Dipankar Das | Materials Science | Young Scientist Award

Posted on 22/08/202422/08/2024 by ScienceFather

Mr. Dipankar Das | Materials Science | Young Scientist Award

Mr. Dipankar Das, Tripura University, India

Publication profile

Academic & Professional Qualifications:

Mr. Dipankar Das has a solid academic background, currently pursuing a Ph.D. in Materials Science and Engineering at Tripura University. He completed his M.Tech. in the same field from Tripura University in 2018, and holds a B.Tech. in Mechanical Engineering from Dr. A.P.J. Abdul Kalam Technical University, Uttar Pradesh (2016). His foundational education includes a diploma in Mechanical Engineering and secondary education from the Tripura Board of Secondary Education.

Professional Experience:

Mr. Das has gained valuable research experience as a Junior and Senior Project Fellow at Tripura University from July 2018 to March 2021. His responsibilities focused on research and development in the Department of Material Science and Engineering, contributing to significant academic projects.

Awards & Distinctions:

Mr. Das has been recognized with numerous awards and certifications throughout his academic and professional journey. Notable achievements include the Dr. B. R. Ambedkar Memorial Award, multiple prizes in science exhibitions, and certifications in AutoCAD, Product Design Development, and 3D Printing Technology. He also excelled in competitions like the Smart India Hackathon 2019 and received prestigious awards for his research presentations and prototypes at various national and international conferences. Recently, he was awarded the Daniel Gabriel Fahrenheit Scholarship at the University of Gdansk, Poland, in October 2023.

Publication Top Notes

Geopolymer bricks: The next generation of construction materials for sustainable environment | 2024 | Construction and Building Materials | Cited by: Not Available 📚🏗️
Coal Fly Ash Utilization in India | 2023 | New Horizons for Industry 4.0 in Modern Business | Cited by: Not Available 🏭🌍
Preparation of Cellulose Hydrogels and Hydrogel Nanocomposites Reinforced by Crystalline Cellulose Nanofibers (CNFs) as a Water Reservoir for Agriculture Use | 2023 | ACS Applied Polymer Materials | Cited by: Not Available 💧🌱
Synthesis of Inorganic Polymeric Materials from Industrial Solid Waste | 2023 | Silicon | Cited by: Not Available 🏭⚛️
A Review of Coal Fly Ash Utilization to Save the Environment | 2023 | Water, Air, & Soil Pollution | Cited by: Not Available 🏞️🌱
Cellulose: a fascinating biopolymer for hydrogel synthesis | 2022 | Journal of Materials Chemistry B | Cited by: Not Available 🌱🧪
Effect of Diesel-Turpentine binary blends on performance, combustion, exergy, and emission parameters of a stationary compression ignition engine | 2022 | Journal of Thermal Analysis and Calorimetry | Cited by: Not Available 🚛🔥
Mullite Ceramics Derived from Fly Ash Powder by Using Albumin as an Organic Gelling Agent | 2022 | Biointerface Research in Applied Chemistry | Cited by: Not Available 🏺⚗️
Effect of mechanical milling of fly ash powder on compressive strength of geopolymer | 2022 | Materials Today: Proceedings | Cited by: Not Available 🛠️🏗️
Fabrication of Mullite Ceramic by Using Industrial Waste | 2022 | Smart Cities: Concepts, Practices, and Applications | Cited by: Not Available 🏙️🏭
Synthesis and Characterization of Fly Ash and GBFS Based Geopolymer Material | 2021 | Biointerface Research in Applied Chemistry | Cited by: Not Available ⚛️🏗️
Synthesis and Characterization of Superabsorbent Cellulose-Based Hydrogel for Agriculture Application | 2021 | Starch – Stärke | Cited by: Not Available 🌱💧
Synthesis, Characterization and Properties of Fly Ash Based Geopolymer Materials | 2021 | Journal of Materials Engineering and Performance | Cited by: Not Available 🏗️⚛️
A Review of Advanced Mullite Ceramics | 2021 | Engineered Science | Cited by: Not Available 🏺🧪
Effect of Slag Addition on Compressive Strength and Microstructural Features of Fly Ash Based Geopolymer | 2021 | Circular Economy in the Construction Industry | Cited by: Not Available ♻️🏗️
Industrial solid wastes and their resources | 2021 | Emerging Trends in Science and Technology | Cited by: Not Available 🏭♻️
E-Waste Management in India – A Review | 2021 | Future of E-waste Management: Challenges and Opportunities | Cited by: Not Available ♻️🔋
Utilization of thermal industry waste: From trash to cash | 2019 | Carbon – Science and Technology | Cited by: Not Available 💰♻️

Conclusion:

Given Mr. Das’s strong academic foundation, research experience, and numerous accolades, he appears to be a suitable candidate for the Research for Young Scientist Award. His dedication to materials science and engineering, coupled with his recognition in both national and international platforms, aligns well with the criteria for this prestigious award.

Zeev Zalevsky | Materials Science | Best Researcher Award

Posted on 13/08/202413/08/2024 by ScienceFather

Zeev Zalevsky | Materials Science | Best Researcher Award

Prof Zeev Zalevsky, Bar-Ilan University, Israel

Prof. Zeev Zalevsky: A Candidate for the Best Researcher Award.

Publication profile

google scholar

Education

Prof. Zeev Zalevsky has a solid educational background, with a B.Sc. in Electrical Engineering, Cum Laude, from Tel Aviv University (1989-1993). He pursued direct Ph.D. studies at the same university from 1993 to 1996, focusing on “Unconventional Optical Processors for Pattern Recognition and Signal Processing” under the guidance of Prof. David Mendlovic and Prof. Amos Hardy.

Professional Occupation

Prof. Zalevsky has extensive professional experience, starting as a teaching assistant at Tel Aviv University and later serving as an adjunct lecturer at various institutions, including Ariel Academic College and Weizmann Institute. He has held significant roles in both academia and industry, such as Project Officer in the Israeli Air Force’s R&D Department (1996-2001) and Founder and CTO of several technology companies. His contributions to electro-optics and photonics are particularly noteworthy, including his long tenure at Bar-Ilan University, where he founded and led the electro-optics track and the Nano-Photonics Center at BINA.

Scientific Achievements and Awards

Prof. Zalevsky’s work has earned him numerous awards and recognitions. He was instrumental in the development of the Kinect’s optical sensor, which garnered international acclaim and several prestigious awards, including the MacRobert Award for engineering innovation. His research has also been recognized by the National Institutes of Health (NIH), the European Commission, and other prominent organizations. Prof. Zalevsky has also mentored many successful researchers, further amplifying his impact on the scientific community.

Publications and Patents

Prof. Zalevsky’s prolific publication record includes influential works such as “The Fractional Fourier Transform” and “Space–Bandwidth Product of Optical Signals and Systems.” He holds multiple patents, including those for extended depth of focus imaging systems and three-dimensional sensing technologies. His research has significantly advanced the fields of optics, photonics, and biomedical engineering, with applications ranging from ophthalmic devices to remote sensing of biomedical parameters.

Conclusion

Prof. Zeev Zalevsky’s impressive academic background, extensive professional experience, and significant contributions to research make him a highly suitable candidate for the Best Researcher Award. His pioneering work in optics and photonics, coupled with his leadership in both academia and industry, demonstrates his exceptional qualifications for this honor.

Research focus

Zeev Zalevsky is a prominent researcher whose work primarily focuses on optical systems, particularly in areas such as superresolution imaging, 3D sensing, and extended depth of focus. His research includes developing innovative optical methods and systems, such as the Gerchberg-Saxton algorithm in the fractional Fourier domain and techniques for speckle pattern analysis. Zalevsky has made significant contributions to the fields of optical signal processing, synthetic aperture superresolution, and depth-varying light fields. His work is widely recognized, with numerous patents and publications reflecting his expertise in optics and photonics. 🌐🔬📸

Publication top notes

The fractional Fourier transform

Space–bandwidth product of optical signals and systems

Optical method and system for extended depth of focus

Depth-varying light fields for three dimensional sensing

Synthetic aperture superresolution with multiple off-axis holograms

Range mapping using speckle decorrelation

Gerchberg–Saxton algorithm applied in the fractional Fourier or the Fresnel domain

Fractional hilbert transform

Simultaneous remote extraction of multiple speech sources and heart beats from secondary speckles pattern

Three-dimensional sensing using speckle patterns

SUNG GYU PYO | Materials Science | Best Researcher Award

Posted on 07/08/202407/08/2024 by ScienceFather

SUNG GYU PYO | Materials Science | Best Researcher Award

Prof SUNG GYU PYO, Chung-Ang University, South Korea

Based on the detailed profile of Prof. Sung Gyu Pyo, he appears highly suitable for the “Best Researcher Award.

Publication profile

google scholar

Research Interests

Nano Microstructural Control: Prof. Pyo’s expertise in the nano microstructural control and evolution in various materials demonstrates his innovative approach in advanced materials science. Semiconductor Materials: His work in semiconductor materials and processing, including process integration and interconnect technology, is at the forefront of technological advancements in electronics. Advanced Technologies: Prof. Pyo’s involvement in cutting-edge technologies like Atomic Force Microscopy (AFM), HBM 3D integration, MEMS/sensors, and packaging processes highlights his comprehensive understanding and contributions to modern engineering.

Education and Professional Experience

Educational Background: With a robust educational foundation, including post-doctoral work at prestigious institutions like MIT and Kyoto University, Prof. Pyo is well-equipped with advanced knowledge and research skills. Teaching and Leadership: His roles as a Professor and former Dean at Chung-Ang University, along with his exchange professorship at the University of Texas, Austin, underline his leadership in academia and his commitment to education. Industry Contributions: Prof. Pyo’s extensive experience in the semiconductor industry, including leadership positions at SK Hynix and MagnaChip Semiconductor, showcases his ability to bridge the gap between academic research and industrial application.

Achievements

Publications and Patents: With approximately 100 publications and 200 patents, Prof. Pyo has made significant contributions to scientific literature and technological innovation. His work has been widely cited, reflecting the impact and relevance of his research. Editorial Roles: Serving on editorial boards of journals like Electronic Materials Letter and Advanced Science, Engineering and Medicine, he has contributed to shaping the field’s research directions.

Selected Publications

Optimizing Nanocomposite Structures: His publication on enhancing charge storage in nanocomposites is a testament to his innovative research in energy materials. Manufacturing Techniques: Several of his patents and publications focus on advanced manufacturing techniques for semiconductor devices, indicating his practical contributions to improving technology.

Recognition and Memberships

Who’s Who Listings: Prof. Pyo’s inclusion in Who’s Who in the World highlights his global recognition as a leading researcher. Professional Memberships: His involvement with the Korea Research Council for Industrial Science and Technology and the System IC Foundry Research Group reflects his influence in advancing industrial science.

Conclusion

Prof. Sung Gyu Pyo’s extensive research in materials science, significant contributions to semiconductor technology, and influential roles in academia and industry make him a strong candidate for the “Best Researcher Award.” His innovative work and leadership have not only advanced scientific understanding but have also driven technological progress, making him highly deserving of this recognition.

Research focus

Dr. SG Pyo’s research primarily focuses on semiconductor devices, specifically in the development and enhancement of image sensors and metal wiring. His notable contributions include advancements in backside illuminated sensors, fabrication of electrocatalysts for water splitting, and innovations in photoelectrodes for perovskite solar cells. His work spans across multiple areas including materials science, nanotechnology, and surface science, making significant strides in both theoretical and applied aspects of semiconductor technology. Dr. Pyo’s research has been published in high-impact journals and patented, showcasing his expertise in enhancing device performance and efficiency.

🔬📸🌟🧪✨🔋

Publication top notes

Atomic layer etching applications in nano-semiconductor device fabrication

Heater block having catalyst spray means

Zn₂SnO₄-Based Photoelectrodes for Organolead Halide Perovskite Solar Cells

Method of forming a metal wiring in a semiconductor device

Backside illuminated image sensor

Fabrication and evaluation of nickel cobalt alloy electrocatalysts for alkaline water splitting

Development of a production-ready, back-illuminated CMOS image sensor with small pixels

Microstructural analysis of multilayered titanium aluminide sheets fabricated by hot rolling and heat treatment

Enhanced charge storage by optimization of pore structure in nanocomposite between ordered mesoporous carbon and nanosized WO3− x

Fabrication of multilayered titanium aluminide sheets by self-propagating high-temperature synthesis reaction using hot rolling and heat treatment

Wenyao Zhang | Materials Science | Young Scientist Award

Posted on 19/06/202419/06/2024 by ScienceFather

Dr Wenyao Zhang | Materials Science | Young Scientist Award

professor at Nanjing university of science and technology, China

Dr. Wenyao Zhang is a distinguished professor at the School of Chemistry and Chemical Engineering, Nanjing University of Science & Technology in Nanjing, China. He currently leads research in the field of aqueous Zn-ion batteries, focusing on the surface chemistry of Zn metal and the stabilization of metal clusters.

Publication profile

Google Scholar

Educational Background:

Ph.D. in Materials Science & Engineering (2012 – 2017): Nanjing University of Science and Technology, China.
Joint Ph.D. in Colloid Chemistry (2015 – 2017): Max Planck Institute of Colloids and Interfaces, Germany.
B.Eng. in Materials Chemistry (2008 – 2012): Nanjing University of Science and Technology, China.

Dr. Zhang’s research contributions have significantly advanced the understanding and application of nanomaterials in energy storage and conversion technologies.

Professional Experience:

2022 – Present: Professor, Overseas High-Level Talent Recruitment Programs, Nanjing University of Science & Technology.
- Research: Zn metal surface chemistry, aqueous Zn-ion batteries, stabilization of atomic/subnanometric metal clusters.
2020 – 2022: Postdoctoral Researcher, Chemical & Materials Engineering, University of Alberta, Canada.
- Co-Advisors: Prof. Ken Cadien, Prof. Zhi Li.
2017 – 2020: Postdoctoral Researcher, Waterloo Institute for Nanotechnology, University of Waterloo, Canada.
- Co-Advisors: Prof. Zhongwei Chen, Prof. Aiping Yu.

Academic Background:

Dr. Zhang earned his Ph.D. in Materials Science and Engineering from Nanjing University of Science and Technology in 2017, under the supervision of Prof. Xin Wang. He conducted joint Ph.D. research in Colloid Chemistry at the Max Planck Institute of Colloids and Interfaces in Germany, under Prof. Markus Antonietti. His research during this period focused on carbon-nitrogen materials for electrocatalysis and lithium-ion batteries, and carbon nitride-based materials for photoelectrochemical water splitting.

Materials Science Research Focus:

Dr. Wenyao Zhang’s research in materials science primarily revolves around energy storage and conversion technologies, with a significant emphasis on the following areas:

Aqueous Zn-ion Batteries:
- Zn Metal Surface Chemistry: Investigating the chemical interactions and surface modifications of zinc metal to enhance the performance and stability of aqueous Zn-ion batteries.
- Stabilization of Metal Clusters: Developing molecular trapping strategies to stabilize atomic and subnanometric metal clusters, which are crucial for improving the efficiency and longevity of battery systems.
Electrocatalysis:
- Carbon-Nitrogen Materials: Designing novel carbon-nitrogen materials to serve as supports for electrocatalysts, enhancing their activity and durability for various electrochemical reactions.
Photoelectrochemical Water Splitting:
- Carbon Nitride-Based Materials: Creating high-performance carbon nitride-based materials to act as catalysts for photoelectrochemical water splitting, aiming to generate hydrogen efficiently using solar energy.
Nanostructured Materials:
- Growth of MnO2 on Carbon Nanotubes: Controlled synthesis of nanostructured manganese dioxide on carbon nanotubes to develop high-performance electrochemical capacitors.

Dr. Zhang’s innovative research integrates advanced material design and synthesis techniques to address critical challenges in energy storage and conversion, contributing to the development of sustainable and efficient energy solutions.

Citations:

Total Citations: 1,645
Citations Since 2019: 1,437
h-index: 21
i10-index: 28

Publication Top Notes

Ternary manganese ferrite/graphene/polyaniline nanostructure with enhanced electrochemical capacitance performance
- P. Xiong, C. Hu, Y. Fan, W. Zhang, J. Zhu, X. Wang, Journal of Power Sources, 266, 384-392, 2014
- Citations: 183
Palladium nanoparticles supported on graphitic carbon nitride-modified reduced graphene oxide as highly efficient catalysts for formic acid and methanol electrooxidation
- W. Zhang, H. Huang, F. Li, K. Deng, X. Wang, Journal of Materials Chemistry A, 2 (44), 19084-19094, 2014
- Citations: 169
Defect‐Enriched Nitrogen Doped–Graphene Quantum Dots Engineered NiCo2S4 Nanoarray as High‐Efficiency Bifunctional Catalyst for Flexible Zn‐Air Battery
- W. Liu, B. Ren, W. Zhang, M. Zhang, G. Li, M. Xiao, J. Zhu, A. Yu, Small, 15 (44), 1903610, 2019
- Citations: 99
Merging single‐atom‐dispersed iron and graphitic carbon nitride to a joint electronic system for high‐efficiency photocatalytic hydrogen evolution
- W. Zhang, Q. Peng, L. Shi, Q. Yao, X. Wang, A. Yu, Z. Chen, Y. Fu, Small, 15 (50), 1905166, 2019
- Citations: 90
Zn-free MOFs like MIL-53 (Al) and MIL-125 (Ti) for the preparation of defect-rich, ultrafine ZnO nanosheets with high photocatalytic performance
- H. Xiao, W. Zhang, Q. Yao, L. Huang, L. Chen, B. Boury, Z. Chen, Applied Catalysis B: Environmental, 244, 719-731, 2019
- Citations: 90
Controlled growth of nanostructured MnO2 on carbon nanotubes for high-performance electrochemical capacitors
- H. Huang, W. Zhang, Y. Fu, X. Wang, Electrochimica Acta, 152, 480-488, 2015
- Citations: 87
Self-repairing interphase reconstructed in each cycle for highly reversible aqueous zinc batteries
- W. Zhang, M. Dong, K. Jiang, D. Yang, X. Tan, S. Zhai, R. Feng, N. Chen, Nature Communications, 13 (1), 5348, 2022
- Citations: 84
A general approach for fabricating 3D MFe2O4 (M= Mn, Ni, Cu, Co)/graphitic carbon nitride covalently functionalized nitrogen-doped graphene nanocomposites as advanced anodes
- W. Zhang, Y. Fu, W. Liu, L. Lim, X. Wang, A. Yu, Nano Energy, 57, 48-56, 2019
- Citations: 82
A “trimurti” heterostructured hybrid with an intimate CoO/Co x P interface as a robust bifunctional air electrode for rechargeable Zn–air batteries
- Y. Niu, M. Xiao, J. Zhu, T. Zeng, J. Li, W. Zhang, D. Su, A. Yu, Z. Chen, Journal of Materials Chemistry A, 8 (18), 9177-9184, 2020
- Citations: 81
One-pot synthesis of nickel-modified carbon nitride layers toward efficient photoelectrochemical cells
- W. Zhang, J. Albero, L. Xi, K. M. Lange, H. Garcia, X. Wang, M. Shalom, ACS Applied Materials & Interfaces, 9 (38), 32667-32677, 2017
- Citations: 67

Bing Bai | Advanced Materials Award | Best Researcher Award

Posted on 04/04/202404/04/2024 by ScienceFather

Prof Dr. Bing Bai | Advanced Materials Award | Best Researcher Award

Prof Dr. Bing Bai, Beijing jiaotong University, China

Prof. Dr. Bing Bai, born October 1966, is a distinguished male professor and doctoral supervisor at Beijing Jiaotong University, China 🇨🇳. With over 180 papers in international journals and 10 academic books, he’s a prominent figure in geotechnical engineering. Honored with the Beijing Natural Science Award and the Ministry of Education’s Natural Science Prize, his research is internationally acclaimed. Named among the “World’s Top 2% Scientists” by Stanford University for three years, he also received the prestigious “Scott Sloan Award” from the Royal Academy of Sciences. Serving on editorial boards and professional committees, he’s a leading authority in his field.

Publication Profile

Scopus

Orcid

Education and Experience 🎓

Prof. Dr. Bai Bing, born in October 1966, is a distinguished professor and doctoral supervisor at Beijing Jiaotong University, China. With an illustrious academic journey, he has authored over 180 papers in esteemed international journals and edited 10 academic monographs and textbooks.

Academic Achievements 🏆

His groundbreaking research has earned him prestigious accolades including the Beijing Natural Science Award and the Natural Science Prize from the Ministry of Education of China. He’s been consistently recognized among the “World’s Top 2% Scientists” by Stanford University. Notably, he clinched the esteemed “Scott Sloan Award for best paper in 2021” from the Royal Academy of Sciences.

Research Focus 📚

Prof. Dr. Bing Bai’s extensive research spans across diverse domains within geotechnical and environmental engineering. His work delves into the constitutive behavior of geomaterials, including the thermo-mechanical properties of soils and sediments. He investigates the transport phenomena of contaminants and suspended particles in porous media, exploring their interaction with factors like temperature, pore structure, and hydrodynamic forces. Additionally, he’s contributed significantly to understanding consolidation processes induced by thermal loading and cyclic loading. Prof. Bai’s interdisciplinary research sheds light on critical aspects of geoenvironmental problems, offering valuable insights for sustainable underground construction and environmental management.

Publication Top Notes

“Laboratory Model Test of Rock-Socketed Pile Groups in Steep-Inclined Bedrock Under a Reduced Constraint” | Published: 2023
“Special Issue on the Geo-Environmental Problems Caused by Underground Construction” | Published: 2023
“The constitutive behavior and dissociation effect of hydrate-bearing sediment within a granular thermodynamic framework” | Published: 2023
“A thermodynamic model to simulate the thermo-mechanical behavior of fine-grained gassy soil” | Published: 2020
“Constitutive modeling for undrained shear behavior of gassy sand considering energy dissipation at the mesoscopic level” | Published: 2020
“Cotransport of heavy metals and SiO2 particles at different temperatures by seepage” | Published: 2020
“Physicochemical and microstructural properties of red muds under acidic and alkaline conditions” | Published: 2020
“Study of the factors influencing diffusive tortuosity based on pore‑scale SPH simulation of granular soil” | Published: 2020
“Temperature-driven migration of heavy metal Pb2+ along with moisture movement in unsaturated soils” | Published: 2020
“The transport of solid particle suspension at different alkalinities in saturated porous media” | Published: 2020
“The Deposition Characteristics of Coupled Lead Ions and Suspended Silicon Powders Along the Migration Distance in Water Seepage” | Published: 2020

Subramanian K.R.V | Nanomaterials Award | Excellence in Research

Posted on 21/03/202421/03/2024 by ScienceFather

Prof Dr. Subramanian K.R.V | Nanomaterials Award | Excellence in Research

Prof Dr. Subramanian K.R.V, Ramaiah institute of Technology, Bangalore, India

Dr. Subramanian K.R.V is a distinguished Professor of Mechanical Engineering with a robust background in nanotechnology and metallurgy. With a Ph.D. from the University of Cambridge and extensive experience in academia and industry, he leads groundbreaking research in nanocomposites, solar energy, and nanofluids. 🌱 His pioneering work includes the development of nanostructured solar cells and supercapacitors, earning recognition globally. 🌟 As a mentor, he has guided numerous Ph.D. and M.Tech students, fostering innovation in energy storage and materials science. Dr. Subramanian’s contributions epitomize excellence at the intersection of nanotechnology and sustainable technology. 🚀

Publication Profile

Google Scholar

Education 📚

Dr. Subramanian K.R.V pursued his Ph.D. in Nanotechnology from the University of Cambridge, England, focusing on spin-coatable oxide resists for electron beam nanolithography. His master’s degree in Metallurgy from the Indian Institute of Science and bachelor’s degree in Metallurgical Engineering from the National Institute of Technology, Tiruchirapalli, laid the foundation for his illustrious career in materials science.

Employment 🏢

Dr. Subramanian has held significant roles in academia and industry, including positions at Ramaiah Institute of Technology, GITAM University, and Shriram Institute for Industrial Research. His expertise spans nanocomposites, solar energy, nanofluids, and nanotechnology applications in various fields.

Recognition 🏅

Dr. Subramanian is a fellow of prestigious organizations like the Cambridge Commonwealth Society and the Royal Society of Chemistry. His contributions have earned him recognition in the Marquis Who’s Who of the World and as one of the Top 100 Professionals by the International Biographical Centre.

Research Focus 🧪

Dr. Subramanian K.R.V’s research spans a diverse array of topics in materials science and nanotechnology, with a particular emphasis on energy storage and nanofabrication. 🌱 His work encompasses the development of electrode materials for supercapacitors, such as electrospun α-Fe2O3 nanostructures and graphene/poly(pyrole) composites. ⚡ He also explores the fabrication of nanostructured ceramic oxides and the synthesis of novel polymers with pendant photocrosslinkable groups. Dr. Subramanian’s contributions extend to nanolithography techniques, including sub-10 nm electron beam patterning and femtosecond laser pulse-based 3D patterning. His research endeavors significantly advance the frontiers of nanoscience and renewable energy technologies. 🚀

Publication Top Notes

Electrospun α-Fe 2 O 3 nanostructures for supercapacitor applications🔄 Cited by: 236 📅 Year: 2013
Highly super capacitive electrodes made of graphene/poly (pyrrole)🔄 Cited by: 228 📅 Year: 2011
Effect of particulate reinforced aluminium metal matrix composite–a review 🔄 Cited by: 133 📅 Year: 2015
Sub-10 nm electron beam nanolithography using spin-coatable TiO2 resists🔄 Cited by: 127 📅 Year: 2003
On global energy scenario, dye-sensitized solar cells and the promise of nanotechnology🔄 Cited by: 122 📅 Year: 2014
Electrical and optical properties of electrospun TiO 2-graphene composite nanofibers and its application as DSSC photo-anodes 🔄 Cited by: 109 📅 Year: 2012
Direct 3D patterning of TiO2 using femtosecond laser pulses🔄 Cited by: 106 📅 Year: 2007
Development of cerium oxide nanoparticles and its cytotoxicity in prostate cancer cells 🔄 Cited by: 101 📅 Year: 2012
Electrodeposition of bronze–PTFE composite coatings and study on their tribological characteristics🔄 Cited by: 94 📅 Year: 2006
Chemical and structural stability of porous thin film NiO nanowire based electrodes for supercapacitors🔄 Cited by: 92 📅 Year: 2013