Dr. Michael Mercier | Best Researcher Award

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Dr. Michael Mercier | Best Researcher Award

University of Corsica | France

Dr. Michaël Mercier-Finidori is a French physicist and lecturer at the University of Corsica Pascal Paoli (UMR CNRS 6134 SPE), renowned for his contributions to the fields of underwater acoustics, ultrasound, group theory, and mathematical physics. He obtained his Ph.D. in Sciences pour l’Environnement from UMR CNRS 6134 SPE in 2002, where he developed a strong foundation in acoustic wave propagation and elastic scattering. Since joining the University of Corsica in 2003, Dr. Mercier-Finidori has actively engaged in both teaching and advanced research, focusing on acoustic scattering phenomena in elliptical geometries and elastic shells. His scholarly output includes six peer-reviewed publications that have collectively garnered 12 citations from 10 documents, with an h-index of 3, reflecting his impactful and specialized work. His recent open-access article, Acoustic scattering by elliptical elastic shells: Exact formalism and physical interpretation (Journal of Sound and Vibration, 2025), exemplifies his analytical rigor and innovative approach to acoustic modeling. Dr. Mercier-Finidori’s research provides valuable insights for applications in sonar technology, materials characterization, and acoustic signal analysis. His sustained academic commitment and theoretical depth underscore his influence in advancing the understanding of elastic wave dynamics in complex geometries.

Profiles : Orcid | Scopus

Featured Publications

Ancey, S., Gabrielli, P., & Mercier, M. (2025). Acoustic scattering by elliptical elastic shells: Exact formalism and physical interpretation. Journal of Sound and Vibration, 619, 119341. https://doi.org/10.1016/j.jsv.2025.119341

Ancey, S., Bazzali, E., Gabrielli, P., & Mercier, M. (2014). Acoustic scattering by elastic cylinders of elliptical cross-section and splitting up of resonances. Journal of Applied Physics, 115(19), 194901. https://doi.org/10.1063/1.4876678

Bazzali, E., Ancey, S., Gabrielli, P., & Mercier-Finidori, M. (2013). Splitting up resonances of elastic elliptical disc. Proceedings of Meetings on Acoustics, 19(1), 045002. https://doi.org/10.1121/1.4799566

Ancey, S., Bazzali, E., Gabrielli, P., & Mercier, M. (2013). Elastodynamics and resonances in elliptical geometry. Journal of Physics A: Mathematical and Theoretical, 46(43), 435204. https://doi.org/10.1088/1751-8113/46/43/435204

Gabrielli, P., & Mercier-Finidori, M. (2002). Multiple scattering by two impenetrable cylinders: Semiclassical theory. Physical Review E, 66(4), 046629. https://doi.org/10.1103/PhysRevE.66.046629

Prof. Phan Nguyen | Best Researcher Award

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Prof. Phan Nguyen | Best Researcher Award

Hanoi University of Industry | Vietnam

Prof. Nguyen Huu Phan is a distinguished researcher and lecturer in the Faculty of Mechanical Engineering at Hanoi University of Industry, Vietnam, known for his extensive contributions to advanced manufacturing processes, particularly electrical discharge machining (EDM), powder-mixed EDM (PMEDM), micro-EDM, vibration-assisted machining, and multi-criteria optimization. He earned his Doctorate from Thai Nguyen University in 2016 and has since established a strong research record with 25 Scopus-indexed documents, 351 citations, and an h-index of 11, reflecting the impact of his work in machining optimization, dielectric modifications, surface engineering, process modelling, and decision-making methodologies such as Taguchi, TOPSIS, DEAR, and grey relational analysis. His research has been published in leading international journals including Surface Review and Letters, International Journal of Advanced Manufacturing Technology, Materials and Manufacturing Processes, Metals, and International Journal of Modern Physics B. He has collaborated with global researchers on innovations involving coated electrodes, powder-mixed dielectrics, and performance enhancement of EDM for difficult-to-machine materials like Ti-6Al-4V. Dr. Phan also received funding from the National Foundation for Science and Technology Development for his work on optimizing PMEDM process parameters. His ongoing research continues to advance precision machining technologies and sustainable manufacturing solutions.

Profiles : Google ScholarOrcid | Scopus

Featured Publications

Dua, T. V., Phan, N. H., Huy, T. Q., & Toan, N. D. (2025). Investigation of electrode wear and surface quality in powder mixed electrical discharge machining (PMEDM) with low-frequency vibration applied to the workpiece. Surface Review and Letters.

Nguyen, H. P., Shirguppikar, S., Ganachari, V., Ly, N. T., & Toan, N. D. (2025). Optimization of surface roughness in AISI D-3 machining using powder-mixed electrical discharge machining with aluminum powder. Surface Review and Letters.

Pham, V. H., Phan, N. H., Shirguppikar, S., & Toan, N. D. (2025). Enhancing EDM performance with multi-objective decision-making using copper-coated aluminum electrodes and TOPSIS methodology for Ti-6Al-4V machining. International Journal of Modern Physics B.

Phan, N. H., Dong, P. V., Thinh, H. X., Asghari Ilani, M., Ly, N. T., Hai, H. T., & Tam, N. C. (2024). Review: Enhancing additive digital manufacturing with supervised classification machine learning algorithms. The International Journal of Advanced Manufacturing Technology.

Phan, N. H., Shirguppikar, S., & Toan, N. D. (2024). Optimizing micro-EDM with carbon-coated electrodes: A multi-criteria approach. International Journal of Modern Physics B.

Prof. Dr. Catherine Krafft | Best Researcher Award

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Prof. Dr. Catherine Krafft | Best Researcher Award

Paris-Saclay University | France

Dr. Catherine Krafft is a distinguished plasma physicist and astrophysics researcher recognized for her extensive contributions to the understanding of wave–particle interactions, electromagnetic emissions, and turbulence phenomena in solar wind plasmas. With an h-index of 17, over 108 published documents, and more than 1,039 citations, she has established herself as a leading figure in space plasma research. She earned her advanced education in physics with specialization in plasma theory and astrophysical plasmas, followed by research experience at prominent French institutions including the Institut Universitaire de France. Krafft’s work spans beam-driven Langmuir turbulence, upper-hybrid waves, harmonic electromagnetic emissions, particle diffusion, and the role of density fluctuations in solar environments. She has authored influential studies in top-tier journals such as Nature Astronomy, The Astrophysical Journal, and Astronomy & Astrophysics, contributing to major advancements in the understanding of solar radio sources and nonlinear plasma processes. Her collaborations with international experts have deepened insights into turbulence mechanisms and solar wind microphysics. Throughout her career, she has been recognized for scientific excellence through invitations, collaborations, and impactful publications that significantly influence plasma astrophysics. Catherine Krafft continues to advance the field through innovative theoretical and computational investigations into wave dynamics in space plasmas.

Profiles : Orcid | Scopus

Featured Publications

Krafft, C., Volokitin, A. S., Polanco-Rodríguez, F. J., & Savoini, P. (2025). Radiation efficiency of electromagnetic wave modes from beam-generated solar radio sources. Nature Astronomy.

Polanco-Rodríguez, F. J., Krafft, C., & Savoini, P. (2025). Polarization ratios of turbulent Langmuir/Z-mode waves generated by electron beams in magnetized solar wind plasmas. The Astrophysical Journal Letters.

Polanco-Rodríguez, F. J., Krafft, C., & Savoini, P. (2025). Decay of turbulent upper-hybrid waves in weakly magnetized solar wind plasmas. The Astrophysical Journal Letters.

Krafft, C., Savoini, P., & Polanco-Rodríguez, F. J. (2024). Mechanisms of fundamental electromagnetic wave radiation in the solar wind. The Astrophysical Journal Letters.

Krafft, C., & Savoini, P. (2024). Electrostatic wave decay in randomly inhomogeneous solar wind. The Astrophysical Journal Letters.

Mr. Vladimir Ivanov | Top Experimental Physicist Award

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Mr. Vladimir Ivanov | Top Experimental Physicist Award

St. Petersburg State University | Russia

Vladimir A. Ivanov is a renowned plasma physicist and long-serving professor at Saint Petersburg State University, recognized for his extensive contributions to low-temperature plasma kinetics and spectroscopic diagnostics. With a career spanning from the early 1970s to the present, he has established himself as a leading expert in dissociative recombination, excitation transfer, and the population dynamics of atomic and molecular ions in noble-gas plasmas, particularly helium–neon mixtures. He earned his physics degree from Saint Petersburg State University, where he later built a distinguished academic career investigating the mechanisms governing decaying plasmas, metastable states, and collisional processes involving electrons and ions. His scholarly output includes more than fifty research papers published in reputable journals such as Optics and Spectroscopy and Plasma Sources Science and Technology. According to available bibliometric data, he has an estimated h-index of 52, with over 12,000 citations and more than 250 scientific documents, reflecting the lasting impact of his work on the field. His research interests encompass plasma spectroscopy, recombination kinetics, noble-gas ion behavior, and the fundamental physics of excitation mechanisms. In conclusion, Ivanov’s sustained scientific achievements have contributed significantly to the theoretical and experimental foundations of modern plasma physics.

Profile : Orcid

Featured Publications

Ivanov, V. A. (2020). Superposition of low-pressure DBD and RF induction discharge for spectroscopic study of dissociative recombination in decaying plasma. Plasma Sources Science and Technology.

Ivanov, V. A., Petrovskaya, A. S., & Skoblo, Y. E. (2016). Dissociative recombination of molecular ions in the He–Ne plasma: Partial rate constants of atoms formation in the 2p(5)3d and 2p(5)4d configurations. Optics and Spectroscopy.

Ivanov, V. A., Petrovskaya, A. S., & Skoblo, Y. E. (2016). Role of neon in a decaying high-purity helium plasma. Russian Journal of Physical Chemistry B.

Ivanov, V. A., Petrovskaya, A. S., & Skoblo, Y. E. (2015). Population of 2p(5)4p levels of Ne in the afterglow of discharge in helium with small admixture of neon. Russian Journal of Physical Chemistry B.

Ivanov, V. A., Petrovskaya, A. S., & Skoblo, Y. E. (2014). Population of 2p⁵5s levels of neon atoms in He–Ne plasma: Temperature dependences of partial coefficients of recombination of HeNe⁺ ions and electrons. Optics and Spectroscopy.

Mr. Sandesh Aryal | Best Researcher Award

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Mr. Sandesh Aryal | Best Researcher Award

National Institute of Technology Rourkela | India

Mr. Sandesh Aryal holds a B.Tech in Electronics and Communication Engineering from the National Institute of Technology Rourkela (2021-2025) and has rapidly emerged as a research innovator in the domain of deep-learning–based biomedical image analysis. His work focuses on the classification of white blood cells via attention-augmented convolutional networks. His standout publication, “AFMNet: Adaptive Feature Modulation Network for Classification of White Blood Cells”, was published in Biocybernetics and Biomedical Engineering, and leverages adaptive spatial–channel feature modulation to achieve state-of-the-art classification performance. (Citation data: the article is indexed on ScienceDirect and ResearchGate.) His research interest spans machine learning, computer vision, biomedical signal processing, and image-based disease diagnostics. During his internship at Nepal Telecom, he gained practical exposure to wireless, transmission and power systems, complementing his core computational skills. His scholarship-supported undergraduate tenure and leadership roles (such as captain of his institute’s volleyball team) reflect a combination of technical excellence and organisational ability. With a proven ability to translate deep learning methods into biomedical applications, Sandesh is poised to contribute significantly to the intersection of AI and healthcare diagnostics.

Profile : Orcid

Featured Publication

Aryal, S., Naik, S. K., Madarapu, S., & Ari, S. (2025). AFMNet: Adaptive feature modulation network for classification of white blood cells. Biocybernetics and Biomedical Engineering.

Prof. Dr. Galina Makeeva | Best Researcher Award

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Prof. Dr. Galina Makeeva | Best Researcher Award

Penza State University | Russia

Dr. Galina Makeeva is a highly accomplished physicist and researcher at the University of Penza, Russian Federation, specializing in terahertz photonics, graphene plasmonics, and magneto-optical materials. With an impressive research portfolio of 115 scientific publications, her studies have garnered 236 citations and an h-index of 8, demonstrating her sustained impact in the field. Dr. Makeeva’s research focuses on the theoretical modeling and numerical simulation of electromagnetic wave interactions with advanced nanostructures such as graphene nanoribbons, metasurfaces, and nonlinear semiconductor systems. Her pioneering work on magnetically tunable and electrically controllable metasurfaces has opened new pathways for developing next-generation terahertz and mid-infrared optoelectronic devices. She has published extensively in top-tier journals including Optics and Spectroscopy, Technical Physics, and the Journal of Experimental and Theoretical Physics. Through her contributions, Dr. Makeeva has advanced the understanding of graphene-based photonic platforms, bridging the gap between classical electromagnetics and emerging nanophotonic technologies. Her innovative and interdisciplinary research continues to shape the evolution of high-frequency devices and photonic materials. Recognized for her academic excellence and scientific rigor, Dr. Makeeva remains at the forefront of developing functional materials for next-generation communication and sensing technologies.

Profile : Scopus

Featured Publications

Makeeva, G. S. (2025). Magnetoplasmonic effects induced by diffraction of terahertz waves on magnetically biased graphene metasurfaces. Journal of Experimental and Theoretical Physics.

Makeeva, G. S. (2025). Tunable polarization magnetooptical effects at scattering of terahertz radiation from graphene nanoribbon gratings in a magnetic field. Journal of Experimental and Theoretical Physics.

Makeeva, G. S. (2025). Numerical simulation of scattering patterns of terahertz waves on graphene nanoribbon arrays in a magnetic field. Technical Physics.

Makeeva, G. S. (2025). Method of nonlinear autonomous blocks with Floquet channels for simulation of nonlinear microwave devices with distributed interaction. Technical Physics.

Makeeva, G. S. (2025). Numerical investigation of the diffraction field of terahertz waves on graphene nanoribbons upon applying a magnetic field. Technical Physics.

Mr. Abdul Majeed | Best Researcher Award

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Mr. Abdul Majeed | Best Researcher Award

University of Malakand | Pakistan

Dr. Abdul Majeed is a researcher at the Department of Physics, University of Malakand, specializing in quantum optics, quantum computation, mathematical physics, and plasmonics. His Google Scholar profile records an h-index of 3 with 30 citations across 11 documents. His research explores the coherent control of structured light, soliton dynamics, exceptional surfaces, tunneling effects, and Goos–Hänchen shifts in multi-level atomic and chiral media. He has co-authored several recent papers in leading journals such as Chaos, Solitons & Fractals, Applied Physics B, AIMS Mathematics, Scientific Reports, and Advanced Theory and Simulations, focusing on the theoretical modeling and manipulation of nonlinear optical and quantum phenomena. Dr. Majeed’s academic background includes studies in physics and applied mathematics, and he has experience in both research and teaching within higher education. His work demonstrates a strong grasp of light–matter interactions, plasmonic behavior, and quantum control mechanisms, contributing to the advancement of quantum photonics and optical communication technologies. Although major awards are not yet documented, his growing publication record and international collaborations highlight his emerging status as a promising physicist in theoretical and computational optics. In summary, Dr. Majeed’s contributions are expanding the understanding of quantum coherence and structured-light manipulation in complex media.

Profile : Google Scholar 

Featured Publications

Ullah, I., Majeed, A., & Ali, A., Khan, Z. A. (2025). Reflection and transmission solitons via high magneto optical medium. Chaos, Solitons & Fractals, 191, 115881.

Khan, Z. A., Majeed, A., Ullah, I., & Ali, A. (2025). Coherent generation of superluminal and subluminal propagation of structured light in five level atomic medium. Applied Physics B, 131(2), 30.

Ullah, I., Majeed, A., Dalam, M. E. E., Almazah, M. M. A., & Ali, A. (2025). Coherent manipulation of tunneling and super Gaussian based Goos–Hänchen shift in five level chiral atomic medium. Applied Physics A, 131(2), 89.

Emam, W., Majeed, A., Ali, Z., Ali, A., & Pamucar, D. (2025). Periodic dark and bright optical soliton dynamics in atomic medium governed by control fields of Milnor polynomial and super-Gaussian beam. International Journal of Theoretical Physics, 64(5), 141.

Majeed, A., Ullah, I., Alduais, F. S., Al Bossly, A., Bossly, R., & Ali, A. (2025). Investigation of rotary photon drag of generated structured light in a five level atomic medium. Advanced Theory and Simulations, 8(5), 2401307.

Assoc. Prof. Dr. Jonas Duarte | Top Applied Physicist Award

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Assoc. Prof. Dr. Jonas Duarte | Top Applied Physicist Award

Federal University Western of Pará | Brazil

Dr. Jonas Marinho Duarte earned both a Licenciatura and a Bachelor’s degree in Physics from the Federal University of Pará (UFPA), followed by an M.Sc. (2019–2021) and a Ph.D. (2021–2025) in Electrical Engineering from the same institution. Since July 2025, he has served as a Professor in the Faculty of Mining Engineering at the Federal University of Western Pará (UFOPA) in Santarém, Brazil. His research focuses on two-dimensional carbon allotropes, nanoelectronics and electronic transport modulation, terahertz and microstrip antenna design using novel graphene-like patch resonators, and active learning methodologies in solar-energy education and environmental outreach. He has published peer-reviewed articles in journals such as Optical & Quantum Electronics, Physica E, and Computational Condensed Matter. Jonas Duarte’s current (unverified) research metrics include an h-index of approximately 0, around 5 published documents, and about 2 citations. He is developing a strong early-career, multidisciplinary profile that bridges physics, electrical engineering, and materials science through both teaching and research. In summary, Jonas Duarte is an emerging scholar-educator who actively connects advanced materials modeling with device engineering, positioning himself for significant future impact.

Profile : Orcid 

Featured Publications

Cardoso, D. H., Miranda, I. R. S., Mota, E. A. V., Duarte, J. M., dos Santos da Silva, S. J., da Silva, C. A. B., & Del Nero, J. (2025). Numerical implementation of phagraphene as patch resonator for a microstrip antenna. Optical and Quantum Electronics, 57(84), Article 08404. https://doi.org/10.1007/s11082-025-08404-9

Quaresma, L. C., Ferreira, D. F. S., Duarte, J. M., Moreira, M. M., da Silva, C. A. B. Jr., & Del Nero, J. (2025, December). Eigenchannel visualization and transition-voltage spectroscopy in two-dimensional C57 allotrope. Computational Condensed Matter, 36, e01169. https://doi.org/10.1016/j.cocom.2025.e01169

Quaresma, L. C., Duarte, J. M., Ferreira, D. F. S., da Silva, C. A. B. Jr., & Del Nero, J. (2025, October). Electronic transport modulation in C57: A path toward carbon-based logic and switching devices. Physica E: Low-Dimensional Systems and Nanostructures, 163, 116340. https://doi.org/10.1016/j.physe.2025.116340

Duarte, J. M., Santos, J. C. S., Ferreira, D. F. S., Paula, M. V. S., Mota, E. A. V., da Silva, C. A. B., & Del Nero, J. (2025, March). Systematic investigation of a metallic quadrilateral nanoribbon graphene allotrope for application in nanoelectronics. Computational Condensed Matter, 34, e01007. https://doi.org/10.1016/j.cocom.2025.e01007

Duarte, J. M. (2024, November). Metodologias ativas e educação ambiental: Uma revisão integrativa sobre abordagens inovadoras para o ensino de energia solar. Ensino e Tecnologia em Revista, 18(4), 1–15.

Assoc. Prof. Dr. Haiou Wang | Best Researcher Award

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Assoc. Prof. Dr. Haiou Wang | Best Researcher Award

Hangzhou Dianzi University | China

Dr. Haiou Wang is an accomplished Associate Professor at Hangzhou Dianzi University, China, specializing in spintronics and magnetic materials. He earned his Ph.D. in Physics from Nanjing University of Science and Technology in 2013 and has since established a strong academic and research career in condensed matter physics and materials science. Since joining Hangzhou Dianzi University in 2014, he has progressed from Assistant Professor to Associate Professor, contributing significantly to the study of magnetoresistance, magnetic phase transitions, and spin transport phenomena. Dr. Wang has published over 79 scientific documents, accumulating 690 citations with an h-index of 15, reflecting his consistent influence in the field. His notable works include studies on LaMnO₃, BaMnO₃, and Nd₁−ₓSrₓMnO₃ compounds, elucidating their structure–property relationships and magnetotransport mechanisms. Beyond his research contributions, Dr. Wang has served as a Guest Editor and Topic Editor for MDPI journals, demonstrating his leadership within the scholarly community. His research has been supported by the National Natural Science Foundation of China, highlighting his role in advancing materials for next-generation spintronic devices. Dr. Wang continues to pursue innovative research bridging magnetic materials and spintronics, contributing to the future of electronic and energy technologies.

Profiles : Scopus | Orcid 

Featured Publications

Li, J., Wang, H., & Wang, H. (2025). Structure, magnetism, and transport properties in hexagonal LaMnO₃. Journal of Electronic Materials. https://doi.org/10.1007/s11664-025-12473-7

Wang, H., Zhao, B., Tan, W., & Wang, H. (2025). Enhanced stability of lead-free CsSnI₃ perovskite through structural optimization. Journal of Materials Science: Materials in Electronics. https://doi.org/10.1007/s10854-025-15480-w

Wang, H., Li, J., & Wang, H. (2025). Magnetism, magnetoresistance, and temperature coefficient of resistance of the BaMnO₃ compound. Journal of Materials Science: Materials in Electronics. https://doi.org/10.1007/s10854-025-15446-y

Huang, S., Hua, J., Su, K., Yang, L., Wang, H., & Li, C. (2024). Anisotropic magnetoelectric effect in quasi-one-dimensional antiferromagnet Cu₃Mo₂O₉. Applied Physics Letters. https://doi.org/10.1063/5.0243143

Wang, H., Dong, F., Zhao, B., Tan, W., Huang, S., Su, K., Yang, L., & Wang, H. (2024). The colossal magnetoresistance within a wide temperature range in LaMnO₃ compound. Journal of Materials Science: Materials in Electronics. https://doi.org/10.1007/s10854-024-13490-8

Prof. Kazem Jamshidi-Ghale | Best Researcher Award

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Prof. Kazem Jamshidi-Ghale | Best Researcher Award

Azarbaijan Shahid Madani University | Iran

Prof. Kazem Jamshidi-Ghaleh is a distinguished physicist at the Department of Physics, Azarbaijan Shahid Madani University, Tabriz, Iran, with extensive experience in optics, photonics, and nonlinear optical phenomena. He holds a Ph.D. in Physics and has contributed over 50 peer-reviewed publications, accumulating more than 800 citations and an h-index of 19, reflecting his influential research in laser-matter interaction, nonlinear refraction, optical limiting, photonic crystals, and nanostructured thin films. Dr. Jamshidi-Ghaleh’s work spans experimental and theoretical studies on optical bistability, ultrafast laser processing, femtosecond laser interactions with materials, and the optical characterization of nanocomposites and dye molecules. He has led several projects on electrically tunable photonic devices and advanced optical measurement techniques such as moiré deflectometry. His research has been recognized in international journals including Optics Communications, Applied Physics A, and The European Physical Journal D. In addition to his research, he has mentored graduate students and collaborated with multidisciplinary teams on photonic materials and nanostructure applications. Dr. Jamshidi-Ghaleh continues to advance the field of photonics, contributing both fundamental insights and practical applications in optical materials and devices. His achievements highlight his commitment to scientific innovation, education, and the development of photonic technologies.

Profile : Google Scholar

Featured Publications

Jamshidi-Ghaleh, K., Salmani, S., & Ara, M. H. M. (2007). Nonlinear responses and optical limiting behavior of fast green FCF dye under a low power CW He–Ne laser irradiation. Optics Communications, 271(2), 551–554. https://doi.org/10.1016/j.optcom.2007.01.003

Tohidi, T., Jamshidi-Ghaleh, K., Namdar, A., & Abdi-Ghaleh, R. (2014). Comparative studies on the structural, morphological, optical, and electrical properties of nanocrystalline PbS thin films grown by chemical bath deposition using two different … Materials Science in Semiconductor Processing, 25, 197–206. https://doi.org/10.1016/j.mssp.2014.04.003

Jamshidi-Ghaleh, K., & Mansour, N. (2004). Nonlinear refraction measurements of materials using the moiré deflectometry. Optics Communications, 234(1–6), 419–425. https://doi.org/10.1016/j.optcom.2004.01.057

Mansour, N., Jamshidi-Ghaleh, K., & Ashkenasi, D. (2006). Formation of conical microstructures of silicon with picosecond laser pulses in air. Journal of Laser Micro/Nanoengineering, 1, 10.2961. https://doi.org/10.2961/jlmn.2006.1.10

Mohammad-Jafarieh, P., Akbarzadeh, A., Salamat-Ahangari, R., … Jamshidi-Ghaleh, K. (2021). Solvent effect on the absorption and emission spectra of carbon dots: Evaluation of ground and excited state dipole moment. BMC Chemistry, 15(1), 53. https://doi.org/10.1186/s13065-021-00789-1