energy-efficient systems and intelligent control techniques. Dr. Al-Ghosoun’s commitment to advancing knowledge in hydrodynamics and environmental modeling has resulted in impactful publications and contributions to numerical simulation and uncertainty quantification. She is passionate about improving the practical application of engineering solutions for environmental challenges.

Profile

Scopus

Strengths for the Award

  1. Advanced Academic Background:
    • Dr. Al-Ghosoun holds a Doctor of Philosophy in Engineering from Durham University, UK, where her research focused on shallow water flow dynamics and adaptive control techniques to improve the accuracy of these systems. This is a highly specialized field with significant implications in environmental modeling, water systems, and engineering, marking her as an expert in computational engineering and fluid dynamics.
    • Her post-doctoral research at Durham University further solidifies her expertise, particularly in understanding and quantifying uncertainty in numerical modeling of hydrodynamics, which is crucial for predicting real-world environmental phenomena.
  2. Impactful and Diverse Research Contributions:
    • Dr. Al-Ghosoun has published several peer-reviewed papers in high-impact journals such as Environmental Modelling and Software, Communications in Computational Physics, and International Journal of Computational Methods. These works cover areas such as uncertainty quantification, morphodynamics, and numerical simulation of shallow water flows and hydrosediment processes.
    • Her conference papers and book chapters demonstrate a commitment to advancing computational methods in hydrodynamics and environmental modeling, particularly addressing the challenges of bed topography deformation, fluid-structure interactions, and stress analysis in hydro-sediment systems.
  3. Interdisciplinary Research:
    • Dr. Al-Ghosoun’s research stands at the intersection of mechatronics, engineering, and environmental sciences, with a focus on adaptive control techniques and artificial intelligence. This interdisciplinary approach is essential in addressing complex real-world problems related to fluid dynamics and energy systems.
    • The integration of AI techniques (such as genetic algorithms) in energy consumption optimization and shallow water flow models highlights her innovative approach to solving large-scale engineering problems.
  4. Global Collaboration and Recognition:
    • With international experience as a Post-Doctoral Researcher at Durham University and several collaborative research efforts with Jordanian and UK-based academic institutions, Dr. Al-Ghosoun has developed a robust international network. Her involvement in global research platforms, such as ResearchGate, attests to her active engagement in the academic community and dissemination of her work.
  5. Teaching and Mentoring Experience:
    • Dr. Al-Ghosoun has demonstrated a strong commitment to education as an Assistant Professor at Philadelphia University, where she contributes to the development of young engineers in Mechatronics Engineering. Her role as a Teaching Assistant and Research Assistant at various institutions indicates her foundational experience in nurturing future engineers and scientists.
  6. Recognition of Research Excellence:
    • Dr. Al-Ghosoun’s papers, particularly her works on uncertainty quantification and modeling techniques for shallow water systems, have gained traction in the academic community. For instance, her work published in Environmental Modelling and Software (2021) has already accumulated 10 citations, signaling its importance in the field.

Areas for Improvement

  1. Broader Citation Impact:
    • While Dr. Al-Ghosoun’s work is highly specialized and impactful, the citation counts for some of her research papers remain low (e.g., her paper on stress analysis has 0 citations). Increasing visibility in wider journals and collaborating with researchers in complementary fields could enhance the reach and impact of her publications.
  2. Increased Public Engagement:
    • Engaging in public outreach or community-based projects that demonstrate the application of her research (e.g., how adaptive control methods improve water management or energy efficiency in real-world scenarios) could enhance the broader social impact of her work.
  3. Further Collaborative Interdisciplinary Projects:
    • Although her work spans several fields, further involvement in cross-disciplinary projects—especially those integrating sustainable engineering and climate resilience—could increase the relevance of her research to pressing global challenges, like climate change adaptation and sustainable resource management.

Education

Dr. Alia Radwan Al-Ghosoun earned her Doctor of Philosophy (DPhil) in Engineering from Durham University, UK in January 2021. Her doctoral research focused on understanding the effects of bathymetric movement on shallow water flows and their interaction with the seabed, leading to the development of adaptive control methods for improved accuracy in hydrodynamic simulations. Prior to this, she completed a Post-Doctorate at Durham University in 2022, where she explored the application of uncertainty quantification in complex engineering models. Dr. Al-Ghosoun holds a Master’s Degree in Mechanical Engineering from the University of Jordan, where she developed AI-based predictive models for fuel consumption in Jordan and optimized energy efficiency through genetic algorithms. She also earned her Bachelor’s degree in Mechatronics Engineering from the University of Jordan. Dr. Al-Ghosoun’s academic background equips her with interdisciplinary expertise in engineering and environmental science.

Experience

Dr. Alia Radwan Al-Ghosoun is currently an Assistant Professor at Philadelphia University in the Mechatronics Engineering Department since October 2022, where she teaches and conducts research in engineering systems and adaptive control techniques. Prior to this, she was a Post-Doctoral Researcher at Durham University, UK (2021-2022), focusing on uncertainty quantification in shallow water systems. Dr. Al-Ghosoun completed her DPhil at Durham University (2016-2021), where her research involved modeling shallow water flows and the interaction of bed topography. She has also held roles as a Research Assistant at the University of Jordan’s Water, Energy, and Environment Center (2012-2016) and the King Abdullah Design and Development Bureau (KADDB) (2012). Earlier in her career, she worked as a Teaching Assistant in both Mechatronics and Mechanical Engineering departments at the University of Jordan. Dr. Al-Ghosoun’s interdisciplinary experience blends academia with applied engineering solutions.

Awards and Honors

Dr. Alia Radwan Al-Ghosoun has been recognized for her research excellence and commitment to advancing knowledge in hydrodynamics and adaptive control systems. Her academic achievements are highlighted by her work at Durham University, where she earned a prestigious Doctoral Fellowship for her research on shallow water dynamics and bed interaction. She has also received recognition for her post-doctoral research contributions in uncertainty quantification and numerical simulations. Dr. Al-Ghosoun’s work has been presented at major academic conferences, and she has contributed to a variety of high-impact journal publications. In addition to her research accomplishments, she has been awarded teaching grants to support her role as an educator at Philadelphia University, where she mentors the next generation of Mechatronics engineers. Her consistent efforts to bridge the gap between theoretical research and practical engineering applications have earned her widespread recognition within her academic and professional communities.

Research Focus

Dr. Alia Radwan Al-Ghosoun specializes in hydrodynamic modeling, shallow water flows, and the application of adaptive control systems to improve the accuracy of complex environmental simulations. Her research interests focus on uncertainty quantification and the development of computational models for the numerical simulation of fluid dynamics, particularly in the context of stochastic bed topography and morphodynamics. She has worked extensively on shallow water waves, bathymetric effects, and water-bed interaction. One of her core research goals is to enhance the predictive accuracy of models used for environmental management and engineering systems by incorporating artificial intelligence techniques, such as genetic algorithms and surrogate models. Dr. Al-Ghosoun is passionate about integrating AI-based solutions into environmental and energy systems to address challenges like resource optimization, pollution reduction, and sustainable energy. Her work in hydro-sediment-morphodynamics provides valuable insights into climate change adaptation and water resource management.

Publication Top Notes

  1. Uncertainty quantification for stochastic morphodynamics 🌊🧑‍🔬, AIP Conference Proceedings, 2024.
  2. A Novel Computational Approach for Wind-Driven Flows over Deformable Topography 💨🌍, Lecture Notes in Computer Science, 2024.
  3. A Nonintrusive Reduced-Order Model for Uncertainty Quantification in Numerical Solution of One-Dimensional Free-Surface Water Flows Over Stochastic Beds 📊💧, International Journal of Computational Methods, 2022.
  4. Efficient Computational Algorithm for Stress Analysis in Hydro-Sediment-Morphodynamic Models 💻⚙️, Lecture Notes in Computer Science, 2022.
  5. A surrogate model for efficient quantification of uncertainties in multilayer shallow water flows 🌊🔬, Environmental Modelling and Software, 2021.
  6. A computational model for simulation of shallow water waves by elastic deformations in the topography 🌊⚡, Communications in Computational Physics, 2021.
  7. Uncertainty Quantification of Bathymetric Effects in a Two-Layer Shallow Water Model: Case of the Gibraltar Strait 🏝️🌊, Springer Water, 2020.
  8. A hybrid finite volume/finite element method for shallow water waves by static deformation on seabeds 🌊🧮, Engineering Computations, 2020.
  9. A new numerical treatment of moving wet/dry fronts in dam-break flows 💧🚨, Journal of Applied Mathematics and Computing, 2019.

Conclusion

Dr. Alia Radwan Al-Ghosoun is an exceptional candidate for the Best Researcher Award. Her contributions to the fields of hydrodynamics, uncertainty quantification, and adaptive control systems are not only advancing the understanding of complex environmental processes but are also pioneering new computational techniques that can improve the accuracy and efficiency of engineering systems. Her ability to merge artificial intelligence with environmental modeling positions her as a leader in the field. Her ongoing efforts in teaching, mentoring, and global academic collaborations further highlight her potential to shape the future of engineering and environmental sciences. With a few strategic steps to broaden her citation impact and public visibility, Dr. Al-Ghosoun could solidify her place as a thought leader in her field.

Muhammad Khalid Anser | Economics Awards | Best Researcher Award

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Dr Muhammad Khalid Anser | Economics Awards | Best Researcher Award

Associate Professor, Xi’an International University, China

Dr. Muhammad Khalid Anser is an accomplished academic with extensive experience in economics and business disciplines, specializing in environmental economics, sustainable development, and economic modeling. Holding a Ph.D. in Economics from Shaanxi Normal University, China, he has contributed significantly to the academic community with over 170 published articles, including 70 as the lead author, and over 6000 citations. Dr. Anser has also been recognized as one of the “World’s Top 2% Scientists” by Stanford University. His teaching philosophy focuses on critical thinking, real-world applications, and student engagement across graduate, master’s, and Ph.D. levels. Dr. Anser has presented his research at international conferences and served as a reviewer for prestigious journals. Currently an Associate Professor at Xi’an International University, China, he continues to drive research and academic excellence in economics, contributing to both education and impactful publications in environmental economics and policy analysis.

Strengths for the Award

Dr. Anser’s academic achievements are exemplary. With over 170 publications, more than 6000 citations, and recognition as one of the “World’s Top 2% Scientists,” his research impact is significant. His work addresses pressing global challenges like environmental sustainability, economic growth, and policy uncertainty. Dr. Anser’s ability to merge theoretical and applied economics through robust data analysis and advanced econometric techniques demonstrates a high level of research excellence.

Areas for Improvements

While Dr. Anser’s research is already widely recognized, he could further expand his work into interdisciplinary areas, particularly the intersection of economics, technology, and climate change, which would increase its broader applicability. Collaborative efforts with international think tanks or governmental organizations could help translate his research into policy advocacy.

Profile

Education

Dr. Muhammad Khalid Anser holds a Ph.D. in Economics from the International Business School at Shaanxi Normal University, China (2018). He earned his M.Phil. in Economics from The Islamia University, Bahawalpur, Pakistan, in 2012, following his M.Sc. in Economics from Bahauddin Zakariya University, Pakistan, in 2006. Dr. Anser’s educational foundation also includes a B.Sc. in Statistics, Mathematics, and Economics from Bahauddin Zakariya University, Multan, Pakistan (2004). His academic background equips him with a multidisciplinary approach to economics, integrating theoretical knowledge with practical, data-driven solutions. Dr. Anser’s advanced education in economics has fueled his research in areas such as environmental sustainability, economic growth, and financial development, contributing to his success as both an educator and researcher.

Experience

Dr. Muhammad Khalid Anser has held several prestigious academic positions. Currently, he serves as an Associate Professor at the School of Business at Xi’an International University, China, where he teaches economics and business courses and leads research initiatives. He previously worked as an Assistant Professor at Xi’an University of Architecture and Technology, China, contributing to graduate and Master’s-level education in economics and business. Dr. Anser’s teaching career began in Pakistan, where he held roles as a permanent lecturer at the Higher Education Department, Government of Punjab, and as a visiting lecturer at Bahauddin Zakariya University and Allama Iqbal College of Commerce. His diverse academic experience spans over a decade and reflects his commitment to high-quality teaching and research. In addition, Dr. Anser has worked as a tutor in economics and business studies at the AP and A/O levels, showcasing his adaptability across different educational settings.

Research Focus

Dr. Muhammad Khalid Anser’s research primarily focuses on environmental economics, sustainable development, and the relationship between economic growth, human capital, and environmental degradation. He has published extensively on topics such as the impact of economic policy uncertainty, energy consumption, and financial development on environmental sustainability. His work often integrates advanced econometric techniques, including ARDL modeling, GMM estimation, and machine learning, to analyze complex economic relationships and their policy implications. Dr. Anser’s recent research has focused on the dynamic interactions between financial development, urbanization, and carbon emissions, particularly in emerging economies. His studies have implications for environmental policy, sustainable business practices, and the role of innovation in driving corporate social responsibility. As a leading expert in the field, Dr. Anser aims to contribute valuable insights for policymakers seeking to balance economic development with environmental preservation.

Publication Top Notes

  1. Caring for the environment: How human capital, natural resources, and economic growth interact with environmental degradation in Pakistan? A dynamic ARDL approach 🌱📊
  2. Dynamic interaction between financial development and natural resources: Evaluating the ‘Resource curse’ hypothesis 💰🌍
  3. A review on Malaysia’s solar energy pathway towards carbon-neutral Malaysia beyond Covid’19 pandemic ☀️🇲🇾
  4. A comprehensive review of recent advances in smart grids: A sustainable future with renewable energy resources ⚡🔋
  5. Moderating effect of innovation on corporate social responsibility and firm performance in realm of sustainable development 📈🌍
  6. Impact of economic policy uncertainty on CO2 emissions: Evidence from top ten carbon emitter countries 🌍📉
  7. Impact of urbanization, economic growth, and population size on residential carbon emissions in the SAARC countries 🏙️🌱
  8. Usage of social media, student engagement, and creativity: The role of knowledge sharing behavior and cyberbullying 📱👩‍🎓
  9. Outbreak investigation of ceftriaxone-resistant Salmonella enterica serotype Typhi and its risk factors among the general population in Hyderabad, Pakistan 🦠💉
  10. Machine learning in state of health and remaining useful life estimation: Theoretical and technological development in battery degradation modelling 🔋🤖

Conclusion

Dr. Muhammad Khalid Anser’s track record of impactful research, teaching excellence, and scholarly contributions make him a strong candidate for the Best Researcher Award. His continued focus on sustainable development and environmental economics positions him as a leader in his field, with the potential for even greater influence in the future.

Adam Khan | Botany | Young Scientist Award

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Assist. Prof. Dr Adam Khan | Botany | Young Scientist Award

Assistant Professor , University of Lakki Marwat , Pakistan

Dr. Adam Khan is an accomplished scientist specializing in dendroclimatology, with a strong focus on climate reconstruction through tree-ring data. His research integrates ecology, climate science, and environmental dynamics to explore long-term climate variability and its effects on ecosystems. He has made significant contributions to the understanding of past climate patterns, including precipitation, temperature, and river flow, particularly in regions of South Asia and Central Asia. Dr. Khan is an Assistant Professor in the Department of Botany at the University of Lakki Marwat, Pakistan, and an editorial board member of several esteemed scientific journals. He is dedicated to advancing both academic knowledge and practical applications of climate science and ecology, especially in the context of climate change and forest resilience. His multidisciplinary research has garnered global recognition, and he actively mentors students and collaborates with international researchers.

Profile

Scopus

Strengths for the Award

  1. Research Excellence and Innovation: Dr. Khan’s research focus on dendroclimatology and ecological studies is not only highly relevant to contemporary environmental challenges but also positions him at the cutting edge of climate science. His work in reconstructing past climates through tree-ring data, specifically related to precipitation, temperature, and river flow patterns, is pivotal in understanding long-term climate variability. This aligns with the core objectives of the Young Scientist Award, which seeks to recognize innovative scientific contributions.
  2. Publications and Citation Impact: Dr. Khan has a commendable number of high-impact publications in respected journals, such as Climatic Change, International Journal of Biometeorology, and Environmental Research Letters. His research on topics like past climate reconstruction and streamflow variation has been cited frequently, indicating the significant influence his work has on the scientific community. Notably, his article on “A warm-season drought reconstruction in central-northern Pakistan inferred from tree rings since 1670 CE” (2024) is an example of groundbreaking research contributing to our understanding of historical climate extremes.
  3. Research Contributions in Ecological Context: Beyond dendroclimatology, Dr. Khan has contributed extensively to vegetation ecology and studies of forest resilience. His work on the regeneration potential of conifers in disturbed regimes of the Western Himalayas and his studies on vegetation diversity in relation to topographic and edaphic variables are highly relevant for ecological conservation and climate change adaptation strategies. This is an important aspect for the Young Scientist Award, as it recognizes a balanced approach to both environmental and climatic science.
  4. Research Grant and Recognition: Dr. Khan’s NRPU Project award from the Higher Education Commission (HEC) in 2022 highlights his capacity to lead independent research. This competitive grant is a testament to his standing in the academic community and his ability to attract funding for high-impact research projects.
  5. Leadership and Academic Contributions: As an assistant professor at the University of Lakki Marwat, Dr. Khan plays a critical role in educating and mentoring the next generation of scientists. His involvement in editorial roles for various prestigious journals demonstrates his leadership and commitment to advancing research in climatology, ecology, and environmental science.

Areas for Improvement

  1. Public Engagement and Outreach: While Dr. Khan’s research output is impressive, expanding efforts in public engagement and science communication would enhance the societal impact of his work. Engaging with broader audiences, such as through popular science articles, public talks, or media outreach, could amplify the relevance of his findings, particularly on the implications of climate change and ecological shifts.
  2. Interdisciplinary Collaborations: Dr. Khan’s work is already highly interdisciplinary, but there could be further exploration of collaborations with social scientists or policy makers. Understanding the socio-economic impacts of climate variability and developing actionable solutions in response to climate extremes could expand the scope and impact of his research.
  3. Broader Geographic Scope: While Dr. Khan’s work is focused on specific regions like Pakistan and Central Asia, expanding his research to include other climate-sensitive regions could increase the global relevance of his studies. His expertise in dendroclimatology could provide valuable insights into climate patterns in other parts of the world, especially in areas that are vulnerable to climate change impacts.

Education 

Dr. Adam Khan completed his Ph.D. in Dendrochronology and Plant Ecology at the Federal Urdu University of Arts, Science and Technology Karachi in 2018. His dissertation, titled “Ecological and Dendrochronological Studies of Pine Forests at Indus Kohistan of KPK, Pakistan,” highlighted his early commitment to understanding climate and ecological changes through tree-ring data. Before this, he earned his Bachelor of Science (BS) in Botany from the same university in 2012, where he developed his interest in plant ecology and environmental sciences. His early research project on “Combined Effect of Allelopathy and UV-Radiation on Lens Culinaris and Cucumis Sativus” paved the way for his doctoral research, blending plant physiology with environmental factors. His academic journey reflects a deep dedication to climate science and ecology, underpinned by rigorous research training that has shaped his scientific career.

Experience 

Dr. Adam Khan is currently an Assistant Professor in the Department of Botany at the University of Lakki Marwat since March 2021. He previously served as Assistant Professor at the University of Buner from August 2019 to March 2021, where he contributed to both teaching and research in botany, ecology, and climate science. Before his role as Assistant Professor, Dr. Khan worked as a Lecturer at the same department from August 2018 to August 2019. His teaching focuses on environmental science, plant ecology, and climate change, where he integrates his research findings into the curriculum. Dr. Khan has mentored several graduate students and led various research projects related to dendroclimatology and ecosystem resilience. His academic leadership extends beyond teaching, as he also plays an active role in editorial responsibilities for top-tier scientific journals in climatology and ecology, further contributing to advancing his field.

Awards and Honors 

In April 2022, Dr. Adam Khan was awarded the NRPU Project Grant by the Higher Education Commission (HEC) of Pakistan. This prestigious award enabled him to continue his groundbreaking research in dendroclimatology and climate change, marking a significant milestone in his career. The recognition underscores the importance of his work in climate reconstruction and forest ecology, particularly his research on understanding past climate patterns in South and Central Asia. Dr. Khan’s work has also been recognized internationally, with multiple publications in high-impact journals, contributing to a deeper understanding of long-term climate variability and its ecological impacts. His research contributions, mentorship, and academic leadership have earned him a respected position in the scientific community, with further recognition through editorial roles in leading journals. The HEC award, in particular, exemplifies his excellence in advancing scientific research and education in Pakistan and globally.

Research Focus 

Dr. Adam Khan’s research spans several key areas within dendroclimatology, focusing on reconstructing past climates, including precipitation, temperature, and river flow patterns through tree-ring analysis. His studies have explored how historical climate variability has influenced regional hydrology and ecosystems, particularly in South Asia and Central Asia. Additionally, Dr. Khan is dedicated to understanding the effects of climate change on ecosystems, with an emphasis on vegetation ecology, forest resilience, and ecological dynamics. His work integrates ecological theory with climate science to explore how forests and ecosystems respond to changing climatic conditions. He has also conducted research on forest regeneration potential under disturbed regimes, as well as the relationship between topographic and edaphic variables in shaping plant communities. This interdisciplinary approach provides valuable insights into the past, present, and future of ecological systems and their role in mitigating climate change.

Publication 

  1. A warm-season drought reconstruction in central-northern Pakistan inferred from tree rings since 1670 CE 🌲🌞📚
  2. Vegetation diversity pattern during spring season in relation to topographic and edaphic variables in sub-tropical zone 🌱🌄📊
  3. The Western Himalayan fir tree ring record of soil moisture in Pakistan since 1855 🌲💧📅
  4. Streamflow reconstruction in the Kafirnigan River, Tajikistan since 1568 CE reveals a linkage between southern Central Asian hydrological variation and ENSO 🌊🌍🌧️
  5. Regeneration potential of conifers along an elevation gradient under highly disturbed regimes in the western Himalayan region 🌲⛰️🔄
  6. Range of factors in the reduction of hyperhydricity associated with in vitro shoots of Salvia santolinifolia Bioss 🌱🔬💧
  7. Floristic Association of Moist Temperate Forests of Shangla District, Delineated by a Multivariate Approach 🌳🔍📊
  8. Reconstructed precipitation in the Lohit River basin, southern Tibetan Plateau since 1720 CE and its weak linkages with monsoon-season Brahmaputra discharge 🌧️🏞️📆
  9. Radial growth, present status and future prospects of west Himalayan fir (Abies pindrow Royle) growing in the moist temperate forest of Himalayan mountains of Pakistan 🌲⏳🌍
  10. Late twentieth century rapid increase in high Asian seasonal snow and glacier-derived streamflow tracked by tree rings of the upper Indus River basin ❄️🌲🏞️

Conclusion

Dr. Adam Khan is an outstanding candidate for the Young Scientist Award. His work in dendroclimatology, climate reconstruction, and ecological resilience is pioneering and directly addresses pressing environmental challenges. His ability to integrate historical climate data with ecological studies makes his contributions not only scientifically significant but also socially relevant. With a proven record of high-impact publications, research funding, and academic leadership, Dr. Khan stands out as a young scientist making a lasting impact on the fields of climatology and ecology.To further enhance his profile for this award, Dr. Khan could focus on increasing public outreach and broadening interdisciplinary collaborations. Nonetheless, his research contributions, academic stature, and leadership in the scientific community make him a highly deserving candidate for this prestigious recognition.

 

 

Saman Shoorabi Sani | highly efficient energy harvesting interface circuits | Best Researcher Award

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MrSaman Shoorabi Sani | highly efficient energy harvesting interface circuits | Best Researcher Award

Circuit Designer , Ferdowsi University of Mashhad , Iran

Saman Shoorabi Sani is a Senior Electronic Technician and Circuit Designer with over 19 years of experience in the electronics and engineering fields. He co-founded ARARAT, a company dedicated to designing and developing electronic products for diverse industries. His expertise spans PCB design, hardware development, and integrated circuit design. Alongside his professional career, Sani is pursuing a PhD in Integrated Circuit Design at Ferdowsi University of Mashhad. His innovative research focuses on structural health monitoring, vibration-based energy harvesting, and energy-efficient circuit designs. Sani has contributed to several groundbreaking projects that apply wireless sensor networks (WSNs) for monitoring infrastructure and has published papers in well-regarded journals. His work bridges the gap between academia and industry, focusing on sustainable technologies and advanced electronic systems for real-world applications.

Profile

Google Scholar

Strengths for the Award

  1. Extensive Experience and Diverse Contributions:
    Saman Shoorabi Sani has over 19 years of experience in electronics and circuit design, with a strong focus on both practical applications and academic research. His experience spans a variety of high-impact fields, including structural health monitoring (SHM), energy harvesting, and integrated circuit design.
  2. Innovative Research in Structural Health Monitoring (SHM):
    His research in SHM, particularly with wireless sensor networks (WSNs), has been highly influential, with multiple published papers in reputable journals. Notable contributions include the study on earthquake-induced damage detection and the application of fuzzy inference and data mining for health monitoring. These papers have practical implications in civil engineering and disaster mitigation, which showcases his ability to merge electronics with real-world applications.
  3. Cutting-Edge Energy Harvesting Work:
    Sani’s research on vibration-based energy harvesting is particularly noteworthy, especially his focus on energy-efficient interface systems for piezoelectric energy harvesters. This aligns with the growing demand for sustainable, low-energy solutions in electronics. His work in this field represents a significant contribution to the development of energy-harvesting systems, which can be utilized in various industrial and commercial applications.
  4. High Citation Impact and Peer Recognition:
    With 7 publications in journals indexed in SCI/Scopus and a citation index of 17, Sani’s work is clearly being recognized by peers in his field. His publications span a wide range of technical areas, indicating his versatility and strong presence in the academic and research community.
  5. Active Engagement with Industry:
    As a co-founder of ARARAT, an electronics design and development company, Sani bridges the gap between academic research and industry needs. His involvement in consultancy projects shows his ability to translate research into viable, real-world solutions.
  6. Academic Standing and Contributions to Knowledge:
    As a PhD student in Integrated Circuit Design at Ferdowsi University of Mashhad, Sani continues to expand his knowledge and contribute to cutting-edge developments in his area of expertise. This positions him as a rising thought leader in his field.

Areas for Improvement

  1. Expansion of Collaborative Efforts:
    Although Sani has collaborated with others on key research projects, he could further expand his network of collaborations, particularly with international institutions or cross-disciplinary projects that integrate more diverse perspectives. This could lead to even greater innovation and broader impact in his research.
  2. Patent Activity:
    While Sani’s research shows a high degree of innovation, he has not yet published any patents. Focusing on commercializing his ideas through patents could enhance the real-world impact of his work and add value to his future research output.
  3. Book Publications:
    Although Sani has contributed significantly to journal publications, he has not yet published any books. Writing a book or a comprehensive monograph in his field could help consolidate his position as a leading researcher and provide a long-lasting contribution to the academic community.

 

Education

Saman Shoorabi Sani is currently pursuing a PhD in Integrated Circuit Design at Ferdowsi University of Mashhad, where he is advancing his knowledge in the development of energy-efficient and sustainable electronic systems. He has earned extensive academic qualifications over the years, building on his foundational expertise as an Electrical Technician. His doctoral research centers on the design of energy harvesting circuits, particularly from piezoelectric sources, and the development of highly efficient interface circuits for power systems. In addition to his ongoing academic work, Sani holds a long history of professional training in electronics and circuit design, which he gained from his extensive industry experience. Throughout his career, he has been involved in several applied research projects, gaining a deep understanding of both theoretical principles and practical implementations in the field of electronic systems and integrated circuit design.

Experience 

Saman Shoorabi Sani brings over 19 years of experience in the electronics and technology sectors. He began his career as an Electrical Technician at Tesla Industries, where he was responsible for the installation and maintenance of elevator and building management systems (BMS). In 2020, he co-founded ARARAT, a company that specializes in the design and development of electronic products, particularly in the areas of PCB design and hardware development. As a Senior Electronic Technician, Sani leads the technical team in delivering high-quality electronic solutions to a variety of industries. His expertise lies in integrated circuit design, structural health monitoring, and energy harvesting systems. In addition to his role at ARARAT, he is a PhD student at Ferdowsi University of Mashhad, where he continues to push the boundaries of research in energy-efficient circuits. His work emphasizes practical, real-world applications, making a significant impact in both academia and industry.

Research Focus

Saman Shoorabi Sani’s research is focused on the development of energy-efficient electronic systems, particularly in the fields of structural health monitoring (SHM) and vibration-based energy harvesting. His work aims to design and optimize integrated circuits for applications such as infrastructure monitoring and sustainable power solutions. Sani’s research in SHM involves using wireless sensor networks (WSNs) to monitor the condition of structures like bridges and buildings, with the goal of detecting damage early to prevent catastrophic failures. His research on energy harvesting focuses on improving the efficiency of piezoelectric devices, which convert mechanical vibrations into electrical energy. Sani is particularly interested in designing interface circuits that enhance the energy conversion process, making it suitable for real-world applications. His ongoing projects in these areas seek to integrate advanced circuit design with practical solutions for sustainability, pushing the boundaries of what is possible in both structural health and energy harvesting technologies.

Publications

  1. “Using a phase difference detection technique for monitoring the structural health of bridge piers” 🏗️📊
  2. “A case study for application of fuzzy inference and data mining in structural health monitoring” 🧠🔍
  3. “Remote Detection of Earthquake Induced Damage on Bridge Piers Using WSN Based on Dual Receiver and Phase Difference Measurement Technique” 🌍🌉
  4. “Study on Health Monitoring of Concrete Structures Using Wireless Sensor Networks” 🏢📡
  5. “A single-inductor self-powered SECE interface circuit for dynamic load multi-PZTs energy harvesting” 🔋⚡
  6. “Landslide Monitoring Using Wireless Sensor Networks” 🌄📡
  7. “A Novel Structure for High Voltage High Power Multilayer RF PIN Diode with an Improved Bandwidth and Sharp Variable Junction Capacitance” 📡🔌

Conclusion

Saman Shoorabi Sani is a highly qualified candidate for the Best Researcher Award. His innovative work in structural health monitoring and energy harvesting demonstrates a clear dedication to advancing both theoretical and practical knowledge in electronics and integrated circuit design. His contributions to improving energy efficiency in energy harvesting systems are particularly commendable. With a solid foundation in both academia and industry, Sani’s work continues to have a significant impact on the field. His combination of research excellence, practical application, and ongoing academic development makes him a standout nominee for this award.

Tajbakhsh Navid Chakherlou | Fatigue and fracture | Best Researcher Award

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Prof Dr Tajbakhsh Navid Chakherlou | Fatigue and fracture | Best Researcher Award

professor , The Faculty of Mechanical Engineering, University of Tabriz , Iran

Dr. Tajbakhsh Navid Chakherlou is a renowned professor in the Department of Mechanical Engineering at the University of Tabriz, Iran. Born on September 18, 1968, in Iran, he has over 25 years of academic and research experience in solid mechanics, particularly in the areas of fatigue and fracture mechanics, residual stress analysis, and bolted joint design. Dr. Chakherlou received his Ph.D. from the University of Bath, UK, in 2002, where he focused on improving the fatigue life of aerospace components. With a robust teaching portfolio, he has guided numerous MSc and Ph.D. students. He is widely recognized for his pioneering work in the mechanical engineering field, particularly on cold expansion and interference fitting methods to enhance the durability of fastener holes in critical applications.

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Strengths for the Best Researcher Award

  1. Extensive Expertise and Specialized Knowledge: Dr. Chakherlou’s expertise in mechanical engineering, particularly in the fields of fatigue and fracture mechanics, residual stress analysis, and the design of bolted joints, has been demonstrated through his high-impact research. His Ph.D. dissertation on cold expansion methods for improving the fatigue life of fastener holes in aerospace aluminium alloy 7075-T6 reflects a deep understanding of critical engineering challenges in materials science and solid mechanics.
  2. Prolific Research Contributions: Dr. Chakherlou has authored several highly cited papers that address fundamental issues in the field of mechanical engineering, particularly those involving fatigue life improvement for bolted and fastener joints. His work, such as “The effect of cold expansion on improving the fatigue life of fastener holes,” published in Engineering Failure Analysis, has become foundational in the field, cited 258 times, demonstrating a lasting impact in both academic and industrial applications.
  3. Impact on Engineering Design and Industry Applications: His research on improving fatigue life in aerospace components through methods such as cold expansion, interference fit, and bolt clamping force optimization has direct industrial applications, particularly in aerospace, automotive, and manufacturing sectors. This work is crucial for enhancing the safety and durability of structural components under cyclic loading.
  4. Teaching Excellence and Mentorship: Dr. Chakherlou has been an active educator for over two decades, teaching a wide range of courses in solid mechanics, fatigue and fracture, plasticity theory, and numerical methods at the University of Tabriz. He has also supervised numerous MSc and Ph.D. theses, many of which have contributed significantly to advancing knowledge in the field. His leadership in the academic community, mentoring a generation of students and researchers, is a clear strength in his career.
  5. Collaboration and International Recognition: His collaborative work with institutions and researchers internationally, as well as the high citation count of his publications, indicates his recognition in the global academic community. His contributions to top journals such as Fatigue & Fracture of Engineering Materials & Structures, Engineering Failure Analysis, and Aerospace Science and Technology have helped solidify his standing as a leader in his field.
  6. Administrative and Leadership Roles: Dr. Chakherlou’s experience in administrative roles, including directing workshops and organizing engineering departments, highlights his ability to contribute to the overall development of his institution. His leadership is an essential component of his career, balancing research, teaching, and institutional growth.

Areas for Improvement

  1. Broader Range of Collaborative Projects: While Dr. Chakherlou has made substantial contributions in the area of mechanical engineering, particularly in fatigue and fracture mechanics, future research could benefit from exploring more interdisciplinary collaborations. For example, integrating his work with cutting-edge technologies such as additive manufacturing, smart materials, or computational optimization could open new avenues for improving material performance and sustainability in engineering design.
  2. Engagement with Emerging Research Areas: Given the rapidly evolving landscape of mechanical engineering, including areas like AI-driven design, nanotechnology, and machine learning applications in material science, Dr. Chakherlou could expand his research interests to engage with these emerging fields. Exploring how these technologies can improve the fatigue life of materials or optimize mechanical systems could enhance his work’s relevance in the next generation of engineering challenges.
  3. Public Dissemination of Research: While Dr. Chakherlou has an impressive body of work and significant impact in peer-reviewed journals, he could work on increasing the visibility of his research to a broader audience outside of academia, including industry leaders and policymakers. Engaging in more outreach activities, public talks, or publishing in more industry-focused journals could further elevate his influence.
  4. Increased Focus on Sustainability and Environmental Considerations: Considering the global emphasis on sustainability, incorporating research on environmentally friendly manufacturing processes or the development of materials with better energy efficiency and recyclability could significantly enhance the societal impact of his work.

Education

Dr. Chakherlou completed his Ph.D. in Mechanical Engineering at the University of Bath, UK, in 2002, specializing in the fatigue life improvement of fastener holes using cold expansion techniques. His MSc was awarded by the Iran University of Science and Technology in 1995, where his thesis focused on the fatigue behavior of notched members. He earned his BSc in Mechanical Engineering from Amir Kabir University of Technology in 1992. His extensive academic training equipped him with a deep understanding of solid mechanics, which he applies in both his research and teaching. The combination of his education and international research experience has positioned him as an influential figure in the engineering community, particularly in the design and optimization of mechanical systems under cyclic loads.

Experience

Dr. Chakherlou has been a Professor of Solid Mechanics at the University of Tabriz since 2012. He has previously served as an Associate Professor (2008–2012) and Assistant Professor (2002–2008). Before that, he was a Lecturer at Sahand University of Technology (1996–1999). He has taught a wide range of courses, including Finite Element Methods, Fatigue and Fracture, Theory of Plasticity, Thermoelasticity, and Metal Forming at both undergraduate and graduate levels. As a Workshop Director at Sahand University of Technology (1996–1999), Dr. Chakherlou managed and developed the materials engineering department’s practical training programs. He also served in administrative roles, including organizing engineering departments in Mianeh (2006–2010), enhancing his leadership and management skills. His comprehensive experience spans teaching, research, and administrative responsibilities.

Awards and Honors

Dr. Chakherlou has received multiple Research Excellence Awards throughout his career, recognizing his contributions to solid mechanics and fatigue life improvement. His highly-cited papers have earned international recognition, and his work on cold expansion methods is considered pioneering in the aerospace and automotive industries. His collaboration with top international researchers has earned him accolades in academic circles, and his leadership in supervising MSc and Ph.D. theses has shaped the next generation of engineers. His publications, many of which have appeared in prestigious journals like Engineering Failure Analysis and Fatigue & Fracture of Engineering Materials & Structures, have contributed significantly to the scientific community. Although specific awards are not listed, his citation count and contributions to critical fields underline his academic achievements.

Research Focus

Dr. Chakherlou’s research focuses on fatigue and fracture mechanics, specifically the improvement of the fatigue life of fastener holes and bolted joints in aerospace and manufacturing components. He is particularly known for his work on cold expansion and interference fit methods to enhance the residual stresses around fastener holes, thus improving the fatigue strength of materials like aerospace aluminum alloys. His research involves both numerical simulations and experimental investigations to explore the influence of various factors such as clamping force, bolt preload, and temperature on the fatigue performance of joints. He also investigates the fracture behavior and stress distribution in bolted and hybrid joints. Dr. Chakherlou’s interdisciplinary approach bridges mechanical engineering with practical industry applications, particularly in the aerospace, automotive, and manufacturing sectors.

Publications

  1. The effect of cold expansion on improving the fatigue life of fastener holes 🔧💥
  2. Experimental and numerical investigation of the effect of clamping force on the fatigue behaviour of bolted plates 🔩📊
  3. An investigation about interference fit effect on improving fatigue life of a holed single plate in joints ⚙️📐
  4. The effect of bolt clamping force on the fracture strength and the stress intensity factor of a plate containing a fastener hole with edge cracks 🔩💥
  5. Experimental and numerical investigations into the effect of an interference fit on the fatigue life of double shear lap joints 🔧🛠️
  6. A novel method of cold expansion which creates near‐uniform compressive tangential residual stress around a fastener hole 🌀🔩
  7. An experimental investigation of the bolt clamping force and friction effect on the fatigue behavior of aluminum alloy 2024-T3 double shear lap joint 🛠️🪛
  8. Effects of aluminum surface treatments on the interfacial fracture toughness of carbon-fiber aluminum laminates 🌐🔬
  9. Investigation of bolt clamping force on the fatigue life of double lap simple bolted and hybrid (bolted/bonded) joints via experimental and numerical analysis ⚙️💡
  10. Experimental and numerical comparison of cold expansion and interference fit methods in improving fatigue life of holed plate in double shear lap joints 🔩🔧
  11. On the fatigue behavior of cold expanded fastener holes subjected to bolt tightening 🔧🛠️
  12. Experimental and numerical study of fatigue crack growth of aluminum alloy 2024-T3 single lap simple bolted and hybrid (adhesive/bolted) joints 📉⚙️
  13. Prediction of fatigue life in aircraft double lap bolted joints using several multiaxial fatigue criteria 🚀🔩
  14. Investigation of the fatigue life and crack growth in torque tightened bolted joints 🔩⚡
  15. Numerical simulation of residual stress relaxation around a cold‐expanded fastener hole under longitudinal cyclic loading using different kinematic hardening models 💻🔬

Conclusion

Dr. Tajbakhsh Navid Chakherlou’s career is a testament to his dedication and excellence in the field of mechanical engineering, particularly in the areas of fatigue and fracture mechanics, fastener design, and material improvement methods. His prolific research, impactful publications, and longstanding teaching career position him as an ideal candidate for the Best Researcher Award. His work has not only advanced the field but has also had significant practical applications in aerospace and manufacturing industries.While there are areas where he could expand his research focus, such as interdisciplinary collaboration, emerging technologies, and sustainability, these are complementary directions for future growth and do not detract from his outstanding achievements to date. Therefore, Dr. Chakherlou is highly deserving of the Best Researcher Award in recognition of his significant contributions to engineering science and education.

Shiva PrasadKollur | Materials Science | Best Researcher Award

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Assoc. Prof. Dr Shiva Prasad Kollur | Materials Science | Best Researcher Award

Associate Professor , Amrita Vishwa Vidyapeetham , India 

Dr. Shiva Prasad Kollur is an Associate Professor in the Department of Sciences at Amrita Vishwa Vidyapeetham, Mysuru Campus, India. With over a decade of experience in research and teaching, Dr. Kollur specializes in interdisciplinary fields of Chemistry, focusing on inorganic chemistry, nanomaterials, and bioinorganic chemistry. His research aims to explore the synthesis, characterization, and biological applications of metal complexes, green chemistry, and nanotechnology, with a particular emphasis on their therapeutic potentials. Dr. Kollur has published extensively in peer-reviewed journals and has been involved in various international collaborations. He has mentored over 45 Master’s students and currently supervises six Ph.D. candidates. His research contributions have earned him recognition in prestigious journals and numerous international awards.

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Strengths for the Award

  1. Interdisciplinary Research Expertise: Dr. Kollur has demonstrated significant expertise across multiple subfields of Chemistry, including Inorganic Chemistry, Nanotechnology, Green Chemistry, and Biological Applications. His work spans the synthesis and characterization of novel metal complexes, nanomaterials, and their biomedical applications, which is highly relevant to current global challenges in health and environmental sustainability.
  2. Impactful Research and High Citation Index: His research has garnered considerable attention, with several papers being highly cited. For instance, his work on flavonoids as antiviral agents in Saudi Journal of Biological Sciences (2021) and genistein as an anti-breast cancer agent have been cited over 80 times, highlighting the real-world impact of his findings. Furthermore, his diverse publications across prestigious journals like ACS Sensors, Journal of Organic Chemistry, and Spectrochimica Acta showcase the breadth and depth of his scientific contributions.
  3. Extensive Research Experience: Dr. Kollur’s academic career spans over a decade, with a significant portion of that time spent in interdisciplinary research, as well as a strong foundation in academia through his teaching roles at institutions like Amrita University and Manipal Academy of Higher Education. His postdoctoral fellowship (Dr. D. S. Kothari) and research fellowship underscore his commitment to advancing knowledge and contributing to academic excellence.
  4. Leadership in Research Supervision: As a supervisor, Dr. Kollur has been guiding six PhD candidates and over 45 Master’s students. This speaks to his ability to mentor and cultivate the next generation of scientists. His success in leading students in research, especially in advanced topics, enhances his reputation as a leader in the academic community.
  5. Global Research Collaborations: Dr. Kollur has collaborated with researchers from diverse geographical regions, including Europe, South America, North America, and Asia. His international exposure and ability to engage in cross-border research projects enhance the global relevance of his work. Notably, his visits to prominent institutions like the University of São Paulo, University of South Pacific, and National University of Singapore highlight his international standing.
  6. Peer Recognition and Scholarly Service: Dr. Kollur has an established role in the global academic community, as evidenced by his peer-review contributions for top journals in the field, such as Nature, RSC Advances, and ACS Sensors. This indicates that he is well-respected by his peers and trusted with maintaining the quality and integrity of the scientific literature.
  7. Event Organization and Contribution to Academia: His involvement in organizing three international and four national conferences, along with a national-level workshop, reflects his leadership skills and commitment to advancing scientific dialogue. These initiatives demonstrate his drive to foster collaboration and knowledge exchange within the scientific community.

Areas for Improvement

  1. Broader Public Outreach and Dissemination: While Dr. Kollur’s academic and research achievements are impressive, increasing the visibility of his work outside the academic community, especially to the general public, could enhance its broader impact. Initiatives such as public talks, interviews, and collaboration with industries could help translate his research into real-world applications and policy discussions.
  2. Research Focus on Emerging Areas: While his interdisciplinary work in nanotechnology and drug discovery is highly relevant, Dr. Kollur could consider diversifying his research into emerging and high-impact areas, such as AI-driven drug design, quantum chemistry for material science, or sustainable chemistry practices for climate change mitigation. This could position his research even more strategically for future funding and collaborations.
  3. Interdisciplinary Integration with Other Sciences: Although his research spans chemistry, biology, and material science, integrating computational tools or cross-disciplinary work with engineering or data science could open up new dimensions of research, particularly in areas like precision medicine, biomaterials, and environmental remediation.
  4. Collaboration with Industry: Strengthening collaborations with industries, particularly those in pharmaceuticals and materials science, could allow Dr. Kollur to translate his academic research into commercial applications. This could lead to impactful innovations that reach a wider audience and generate more public and private sector interest.

Education 

Dr. Shiva Prasad Kollur holds a Ph.D. in Chemistry from the University of Mysore (2011), where he conducted research in the areas of coordination chemistry and bioinorganic systems. He completed his M.Sc. in Chemistry from the same university in 2007, where his academic performance was distinguished. Dr. Kollur’s undergraduate studies were undertaken at JSS College, Mysuru, where he earned a B.Sc. in Chemistry in 2005. Throughout his educational journey, he demonstrated strong academic aptitude and a passion for scientific exploration. His postdoctoral work at the Indian Institute of Science, Bengaluru (2011–2013), under the prestigious Dr. D.S. Kothari Postdoctoral Fellowship, further honed his research skills, allowing him to delve into advanced inorganic and physical chemistry research. This solid academic foundation has enabled Dr. Kollur to pursue a distinguished career in teaching and research.

Experience 

Dr. Shiva Prasad Kollur’s academic career spans over a decade, with significant teaching and research roles at prestigious institutions. He is currently serving as an Associate Professor in the Department of Sciences at Amrita Vishwa Vidyapeetham, Mysuru Campus, where he has been since 2020. Prior to this, he worked as an Assistant Professor at the Manipal Centre for Natural Sciences, Manipal Academy of Higher Education (2015–2020), and at JSS College, Mysuru (2013–2015). Dr. Kollur also held a postdoctoral position at the Indian Institute of Science, Bengaluru, from 2011 to 2013. Over the years, he has guided more than 45 Master’s students and currently supervises six Ph.D. candidates in their research. Dr. Kollur has been actively involved in organizing international and national conferences, fostering scientific collaboration and knowledge exchange. His experience also extends to peer review and research collaborations with institutions across the globe.

Awards and Honors 

Dr. Shiva Prasad Kollur has been recognized for his excellence in research and academic contributions. He received the prestigious Dr. D.S. Kothari Post-Doctoral Fellowship (2011–2013), one of India’s top fellowships for promising researchers. In addition, he was awarded the Research Fellowship in Sciences for Meritorious Students (2009–2011), highlighting his early promise in scientific research. His research in bioinorganic chemistry, nanotechnology, and green chemistry has earned him numerous citations in top-tier journals, further establishing his academic reputation. Dr. Kollur’s work in the field of cancer therapeutics, antiviral agents, and green synthesis has attracted recognition at both national and international levels. He has also contributed significantly to the academic community by reviewing articles for high-impact journals like Nature, ACS Sensors, and RSC Advances. His efforts in organizing and leading international and national conferences have solidified his role as a leader in the academic field.

Research Focus 

Dr. Shiva Prasad Kollur’s research focuses on the synthesis, characterization, and biological applications of metal complexes, nanomaterials, and bioinorganic systems. His work has significant implications in the fields of cancer therapy, antiviral drug design, and environmental sustainability. He is particularly interested in green chemistry, exploring the use of plant extracts for the synthesis of nanoparticles and studying their therapeutic potential. His interdisciplinary approach spans chemistry, biology, and materials science, with a special emphasis on nanotechnology, drug discovery, and biomedical applications. Dr. Kollur’s work on metal-based drugs, including palladium and copper complexes, has been pivotal in understanding their antimicrobial, anticancer, and DNA-binding properties. Additionally, he is involved in computational studies for evaluating the antiviral properties of natural compounds like flavonoids against pathogens such as SARS-CoV-2. Dr. Kollur’s research aims to bridge the gap between chemistry and medicine, with an emphasis on sustainable and effective solutions for global health challenges.

Publications

  1. In silico evaluation of flavonoids as effective antiviral agents on the spike glycoprotein of SARS-CoV-2 🦠🔬 (Saudi Journal of Biological Sciences, 2021)
  2. Genistein: a potent anti-breast cancer agent 💊🌸 (Current Issues in Molecular Biology, 2021)
  3. Preparation, spectral characterization and biological applications of Schiff base ligand and its transition metal complexes 🧪💚 (Results in Chemistry, 2019)
  4. Palladium (II) complexes as biologically potent metallo-drugs: Synthesis, spectral characterization, DNA interaction studies and antibacterial activity 💡🧬 (Spectrochimica Acta, 2013)
  5. Aqueous Extract of Saraca indica Leaves in the Synthesis of Copper Oxide Nanoparticles: Finding a Way towards Going Green 🌱🔋 (Journal of Nanotechnology, 2017)
  6. Detection of Quorum Sensing Molecules and Biofilm Formation in Ralstonia solanacearum 🦠🧫 (Current Microbiology, 2016)
  7. Synthesis, characterization, antioxidant, antimicrobial, DNA binding and cleavage studies of mononuclear Cu (II) and Co (II) complexes ⚗️🧬 (European Journal of Chemistry, 2011)
  8. Oxovanadium complexes with bidentate N, O ligands: synthesis, characterization, DNA binding, nuclease activity and antimicrobial studies 🧪🦠 (Chemical Sciences Journal, 2011)
  9. Green synthesis of MnO2 nanorods using Phyllanthus amarus plant extract and their fluorescence studies 🌱🔬 (Green Processing and Synthesis, 2017)
  10. Biogenic Synthesis of NiO Nanoparticles Using Areca catechu Leaf Extract and Their Antidiabetic and Cytotoxic Effects 🌿💊 (Molecules, 2021)

Conclusion

Dr. Shiva Prasad Kollur is an accomplished and highly productive academic professional with a robust research portfolio, extensive mentoring experience, and leadership in global scientific collaborations. His interdisciplinary research in chemistry, especially in areas related to green chemistry, nanotechnology, and biomedical applications, positions him as a leader in his field. With his continued contribution to science through publications, teaching, and global collaborations, Dr. Kollur is undoubtedly a deserving candidate for the Best Researcher Award.Given his strong academic record, research impact, mentorship, and service to the scientific community, Dr. Kollur represents the qualities of an exceptional researcher and educator. With the opportunity to expand his outreach and explore new interdisciplinary collaborations, his future contributions could have an even greater impact on both academia and society.

Xiaojie Liu | Industrial Big Data | Best Researcher Award

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Mr Xiaojie Liu | Industrial Big Data | Best Researcher Award

Professor, North China university of Science and Technology, China

Professor Xiaojie Liu is an associate professor at North China University of Science and Technology, specializing in the optimization of blast furnace operations and intelligent ironmaking technologies. With a focus on integrating big data, machine learning, and advanced process optimization, Liu has significantly contributed to the development of sustainable and efficient metallurgical processes. He obtained his PhD from Northeastern University in 2016, and has since been a key figure in advancing industrial applications of new technologies in ironmaking. As an active reviewer and editorial board member for renowned journals, such as Chinese Journal of Iron and Steel Research and Metallurgical Automation, Liu’s research not only drives academic excellence but also impacts real-world industrial practices. His innovations in hydrogen-rich smelting and data-driven optimization techniques are helping shape the future of the steel industry. He continues to mentor students and lead projects that push the boundaries of intelligent manufacturing.

Profile

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Strengths for the Award

  1. Innovative Research in Ironmaking and Big Data:
    Professor Xiaojie Liu’s research focuses on cutting-edge areas of ironmaking, particularly integrating advanced technologies like machine learning, big data mining, and intelligent systems into blast furnace operations. His work on intelligent ironmaking and hydrogen-rich smelting could have substantial industrial and environmental implications.
  2. Diverse and High-impact Publications:
    With a wide range of peer-reviewed articles in prominent journals like Metals, ISIJ International, and Journal of Cleaner Production, Professor Liu’s research is well-regarded internationally. His work on topics such as blast furnace optimization, molten iron quality prediction, and viscosity modeling in metallurgical processes is both timely and impactful.
  3. Patents and Technological Innovations:
    Liu’s research includes the development of new methodologies, such as the VMD-PSO-BP model for predicting blast furnace permeability and deep learning techniques for raw material granularity recognition, reflecting both scientific rigor and practical applicability.
  4. Leadership in Academic and Editorial Roles:
    As a peer reviewer and young editorial board member of multiple respected journals, Professor Liu plays an influential role in advancing academic discourse. His contributions to the Chinese Journal of Iron and Steel Research and Metallurgical Automation demonstrate his leadership and commitment to fostering innovation within his field.
  5. Collaboration with Industry:
    Liu’s active involvement in industry projects related to ironmaking technologies and process optimization reflects his ability to bridge the gap between academia and industrial application. His work has the potential to drive significant improvements in metallurgical processes.
  6. Mentorship and Teaching:
    As an associate professor and master’s tutor, Liu has contributed to the education and development of young engineers and researchers, enhancing the talent pipeline in his field.

Areas for Improvement

  1. Broader Interdisciplinary Collaborations:
    While Professor Liu has made impressive contributions within the field of metallurgical engineering, exploring broader interdisciplinary collaborations with fields such as materials science, artificial intelligence, and environmental engineering could further enrich his research and lead to more transformative innovations.
  2. Greater Public Engagement:
    While his academic achievements are notable, increasing public engagement through popular science outreach, media, or public lectures would help make his research more accessible to a wider audience and demonstrate the real-world impact of his work.
  3. Diversifying Research Topics:
    While his focus on blast furnace and ironmaking technologies is commendable, expanding his research into complementary areas such as renewable energy integration into smelting processes or circular economy practices in metallurgy could further enhance his contribution to sustainable industry practices.

Education 

Professor Xiaojie Liu completed his doctoral studies in Metallurgical Engineering at Northeastern University in 2016, where he focused on applying machine learning techniques to optimize blast furnace operations. His research during this time centered on the use of big data to improve efficiency and sustainability in ironmaking. Before pursuing his PhD, Liu completed both his undergraduate and master’s degrees in the same field, establishing a strong foundation in both the theoretical and practical aspects of metallurgy. His educational background has been instrumental in his career, allowing him to integrate advanced computational models with traditional ironmaking processes. As an academic, Liu has continued to evolve his expertise by staying at the forefront of industry innovations. He currently holds the position of associate professor at North China University of Science and Technology, where he also acts as a master’s tutor, guiding future generations of engineers in the metallurgical industry.

Experience 

Professor Xiaojie Liu is an accomplished researcher and educator at North China University of Science and Technology, where he serves as an associate professor and master’s tutor. With extensive experience in both academic and industrial applications, Liu’s work is primarily focused on optimizing the operations of blast furnaces using intelligent systems, big data analytics, and process optimization. Liu has collaborated with various industrial partners to apply his research findings in real-world settings, improving both the efficiency and sustainability of ironmaking operations. His work has led to the development of advanced predictive models for molten iron quality, permeability, and blast furnace raw material optimization. He is also a reviewer for top-tier journals, such as Journal of Cleaner Production, MMTB, and China Metallurgy, and has held editorial positions on journals like Chinese Journal of Iron and Steel Research and Metallurgical Automation. His contributions are shaping the future of the steel industry, blending cutting-edge research with practical solutions.

Research Focus

Professor Xiaojie Liu’s primary research interests lie in the areas of intelligent ironmaking and process optimization for blast furnaces. His work integrates big data mining, machine learning, and advanced computational models to improve the efficiency and environmental sustainability of iron and steel production. Liu’s research explores hydrogen-rich smelting processes to reduce carbon emissions and the application of deep learning for optimizing blast furnace operations, such as raw material granularity recognition and viscosity prediction. His ongoing projects focus on improving the precision and reliability of ironmaking systems by developing predictive models for molten iron quality and other critical parameters. Liu’s work also delves into the optimization of blast furnace operating parameters, utilizing intelligent systems for real-time process control and decision-making. Through these efforts, Liu is addressing key challenges in the metallurgical industry, such as energy consumption, material waste, and environmental impact, with the goal of creating a more sustainable and efficient future for steelmaking.

Publication Top Notes

  1. A novel anomaly detection and classification algorithm for application in tuyere images of blast furnace
    Engineering Applications of Artificial Intelligence, 2025, 139, 109558 🏭🤖
  2. Blast furnace raw material granularity recognition model based on deep learning and multimodal fusion of 3D point cloud
    Visual Computer, 2024, 40(10), pp. 6939–6954 🧠🔍
  3. Research on Molten Iron Quality Prediction Based on Machine Learning
    Metals, 2024, 14(8), 856 🔮💡
  4. Research on Blast Furnace Ingredient Optimization Based on Improved Grey Wolf Optimization Algorithm
    Metals, 2024, 14(7), 798 🐺📈
  5. Collaborative Optimization Model of Blast Furnace Raw Materials and Operating Parameters Based on Intelligent Calculation
    ISIJ International, 2024, 64(8), pp. 1229–1239 🔧⚙️
  6. Prediction Model for Viscosity of Titanium-Bearing Slag Based on the HIsmelt Process
    Transactions of the Indian Institute of Metals, 2024, 77(6), pp. 1597–1606 🏗️🌋
  7. Analysis of key measures of vanadium extraction from molten iron based on process theory and data mining
    Kang T’ieh/Iron and Steel, 2024, 59(3), pp. 58–78 💎🛠️
  8. Prediction for permeability index of blast furnace based on VMD–PSO–BP model
    Journal of Iron and Steel Research International, 2024, 31(3), pp. 573–583 🏗️🧪
  9. Research on cascade intelligent sinter quality prediction system based on big data technology
    Ironmaking and Steelmaking, 2024, 51(1), pp. 3–14 🔍📊
  10. Prediction model of Bum-through Point based on GA-BP
    Proceedings – 2024 39th Youth Academic Annual Conference of Chinese Association of Automation, YAC 2024, pp. 1286–1291 🤖📅

Conclusion

Professor Xiaojie Liu’s qualifications for the Best Researcher Award are compelling. His pioneering research in intelligent ironmaking and big data applications, combined with his strong academic leadership and collaboration with industry, positions him as a highly impactful figure in his field. With his track record of publications in top-tier journals, a deep commitment to advancing ironmaking technologies, and his contribution to the development of sustainable industrial practices, Liu demonstrates the traits of a transformative researcher. If awarded, his continued work could drive significant innovations in the iron and steel industry, especially in areas critical to sustainability and efficiency.

 

 

Kejie Zhai | Underground Pipelines | Best Researcher Award

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Dr Kejie Zhai | Underground Pipelines | Best Researcher Award

Professor, Zhengzhou University, China

Professor Kejie Zhai is a distinguished academic and researcher currently serving as a professor at Zhengzhou University, China. He earned his PhD from Sun Yat-sen University under the supervision of Professor Wang Fuming, an academician of the Chinese Academy of Engineering (CAE). He has also conducted a visiting study at Queen’s University in Canada, working closely with Professor Ian D. Moore. Professor Zhai’s primary research interest lies in underground pipelines, and he has published over 50 academic papers in this field. His work addresses both the theoretical and practical aspects of pipeline engineering, including the evaluation and reinforcement of pipeline structures. Professor Zhai’s contributions have advanced the understanding of pipe behavior under complex loading conditions and innovative reinforcement technologies.

Profile

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Strengths for the Award

  1. Research Expertise:
    • Kejie Zhai’s extensive research in the field of underground pipelines and related areas, such as prestressed concrete cylinder pipes and gravity flow pipe liners, makes him a leading expert in his field. His work is highly relevant to infrastructure and civil engineering applications, which has both academic and practical significance.
  2. Innovative Contributions:
    • Zhai has designed novel equations and technologies for assessing and reinforcing pipeline systems. His research in the development of failure pressure prediction models, as well as bending response equations for gravity-flow pipe liners, demonstrates innovation and problem-solving in pipeline engineering.
  3. Interdisciplinary Collaborations:
    • Zhai’s work with renowned scholars such as Professor Ian D. Moore from Queen’s University, and his collaboration with Hongyuan Fang, indicates a strong ability to foster international academic collaborations. Such partnerships enrich the quality and impact of his research, expanding its reach globally.
  4. Impact and Citation Index:
    • Zhai has an h-index of 14 and has published over 50 academic papers in prominent journals, which is an indication of both the breadth and depth of his research contributions. His work is regularly cited, underscoring its impact in his field.
  5. National Recognition:
    • Zhai is involved in multiple prestigious research projects, such as those funded by the National Natural Science Foundation of China, and postdoctoral programs, reinforcing his academic credibility and involvement in high-impact research.
  6. Diverse Research Applications:
    • Zhai’s research spans a wide range of engineering problems, from the mechanical behavior of pipes to advanced analysis methods, such as the use of deep learning for cement hydration and crack detection. This diversity strengthens his profile as a researcher capable of tackling complex engineering challenges.

Areas for Improvement

  1. Industry Collaboration and Consultancy:
    • Although Zhai has an impressive academic profile, there is no mention of significant involvement in industry collaborations or consultancy projects. Expanding his research impact into practical, real-world applications in the industry could strengthen his profile further, particularly if it leads to the development of technologies or solutions that are adopted outside academia.
  2. Public Engagement:
    • While Zhai’s academic output is notable, increasing engagement with broader, non-academic audiences (e.g., through media, public talks, or policy recommendations) could enhance his visibility and the practical impact of his research. This may also involve presenting findings to policy-makers in infrastructure planning and development.
  3. Broader Citation Impact:
    • Though his h-index of 14 is a positive indicator of academic impact, there may be room to further increase the visibility of his research. Strategies for greater citation impact, such as publishing in higher-impact journals or exploring new avenues for dissemination (e.g., interdisciplinary journals), could increase the recognition of his work.

Education

Professor Kejie Zhai holds a Ph.D. in Civil Engineering from Sun Yat-sen University (Guangzhou, China), where he was mentored by Professor Wang Fuming, a renowned academician of the Chinese Academy of Engineering (CAE). His research interests during his doctoral studies focused on underground pipelines and the development of novel technologies for pipeline design and evaluation. Additionally, he completed a visiting study program at Queen’s University, Canada, where he worked with Professor Ian D. Moore, an expert in pipeline systems engineering. This international exposure broadened his research horizons and deepened his understanding of complex engineering problems in the pipeline field. With a solid academic foundation and global research collaborations, Professor Zhai has made significant contributions to both theoretical and applied aspects of civil and structural engineering.

Experience

Professor Kejie Zhai has over a decade of experience in the field of civil and structural engineering, focusing on underground pipeline systems. Currently, he is a Professor at Zhengzhou University, where he conducts research and teaches undergraduate and graduate courses in Civil Engineering. Before this, Professor Zhai earned his PhD from Sun Yat-sen University, where he developed a strong foundation in pipeline mechanics, leading to significant research outputs. He also completed a visiting research stint at Queen’s University in Canada, collaborating with Professor Ian D. Moore on several cutting-edge research projects related to pipeline systems. His career is marked by several high-impact research projects, including those funded by the National Natural Science Foundation of China. Additionally, he has been a key contributor to international collaborations, significantly advancing the field of pipeline technology, particularly in the areas of pipeline failure prediction and reinforcement methods.

Research Focus

Professor Kejie Zhai’s research primarily focuses on underground pipelines and the complex engineering challenges associated with their design, reinforcement, and performance under various environmental and operational conditions. His work spans a range of topics, including the structural integrity of concrete pipes under fatigue and traffic loads, as well as innovative reinforcement technologies for prestressed concrete cylinder pipes. A significant portion of his research addresses the mechanics of pipeline behavior under shear, rotation, and axial movement, with an emphasis on gravity flow pipe liners crossing ring fractures or joints. Professor Zhai has developed new equations and models to predict pipeline failure and optimize the design of pipeline systems. He also explores the use of advanced computational techniques such as XGBoost-PSO algorithms for stress prediction and machine learning-based methods for improving the reliability and longevity of underground infrastructure. His work is of great relevance to both academic researchers and practitioners in pipeline engineering.

Publications Top Notes

  1. Limit state equation and failure pressure prediction model of pipeline with complex loading 🌍📚
  2. Study on ground-penetrating radar wave field characteristics for earth dam disease considering the medium randomness 🔍📡
  3. Long-term performance of concrete pipes under fatigue traffic loads 🚗🛠️
  4. Bending Response and Design Equations for Gravity-Flow Pipe Liners Passing across Ring Fractures or Joints 🔩📏
  5. Influence of Excavation Radius on Behavior of Circular Foundation Pits Supported by Prefabricated Recyclable Structures 🚧🏗️
  6. Prediction model of maximum stress for concrete pipes based on XGBoost-PSO algorithm 🤖💡
  7. Evolution of the microporous structure in cement hydration: A deep learning-based image translation method 🧠🧪
  8. MFAFNet: An innovative crack intelligent segmentation method based on multi-layer feature association fusion network 💻🔍
  9. Mechanical behavior and parameter sensitivity analysis of water supply steel pipes under complex service load combinations 💧🔧
  10. Corrigendum to “Numerical manifold simulation and medium-parameter analysis of the polymer grouting process in three-dimensional rock fractures” 🧮🔄

Conclusion

Professor Kejie Zhai is an outstanding candidate for the Best Researcher Award based on his innovative contributions to the field of underground pipeline engineering. His research is of high practical significance, particularly in infrastructure systems that are critical to urban lifelines. His collaborative work with global experts, the development of novel solutions for complex pipeline challenges, and his role in advanced academic research projects position him as a leader in his field. With further involvement in industry applications and greater efforts to expand his research impact, he can continue to build on his already impressive career. Overall, Professor Zhai’s strengths in research, innovation, and international collaboration make him highly deserving of this award.

 

 

Tatiana Mayskaya | Economics | Best Researcher Award

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Assist. Prof. Dr Tatiana Mayskaya | Economics | Best Researcher Award

Assistant Professor, National Research University Higher School of Economics, Russia

Tatiana Mayskaya is an Assistant Professor at the International College of Economics and Finance (ICEF) and the Faculty of Economic Sciences at the Higher School of Economics (HSE), Moscow. She holds a Ph.D. in Social Science from the California Institute of Technology (Caltech), where she also completed an M.Sc. Her research interests focus on information economics, decision-making under uncertainty, and the economics of market dynamics. Mayskaya is an active researcher, regularly presenting at international conferences and publishing in high-impact journals. Besides her research, she has earned recognition as an outstanding educator, receiving multiple Best Teacher awards at ICEF. She has held leadership roles in academic services, including organizing research seminars and coordinating faculty activities. Mayskaya is known for her interdisciplinary approach and impactful contributions to the fields of economics and social science.

Profile

Strengths for the Best Researcher Award

  1. Academic Credentials & Education:
    • Ph.D. in Social Science from California Institute of Technology (Caltech), a prestigious institution that reflects high intellectual capacity and a rigorous training background.
    • Prior education from top Russian institutions like New Economic School and Lomonosov Moscow State University adds to her solid academic foundation.
    • Dissertation and thesis topics such as “Essays on Information Collection” and “The Compromise Effect in Monopolistic and Competitive Markets” demonstrate a deep understanding of economics, particularly in information theory, market structures, and decision-making.
  2. Research Contributions:
    • Mayskaya has contributed extensively to the academic literature, with several high-impact publications and working papers in prominent journals and platforms, such as American Economic Journal: Microeconomics, Games and Economic Behavior, and Journal of Economic Theory.
    • Key research areas include information theory, decision-making under uncertainty, the economics of transparency, diversity in teams, and data linkage between markets.
    • Her work on the “dark side of transparency” and the “emergence of an informed insurer” has likely generated significant interest in the academic community.
    • Her research is forward-looking and interdisciplinary, with applications to real-world issues such as market dynamics, mergers, innovation, and behavioral economics.
  3. Impact & Recognition:
    • Mayskaya’s research has been widely cited, with papers on topics like “Dynamic choice of information sources” and “Diversity in teams” being actively discussed in the economics community.
    • Awards such as Best Teacher at ICEF (2019-2021) show her dual commitment to both research and teaching, further reinforcing her overall contribution to the academic world.
  4. Teaching Excellence:
    • Mayskaya’s repeated recognition as Best Teacher attests to her strong commitment to education, an important quality for a researcher who can effectively communicate complex ideas.
    • Her teaching experience spans various programs, including bachelor’s and master’s courses on subjects like Game Theory, Microeconomics, and Contract Theory, which are vital for building the next generation of economists.
  5. Professional Service & Leadership:
    • Active in institutional service as Coordinator for Brown Bag seminars and Academic Head of the Advance Training Program at ICEF-HSE, demonstrating leadership and a commitment to the academic community.
    • Co-organizer of research seminars and a member of international collaboration committees, contributing to the academic ecosystem both locally and globally.
  6. International Recognition & Collaboration:
    • Regularly invited to present her research at top-tier seminars and conferences at institutions like Oxford, MIT, Warwick, Cambridge, and University of London.
    • Collaborations with prominent scholars such as Federico Echenique, Jaksa Cvitanic, and Benjamin J. Gillen demonstrate her standing in the international academic community.

Areas for Improvement

  1. Broader Outreach & Public Engagement:
    • While Mayskaya’s research is highly regarded in academic circles, expanding her public outreach—through popular science articles, podcasts, or collaborations with policymakers—could help translate her findings into more direct societal impact.
    • Greater engagement with media outlets or public events could help make her work more accessible to a wider audience outside the academic community.
  2. Further Diversification of Research Topics:
    • Mayskaya’s research is predominantly focused on information theory, decision-making, and economics of markets. While these are highly important fields, exploring more applied areas (e.g., public policy, environmental economics, or global economic issues) could increase her contribution to contemporary challenges.
    • Engaging more with emerging topics such as Artificial Intelligence (AI), behavioral insights in policy design, or global economic trends could expand the scope of her research.
  3. Mentorship and Collaboration with Early-Career Scholars:
    • While Mayskaya is a highly accomplished scholar, further mentorship and collaboration with junior researchers could help in expanding the reach of her research and also in shaping the next wave of economists.

Education

Tatiana Mayskaya completed her Ph.D. in Social Science at California Institute of Technology (Caltech) in 2017. Her dissertation, titled “Essays on Information Collection”, focused on the economic analysis of information aggregation and decision-making in environments of uncertainty. She also holds a Master of Science in Social Science from Caltech (2014). Prior to her time at Caltech, Mayskaya earned a Master’s degree in Economics (summa cum laude) from the New Economic School (2012), where she researched the Compromise Effect in Monopolistic and Competitive Markets. Earlier, she completed a Specialist Degree in Applied Mathematics and Computer Science from Lomonosov Moscow State University (2010), where her thesis focused on multiobjective optimization. Her academic background combines economics, social science, and mathematical modeling, providing a robust foundation for her research and teaching in theoretical economics.

Experience

Tatiana Mayskaya has been an Assistant Professor at the Higher School of Economics since 2017, where she teaches at both the International College of Economics and Finance (ICEF) and the Faculty of Economic Sciences (FES). Her teaching includes courses in Game Theory, Contract Theory, and Microeconomics at both the undergraduate and graduate levels. In addition to her teaching role, she has contributed significantly to academic leadership, serving as the Coordinator for Brown Bag Seminars and the Academic Head of the Advance Training Program at ICEF. She has also been actively involved in organizing research seminars at HSE and collaborating on research initiatives with international institutions. Mayskaya has presented her work at numerous prestigious conferences and institutions worldwide, including Oxford University, MIT, and Toulouse School of Economics, further solidifying her international academic reputation.

Awards and Honors

Tatiana Mayskaya has received numerous prestigious awards for her excellence in both research and teaching. She was named Best Teacher at the International College of Economics and Finance (ICEF) for three consecutive years (2019-2021), an accolade that underscores her dedication to high-quality education. Mayskaya was also awarded the Ronald and Maxine Linde Institute of Economic and Management Sciences Graduate Fellowship at California Institute of Technology (Caltech) (2016-2017) for her academic achievements. At the New Economic School, she received the Deutsche Bank Scholarship (2011-2012) and the Alumni Fellowship Fund Scholarship (2010-2011). These awards recognize her outstanding performance as a student and her contributions to the academic community. Her excellence in research, teaching, and service reflects a commitment to advancing economics both within academia and in broader social contexts.

Research Focus

Tatiana Mayskaya’s research focuses on information economics, decision-making, and the role of information in markets. Her work explores the dynamic choice of information sources, market transparency, and how information asymmetries affect economic behavior and market outcomes. A key area of interest is the intersection between competition and innovation, including the effects of mergers on innovation and the emergence of informed players in markets. Mayskaya’s interdisciplinary approach combines theoretical economics with applied behavioral insights, investigating how biases, overconfidence, and persuasion influence decision-making. She also studies the role of diversity in teams and data ordering as a persuasive tool in both economic and social contexts. Her work has applications in contract theory, market design, and organizational economics, and she regularly collaborates with leading economists and researchers in these fields to advance understanding of how information and incentives shape economic outcomes.

Publication Top Notes

  • “Data Linkage between Markets: Does the Emergence of an Informed Insurer Cause Consumer Harm?” 📊💡
  • “The Effect of Mergers on Innovation” 🔄💼
  • “Diversity in Teams” 👥🔍
  • “Ordering Data to Persuade” 📑🧠
  • “The Dark Side of Transparency: When Hiding in Plain Sight Works” 🕵️‍♀️🔒
  • “Talking with an Extremist” 💬⚖️
  • “The Effect of Mergers on Innovations” 📉🚀
  • “Implications of Overconfidence on Information Investment” 💭💰
  • “Following Beliefs or Excluding the Worst? The Role of Unfindable State in Learning” 🔍📚
  • “Imposing Commitment to Rein in Overconfidence in Learning” 🧠📉
  • “Disagreement Under Almost Common Knowledge of Rationality” 🤔📉
  • “Cognitive Hierarchical Model in Networks” 🧠🌐
  • “Are People Subject to Persuasion Bias? Test of Degroot Model” 📊🔄
  • “Essays on Information Collection” 📘🔍
  • “Stochastic Choice in Criterion Space” 🎲📈

Conclusion

Tatiana Mayskaya is highly deserving of the Best Researcher Award. Her research contributions are innovative, impactful, and make significant strides in understanding complex economic phenomena. Her interdisciplinary approach to topics like information economics, market behavior, and diversity in teams showcases her intellectual depth and relevance in current economic discourse. Her consistent publication in top journals, recognition as an outstanding educator, and leadership in academic service further demonstrate her excellence. However, expanding her public outreach and diversifying her research areas could enhance her visibility and broaden the scope of her influence. In conclusion, Mayskaya stands out as a researcher who not only excels in academic rigor but also contributes meaningfully to the academic community and beyond.

Pezhman Molaei | Photocatalyst | Excellence in Innovation

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Dr Pezhman Molaei | Photocatalyst | Excellence in Innovation

Nano materials , Islamic Azad University , Iran

Dr. P. Molaei is an assistant professor at Islamic Azad University in Masjedsoleiman, Iran, specializing in nanomaterials for energy conversion and storage applications. With a background in condensed matter physics, his research focuses on the development of advanced nanostructured materials for solar cells, photocatalysts, and photoelectrochemical systems. Dr. Molaei has made notable contributions in fabricating efficient solar cell absorber layers, including the Sb₂S₃/reduced graphene oxide (rGO) composite and ZnO-based materials. His work on scalable synthesis of graphene quantum dots (GQDs) and composite photocatalysts has earned recognition in the scientific community. Dr. Molaei’s interdisciplinary expertise spans nanoscience, solid-state physics, and materials engineering, with a commitment to sustainable energy solutions. His research, supported by innovative synthesis methods and in-depth material characterization, has significant applications in clean energy, environmental remediation, and next-generation electronic devices.

Profile

Google Scholar

Strengths for the Award

  1. Pioneering Research Contributions:
    • Dr. Molaei has demonstrated significant innovation in the design, synthesis, and characterization of nanomaterials, particularly for energy conversion and storage. His work on the fabrication of solar cells based on antimony sulfide/reduced graphene oxide (Sb2S3/rGO) as the absorber layer is groundbreaking, contributing to advancements in photocurrent efficiency for solar cells.
    • The one-step synthesis of Sb2S3/rGO composites and the hot-injection method for their preparation, which is nontoxic and novel, highlights Dr. Molaei’s ability to create sustainable and scalable solutions for next-generation energy devices.
  2. Impactful Methodologies:
    • The chemical vapor deposition (CVD) route developed by Dr. Molaei for ZnO-rGO composite layers (with absorption in the near-infrared region) is highly innovative, offering new possibilities for multifunctional materials in solar cells and optoelectronics. His work bridges material synthesis with practical applications, providing materials that function both as light absorbers and electron transport layers in solar devices.
  3. Scalability and Yield:
    • Dr. Molaei has demonstrated remarkable success in achieving gram-scale synthesis of graphene quantum dots (GQDs). This scalable synthesis is critical for practical applications in photovoltaics and photocatalysis, where large quantities of material are needed for commercialization.
  4. Diverse Expertise in Material Synthesis:
    • His expertise in a wide range of nanomaterial synthesis techniques (such as chemical bath deposition, hot injection, chemical vapor deposition) showcases his versatility. This diversity enables the creation of nanostructured materials for a variety of applications including photocatalysis, energy storage, and photovoltaics.
  5. Research and Publishing Record:
    • Dr. Molaei’s research has already led to several highly cited papers in reputable journals like the Journal of Nanoparticle Research and Ceramics International. The impact of his work is evident from the citations, indicating significant interest and validation from the scientific community.
  6. Environmental and Sustainable Applications:
    • Dr. Molaei’s focus on environmentally friendly materials (e.g., nontoxic solvents in synthesis) and sustainable energy solutions like solar cells and photocatalysts aligns well with the current global push for green technologies. His work holds promise in addressing pressing challenges in clean energy and environmental remediation.

Areas for Improvement

  1. Broader Application of Findings:
    • While Dr. Molaei has developed several promising materials for solar cells and photocatalysis, future work could benefit from demonstrating the commercial viability of these materials in real-world conditions. Long-term stability and efficiency under operational stress tests (e.g., light, temperature, moisture) are crucial for scaling up.
  2. Collaborative Research and Interdisciplinary Approaches:
    • Dr. Molaei’s work is already interdisciplinary, involving materials science, physics, and engineering. However, further collaboration with experts in device engineering and industry partners could accelerate the translation of his innovations from the lab to large-scale applications. Partnerships with energy companies and environmental organizations could lead to more practical applications.
  3. Optimization for Large-Scale Manufacturing:
    • While Dr. Molaei has focused on scalability (e.g., in GQDs synthesis), future efforts could target the industrial scalability of his nanomaterial synthesis processes. Developing more efficient and cost-effective production methods could enhance the potential impact of his work in the commercial market.
  4. Broader Implications of Work:
    • It would be beneficial to expand research to include life-cycle analysis of the nanomaterials developed, to assess their environmental impact from synthesis through to disposal. This would provide a more comprehensive understanding of their sustainability and potential risks in industrial applications.

Education 

Dr. P. Molaei earned his Ph.D. in Condensed Matter Physics from Shahid Chamran University of Ahvaz, Iran (2013–2019). His doctoral research, titled “Fabrication and Characterization of a Solar Cell Based on Antimony Sulfide/Reduced Graphene Oxide as Absorber Layer”, focused on the development of innovative materials for solar energy conversion. Prior to his Ph.D., he completed a Master of Science in Elementary Particle Physics at the University of Yazd (2003–2006), where he developed a strong foundation in theoretical and experimental physics. He also obtained his Bachelor’s degree in Physics from Isfahan University of Technology (2003–2006). Dr. Molaei’s educational journey has provided him with a deep understanding of nanomaterials, energy systems, and solid-state physics, all of which he applies in his research to solve challenges in energy storage, conversion, and environmental applications.

Experience 

Dr. Molaei is currently serving as an Assistant Professor at Islamic Azad University, Masjedsoleiman (2019-present), where he leads cutting-edge research in nanomaterials and energy conversion technologies. He has successfully developed a CVD route for synthesizing ZnO-rGO composites with near-infrared absorption, targeted for solar cells and optoelectrical applications. He has also pioneered gram-scale synthesis of graphene quantum dots (GQDs) using a copper-based catalyst, demonstrating impressive yield and scalability. Previously, Dr. Molaei was a Ph.D. candidate at Shahid Chamran University of Ahvaz (2013-2019), where he proposed innovative approaches to Sb₂S₃/rGO composite solar cells and developed novel synthesis methods, including hot-injection and CVD for nanowires. His expertise spans material characterization (XRD, UV-vis, Raman spectroscopy, EIS), and he is proficient in various synthesis techniques such as chemical bath deposition (CBD) and chemical vapor deposition (CVD). His research has led to numerous high-impact publications.

Research Focus 

Dr. P. Molaei’s research focuses on the synthesis and characterization of nanomaterials with applications in energy storage and conversion technologies. His key areas of interest include the development of solar cells,t photocatalysts, and photoelectrochemical systems. He specializes in designing nanostructured materials such as metal oxides, metal chalcogenides, and 2D nanomaterials, optimizing their properties for photovoltaic and environmental remediation applications. A major part of his work includes designing composite materials, such as Sb₂S₃/rGO for solar cell absorbers and ZnO-rGO for near-infrared absorbing layers. Dr. Molaei also investigates graphene quantum dots (GQDs), exploring scalable synthesis routes with novel catalysts. His goal is to advance clean energy technologies, particularly solar power, by developing efficient, low-cost, and environmentally friendly materials. Additionally, he is interested in enhancing the performance of photocatalysts for environmental cleanup and water splitting applications.

Publications

  1. Impact of rGO on photocatalytic performance of Cd-doped ZnO nanostructures synthesized via a simple aqueous co-precipitation route
  2. One-step in situ synthesis of antimony sulfide/reduced graphene oxide composite as an absorber layer with enhanced photocurrent performances for solar cells
  3. Porous g-C₃N₄ nanosheets through facile thermal polymerization of melamine in the air for photocatalyst application
  4. Extended photocurrent performance of antimony trisulfide/reduced graphene oxide composite prepared via a facile hot-injection route
  5. Seed-free synthesis of ZnO nanorods through egg white/glycerol medium for photocatalyst applications
  6. Optimized synthesis of ZnO nanostructures by egg-white content ratio manipulation for photocatalytic applications
  7. One-Step Fabrication of S-Scheme ZnO/G-C₃N₄ Composites for Enhanced Environmental Photocatalysis

Conclusion

Dr. P. Molaei is a promising and innovative researcher whose work has already made substantial contributions to the fields of nanomaterials and energy technologies. His research has not only advanced the fundamental understanding of material properties but also introduced practical approaches to solar energy harvesting and environmental remediation. His innovative methodologies, successful scalability efforts, and deep interdisciplinary expertise position him as a strong candidate for the Excellence in Innovation Award. By addressing the few areas for improvement related to the commercialization and environmental impact of his materials, Dr. Molaei could further strengthen his position as a leader in his field and have a significant impact on both science and society.