Nazila Zarabinia | solar energy | Best Researcher Award

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Dr. Nazila Zarabinia | solar energy | Best Researcher Award

Researcher at Nik Hamel Noor, Iran

🌟 Nazila Zarabinia is a dedicated researcher in solid-state physics, specializing in solar cell technologies and nanomaterials. She completed her PhD at the University of Zanjan, exploring perovskite phase deposition for solar cell performance. With experience as a researcher at Shahid Beheshti University and a scholarship recipient at the University of Rome “Tor Vergata,” she has made significant contributions to renewable energy. She is recognized for her innovative research on flexible perovskite solar cells and her active role in academic and scientific communities.

Publication Profile

scopus

Education 🎓

Bachelor’s in Solid-State Physics, Khajeh Nasir University, Tehran, 2002–2006. Master’s in Solid-State Physics, Alzahra University, Tehran, 2013–2015. PhD in Solid-State Physics, University of Zanjan, 2017–2021. Scholarship recipient at the Center for Hybrid and Organic Solar Energy, University of Rome “Tor Vergata,” 2019–2020.

Experience💼

Advisor, Young Elite Institute. Researcher, Shahid Beheshti University Photonic Lab, 2018–2019, 2021–2022. Content Producer, NikCell Company. Professor, Azad University, teaching physics and mathematics.

Awards & Honors 🏆

National Foundation of Elites Prize. National Patent: Ceramic stylus head. Top Researcher at Alzahra University.

Research Focus 🔬

Flexible perovskite solar cells. Advanced deposition techniques like spin-coating, spray coating, and soft covering. Nanomaterials synthesis and solar cell characterization. Quantum dots, graphene-based hole transport layers, and superconductor YBCO synthesis.

Publications 📖

Open Access 📖: Open-access articles (e.g., in iScience and Scientific Reports) are freely available to a larger audience, leading to more visibility and citations.

Practical Impact ⚡: Works like “Simple and effective deposition method for solar cell perovskite films using a sheet of paper” propose innovative and accessible methods, attracting researchers in both academia and industry.

Collaborations with Renowned Researchers 🤝: Co-authorship with well-known researchers, such as Thomas M. Brown, enhances a paper’s credibility and reach.

Timeliness of the Topic 🕒: Topics like perovskite solar cells and their efficiency enhancements are trending in renewable energy research, increasing citation rates.

Conference Contributions 🎤: Presenting at conferences like FLEPS 2022 enhances a paper’s visibility and citations by attendees and participants.

Conclusion

The candidate’s strong academic background, innovative research contributions, technical expertise, and global recognition make them a compelling nominee for the Best Researcher Award. Their work on perovskite solar cells, advanced deposition methods, and nanomaterial synthesis positions them as a leader in renewable energy and materials science. While their focus on research is commendable, expanding their influence through industrial applications, community engagement, and leadership in large-scale projects could further solidify their case as a top contender for the award.

Prof. Jiandong Fan | Photovoltaic cells | Best Researcher Award

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Prof. Jiandong Fan | Photovoltaic cells | Best Researcher Award 

Prof. Jiandong Fan, Jinan University, China

Prof. Jiandong Fan is academic and researcher in the field of renewable energy, holds a PhD in Bio systems Engineering from Kangwon National University, South Korea. His academic journey has been marked by a profound dedication to advancing solar energy technologies, specifically in solar thermal harvesting and its integration into agricultural and architectural applications.

Professional Profiles:

Orcid

Google scholar

🎓 Education 🎓

Ph.D. in Physics
University of Barcelona, Spain
Duration: 12/2009 − 07/2013M.S. in Material Science
Shandong University, China
Duration: 09/2003 − 07/2006B.S. in Material Science
Jinan University, China
Duration: 09/1999 − 07/2003

👨‍🏫 Academic Research Experience 👩‍🔬

Full Professor
Institution: Jinan University, China
Research Focus: Perovskite solar cells
Duration: 09/2016 − PresentPostdoctoral Researcher
Institution: Oxford University, U.K.
Research Focus: Perovskite solar cells
Duration: 09/2014 − 08/2016Postdoctoral Researcher
Institution: Swinburne University of Technology, Australia
Research Focus: Thin film solar cells
Duration: 11/2013 − 05/2014Postdoctoral Researcher
Institution: Catalonia Institute for Energy Research, Spain
Research Focus: All-solid state solar cells
Duration: 07/2013 − 11/2013Researcher
Institution: Shandong University, China
Research Focus: Crystallography
Duration: 09/2006 − 12/2009

📑 Representative Publications 🏆

Overall H-index: 36
Total Journal Articles: 88
Total Citations: Over 5600 (Google Scholar)

📖 Publications Top Note :

Enhanced UV-light stability of planar heterojunction perovskite solar cells with caesium bromide interface modification
Energy & Environmental Science 9 (2), 490-498, 2016
Citations: 608

All-Inorganic CsPbI2Br Perovskite Solar Cells with High Efficiency Exceeding 13%
Journal of the American Chemical Society 140 (11), 3825-3828, 2018
Citations: 559

Controllable grain morphology of perovskite absorber film by molecular self-assembly toward efficient solar cell exceeding 17%
Journal of the American Chemical Society 137 (32), 10399-10405, 2015
Citations: 398

Addictive-assisted construction of all-inorganic CsSnIBr2 mesoscopic perovskite solar cells with superior thermal stability up to 473 K
Journal of Materials Chemistry A 4 (43), 17104-17110, 2016
Citations: 287

Structurally Reconstructed CsPbI2Br Perovskite for Highly Stable and Square-Centimeter All-Inorganic Perovskite Solar Cells
Advanced Energy Materials 9 (7), 1803572, 2019
Citations: 221

Ultra-thin MoOx as cathode buffer layer for the improvement of all-inorganic CsPbIBr2 perovskite solar cells
Nano Energy 41, 75-83, 2017
Citations: 204

Nonlinear optical response of organic–inorganic halide perovskites
ACS Photonics 3 (3), 371-377, 2016
Citations: 176

Core–shell nanoparticles as building blocks for the bottom-up production of functional nanocomposites: PbTe–PbS thermoelectric properties
ACS Nano 7 (3), 2573-2586, 2013
Citations: 170

Thermodynamically self-healing 1D–3D hybrid perovskite solar cells
Advanced Energy Materials 8 (16), 1703421, 2018
Citations: 168

In Situ Regulating the Order–Disorder Phase Transition in Cs2AgBiBr6 Single Crystal toward the Application in an X-Ray Detector
Advanced Functional Materials 29 (20), 1900234, 2019
Citations: 137

Morphology evolution of Cu2−xS nanoparticles: from spheres to dodecahedrons
Chemical Communications 47 (37), 10332-10334, 2011
Citations: 137

Antimony-Based Ligand Exchange To Promote Crystallization in Spray-Deposited Cu2ZnSnSe4 Solar Cells
Journal of the American Chemical Society 135 (43), 15982-15985, 2013
Citations: 130

Perovskite-based low-cost and high-efficiency hybrid halide solar cells
Photonics Research 2 (5), 111-120, 2014
Citations: 128

Highly efficient perovskite solar cells with substantial reduction of lead content
Scientific Reports 6 (1), 35705, 2016
Citations: 110

Hysteretic behavior upon light soaking in perovskite solar cells prepared via modified vapor-assisted solution process
ACS Applied Materials & Interfaces 7 (17), 9066-9071, 2015
Citations: 98

Influence of the annealing atmosphere on the performance of ZnO nanowire dye-sensitized solar cells
The Journal of Physical Chemistry C 117 (32), 16349-16356, 2013
Citations: 90

Lattice vibration spectra and thermal properties of SrWO4 single crystal
Chemical Physics Letters 426 (1-3), 85-90, 2006
Citations: 87

C60 additive-assisted crystallization in CH3NH3Pb0.75Sn0.25I3 perovskite solar cells with high stability and efficiency
Nanoscale 9 (37), 13967-13975, 2017
Citations: 85

In situ induced core/shell stabilized hybrid perovskites via gallium(III) acetylacetonate intermediate towards highly efficient and stable solar cells
Energy & Environmental Science 11 (2), 286-293, 2018
Citations: 83

Cobalt(II/III) redox electrolyte in ZnO nanowire-based dye-sensitized solar cells
ACS Applied Materials & Interfaces 5 (6), 1902-1906, 2013
Citations: 75