Nikolai Kocherginsky | Chemical Physics | Best Researcher Award

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Dr. Nikolai Kocherginsky | Chemical Physics | Best Researcher Award

Founder at Next-ChemX, United States

Dr. Nikolai Kocherginsky 🎓 is the Founder and Chief Scientist at Next-ChemX 🔬, with a strong legacy in membrane technology and chemical innovation. Holding a Ph.D. from the Institute of Chemical Physics, Moscow 🇷🇺, and an M.S. in Chemistry from Moscow State University 🧪, he has taught and conducted research globally 🌍, including at UIUC 🇺🇸, Technion 🇮🇱, and NUS 🇸🇬. His groundbreaking work in lithium extraction and biomimetic membranes has gained international recognition 💧⚗️. Dr. Kocherginsky’s dedication to sustainable technologies and education 📘 has shaped both industrial advancements and academic development worldwide 🧠🌱.

Professional Profile:

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🔹 Education & Experience 

📚 Education:

  • 🎓 Ph.D. – Institute of Chemical Physics, Moscow, USSR

  • 📘 M.S. in Chemistry – Moscow State University

👨‍🏫 Academic & Research Experience:

  • 🧠 George A. Miller Visiting Scholar, UIUC (USA)

  • 🌏 Visiting Professor – Naresuan University, Thailand

  • 🕍 Lady Davis Fellow – Technion, Haifa, Israel

  • 🧪 Associate Professor – National University of Singapore

  • 🧬 Visiting Scholar – Dartmouth Medical School, USA

  • 🏆 Faculty Fellowship – U.S. Department of Energy (via AWU Inc.)

  • 📖 Taught General, Physical, Organic Chemistry, Biochemistry, and Membrane Science

  • 💻 Developed web-based learning tools and lab manuals

🔹 Professional Development 

Dr. Kocherginsky’s professional development 🌟 spans multiple continents, blending cutting-edge research with academic mentorship 🧑‍🏫. His work focuses on interdisciplinary approaches to chemical engineering and membrane technology ⚗️🌍. He has continuously evolved through visiting professorships 🧳 and global collaborations, notably with institutions like UIUC 🇺🇸 and Technion 🇮🇱. He has innovated in curriculum design 💡, particularly in web-based and lab-intensive chemical education 🧫🖥️. His professional path reflects a balance of industry-driven innovation and academic excellence 📈, pushing the frontiers in sustainable tech and separation sciences ♻️💧. His global mindset and adaptability make him a leader in next-gen chemistry applications 🔋🧠.

🔹 Research Focus 

Dr. Kocherginsky’s research centers around membrane science, green chemistry, and advanced separation technologies 🧪🔍. His projects emphasize nontraditional, biomimetic membranes for water purification 💧, lithium extraction 🔋, and radioactive metal separation ☢️. With a strong background in physical and organic chemistry ⚛️, he develops environmentally responsible methods for critical resource recovery 🌿. Supported by major agencies like ASTAR 🇸🇬, his work addresses global challenges in clean water, sustainable energy, and chemical waste reduction 🌎♻️. This multidisciplinary approach blends chemistry, environmental science, and nanotech innovation 🧬, contributing significantly to next-generation industrial applications and sustainability goals.

🔹 Awards & Honors 

🏅 Awards & Fellowships:

  • 🧠 George A. Miller Visiting Scholar – UIUC

  • 🕍 Lady Davis Fellowship – Technion, Israel

  • 🎓 Faculty Fellowship – U.S. Department of Energy via AWU, Inc.

  • 🌟 Recognized for securing nearly $1 million in research grants (e.g., ASTAR, Singapore)

  • 📜 Honored globally for contributions to membrane-based separation science and education

Publication Top Notes

1. Recent advances in supported liquid membrane technology

Authors: N.M. Kocherginsky, Q. Yang, L. Seelam
Journal: Separation and Purification Technology, 2007, Vol. 53(2), pp. 171–177
Citations: 542
Summary:
This review outlines the principles, benefits, and limitations of supported liquid membrane (SLM) technology. It explores its evolution, mechanisms of mass transfer, membrane stability, and scale-up potential for industrial applications such as metal ion separation and waste treatment.

2. Nitroxide spin labels: reactions in biology and chemistry

Authors: N. Kocherginsky, H.M. Swartz
Publisher: CRC Press, 1995
Citations: 382
Summary:
A comprehensive monograph on the chemistry and biological applications of nitroxide spin labels, especially in electron paramagnetic resonance (EPR). The book delves into their synthesis, stability, and use as probes in studying biomolecular structures and dynamics.

3. Demulsification of water-in-oil emulsions via filtration through a hydrophilic polymer membrane

Authors: N.M. Kocherginsky, C.L. Tan, W.F. Lu
Journal: Journal of Membrane Science, 2003, Vol. 220(1-2), pp. 117–128
Citations: 239
Summary:
This paper investigates the mechanism and efficiency of separating water-in-oil emulsions using hydrophilic polymer membranes, offering a novel physical method of demulsification without surfactants.

4. Antiplasmodial activity of ferrocenyl chalcones: investigations into the role of ferrocene

Authors: X. Wu, E.R.T. Tiekink, I. Kostetski, N. Kocherginsky, et al.
Journal: European Journal of Pharmaceutical Sciences, 2006, Vol. 27(2–3), pp. 175–187
Citations: 157
Summary:
This research explores the biological activity of ferrocene-containing chalcones against Plasmodium falciparum, linking ferrocene’s redox properties to enhanced antimalarial efficacy.

5. Copper corrosion in mildly alkaline water with the disinfectant monochloramine

Authors: X. Zhang, S.O. Pehkonen, N. Kocherginsky, G.A. Ellis
Journal: Corrosion Science, 2002, Vol. 44(11), pp. 2507–2528
Citations: 145
Summary:
A detailed study on the corrosion behavior of copper pipes in water treated with monochloramine, examining the roles of surface film formation and redox chemistry using electrochemical and spectroscopic techniques.

6. DSC and EPR investigations on effects of cholesterol component on molecular interactions between paclitaxel and phospholipid within lipid bilayer membrane

Authors: L. Zhao, S.S. Feng, N. Kocherginsky, I. Kostetski
Journal: International Journal of Pharmaceutics, 2007, Vol. 338(1–2), pp. 258–266
Citations: 112
Summary:
This work uses Differential Scanning Calorimetry (DSC) and EPR spectroscopy to study how cholesterol modulates drug-membrane interactions between paclitaxel and phospholipids, relevant to liposomal drug delivery systems.

7. The first fully characterized 1,3-polyazulene: High electrical conductivity resulting from cation radicals and polycations generated upon protonation

Authors: F. Wang, Y.H. Lai, N.M. Kocherginsky, Y.Y. Kosteski
Journal: Organic Letters, 2003, Vol. 5(7), pp. 995–998
Citations: 110
Summary:
Describes the synthesis and characterization of a 1,3-polyazulene polymer, highlighting its unique conductive properties due to proton-induced charge delocalization, a promising material for organic electronics.

8. Copper recovery and spent ammoniacal etchant regeneration based on hollow fiber supported liquid membrane technology: from bench-scale to pilot-scale tests

Authors: Q. Yang, N.M. Kocherginsky
Journal: Journal of Membrane Science, 2006, Vol. 286(1–2), pp. 301–309
Citations: 100
Summary:
Describes a scalable process using hollow fiber SLMs for recovering copper from spent etchants. The work presents both experimental optimization and industrial pilot-scale results.

9. Doping-dependent ion selectivity of polyaniline membranes

Authors: L. Wen, N.M. Kocherginsky
Journal: Synthetic Metals, 1999, Vol. 106(1), pp. 19–27
Citations: 75
Summary:
Investigates how dopant types and levels affect the ion transport properties of polyaniline membranes, suggesting applications in chemical sensing and selective separations.

10. Copper removal from ammoniacal wastewater through a hollow fiber supported liquid membrane system: modeling and experimental verification

Authors: Q. Yang, N.M. Kocherginsky
Journal: Journal of Membrane Science, 2007, Vol. 297(1–2), pp. 121–129
Citations: 72
Summary:
This paper presents mathematical modeling and experimental studies for optimizing the removal of copper ions from wastewater using SLM systems, reinforcing the method’s efficiency and predictability.

Conclusion

Dr. Nikolai Kocherginsky exemplifies the ideal profile for a Best Researcher Award—a visionary scholar with decades of impactful research, global academic service, and translational science that bridges laboratory innovation and industrial application. His career achievements, especially in membrane technology for sustainable separation processes, make him a deserving and high-impact candidate for recognition.

Pengxia Zhou | Physics | Best Researcher Award

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Prof. Dr. Pengxia Zhou | Physics | Best Researcher Award

Associate professor at Nantong University, China

Zhou Pengxia (Zhou Pengxia) 🎓, born on October 24, 1977 🎂, is a dedicated physicist and educator at the School of Physical Science and Technology, Nantong University 🇨🇳. With over two decades of experience, she has contributed significantly to condensed matter physics and multiferroic materials research ⚛️. She earned her Ph.D. from Nanjing University and conducted postdoctoral research at leading institutions in Singapore 🌏. As the principal investigator of an NSFC-funded project, she explores octahedral rotations in perovskite superlattices 🧪. Her work bridges teaching and innovation, advancing the frontiers of physics through both academia and international collaboration 🌟.

Professional Profile:

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🔹 Education and Experience 

📘 Education:

  • 🎓 1997–2001: Bachelor’s Degree in Physics – Yanbei Normal College

  • 📚 2001–2004: Master’s Degree in Condensed Matter Physics – Yangzhou University

  • 🧠 2011–2015: Doctor’s Degree in Physics – Nanjing University

🧑‍🏫 Professional Experience:

  • 🏫 2004–Present: Lecturer – Nantong University

  • 🌏 2017.10–2018.02: Visiting Scholar – Singapore University of Technology and Design

  • 🌐 2018.09–2019.08: Research Fellow – National University of Singapore

🔹 Professional Development 

Dr. Zhou Pengxia’s professional journey reflects her passion for physics and global academic growth 🌍📈. She has participated in international collaborations in Singapore, enriching her research and teaching perspectives 🇸🇬🔬. At Nantong University, she not only teaches but also mentors students in advanced materials science 🎓🧪. Her participation in cutting-edge research on perovskite superlattices and multiferroicity has positioned her as a recognized contributor in her field ⚛️. Through continual learning, overseas exchanges, and scientific leadership, Dr. Zhou remains committed to academic excellence and innovation in physical science education and research 📘🌟.

🔹 Research Focus 

Dr. Zhou Pengxia’s research is centered around condensed matter physics with a specific emphasis on multiferroic materials and perovskite superlattices 🧲⚡. She investigates how octahedral rotation affects multiferroicity, exploring mechanisms to enhance functional properties of complex oxides 🧪🧬. Her work contributes to the understanding and engineering of materials that exhibit both ferroelectric and magnetic properties – critical for next-generation electronic devices 💻🔋. With a focus on crystal structures and symmetry interactions, her research bridges fundamental science and potential applications in sensors, memory devices, and spintronics 🌐🔧. Zhou’s interdisciplinary approach adds great value to material innovation 🔍🧠.

🔹 Awards and Honors 

🏆 Awards & Honors:

  • 🌟 Principal Investigator – National Natural Science Foundation of China (2017–2019) for research on perovskite superlattices

  • 🎓 Invited Research Fellow – National University of Singapore (2018–2019)

  • 🌍 International Collaboration Grant – Singapore University of Technology and Design (2017–2018)

Publication Top Notes

1. Employing interpretable multi-output machine learning to predict stable perovskites in photovoltaics

Journal: Materials Today Communications, 2025
DOI: 10.1016/j.mtcomm.2025.112552
Summary:
This study leverages interpretable multi-output machine learning models to predict thermodynamically stable perovskite materials for photovoltaic applications. The key innovation lies in the simultaneous prediction of multiple material properties (e.g., stability, band gap, defect tolerance) using models that offer transparency into decision-making (e.g., SHAP values, decision trees). This work contributes to faster and explainable discovery of efficient perovskites for solar cell design.

2. A first-principles study on the multiferroicity of semi-modified X₂M (X = C, Si; M = F, Cl) monolayers

Journal: Physical Chemistry Chemical Physics, 2023
DOI: 10.1039/D2CP04575C
Summary:
This DFT-based study explores multiferroic behavior in 2D monolayers composed of X₂M (X = C, Si; M = F, Cl), highlighting their coexisting ferroelectric and magnetic properties. The findings suggest semi-modified 2D materials could serve as candidates for spintronic and memory devices, due to their tunable multiferroic characteristics.

3. Theoretical investigation of the magnetic and optical properties in a transition metal-doped GaTeCl monolayer

Journal: Physical Chemistry Chemical Physics, 2023
DOI: 10.1039/D3CP02313C
Summary:
This study investigates how doping GaTeCl monolayers with transition metals (e.g., Mn, Fe, Co) affects their magnetic and optical behavior. Using DFT, the authors show enhanced magneto-optical properties, suggesting that doped GaTeCl systems are promising for optoelectronic and spintronic devices.

4. Magnetism and hybrid improper ferroelectricity in LaMO₃/YMO₃ superlattices

Journal: Phys. Chem. Chem. Phys., 2019
Author: Pengxia Zhou
Summary:
This work presents a theoretical analysis of LaMO₃/YMO₃ (M, Y = transition metals) superlattices, showing hybrid improper ferroelectricity arising from coupling between octahedral tilting and rotations, along with magnetic ordering. The results support the design of multifunctional oxide heterostructures combining electric and magnetic orderings.

5. The excitonic photoluminescence mechanism and lasing action in band-gap-tunable CdS₁−ₓSeₓ nanostructures

Journal: Nanoscale, 2016
Author: Pengxia Zhou
Summary:
This paper discusses CdS₁−ₓSeₓ nanostructures with tunable band gaps. The team demonstrates strong excitonic photoluminescence and low-threshold lasing, linking optical properties to composition and quantum confinement. It provides a foundational understanding for nanoscale optoelectronic and laser devices.

6. Ferroelectricity driven magnetism at domain walls in LaAlO₃/PbTiO₃ superlattices

Journal: Scientific Reports, 2015
Author: Pengxia Zhou
Summary:
This study reveals that in LaAlO₃/PbTiO₃ superlattices, ferroelectric domain walls can induce localized magnetic moments due to lattice distortions and charge redistributions. This domain-wall magnetism introduces the potential for non-volatile magnetic memory controlled by ferroelectric domains.

Conclusion:

Dr. Zhou Pengxia is a suitable candidate for a Best Researcher Award, particularly in the fields of condensed matter physics and material science. Her leadership in nationally funded research, international collaboration experience, and long-standing academic service reflect a researcher committed to scientific advancement and knowledge dissemination. While her publication record and citation metrics were not provided, her PI role on an NSFC project suggests peer recognition and scholarly maturity.

Tan Zhiguang | Phenomenology model | Best Researcher Award

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Yang Han | Condensed Matter Physics | Best Researcher Award

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Prof Dr.Yang Han | Condensed Matter Physics | Best Researcher Award

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Educational Details:

Yang Han completed her Ph.D. in 2014 from Nanjing University, China. Following her doctorate, she pursued postdoctoral research at RWTH Aachen University, Germany, from 2014 to 2016, where she focused on [research focus, e.g., materials science, mechanical properties, etc.]. She then continued her postdoctoral work at the University of Lorraine, France, from 2016 to 2018, concentrating on [research focus, e.g., thermoelectric properties, molecular dynamics simulations, etc.]. With a strong background in first-principles calculations and numerical simulations, she now serves as a professor and Ph.D. supervisor at Harbin Engineering University.

Research and Innovations:

Yang Han has made significant contributions to the fields of material science and computational modeling, particularly through her innovative research using numerical simulations to understand the mechanical, thermal transport, electronic, magnetic, and thermoelectric properties of advanced materials. Her groundbreaking work has centered on the following key research innovations:

  1. Topological Defects and Heterojunctions in 3D Graphene Structures: Through the support of the National Natural Science Foundation of China (Project No. 12104111), Yang’s research has provided vital insights into the stability and physical properties of three-dimensional graphene structures. By exploring the influence of topological defects and heterojunctions, her research has enhanced the understanding of how these factors contribute to material performance, with potential applications in advanced electronics and nanotechnology.
  2. Natural Gas Hydrate Self-Protection Mechanisms: Under the Basic Research Funds for Central Universities, Yang’s research on natural gas hydrates has delved into the microscopic mechanisms that enable these structures to self-protect, which has crucial implications for energy storage and environmental sustainability. Her molecular dynamics simulations have uncovered novel pathways for optimizing the extraction and stability of natural gas hydrates.
  3. Combustible Ice Formation Mechanism: Another major contribution is her simulation study on the formation mechanism and physical properties of combustible ice. This research, funded by Central Universities’ Free Exploration Support Program, sheds light on the potential of combustible ice as a future energy source by providing a detailed understanding of its formation at the molecular level.
  4. Thermal Conductivity in Carbon Honeycomb Structures: At RWTH Aachen University, Yang’s work using high-performance computing resources has advanced the understanding of how tensile strain impacts the thermal conductivity of carbon-based materials. This research has potential implications for the development of advanced materials with tailored thermal properties for use in electronics and energy systems.
  5. Ab initio Calculations for Predicting Thermal Materials: Yang’s predictive models using ab initio calculations to discover new thermal materials have been pivotal in the design and application of next-generation materials with enhanced heat conduction properties. This project at RWTH Aachen University led to the development of methods that could revolutionize industries ranging from electronics to aerospace by providing better materials for thermal management.

These research innovations demonstrate Yang HAN’s pioneering contributions to material science, leveraging cutting-edge computational techniques to solve complex problems with wide-ranging impacts across multiple scientific and industrial domains.

Research Interest: 

Yang Han research focuses on utilizing numerical simulations to investigate the formation mechanisms and physical properties of natural gas hydrates. Her work delves into understanding how these hydrates form and stabilize at the molecular level, which has significant implications for energy storage and environmental applications. By employing molecular dynamics simulations, she provides crucial insights into the self-preservation behaviors of natural gas hydrates, aiding in their practical extraction and use as alternative energy sources.

Additionally, Yang has made substantial contributions to the study of the mechanical, thermal, electronic, magnetic, and thermoelectric properties of materials. Using a combination of first-principles calculations, molecular dynamics simulations, and analytical models, her research investigates how various materials behave under different physical conditions. This includes exploring their conductivity, structural stability, and magnetic properties, which are essential for designing advanced materials for electronics, thermoelectric devices, and other high-performance applications. Her multi-disciplinary approach is instrumental in advancing the field of material science, offering potential innovations across a wide range of industries.

Contributions: 

Yang Han is a seasoned researcher with over 10 years of experience in the field of numerical simulations, specializing in the mechanical, thermal transport, electronic, magnetic, and thermoelectric properties of materials. Her work primarily involves first-principles calculations and molecular dynamics simulations, which allow her to explore and predict the behavior of materials under various conditions. Her research also extends to water clathrate structures, such as methane hydrate, which have significant implications for energy storage and environmental conservation.

Yang’s academic contributions include 29 SCI-indexed papers, with two of her publications being specially highlighted by the editorial office of Nanotechnology and one chosen as a SCIlight by the Journal of Applied Physics. These recognitions underscore the impact and innovation of her work in material science, particularly in advancing the understanding of material properties for real-world applications in energy and technology.

Top Notable Publications

Rapid growth of CO2 hydrate as a promising way to mitigate the greenhouse effect
Authors: S. Jia, L. Yang, Y. Han, T. Zhang, X. Zhang, P. Gong, S. Du, Y. Chen, J. Ding
Year: 2024
Journal: Materials Today Physics, Article No. 101548
Citations: Not yet available (2024 publication)

Buckling Hydrogenated Biphenylene Network with Tremendous Stretch Extent and Anomalous Thermal Transport Properties
Authors: X. Zhang, M. Poulos, K. Termentzidis, Y. Han, D. Zhao, T. Zhang, X. Liu, S. Jia
Year: 2024
Journal: The Journal of Physical Chemistry C, 128 (13), 5632-5643
Citations: Not yet available (2024 publication)

Ferroelectricity of ice nanotube forests grown in three-dimensional graphene: the electric field effect
Authors: T. Zhang, Y. Han, C. Luo, X. Liu, X. Zhang, Y. Song, Y. T. Chen, S. Du
Year: 2024
Journal: Nanoscale, 16 (3), 1188-1196
Citations: 2

DFT characterization of a new possible two-dimensional BN allotrope with a biphenylene network structure
Authors: Y. Han, T. Hu, X. Liu, S. Jia, H. Liu, J. Hu, G. Zhang, L. Yang, G. Hong, Y. T. Chen
Year: 2023
Journal: Physical Chemistry Chemical Physics, 25 (16), 11613-11619
Citations: 5

Modulating thermal transport in a porous carbon honeycomb using cutting and deformation techniques
Authors: Y. Han, C. Zhao, H. Bai, Y. Li, J. Yang, Y. T. Chen, G. Hong, D. Lacroix, M. Isaiev
Year: 2022
Journal: Physical Chemistry Chemical Physics, 24 (5), 3207-3215
Citations: 1

Stretched three-dimensional white graphene with a tremendous lattice thermal conductivity increase rate
Authors: Y. Han, Y. Liang, X. Liu, S. Jia, C. Zhao, L. Yang, J. Ding, G. Hong
Year: 2022
Journal: RSC Advances, 12 (35), 22581-22589
Citations: 3

Condition monitoring and performance forecasting of wind turbines based on denoising autoencoder and novel convolutional neural networks
Authors: X. Jia, Y. Han, Y. Li, Y. Sang, G. Zhang
Year: 2021
Journal: Energy Reports, 7, 6354-6365
Citations: 37

Prediction of equilibrium conditions for gas hydrates in the organic inhibitor aqueous solutions using a thermodynamic consistency-based model
Authors: S. Li, Y. Li, L. Yang, Y. Han, Z. Jiang
Year: 2021
Journal: Fluid Phase Equilibria, 544, 113118
Citations: 15

Tailoring the activity of NiFe layered double hydroxide with CeCO3OH as highly efficient water oxidation electrocatalyst
Authors: J. Ding, Y. Han, G. Hong
Year: 2021
Journal: International Journal of Hydrogen Energy, 46 (2), 2018-2025
Citations: 14

Srinivasa Rao Konda | Optics Physics | Best Researcher Award

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Dr. Srinivasa Rao Konda | Optics Physics | Best Researcher Award

Dr. Srinivasa Rao Konda, GPL Photonics Laboratory Changchun Institute of Optics Fine Mechanics and Physics, China

Dr. Srinivasa Rao Konda is a materials scientist specializing in optics and physics. He is currently affiliated with the GPL Photonics Laboratory at the Changchun Institute of Optics, Fine Mechanics and Physics in China. Dr. Konda’s research focuses on the development of advanced materials for photonics applications, with a particular emphasis on optical materials and devices. He has contributed significantly to the field through his work in material science, optics, and photonics technologies.

PROFILE

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Educational Details

Dr. Srinivasa Rao Konda has a diverse academic background in physics and computational techniques. He completed his Ph.D. in Physics from the University of Hyderabad, India, from August 2010 to July 2016. Prior to this, he earned a Master of Technology (M.Tech) in Computational Techniques from the same university between August 2008 and June 2010, achieving a CGPA of 8.04/10. He also holds a Master of Science (M.Sc) in Computational Physics from Osmania University, India, completed from June 2006 to May 2008 with a score of 68.4%. Dr. Konda began his academic journey with a Bachelor of Science (B.Sc) in Mathematics, Physics, and Chemistry (M.P.C) from Kakatiya University, India, in June 2003, graduating in April 2006 with 90.3%. He completed his Intermediate education in M.P.C from the Board of Intermediate Education, Andhra Pradesh, India, in May 2003, securing 86.7%, and his SSC from the Board of Secondary Education, AP, in April 2001 with 89.3%.

Teaching Experience

Dr. Srinivasa Rao Konda has extensive teaching experience in a variety of physics-related subjects. His expertise includes Classical Mechanics, Quantum Mechanics, and Heat and Thermodynamics, where he teaches fundamental concepts essential to understanding the physical world. He also covers specialized topics such as Optics, Nonlinear Optics, Lasers, and Nanophotonics, reflecting his strong background in photonics and material science. Dr. Konda has taught Physics of Atoms and Molecules, providing students with insights into the microscopic world, as well as Computational Methods in Physics and Mathematical Methods in Physics, equipping them with the tools to solve complex physical problems. Additionally, he is proficient in MATLAB, Numerical Methods, and Computational Physics, which form a key part of his computational physics instruction, emphasizing the application of numerical techniques in solving physical equations.

Research  Interest

Dr. Srinivasa Rao Konda’s research is focused on Nonlinear Optics and Photonics, with a strong emphasis on material synthesis, light-matter interaction, and advanced optical applications. His work involves the synthesis and production of nanoparticles and thin films through methods such as laser ablation in liquids, chemical processes, pulsed laser deposition, and spin coating. He specializes in the optical and structural characterization of materials, using advanced techniques like UV-Visible spectroscopy, EDS, XPS, photoluminescence, time-resolved photoluminescence, XRD, HRTEM, FTIR, and Raman measurements. In the realm of nonlinear optics, Dr. Konda investigates third-order nonlinear optical (NLO) properties and carrier dynamics using Z-scan and time-resolved pump-probe methods, while exploring the generation of terahertz (THz) radiation through optical rectification in NLO crystals, 2D materials, and air plasma filamentation.

Dr. Konda’s work also delves into the applications of terahertz radiation, particularly through terahertz time-domain spectroscopy (THz-TDs) and time-resolved THz spectroscopy to examine quantum materials. Additionally, he is involved in the development of extreme ultraviolet (EUV) light sources and attosecond pulses, generated via higher-order harmonics using laser-induced plasmas from quantum materials. His expertise in light-matter interaction includes the fabrication of micro/nanostructures for optical and photonics applications, the creation of superhydrophobic and hydrophilic surfaces for anticorrosion uses, and the study of pulsed laser-material interaction. This includes laser plasma, nanoparticle deposition, surface morphology, and laser direct writing techniques. Furthermore, Dr. Konda investigates ultra-fast laser-matter interactions, such as femtosecond filamentation in air, and its role in generating terahertz radiation, along with plasma imaging in both air and vacuum conditions.

Top Notable Publications

Outstanding nonlinear optical properties of all-inorganic perovskite CsPbX3 (X=Cl, Br, I) precursor solutions and polycrystalline films

Authors: Fu, Y., Konda, S.R., Ganeev, R.A., Yu, W., Li, W.

Journal: iScience, 2023, 26(12), 108514

Citations: 0

Enhanced Higher Harmonic Generation in Modified MAPbBr3-xClx Single Crystal by Additive Engineering

Authors: Khanam, S.J., Konda, S.R., Ketavath, R., Li, W., Murali, B.

Journal: Journal of Physical Chemistry Letters, 2023, 14(41), pp. 9222–9229

Citations: 0

Aromatic Additives Boost the Terahertz Properties of Mixed Halide Perovskite Single Crystals

Authors: Khanam, S.J., Konda, S.R., Li, W., Murali, B.

Journal: Journal of Physical Chemistry Letters, 2023, 14(24), pp. 5624–5632

Citations: 1

Additive engineering in CH3NH3PbBr3 single crystals for terahertz devices and tunable high-order harmonics

Authors: Khanam, S.J., Konda, S.R., Premalatha, A., Li, W., Murali, B.

Journal: Journal of Materials Chemistry C, 2023, 11(29), pp. 9937–9951

Citations: 2

High-Order Harmonics Generation in MoS2 Transition Metal Dichalcogenides: Effect of Nickel and Carbon Nanotube Dopants

Authors: Venkatesh, M., Kim, V.V., Boltaev, G.S., Li, W., Ganeev, R.A., Konda, S.R.

Journal: International Journal of Molecular Sciences, 2023, 24(7), 6540

Citations: 4

Influence of embedded NiO-nanoparticles on the nonlinear absorption of tungsten disulfide nanolayers

Authors: Konda, S.R., Rajan, R.A., Singh, S., Guo, C., Li, W.

Journal: Optical Materials, 2023, 138, 113657

Citations: 4

High-order harmonics generation in nanosecond-pulses-induced plasma containing Ni-doped CsPbBr3 perovskite nanocrystals using chirp-free and chirped femtosecond pulses

Authors: Konda, S.R., Ganeev, R.A., Kim, V.V., Yu, J., Li, W.

Journal: Nanotechnology, 2023, 34(5), 055705

Citations: 4

Measurement of Optical Properties of CH3NH3PbX3 (X = Br, I) Single Crystals Using Terahertz Time-Domain Spectroscopy

Authors: Konda, S.R., Lin, Y., Rajan, R.A., Yu, W., Li, W.

Journal: Materials, 2023, 16(2), 610

Citations: 5

Harmonics Generation in the Laser-Induced Plasmas of Metal and Semiconductor Carbide Nanoparticles

Authors: Kim, V.V., Konda, S.R., Yu, W., Li, W., Ganeev, R.A.

Journal: Nanomaterials, 2022, 12(23), 4228

Citations: 5

High-order harmonics generation in the laser-induced lead-free perovskites-containing plasmas

Authors: Kim, V.V., Ganeev, R.A., Konda, S.R., Yu, W., Li, W.

Journal: Scientific Reports, 2022, 12(1), 9128

Citations: 5

 

 

Rachid Amrani | Physics | Best Researcher Award

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Dr. Rachid Amrani | Physics | Best Researcher Award

Dr. Rachid Amrani, University of Algiers, Algeria

Dr. Rachid Amrani is a faculty member at the University of Algiers, Algeria. He currently holds the position of Lecturer B, a role he has occupied since July 2023, after serving as Lecturer A from February 2018. Before that, he was an Assistant Professor at the University of Algiers from February 2017 to February 2018. Dr. Amrani has a strong research background, having worked as a Research Scientist at the Center of Development of Advanced Technologies (CDTA) in Algiers from March 2016 to January 2017. Earlier in his career, from 2011 to 2013, he served as a Research Assistant to Dr. Yvan Cuminal at the Institut D’électronique Du Sud (IES), CNRS, University of Montpellier, France. His academic and research experience spans various institutions, focusing on advanced technologies and electronics.

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Scopus Profile

Educational Details

Dr. Rachid Amrani earned his Ph.D. from the University of Montpellier, France, in December 2013, with a thesis focused on the “Growth and Properties of Hydrogenated Silicon Thin Films Deposited Near the Nanocrystalline Amorphous Transition Region from Argon Diluted Silane Plasma.” This work reflects his deep expertise in the field of material sciences, particularly in the study of thin films. Prior to his doctoral studies, Dr. Amrani completed a Magister degree in Physics with a specialization in material sciences at Université d’Oran Es-Senia, Algeria, from 2001 to 2006. His Magister thesis explored the “Optical Properties of Nanocrystalline Silicon Films Prepared by RF Magnetron Sputtering.” His academic journey began at Université d’Oran Es-Senia, where he earned his undergraduate degree in Physics with a focus on Theoretical Physics between 1992 and 1997. Throughout his career, Dr. Amrani has demonstrated a strong foundation in both theoretical and applied physics, particularly in the study of nanomaterials and thin film technologies.

Research  Interest

Dr. Rachid Amrani’s research interests lie at the intersection of material sciences and nanotechnology, with a particular focus on the growth, deposition, and characterization of thin films. His expertise encompasses a range of advanced techniques, including Plasma Enhanced Chemical Vapor Deposition (PECVD), RF magnetron sputtering, and thermal evaporation. Dr. Amrani has extensive experience in cleanroom processes, such as UV lithography, chemical etching, and reactive ion etching, which are essential for fabricating precise nanostructures. His work in characterizing thin films involves sophisticated methods like ellipsometry, Raman scattering spectroscopy, and Atomic Force Microscopy (AFM), aiming to understand the optical and structural properties of nanocrystalline silicon films and other functional materials. Dr. Amrani’s contributions to the field are reflected in his numerous publications and presentations at international conferences, where he has shared his findings on nanomaterials for energy conversion, storage, and other cutting-edge applications in electronics and photonics.

Honours and Awards

The Journal of Non-Crystalline Solids (Elsevier) and the Journal of Nanotechnology (IOPscience) are both prestigious publications in their respective fields. The Journal of Non-Crystalline Solids focuses on the latest research in amorphous materials, including glasses, polymers, and composites, and is known for publishing cutting-edge studies that advance the understanding of non-crystalline structures. Meanwhile, the Journal of Nanotechnology provides a platform for the dissemination of research on nanoscience and nanotechnology, covering topics ranging from the synthesis and characterization of nanomaterials to their applications in various industries. These journals are widely recognized for their rigorous peer-review process and their role in promoting scientific advancements.

 

Top Notable Publications

Investigation of Structural Heterogeneities in Hydrogenated Nanocrystalline Silicon Thin Films from Argon-Diluted Silane Dusty Plasma PECVD

Authors: R. Amrani, F. Lekoui, F. Pichot, S. Oussalah, Y. Cuminal

Year: 2024

Journal: Vacuum

Volume: 229

Article ID: 113568

Citations: 0

Machine Learning-Based Method for Predicting C–V-T Characteristics and Electrical Parameters of GaAs/AlGaAs Multi-Quantum Wells Schottky Diodes

Authors: E. Garoudja, A. Baouta, A. Derbal, N. Sengouga, M. Henini

Year: 2024

Journal: Physica B: Condensed Matter

Volume: 685

Article ID: 415998

Citations: 0

Structural and Optical Properties of Highly Ag-Doped TiO2 Thin Films Prepared by Flash Thermal Evaporation

Authors: R. Amrani, F. Lekoui, E. Garoudja, S. Oussalah, S. Hassani

Year: 2024

Journal: Physica Scripta

Volume: 99(6)

Article ID: 065914

Citations: 0

Optical Parameters Extraction of Zinc Oxide Thin Films Doped with Manganese Using an Innovative Technique Based on the Dragonfly Algorithm and Their Correlation to the Structural Properties

Authors: K. Settara, F. Lekoui, H. Akkari, S. Oussalah, S. Hassani

Year: 2024

Journal: Journal of Ovonic Research

Volume: 20(3)

Pages: 365–380

Citations: 0

On the Substrate Heating Effects on Structural, Mechanical, and Linear/Non-Linear Optical Properties of Ag–Mn Co-Doped ZnO Thin Films

Authors: F. Lekoui, R. Amrani, S. Hassani, N. Hendaoui, S. Oussalah

Year: 2024

Journal: Optical Materials

Volume: 150

Article ID: 115151

Citations: 4

A B3LYP-D3 Computational Study of Electronic, Structural, and Torsional Dynamic Properties of Mono-Substituted Naphthalenes: The Effect of the Nature and Position of Substituent

Authors: A. Benalia, A. Boukaoud, R. Amrani, A. Krid

Year: 2024

Journal: Journal of Molecular Modeling

Volume: 30(3)

Article ID: 88

Citations: 2

Electrical Parameters Extraction of Diode Using Whale Optimization Algorithm

Authors: E. Garoudja, W. Filali, S. Oussalah, F. Lekoui, R. Amrani

Year: 2024

Conference: 2nd International Conference on Electrical Engineering and Automatic Control (ICEEAC 2024)

Citations: 0

Effect of Ti/TiN Thin Film Geometrical Design on the Response of RTDs

Authors: W. Filali, E. Garoudja, F. Lekoui, S. Oussalah, R. Amrani

Year: 2024

Conference: 2nd International Conference on Electrical Engineering and Automatic Control (ICEEAC 2024)

Citations: 0

Artificial Intelligence Approach to Analyze SIMS Profiles of 11B, 31P, and 75As in n- and p-type Silicon Substrates: Experimental Investigation

Authors: W. Filali, M. Boubaaya, E. Garoudja, S. Oussalah, N. Sengouga

Year: 2023

Journal: Zeitschrift für Naturforschung – Section A Journal of Physical Sciences

Volume: 78(12)

Pages: 1143–1151

Citations: 0

Elaboration and Characterization of Pure ZnO, Ag, and Ag-Fe

Thin Films: Effect of Ag and Ag-Fe Doping on ZnO Physical Properties

Authors: F. Lekoui, S. Hassani, E. Garoudja, O. Sifi, S. Oussalah

Year: 2023

Journal: Revista Mexicana de Fisica

Volume: 69(5)

Article ID: 051005

Citations: 3