Mohammed Abdulrahman | Hydrogen Production | Best Researcher Award

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Dr Mohammed Abdulrahman | Hydrogen Production | Best Researcher Award

Dr Mohammed Abdulrahman , RIT Dubai FZE , United Arab Emirates

Dr. Mohammed W. Abdulrahman is a dedicated researcher and assistant professor in the Department of Mechanical and Industrial Engineering at the Rochester Institute of Technology (RIT). With a strong foundation in mechanical and nuclear engineering, he holds a Ph.D. from the University of Ontario Institute of Technology (UOIT). Known for his innovative contributions, he is the sole inventor of two patents and has authored numerous high-quality journal articles. His expertise in thermal hydraulics, particularly in hydrogen production cycles, positions him as a leading figure in the field. With excellent interpersonal skills and a compassionate approach to teaching, Dr. Abdulrahman is committed to mentoring students and advancing research in sustainable energy solutions.

Publication Profile

Google Scholar

Strengths for the Award

  1. Educational Excellence: Mohammed has a strong academic background, with a Ph.D. and Master’s in Mechanical and Nuclear Engineering, demonstrating a solid foundation in relevant disciplines.
  2. Innovative Research Contributions: He is a sole inventor of two patents and has authored numerous high-quality journal articles, showcasing his ability to contribute original ideas to the field.
  3. Recognized Expertise: Awards such as the Best Paper Award and certificates for key scientific articles highlight the quality and impact of his research work.
  4. Teaching and Mentoring: His experience as an Assistant Professor and Teaching Assistant reflects strong communication and interpersonal skills, allowing him to effectively mentor students and foster collaboration.
  5. Diverse Research Portfolio: His publications cover a range of topics in thermal hydraulics, heat transfer, and reactor design, indicating a broad understanding of important engineering concepts and methodologies.
  6. Active Participation in Conferences: Frequent presentations at international conferences underscore his engagement with the global research community and commitment to disseminating knowledge.

Areas for Improvement

  1. Broader Collaboration: While his individual contributions are impressive, increased collaboration with researchers in different fields could enhance interdisciplinary insights and broaden his research impact.
  2. Increased Public Engagement: Greater outreach to non-academic audiences through workshops, public lectures, or social media could raise awareness of his work and its implications for society.
  3. Expanding Funding Opportunities: Actively pursuing more diverse funding sources could facilitate larger-scale projects and collaborations, further advancing his research capabilities.
  4. Publication Strategy: While he has many publications, focusing on targeted high-impact journals could enhance the visibility and recognition of his work.

Education 

Dr. Mohammed W. Abdulrahman earned his Ph.D. in Mechanical Engineering from the University of Ontario Institute of Technology (UOIT), focusing on the thermal hydraulics of multiphase reactors in the Cu-Cl cycle for oxygen production. He achieved a remarkable GPA of 4.3, reflecting his academic excellence. Prior to this, he obtained his M.Sc. in Nuclear Engineering with a specialization in thermo-fluids, where he investigated natural circulation phenomena during coolant accidents, achieving a GPA of 3.72. Dr. Abdulrahman’s educational journey began with a B.Sc. in Mechanical and Nuclear Engineering, where he excelled with a GPA of 3.69. His academic rigor and innovative research form the foundation of his successful career in academia and industry, making him a prominent voice in the field of engineering.

Experience 

Dr. Mohammed W. Abdulrahman has extensive teaching and research experience in mechanical and nuclear engineering. Since 2018, he has served as an Assistant Professor at the Rochester Institute of Technology (RIT), where he teaches graduate courses in alternative fuels and energy efficiency, alongside various undergraduate engineering courses, including engineering mechanics and programming for engineers. His role also includes supervising M.Sc. thesis projects, fostering a research-oriented environment among students. Prior to his position at RIT, he was a Teaching Assistant at UOIT from 2012 to 2016, contributing to courses such as fluid mechanics and life cycle engineering. This diverse experience equips him with the skills to effectively communicate complex engineering concepts while promoting collaborative learning. His commitment to student success and innovative research has established him as a respected educator and mentor in his field.

Awards and Honors 

Dr. Mohammed W. Abdulrahman has received several prestigious awards throughout his academic career, recognizing his exceptional contributions to research and education. He was included in the 2017-2018 edition of Marquis Who’s Who in the World, highlighting his global impact in the engineering field. His research excellence earned him the Best Paper Award at the 18th International Conference on Fluid Mechanics, Heat Transfer, and Thermodynamics in 2016. He also received three Key Scientific Article Certificates from Advances in Engineering Ltd. during 2016-2017. Notably, Dr. Abdulrahman was awarded the Best Presentation Award in the Technology Track at the University of Ontario’s 5th Annual Graduate Research Conference in 2014. Additionally, he has been the recipient of various scholarships, including the Ontario Graduate Scholarship and the Dean’s Graduate Scholarship from UOIT, showcasing his academic prowess and commitment to advancing engineering research.

Research Focus 

Dr. Mohammed W. Abdulrahman’s research primarily centers on thermal hydraulics, particularly within the context of hydrogen production using the Cu-Cl cycle. His investigations delve into multiphase reactors, focusing on heat transfer mechanisms, fluid dynamics, and system optimization. He has made significant contributions through experimental studies and computational fluid dynamics (CFD) simulations, exploring gas holdup, heat transfer coefficients, and the effects of solid particles in bubble columns. His innovative work addresses challenges in sustainable energy production and aims to enhance the efficiency of hydrogen generation processes. Dr. Abdulrahman actively engages in research collaborations and conference presentations, sharing his findings and promoting advancements in renewable energy technologies. His dedication to pioneering research not only impacts the academic community but also has potential applications in industry, particularly in enhancing energy systems and environmental sustainability.

Publications Top Notes

  • Experimental studies of direct contact heat transfer in a slurry bubble column at high gas temperature of a helium–water–alumina system 🌡️
  • CFD simulations of direct contact volumetric heat transfer coefficient in a slurry bubble column at a high gas temperature of a helium–water–alumina system 🧪
  • Experimental studies of gas holdup in a slurry bubble column at high gas temperature of a helium−water−alumina system 🔬
  • Experimental studies of the transition velocity in a slurry bubble column at high gas temperature of a helium–water–alumina system 📈
  • DIRECT CONTACT HEAT TRANSFER IN THE THERMOLYSIS REACTOR OF HYDROGEN PRODUCTION Cu-Cl CYCLE ⚗️
  • Similitude for Thermal Scale-up of a Multiphase Thermolysis Reactor in the Cu-Cl Cycle of a Hydrogen Production 🔄
  • Analysis of the thermal hydraulics of a multiphase oxygen production reactor in the Cu-Cl cycle 🔥
  • Heat Transfer Analysis of a Multiphase Oxygen Reactor Heated by a Helical Tube in the Cu-Cl Cycle of Hydrogen Production 🚀
  • CFD Analysis of Temperature Distributions in a Slurry Bubble Column with Direct Contact Heat Transfer 🌊
  • Temperature profiles of a direct contact heat transfer in a slurry bubble column 📊
  • Effect of Solid Particles on Gas Holdup in a Slurry Bubble Column 📉
  • CFD Simulations of Gas Holdup in a Bubble Column at High Gas Temperature of a Helium-Water System 🌪️
  • Thermohydraulics of a Thermolysis Reactor and Heat Exchangers in the Cu-Cl Cycle of Nuclear Hydrogen Production ⚡
  • Simulation of Materials Used in the Multiphase Oxygen Reactor of Hydrogen Production Cu-Cl Cycle 🧬
  • MATERIAL SUBSTITUTION OF CUPROUS CHLORIDE MOLTEN SALT AND OXYGEN GAS IN THE THERMOLYSIS REACTOR OF HYDROGEN PRODUCTION Cu-Cl CYCLE ⚗️
  • Eulerian Approach to CFD Analysis of a Bubble Column Reactor–A Review 📚
  • HEAT TRANSFER ANALYSIS OF THE SPIRAL BAFFLED JACKETED MULTIPHASE OXYGEN REACTOR IN THE HYDROGEN PRODUCTION Cu-Cl CYCLE 🔬
  • Review of the Thermal Hydraulics of Multi-Phase Oxygen Production Reactor in the Cu-Cl Cycle of Hydrogen Production 📖
  • Exact Analytical Solution for Two-Dimensional Heat Transfer Equation through a Packed Bed Reactor 📏
  • Heat Transfer in a Tubular Reforming Catalyst Bed: Analytical Modelling 🧮

Conclusion

Mohammed W. Abdulrahman demonstrates significant strengths as a researcher through his impressive academic background, innovative contributions, and recognized expertise. His commitment to teaching and engaging with the research community further strengthens his candidacy for the Best Researcher Award. By addressing areas for improvement, particularly in collaboration and public engagement, he can enhance his research impact and continue to advance in his field. Overall, he is a deserving candidate for this prestigious recognition.

 

 

Jasmin Cooper | Environmental Sustainability | Best Researcher Award

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Dr Jasmin Cooper | Environmental Sustainability | Best Researcher Award

Dr Jasmin Cooper, Imperial College London, United Kingdom

Dr. Jasmin Cooper, PhD, AMIChemE, is a leading Research Associate at Imperial College London, specializing in emissions inventory analysis and the life cycle sustainability of energy systems. She earned her PhD in Environment and Sustainable Technology from The University of Manchester, where her research assessed the sustainability of shale gas in the UK. Dr. Cooper’s work primarily focuses on evaluating the environmental, economic, and social sustainability of energy systems, including natural gas, hydrogen, and biomethane. She has consulted on multiple projects, offering expertise in emissions quantification, methane leakage analysis, and the techno-economic assessment of low-carbon technologies. With numerous peer-reviewed publications and involvement in high-profile consultancy projects, Dr. Cooper is a prominent figure in the field of sustainable energy systems.

Publication Profile

Google Scholar

Strengths for the Award

Dr. Jasmin Cooper stands out as an ideal candidate for the Best Researcher Award due to her extensive contributions to the fields of emissions inventory analysis, life cycle sustainability of energy systems, and decarbonization. Her research on methane emissions, sustainability assessments of shale gas, and the environmental impact of various energy technologies has not only resulted in high-impact publications but has also provided valuable insights into sustainable energy pathways for the UK. Dr. Cooper’s ability to secure funding, her role as a consultant on multiple high-profile projects, and her interdisciplinary approach make her a strong contender.

Her work, cited by numerous researchers, emphasizes the breadth of her impact. Key projects, such as life cycle assessments for UK industrial decarbonization, further showcase her leadership in advancing sustainable energy solutions. The breadth of her research covers critical areas like hydrogen emissions, negative emission technologies, and methane detection, proving her expertise in reducing environmental impacts.

Areas for Improvement

While Dr. Cooper’s contributions are exceptional, a potential area for growth could be increasing engagement in cross-disciplinary collaborative projects. By expanding the application of her findings in international contexts or other energy sectors, her research’s influence could reach a broader audience. Additionally, greater involvement in public dissemination could enhance the societal understanding and implementation of her findings on sustainability and decarbonization.

Education

Dr. Jasmin Cooper received her PhD in Environment and Sustainable Technology from The University of Manchester (2013–2017), where her research focused on the life cycle sustainability assessment of shale gas in the UK. Her work, funded by the EPSRC and The University of Manchester, examined the environmental, economic, and social implications of shale gas extraction and electricity generation in the UK, comparing its sustainability with other electricity options. Her thesis, titled Life Cycle Sustainability Assessment of Shale Gas in the UK, was supervised by Professor Adisa Azapagic and Dr. Laurence Stamford. Prior to her PhD, Dr. Cooper completed a First Class (Honours) MEng in Chemical Engineering with Environmental Technology (2009–2013) at The University of Manchester. Her undergraduate dissertation explored the swelling behavior of porous polymer adsorbents used for CO₂ capture, further solidifying her expertise in environmental technology and sustainable energy solutions.

Experience

Dr. Jasmin Cooper is currently a Research Associate at the Department of Chemical Engineering, Imperial College London, where she has worked since 2018. Her research focuses on decarbonizing energy systems by analyzing emissions from natural gas, biomethane, hydrogen, and negative emission technologies. Dr. Cooper conducts emission data analysis and life cycle modelling, and she leads projects on the quantification of methane emissions from natural gas supply chains. Her expertise extends to supply chain sustainability, where she assesses the transfer of greenhouse gas emissions across value chains and validates Scope 3 emissions quantification. Dr. Cooper has also worked as a consultant on various high-profile projects, such as methane leakage analysis for Shell and technoeconomic assessments of low-carbon marine fuels for the Royal Academy of Engineering. She has served as an expert witness and third-party reviewer for several consultancy projects and reports, demonstrating her broad expertise in environmental sustainability.

Research Focus

Dr. Jasmin Cooper’s research focuses on the life cycle sustainability of energy systems, with a particular emphasis on emissions analysis and environmental impact assessment. Her work covers natural gas, biomethane, hydrogen, and negative emission technologies, investigating how these energy sources can be used to decarbonize global energy systems. She specializes in the quantification of methane and other short-lived climate pollutants, as well as the technologies used to detect and measure these emissions. Dr. Cooper also explores the sustainability of energy supply chains, assessing how greenhouse gas emissions transfer across value chains and validating Scope 3 emissions data. In addition to this, her research includes the environmental, economic, and social sustainability assessment of shale gas, providing critical insights into its role in energy markets. Overall, her research contributes to understanding how future energy systems can meet global climate goals while minimizing environmental impacts.

Publications Top Notes

  • Shale gas: A review of the economic, environmental, and social sustainability 🛢️🌍💼 – J Cooper, L Stamford, A Azapagic (Energy Technology, 2016)
  • Hydrogen emissions from the hydrogen value chain-emissions profile and impact to global warming 💨⚗️🌍 – J Cooper, L Dubey, S Bakkaloglu, A Hawkes (Science of The Total Environment, 2022)
  • Economic viability of UK shale gas and potential impacts on the energy market up to 2030 💰💡🇬🇧 – J Cooper, L Stamford, A Azapagic (Applied Energy, 2018)
  • Methane emissions along biomethane and biogas supply chains are underestimated ♻️💨🌾 – S Bakkaloglu, J Cooper, A Hawkes (One Earth, 2022)
  • Environmental impacts of shale gas in the UK: Current situation and future scenarios 🛢️🇬🇧🔍 – J Cooper, L Stamford, A Azapagic (Energy Technology, 2014)
  • Natural gas fuel and greenhouse gas emissions in trucks and ships 🚛⛴️🌍 – J Speirs, P Balcombe, J Cooper (Progress in Energy, 2020)
  • The quantification of methane emissions and assessment of emissions data for natural gas supply chains 📊🌿🛢️ – J Cooper, P Balcombe, A Hawkes (Journal of Cleaner Production, 2021)
  • Social sustainability assessment of shale gas in the UK 💼👨‍👩‍👦🇬🇧 – J Cooper, L Stamford, A Azapagic (Sustainable Production and Consumption, 2018)

Conclusion

Dr. Jasmin Cooper’s research achievements, particularly in the sustainable energy sector, underscore her suitability for the Best Researcher Award. Her work addresses critical global challenges in reducing emissions and advancing renewable energy, demonstrating both academic rigor and practical impact. This combination of scholarly influence and societal relevance makes her an exemplary candidate for this prestigious award.

Bibhudatta Mishra | Renewable Energy Award | Best Researcher Award

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Mr Bibhudatta Mishra | Renewable Energy | Best Researcher Award

Mr Bibhudatta Mishra , NIT Rourkela, India

Bibhudatta Mishra is an accomplished academic and researcher in Electrical Engineering, currently pursuing his Ph.D. at the National Institute of Technology, Rourkela. With expertise in MATLAB/Simulink, Pspice software, and optimization techniques, he has a robust academic background, including an M.Tech in Power System Engineering and a B.Tech in Electrical Engineering. Bibhudatta has a passion for teaching and research, having served as an Assistant Professor and Contractual Lecturer at various prestigious institutions. His contributions to the field are recognized through multiple awards and publications, reflecting his commitment to advancing knowledge in power systems and microgrids. 🌟📚

Education

Bibhudatta Mishra’s educational journey is marked by excellence and dedication. He is currently pursuing a Ph.D. in Electrical Engineering at the National Institute of Technology, Rourkela, where he has achieved a CGPA of 8.39/10. Prior to this, he earned an M.Tech in Power System Engineering from Veer Surendra Sai University of Technology, Burla, with a stellar CGPA of 9.04/10. His undergraduate studies were completed at Biju Pattnaik University of Technology, Rourkela, where he obtained a B.Tech in Electrical Engineering with a CGPA of 7.83/10. His academic foundation was laid at Bhadrak Junior College and Panchayat High School, Bhadrak, where he excelled in science and matriculation. 🎓🔧

Experience

Bibhudatta Mishra’s professional experience spans several years in academia. He served as an Assistant Professor at Silicon Institute of Technology, Sambalpur, from December 2016 to July 2019, where he taught various B.Tech theory and laboratory classes, along with taking on administrative and academic responsibilities. Prior to this, he was a Contractual Lecturer at Veer Surendra Sai University of Technology, Burla, from July 2016 to December 2016, where he taught core theory subjects and laboratory classes for B.Tech and M.Tech students. His roles in these institutions have significantly contributed to his expertise in electrical engineering education and research. 📘🏫

Awards and Honors

Bibhudatta Mishra has received several awards and honors in recognition of his academic and research achievements. He was awarded the Best Paper Award for his presentation at the IEMRE-2022 conference. His academic pursuits have been supported by MHRD Scholarships during his Ph.D. and M.Tech studies. Additionally, he has successfully qualified in the GATE exam multiple times, in the years 2013, 2015, 2017, and 2019. These accolades highlight his dedication to his field and his continuous strive for excellence in electrical engineering research and education. 🏆🎖️

Research Focus

Bibhudatta Mishra’s research focuses on decentralized control strategies for parallel operating inverters in AC microgrids. His doctoral research, titled “Decentralized Control Strategy for Parallel Operating Inverters in an AC Microgrid,” delves into innovative control mechanisms to enhance the performance and stability of microgrids. His M.Tech project involved a comparative study of different tuning algorithms applied to a multi-area thermal system. Additionally, his B.Tech project centered around the design of a three-phase distribution transformer. His research interests encompass advanced power system controls and optimization techniques. 🔬💡

Publication Top Notes

“A Modified Droop-based Decentralized Control Strategy for Accurate Power Sharing in a PV-based Islanded AC Microgrid”

“Enhancement of Power Sharing in an Islanded AC Microgrid Using Modified Reverse Droop Control Strategy”

“A Modified Droop-based Decentralized Control Strategy for an Islanded AC Microgrid”

B. Mishra, R. Pradhan and M. Pattnaik, “A Simple and Novel Tuning Technique for Load Frequency Control in a Multi-Area Microgrid System,”

“Geometrical Interpretation of Incremental Conductance MPPT Algorithm for a Stand-alone Photovoltaic System”

Byoung-Suhk Kim | energy storage devices | Best Researcher Award

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Prof Byoung-Suhk Kim | energy storage devices | Best Researcher Award

Prof Byoung-Suhk Kim, Jeonbuk National University, South Korea

Prof  Byoung-Suhk Kim is a distinguished Professor at Jeonbuk National University, Republic of Korea 🇰🇷. With expertise in materials engineering and a Ph.D. from Hokkaido University, Japan 🎓, he specializes in supercapacitors, transparent flexible electrodes, and electrocatalysts. His extensive international experience includes research roles in the USA, Germany, and Japan 🌍. As an editorial board member for several renowned journals, including ‘Energy and Catalysis’ and ‘Electrochemistry’, he contributes significantly to the field of nanomaterials and polymer science.

Publication Profile

Google scholar

Education

Byoung-Suhk Kim pursued his academic journey with a Ph.D. in Biological Sciences (Macromolecular Functions) from Hokkaido University 🎓 in 1999, preceded by an M.S. in Fiber Chemistry 🧪 from Jeonbuk National University, South Korea 🇰🇷 in 1995, and a B.S. in Textile Engineering 🧵 from the same university in 1993. His educational path equipped him with diverse expertise in polymer science and materials engineering, laying a strong foundation for his esteemed career as a professor and researcher in the field of carbon composites and organic materials.

Experience

Byoung-Suhk Kim has held a distinguished career path, currently serving as a Professor 🎓 at Jeonbuk National University, Republic of Korea 🇰🇷 since March 2012. His global experience includes roles such as Visiting Researcher 🌍 at the University of Pennsylvania, USA 🇺🇸 (2019-2020), Global COE researcher 🌐 at Shinshu University, Japan 🇯🇵 (2008-2012), and Principal Researcher at the Kumho Petrochemical R&BD Center 🧪 in Daejeon, Republic of Korea 🇰🇷 (2007-2008). He has also been a distinguished Alexander von Humboldt Research Fellow 🌐 at the Max-Planck Institute for Polymer Research in Germany 🇩🇪 (2003-2005) and held postdoctoral positions at the University of Connecticut, USA 🇺🇸, and Sogang University, South Korea 🇰🇷.

Research Focus

Byoung-Suhk Kim’s research focuses on advanced materials for energy and biomedical applications 🧬⚡️. His work prominently features electrospun nanofibers, exploring their synthesis and applications in supercapacitors and biomaterials. He investigates polymer blends, nanocomposites, and functional coatings, emphasizing properties like water stability, electrocatalytic activity, and mechanical performance. Kim’s contributions extend to scalable synthesis techniques for nanohybrids, enhancing devices such as flexible electrodes and biosensors. His interdisciplinary approach integrates polymer science with nanotechnology to address challenges in energy storage, sensing, and tissue engineering, aiming to develop sustainable and high-performance materials for diverse technological needs.

Publication Top Notes

Electrospun poly (vinyl alcohol) nanofibers: effects of degree of hydrolysis and enhanced water stability

Titration behavior and spectral transitions of water-soluble polythiophene carboxylic acids

Amphiphilic telechelics incorporating polyhedral oligosilsesquioxane: 1. Synthesis and characterization

Fabrication of nano‐hydroxyapatite on electrospun silk fibroin nanofiber and their effects in osteoblastic behavior

Reversible and universal pH sensing cellulose nanofibers for health monitor

Facile Synthesis of Core/Shell-like NiCo2O4-Decorated MWCNTs and its Excellent Electrocatalytic Activity for Methanol Oxidation

Nanofibers: Production, properties and functional applications

NiCo 2 S 4 nanosheet-decorated 3D, porous Ni film@ Ni wire electrode materials for all solid-state asymmetric supercapacitor applications

Cure behaviors and mechanical properties of carbon fiber-reinforced nylon6/epoxy blended matrix composites

Effect of deacetylation on wicking behavior of co-electrospun cellulose acetate/polyvinyl alcohol nanofibers blend

Agnieszka Pieniążek | Sustainability Award | Best Researcher Award

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Dr Agnieszka Pieniążek | Sustainability Award | Best Researcher Award

Dr Agnieszka Pieniążek, Institute of Physics PAS , Poland

Agnieszka Pieniążek 🌟 is an Assistant Professor at the Institute of Physics PAS, Warsaw, Poland. She completed her doctoral studies in Physical Sciences and holds master’s degrees in Analytical Chemistry and Applied Physics from leading Polish universities. Agnieszka’s research focuses on wide bandgap semiconductors, perovskites, and nanostructures, exploring their optical and electronic properties. She has authored 22 SCI and Scopus indexed articles and holds a patent for quantum nanostructures. Recognized for her Outstanding Doctoral Dissertation by the Polish Society for Crystal Growth, she continues to contribute significantly to the field of materials science and semiconductor physics.

 

Publication Profile

Scopus

Education

Agnieszka Pieniążek pursued her academic journey with dedication and achievement. She completed her Doctoral Studies in Physical Sciences at the Institute of Physics PAS, Warsaw, Poland, spanning from October 2013 to June 2019. Prior to that, she earned a Master’s Degree in Analytical Chemistry from Maria Curie-Skłodowska University, Faculty of Chemistry, Lublin, Poland, during October 2008 to July 2013. Her educational foundation also includes a Master’s Degree in Applied Physics from the same university’s Faculty of Mathematics, Physics, and Computer Science, obtained between October 2007 and July 2012. 🎓

Awards

In June 2022, Agnieszka Pieniążek was honored with the Award from the Polish Society for Crystal Growth for her Outstanding Doctoral Dissertation titled “Local Optical Properties of ZnO Microrods Grown by Hydrothermal Method.” This prestigious accolade recognizes her exceptional research contributions in the field of crystal growth and semiconductor optics. Agnieszka’s dissertation delved into the intricate optical characteristics of ZnO microrods, cultivated through innovative hydrothermal techniques. Her work not only expands the understanding of semiconductor materials but also underscores her commitment to advancing scientific knowledge and applications in materials science. 🏆

Research Focus

Agnieszka Pieniążek 🌟 specializes in the research of wide bandgap semiconductors, perovskites, and nanostructures. Her work primarily revolves around investigating the optical and electronic properties of these materials, with a focus on understanding defects, structural dynamics, and their implications for optoelectronic applications. Through her studies, she explores topics such as the bandgap pressure coefficient in perovskite thin films, interdiffusion phenomena in semiconductor alloys, and the cathodoluminescence patterns of semiconductor microrods. Agnieszka’s contributions significantly advance the field of materials science, particularly in enhancing the efficiency and reliability of semiconductor devices for renewable energy and optoelectronics.

 

Publication Top Notes

“Can a bistable amphoteric native defect model explain the photo-induced transformation of MAPbI3 thin films?” by A. Pienia̧żek et al., Solar Energy Materials and Solar Cells, 2024, 274, 112974 📄 Cited by: 0

“Investigation of interdiffusion in thin films of ZnO/ZnCdO grown by molecular beam epitaxy” by M. Stachowicz et al., Thin Solid Films, 2023, 781, 140003 📄 Cited by: 3

“Bandgap Pressure Coefficient of a CH3NH3PbI3 Thin Film Perovskite” by A. Pienia̧żek et al., Journal of Physical Chemistry Letters, 2023, 14(28), pp. 6470–6476 📄 Cited by: 4

“Mixology of MA1-xEAxPbI3 Hybrid Perovskites: Phase Transitions, Cation Dynamics, and Photoluminescence” by M. Šimėnas et al., Chemistry of Materials, 2022, 34(22), pp. 10104–10112 📄 Cited by: 13

“Detailed surface studies on the reduction of Al incorporation into AlGaN grown by molecular beam epitaxy in the Ga-droplet regime” by D. Majchrzak et al., Vacuum, 2022, 202, 111168 📄 Cited by: 6