Dr. Sergey Uchaikin | Quantum Sensors | Lifetime achievement Award

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Dr. Sergey Uchaikin | Quantum Sensors | Lifetime achievement Award

Senior Research Fellow | Institute for Basic Science | South Korea

Dr. Sergey Uchaikin is a globally recognized scientist and research leader with outstanding contributions to Quantum Sensors research, development, and large scale implementation. His expertise centers on Quantum Sensors for low temperature physics, superconducting technologies, precision measurement, and frontier particle physics experiments, where Quantum Sensors play a decisive role in sensitivity and reliability. He has authored more than one hundred peer reviewed publications that advance Quantum Sensors performance, noise reduction, and system integration, earning widespread citations across the international scientific community. His work on Quantum Sensors has enabled breakthroughs in axion dark matter searches, quantum limited amplification, and cryogenic detection platforms, directly impacting fundamental science and emerging quantum technologies. Through extensive collaborations with leading research institutes and industrial partners worldwide, he has translated Quantum Sensors innovations into practical systems for quantum computing, precision instrumentation, and advanced sensing applications. His leadership continues to shape global progress in Quantum Sensors research, fostering innovation, collaboration, and long term societal benefit in science and technology. Google Scholar profile of 6493 Citations, 28 h-index, 45 i10 index

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Featured Publications

Dr. Maria Hasan | Carbon Nanomaterials | Research Excellence Award

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Dr. Maria Hasan | Carbon Nanomaterials | Research Excellence Award

Researcher | Technical University of Ostrava | Czech Republic

Dr. Maria Hasan is a distinguished researcher whose work in Carbon Nanomaterials has established her as a leading contributor to advanced material chemistry and two dimensional material innovation. Her research journey reflects a sustained commitment to exploring Carbon Nanomaterials through controlled synthesis, structural analysis, functional modification, and application oriented studies. Dr. Maria Hasan has produced influential work on graphene growth, heteroatom doping, electrical property evaluation, and large area fabrication, all rooted in deep expertise in Carbon Nanomaterials. Her publication record spans reputable international journals where Carbon Nanomaterials form the core of her scientific inquiry. She has contributed significantly to collaborative research across global laboratories, integrating Carbon Nanomaterials with emerging approaches in electrochemistry and catalytic systems. Her contributions extend to chromium based nanoparticles and electrocatalytic applications, yet Carbon Nanomaterials remain central to her scientific trajectory. As part of major research programmes supported by international grant frameworks, she continues to advance Carbon Nanomaterials within high technology environments where precision growth of two dimensional heterostructures is essential. Her involvement in supervising research projects and mentoring early career scientists highlights her commitment to strengthening the scientific community through knowledge sharing grounded in Carbon Nanomaterials. Her work is further enriched by peer review service for respected journals, reflecting scholarly integrity and academic responsibility. With an expanding citation record and recognized impact in material science, Dr. Maria Hasan continues to demonstrate how Carbon Nanomaterials can contribute to sustainable technological progress and scientific advancement. Her professional presence in global research networks reinforces the relevance of Carbon Nanomaterials in modern innovation. Scopus profile of 477 Citations, 9 Documents, 7 h index.

Profile: Scopus

Featured Publication

1. Hasan, M., Ta, H. Q., Ullah, S., Yang, X., Luo, J., Bachmatiuk, A., Gemming, T., Trzebicka, B., Mahmood, A., Zeng, M., Fu, L., Liu, L., & Rümmeli, M. H. (2023). Crystal structure, synthesis and characterization of different chromium-based two-dimensional compounds. Arabian Journal of Chemistry, 16(8), Article 104973.

Dr. Mubasher | Condensed Matter Physics | Best Researcher Award

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Dr. Mubasher | Condensed Matter Physics | Best Researcher Award

Assistant Professor | IQRA University | Pakistan

Dr. Mubasher is an accomplished researcher whose scholarly foundation is deeply rooted in Condensed Matter Physics, demonstrating sustained contributions across material synthesis, nanostructure development, and energy-related applications. His body of work reflects a rigorous command of Condensed Matter Physics, particularly in the modification and enhancement of electrode materials, nanohybrids, ferrite systems, graphene derivatives, and multi-walled carbon nanotube composites. With an outstanding record of more than thirty international publications in reputable journals, his research in Condensed Matter Physics exhibits strong emphasis on advanced functional materials and experimental analysis involving impedance spectroscopy, dielectric behavior, cyclic voltammetry, and supercapacitive performance. His professional career represents both academic depth and laboratory capability, further sustained by collaborative research involving interdisciplinary interfaces within Condensed Matter Physics. As an Assistant Professor, his ongoing efforts are directed toward supervising postgraduate and doctoral candidates, enriching the academic environment through applied research in Condensed Matter Physics. His supervision and co-supervision of multiple thesis projects underline a dedication to knowledge transfer, research mentoring, and strengthening the scientific community. His contributions to Condensed Matter Physics extend into peer-review activity for high-impact journals, section editorial work, and involvement in advanced material development with direct relevance to lithium-ion storage and emerging electrochemical technologies. Extensive involvement in composites, doped systems, and material optimization further highlights his innovative approach toward energy-oriented Condensed Matter Physics research. Dr. Mubasher continues to advance the scientific landscape through impactful publications, collaborative research culture, multi-disciplinary integration, and sustained commitment to the global progression of Condensed Matter Physics, reflecting both intellectual maturity and research leadership. His portfolio stands as a remarkable example of academic excellence in the evolving domain of Condensed Matter Physics. Google Scholar profile of 412 Citations, 11 h-index, 12 i10-index.

Profiles: Google Scholar | ORCID

Featured Publications

1. Mujahid, M., Khan, R. U., Mumtaz, M., Soomro, S. A., & Ullah, S. (2019). NiFe₂O₄ nanoparticles/MWCNTs nanohybrid as anode material for lithium-ion battery. Ceramics International, 45(7), 8486–8493.

2. Mubasher, Mumtaz, M., Hassan, M., Ali, L., Ahmad, Z., Imtiaz, M. A., & Aamir, M. F. (2020). Comparative study of frequency-dependent dielectric properties of ferrites MFe₂O₄ (M = Co, Mg, Cr and Mn) nanoparticles. Applied Physics A, 126(5), 334.

3. Mumtaz, M. (2021). Nanocomposites of multi-walled carbon nanotubes/cobalt ferrite nanoparticles: Synthesis, structural, dielectric and impedance spectroscopy. Journal of Alloys and Compounds, 866, 158750.

4. Mumtaz, M., Hassan, M., Ullah, S., & Ahmad, Z. (2021). Nanohybrids of multi-walled carbon nanotubes and cobalt ferrite nanoparticles: High performance anode material for lithium-ion batteries. Carbon, 171, 179–187.

5. Mubasher, Mumtaz, M., & Ali, M. (2021). Structural, dielectric and electric modulus studies of MnFe₂O₄/(MWCNTs)x nanocomposites. Journal of Materials Engineering and Performance, 30(6), 4494–4503.

Dr. Meri Algarni | Condensed Matter Physics | Best Researcher Award

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Dr. Meri Algarni | Condensed Matter Physics | Best Researcher Award

Associate Professor | Al-Baha University | Saudi Arabia

Dr. Meri Algarni is an accomplished researcher in Condensed Matter Physics, recognized for her innovative work on magnetic and topological phenomena in low-dimensional materials. Her contributions have significantly advanced the understanding of electronic and magnetic properties in van der Waals heterostructures, bridging theoretical insights with experimental discoveries in Condensed Matter Physics. With a strong research background in Condensed Matter Physics, she has explored carrier-mediated ferromagnetism, gate-controlled phase transitions, and quantum effects that underpin next-generation spintronic and energy-efficient devices. Dr. Algarni’s expertise in Condensed Matter Physics encompasses nanoscale characterization techniques such as SEM, AFM, and PPMS, enabling her to investigate magnetic and structural behaviors at the atomic scale. Her research in Condensed Matter Physics has been published in high-impact journals, including Physical Review Letters, Nature Communications, and ACS Nano Letters, reflecting global recognition of her scientific contributions. Through her work on tunable artificial topological Hall effects and gate-tuned magnetic transitions, she continues to make influential contributions to Condensed Matter Physics, advancing the development of future quantum materials and low-energy electronic technologies. In addition to her research achievements, Dr. Algarni has actively participated in international conferences and collaborations, strengthening global scientific networks within Condensed Matter Physics. Her dedication to advancing Condensed Matter Physics extends to mentoring and teaching, inspiring emerging scientists to engage in experimental and theoretical studies within the field. Her scholarly impact in Condensed Matter Physics demonstrates a rare combination of technical mastery, analytical rigor, and interdisciplinary insight that drives innovation in material science and nanotechnology. Her Google Scholar profile records 530 citations, an h-index of 11, and an i10-index of 12, underscoring her substantial and growing influence in Condensed Matter Physics worldwide.

Profiles: Google Scholar | ORCID

Featured Publications

1. Zheng, G., Xie, W. Q., Albarakati, S., Algarni, M., Tan, C., Wang, Y., Peng, J., … (2020). Gate-tuned interlayer coupling in van der Waals ferromagnet nanoflakes. Physical Review Letters, 125(4), 047202.

2. Tan, C., Xie, W. Q., Zheng, G., Aloufi, N., Albarakati, S., Algarni, M., Li, J., … (2021). Gate-controlled magnetic phase transition in a van der Waals magnet Fe₅GeTe₂. Nano Letters, 21(13), 5599–5605.

3. Albarakati, S., Xie, W. Q., Tan, C., Zheng, G., Algarni, M., Li, J., Partridge, J., … (2022). Electric control of exchange bias effect in FePS₃–Fe₅GeTe₂ van der Waals heterostructures. Nano Letters, 22(15), 6166–6172.

4. Zheng, G., Wang, M., Zhu, X., Tan, C., Wang, J., Albarakati, S., Aloufi, N., … (2021). Tailoring Dzyaloshinskii–Moriya interaction in a transition metal dichalcogenide by dual-intercalation. Nature Communications, 12(1), 3639.

5. Zheng, G., Tan, C., Chen, Z., Wang, M., Zhu, X., Albarakati, S., Algarni, M., … (2023). Electrically controlled superconductor-to-failed insulator transition and giant anomalous Hall effect in kagome metal CsV₃Sb₅ nanoflakes. Nature Communications, 14(1), 678.

Prof. Dr. Guy Le Lay | Materials for 5G and Beyond | Outstanding Scientist Award

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Prof. Dr. Guy Le Lay | Materials for 5G and Beyond | Outstanding Scientist Award

Professor Emeritus | Aix-Marseille University | France

Prof. Dr. Guy Le Lay, Professor Emeritus at Aix-Marseille University, is an eminent physicist whose pioneering contributions to Materials for 5G and Beyond have reshaped the understanding of low-dimensional quantum systems. He earned his engineering degree from the School of Mines Nancy, followed by doctorates in Engineering and Physics from the University of Provence. His professional journey includes leadership in international collaborations with CNES, ESA, NASA, and major scientific committees. His groundbreaking research on silicene, germanene, and other Xenes has propelled Materials for 5G and Beyond into new scientific frontiers, influencing the evolution of nanostructures and topological quantum materials. Recognized globally, his honors include the IUVSTA Prize for Science, the Fernand Holweck Medal and Prize, and fellowships from Nagoya University and the Japan Society for the Promotion of Science. His research expertise encompasses atomic-scale surface science, quantum materials, and advanced interface engineering key enablers for Materials for 5G and Beyond. With deep proficiency in synchrotron radiation, surface spectroscopy, and nanoscale material design, he remains a visionary in the physics of Materials for 5G and Beyond. His academic excellence is mirrored by leadership in international symposia and scientific advisory roles promoting Materials for 5G and Beyond across global platforms. Prof. Dr. Guy Le Lay’s enduring legacy continues to inspire innovation in Materials for 5G and Beyond applications and quantum device engineering. Google Scholar profile of 19028 Citations, 59 h-index, 171 i10-index.

Profile: Google Scholar

Featured Publications

1. Vogt, P., De Padova, P., Quaresima, C., Avila, J., Frantzeskakis, E., Asensio, M. C., et al. (2012). Silicene: Compelling experimental evidence for graphenelike two-dimensional silicon. Physical Review Letters, 108(15), 155501.

2. Dávila, M. E., Xian, L., Cahangirov, S., Rubio, A., & Le Lay, G. (2014). Germanene: A novel two-dimensional germanium allotrope akin to graphene and silicene. New Journal of Physics, 16(9), 095002.

3. Aufray, B., Kara, A., Vizzini, S., Oughaddou, H., Léandri, C., Ealet, B., & Le Lay, G. (2010). Graphene-like silicon nanoribbons on Ag (110): A possible formation of silicene. Applied Physics Letters, 96(18).

4. De Padova, P., Quaresima, C., Ottaviani, C., Sheverdyaeva, P. M., Moras, P., et al. (2010). Evidence of graphene-like electronic signature in silicene nanoribbons. Applied Physics Letters, 96(26).

5. Le Lay, G. (1983). Physics and electronics of the noble-metal/elemental-semiconductor interface formation: A status report. Surface Science, 132(1–3), 169–204.

Dr. Mohsin Rafique | Condensed Matter Physics | Excellence in Research Award 

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Dr. Mohsin Rafique | Condensed Matter Physics | Excellence in Research Award 

Assistant Research Scientist | Beijing Academy of Quantum Information Sciences | China

Dr. Mohsin Rafique is an accomplished researcher in the field of Condensed Matter Physics, currently serving as a Research Scientist (Assistant) at the Beijing Academy of Quantum Information Sciences, China. His academic foundation in physics, including a PhD and MS from COMSATS Institute of Information Technology, has enabled him to explore critical areas of Condensed Matter Physics, particularly focusing on quantum transport, superconductivity, and magnetoelectric materials. Throughout his professional journey, he has contributed extensively to Condensed Matter Physics research through postdoctoral work at Tsinghua University and collaborative projects in Germany and Italy. His research interests encompass quantum phase transitions, magnetism, and multiferroic thin films all deeply rooted in Condensed Matter Physics principles. Dr. Rafique has received multiple awards and fellowships, including the Tsinghua University Postdoctoral Fellowship and COMSATS Research Productivity Award, reflecting his excellence in Condensed Matter Physics research and innovation. His research skills span quantum material fabrication, magnetoelectric measurements, and nanoscale device development, further demonstrating his command of Condensed Matter Physics methodologies. His work has been published in top-tier journals like Nano Letters, Applied Physics Letters, and Nature Communications, showcasing significant contributions to Condensed Matter Physics and related interdisciplinary fields. With his dedication to advancing scientific understanding in Condensed Matter Physics, Dr. Mohsin Rafique stands as a prominent figure whose expertise continues to influence modern material science.Google Scholar profile of 553 Citations, 13 h-index, 18 i10-index.

Profiles: Google Scholar | ORCID

Featured Publications

1. Rashid, J., Abbas, A., Chang, L. C., Iqbal, A., Haq, I. U., Rehman, A., Awan, S. U., & others. (2019). Butterfly cluster like lamellar BiOBr/TiO₂ nanocomposite for enhanced sunlight photocatalytic mineralization of aqueous ciprofloxacin. Science of the Total Environment, 665, 668–677.

2. Rashid, J., Saleem, S., Awan, S. U., Iqbal, A., Kumar, R., Barakat, M. A., Arshad, M., & others. (2018). Stabilized fabrication of anatase-TiO₂/FeS₂ (pyrite) semiconductor composite nanocrystals for enhanced solar light-mediated photocatalytic degradation of methylene blue. RSC Advances, 8(22), 11935–11945.

3. Liao, M., Wang, H., Zhu, Y., Shang, R., Rafique, M., Yang, L., Zhang, H., Zhang, D., & others. (2021). Coexistence of resistance oscillations and the anomalous metal phase in a lithium intercalated TiSe₂ superconductor. Nature Communications, 12(1), 5342.

4. Awan, S. U., Hasanain, S. K., Rashid, J., Hussain, S., Shah, S. A., Hussain, M. Z., & others. (2018). Structural, optical, electronic and magnetic properties of multiphase ZnO/Zn(OH)₂/ZnO₂ nanocomposites and hexagonal prism shaped ZnO nanoparticles synthesized by pulse laser. Materials Chemistry and Physics, 211, 510–521.

5. Rafique, M., Feng, Z., Lin, Z., Wei, X., Liao, M., Zhang, D., Jin, K., & Xue, Q. K. (2019). Ionic liquid gating induced protonation of electron-doped cuprate superconductors. Nano Letters, 19(11), 7775–7780.*

Assoc. Prof. Dr. Zukhra V. Gareeva | Condensed Matter Physics | Women Researcher Award

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Assoc. Prof. Dr. Zukhra V. Gareeva | Condensed Matter Physics | Women Researcher Award

Leading Scientist | Institute of Molecule and Crystal Physics | Russia

Assoc. Prof. Dr. Zukhra V. Gareeva is a distinguished physicist specializing in Condensed Matter Physics, serving as Head of the Theoretical Physics Laboratory at the Institute of Molecule and Crystal Physics, Russian Academy of Sciences. Her academic foundation in Theoretical and Condensed Matter Physics from Bashkir State University and the General Physics Institute established a prolific research career in Condensed Matter Physics focused on multiferroics, magnetic materials, domain structures, spintronics, and nanostructures. She has contributed significantly to Condensed Matter Physics through extensive studies on magnetoelectric and topological phenomena, advancing understanding of Dzyaloshinskii–Moriya interactions and symmetry analysis in multiferroic systems. With a Doctorate in Condensed Matter Physics, she has authored numerous high-impact publications in journals such as Physical Review B, Journal of Magnetism and Magnetic Materials, and Physics of the Solid State. Her research in Condensed Matter Physics integrates theory and computation to explore the microscopic origins of magnetism and spin dynamics in complex materials. Recognized with over 883 Google Scholar citations, an h-index of 16, and an i10-index of 27, she is a respected voice in international Condensed Matter Physics communities, serving as reviewer and guest editor for leading journals. Her professional achievements in Condensed Matter Physics have been complemented by collaborations with global institutions and contributions to scientific symposia. Through deep expertise in Condensed Matter Physics and innovative approaches to theoretical modeling, Assoc. Prof. Dr. Gareeva continues to shape the future directions of modern materials science and applied magnetism.

Profiles: ORCID | Google Scholar

Featured Publications

1. Gareeva, Z. V., & Filippova, V. V. (2025). Topological states in magnetic multilayers with hybrid anisotropy and Dzyaloshinskii–Moriya interaction. Journal of Magnetism and Magnetic Materials.

2. Gareeva, Z., Filippova, V., Gareev, S., & Sharafullin, I. (2025). Tailoring topological magnetic states in multilayer nanostructures: Bloch points, chiral bobbers, and skyrmion tubes. Nanomaterials.

3. Popov, A. I., Gareeva, Z. V., & Zvezdin, A. K. (2025). Quantum theory of the spin dynamics excited by ultrashort THz laser pulses in rare earth antiferromagnets. DyFeO₃. Journal of Physics: Condensed Matter.

4. Gareeva, Z., Filippova, V., Shulga, N., & Doroshenko, R. (2024). Magnetoelectric effects in magnetic films with alternating magnetic anisotropy: The emergence and stability of Bloch points. Physical Chemistry Chemical Physics.

5. Gareeva, Z. V., Trochina, A. M., Gareev, T., & Zvezdin, A. K. (2024). Magnetoelectric effects in synthetic multiferroic structures for spintronic applications. Bulletin of the Russian Academy of Sciences: Physics.

Prof. Heshmatollah Yavari | Quantum Science | Best Academic Researcher Award

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Prof. Heshmatollah Yavari | Quantum Science | Best Academic Researcher Award

Researcher at University of Isfahan, Iran

Prof. Heshmatollah Yavari has established himself as a leading figure in Quantum Science, contributing significantly to the understanding of superconductivity, superfluidity, and condensed matter systems. His work consistently integrates Quantum Science with theoretical models and practical applications. Prof. Yavari’s expertise in Quantum Science spans ultracold atomic gases, optical lattices, and neutron star physics, offering deep insights into strongly correlated systems. His pioneering role in Quantum Science research has positioned him among scholars who shape the evolution of modern physics. Prof. Yavari has consistently advanced Quantum Science through publications, collaborations, and innovative teaching. His vision within Quantum Science demonstrates a balance between theoretical foundations and cutting-edge applications, ensuring that Quantum Science remains central to future technological advances.

Professional Profile

ORCID Profile | Scopus Profile

Education 

Prof. Heshmatollah Yavari pursued his academic path with a clear dedication to Quantum Science, beginning with foundational studies in physics and advancing into specialized training in theoretical physics. His academic journey reflects a continuous engagement with Quantum Science, from undergraduate exploration to doctoral research. Prof. Yavari’s academic contributions reveal a strong commitment to Quantum Science, particularly in understanding transport phenomena, superconductors, and superfluids. Through each stage of education, Quantum Science remained the guiding principle of his learning and research. Prof. Yavari developed deep theoretical knowledge of Quantum Science, complemented by practical research projects that reinforced his scholarly standing. This trajectory highlights how Quantum Science shaped his intellectual development and prepared him for a lifetime of contribution to global scientific discovery.

Experience 

Prof. Heshmatollah Yavari’s professional career exemplifies dedication to Quantum Science, demonstrated through decades of teaching, mentoring, and research leadership. His role as professor of physics at the University of Isfahan highlights his continuous contribution to Quantum Science across multiple levels of academia. He has guided numerous students into advanced areas of Quantum Science, fostering innovation and critical thinking. His lectures on advanced quantum mechanics, statistical mechanics, and field theory exemplify the integration of Quantum Science with core theoretical frameworks. As a professional, Prof. Yavari actively collaborates with international scholars, expanding Quantum Science into interdisciplinary domains. His administrative roles and research coordination further underline his commitment to ensuring Quantum Science thrives as both a teaching discipline and a global research frontier.

Research Interest 

Prof. Heshmatollah Yavari’s research interests are firmly grounded in Quantum Science, with a focus on superconductivity, Bose-Einstein condensation, ultracold atomic gases, and topological insulators. His scholarly work connects Quantum Science with the mysteries of neutron stars, strongly correlated systems, and Majorana fermions. Prof. Yavari consistently expands the boundaries of Quantum Science by developing theories and models that address both fundamental and applied physics. Quantum Science drives his investigations into spin transport, optical lattices, and nonlocal effects in superconductors. His work reveals how Quantum Science contributes to understanding universal phenomena, from nanoscale materials to astrophysical systems. By integrating theory with experimental possibilities, Prof. Yavari demonstrates the transformative potential of Quantum Science across diverse scientific landscapes, ensuring it remains vital to modern physics.

Award and Honor

Prof. Heshmatollah Yavari has received recognition for his excellence in Quantum Science, reflecting his significant academic and research achievements. Awards and honors granted to Prof. Yavari underscore his enduring contributions to Quantum Science and theoretical physics. His published works in leading journals highlight the respect he commands in the Quantum Science community. Each accolade represents acknowledgment of his outstanding role in shaping Quantum Science and inspiring future generations of researchers. Honors received are not only a personal achievement but also evidence of his commitment to advancing Quantum Science globally. Through academic excellence and influential publications, Prof. Yavari’s reputation continues to strengthen, ensuring his name remains synonymous with quality and leadership in the growing field of Quantum Science.

Research Skill

Prof. Heshmatollah Yavari demonstrates advanced research skills in Quantum Science, applying both theoretical and computational methods to complex problems in physics. His expertise includes modeling superconductivity, analyzing transport properties, and interpreting Quantum Science phenomena in condensed matter systems. Prof. Yavari has mastered Quantum Science techniques related to ultracold atoms, superfluids, and nanoscale structures. His ability to integrate Quantum Science with interdisciplinary domains makes his skillset unique and impactful. Collaborations with other experts further amplify his Quantum Science research capabilities. His analytical approaches, problem-solving methods, and innovative thinking establish him as a skilled leader in Quantum Science. These research skills ensure that Prof. Yavari continuously contributes new insights and strengthens the foundation of Quantum Science in both academic and applied contexts.

Publication Top Notes 

Title: Purity of entangled photon pairs in a semiconductor–superconductor heterostructure in the presence of both Rashba and Dresselhaus SOCs
Authors: Zahra Saeedi; Heshmatollah Yavari
Journal: Materials Research Bulletin

Title: Effects of Rashba and Dresselhaus spin-orbit couplings on the critical temperature and paramagnetic limiting field of superconductors with broken inversion symmetry
Authors: H. Yavari; M. Tayebantayeba
Journal: Physica C: Superconductivity and its Applications

Title: Impurity and hybridization effects on the symmetry classification and magnetic response function of a two-band superconductor with interband pairing order
Authors: F Aghamohammadi Renani; H Yavari
Journal: Progress of Theoretical and Experimental Physics

Title: Three-body and Coulomb interactions in a quasi-two-dimensional dipolar Bose-condensed gas
Authors: Heshmatollah Yavari
Journal: Annals of Physics

Title: Effects of hybridization and spin–orbit coupling to induce odd-frequency pairing in two-band superconductors
Authors: Heshmatollah Yavari
Journal: The European Physical Journal Plus

Title: Shear viscosity in the strong interaction regime of a p-wave superfluid Fermi gas
Authors: Heshmatollah Yavari
Journal: Physics Letters A

Title: Anomalous viscosity of a chiral two-orbital superconductor in tight-binding model
Authors: Heshmatollah Yavari
Journal: The European Physical Journal Plus

Title: Progress in the development and construction of high temperature superconducting magnets
Authors: Heshmatollah Yavari
Journal: Superconductor Science and Technology

Title: On the Properties of Novel Superconductors
Authors: Heshmatollah Yavari
Journal: IntechOpen

Title: Effects of Thermally Induced Roton‐Like Excitation on the Superfluid Density of a Quasi‐2D Dipolar Bose Condensed Gas
Authors: Heshmatollah Yavari
Journal: Annalen der Physik

Title: Effect of long-range 1/r interaction on thermal and quantum depletion of a dipolar quasi-two-dimensional Bose gas
Authors: Heshmatollah Yavari
Journal: Low Temperature Physics

Title: Phase-dependent heat current of granular Josephson junction for different geometries
Authors: Heshmatollah Yavari
Journal: Physics Letters A

Title: Edge currents as a probe of the strongly spin-polarized topological noncentrosymmetric superconductors
Authors: Heshmatollah Yavari
Journal: Physical Review B

Title: Hall viscosity of a chiral two-orbital superconductor at finite temperatures
Authors: Heshmatollah Yavari
Journal: Physica C: Superconductivity and its Applications

Title: Temperature Dependence of the Thermal Conductivity of a Trapped Dipolar Bose-Condensed Gas
Authors: Heshmatollah Yavari
Journal: Brazilian Journal of Physics

Title: Low-Temperature Dependence of the Shear Viscosity in Superconductor S r 2 R u O 4
Authors: Heshmatollah Yavari
Journal: Journal of Superconductivity and Novel Magnetism

Title: Effect of nonlinearity, magnetic and nonmagnetic impurities, and spin-orbit scattering on the nonlocal microwave response of ad-wave superconductor
Authors: Heshmatollah Yavari
Journal: Low Temperature Physics

Title: Landau damping in a dipolar Bose–Fermi mixture in the Bose–Einstein condensation (BEC) limit
Authors: Heshmatollah Yavari
Journal: Chinese Physics B

Title: Depletion of the condensate in a dipolar Bose condensed gas in the presence of impurities
Authors: Heshmatollah Yavari
Journal: The European Physical Journal Plus

Title: Low temperatures shear viscosity of a two-component dipolar Fermi gas with unequal population
Authors: Heshmatollah Yavari
Journal: Annals of Physics

Conclusion

Prof. Heshmatollah Yavari’s career is a testament to the power of Quantum Science in shaping both knowledge and technology. His lifelong dedication to Quantum Science demonstrates how deep theoretical inquiry can lead to transformative discoveries. Prof. Yavari’s role as a professor, researcher, and author illustrates his enduring influence on Quantum Science. By nurturing students, publishing extensively, and advancing new ideas, he ensures that Quantum Science remains dynamic and progressive. His contributions prove that Quantum Science is not only central to academic inquiry but also critical for global innovation. In conclusion, Prof. Yavari embodies excellence in Quantum Science, representing a model scholar whose legacy will continue to inspire future advancements in the ever-expanding universe of Quantum Science.

Dr. Guy-Vano Tsamo | Materials Physics | Best Researcher Award

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Dr. Guy-Vano Tsamo | Materials Physics | Best Researcher Award

Postdoctoral Researcher at LTM/CEA/LETI, France

Dr. Guy-vano Tsamo is a dedicated researcher in materials physics, with a strong background in experimental and theoretical approaches to surface science and nanostructures. His work in materials physics focuses on the growth, characterization, and analysis of complex systems such as III-V heterostructures and III-nitride nanostructures. Through materials physics, he applies advanced spectroscopy, microscopy, and modeling tools to solve challenges in optoelectronics and RF electronics. In his career, materials physics serves as the core framework, guiding innovations in thin-film fabrication, chemical characterization, and interface studies. Dr.  Tsamo’s expertise in materials physics bridges fundamental science and technological applications, making him a recognized figure in the global materials physics research community.

Professional Profile

Scopus

Education 

Dr. Guy-vano Tsamo’s academic path is deeply rooted in materials physics, with advanced studies in condensed matter, nanomaterials, and dense environments. His doctoral research in materials physics explored the growth and characterization of III-nitride nanostructures on III-V substrates using state-of-the-art techniques. Earlier, he pursued master’s-level studies in materials physics with a focus on two-dimensional materials and spin-photodiodes, reinforcing his understanding of electronic and optical properties. This academic progression reflects a continuous commitment to materials physics, enabling him to master both experimental and computational aspects. By integrating materials physics into every phase of his education, Dr.  Tsamo built a versatile foundation for research, combining laboratory precision, theoretical modeling, and a deep appreciation for how materials physics drives technological advances.

Experience 

In his professional journey, Dr. Guy-vano Tsamo has applied materials physics in advanced research environments, particularly in microelectronics and surface analysis. At leading laboratories, his materials physics expertise has been central to projects involving III-V heterostructures, III-nitride nanostructures, and chemical characterization techniques. Through materials physics, he has contributed to optoelectronic and RF component innovation, utilizing XPS, HAXPES, ToF-SIMS, and microscopy tools. His materials physics-based approach ensures precise interface studies, defect analysis, and growth optimization. By combining materials physics theory with practical implementation, Dr. Tsamo has consistently delivered results that push the boundaries of current technologies, making materials physics both his professional signature and his driving force in advancing material science applications.

Research Interest 

Dr. Guy-vano Tsamo’s research interests revolve around materials physics, particularly in the growth, characterization, and analysis of nanoscale and thin-film structures. His work in materials physics spans epitaxial growth, electronic structure analysis, and surface/interface engineering for optoelectronic applications. Within materials physics, he explores III-nitrides, III-V compounds, and two-dimensional materials, aiming to optimize performance for LEDs, detectors, and RF devices. He is passionate about advancing materials physics methodologies, combining spectroscopy, microscopy, and computational modeling. In every project, materials physics provides the conceptual and experimental framework, allowing Dr. Tsamo to connect atomic-scale phenomena to device-scale properties. This deep focus on materials physics ensures his research remains impactful and technologically relevant.

Award and Honor

Dr. Guy-vano Tsamo has earned recognition for his outstanding contributions to materials physics, including prestigious awards for research excellence and scientific communication. His achievements in materials physics have been celebrated in academic and public platforms, highlighting his ability to translate complex materials physics concepts into accessible knowledge. These honors underscore his leadership in advancing materials physics research, from nanoscale fabrication to large-scale applications. Awards in materials physics are not just personal milestones but also affirmations of his broader scientific vision. By excelling in materials physics, Dr. Tsamo continues to inspire peers and future scientists, demonstrating the transformative potential of materials physics in addressing modern technological challenges.

Research Skill

Dr. Guy-vano Tsamo possesses a comprehensive set of skills in materials physics, encompassing epitaxy, spectroscopy, microscopy, and modeling. His materials physics expertise includes operating ultra-high vacuum systems, performing molecular beam epitaxy, and conducting XPS, HAXPES, AR-XPS, and ToF-SIMS analyses. Within materials physics, he also applies atomic force microscopy, low-energy electron diffraction, and image processing tools. His proficiency in materials physics extends to theoretical simulations, data interpretation, and scientific writing. These materials physics skills enable him to design and execute experiments with precision, ensuring reliable results and impactful publications. By mastering both the technical and theoretical aspects of materials physics, Dr. Tsamo stands out as a versatile and innovative researcher.

Publication Top Notes 

Title : Growth Mechanisms of GaN/GaAs Nanostructures by Droplet Epitaxy Explained by Complementary Experiments and Simulations
Authors : Guy-Vano Tsamo; Alla G. Nastovjak; Nataliya L. Shwartz; Philip E. Hoggan; Christine Robert-Goumet; Alberto Pimpinelli; Matthieu Petit; Alain Ranguis; Emmanuel Gardes; Mamour Sall; Luc Bideux; Guillaume Monier
Journal : The Journal of Physical Chemistry C, Volume 128, Issue 12, March 2024

Conclusion

In conclusion, Dr. Guy-vano Tsamo’s career is a testament to the power and versatility of materials physics. Across education, professional experience, research, awards, and publications, materials physics has been the unifying theme guiding his work. His mastery of materials physics techniques and concepts allows him to tackle complex challenges in nanostructure growth, spectroscopy, and device optimization. The continuous application of materials physics principles ensures that his research not only deepens scientific understanding but also contributes to technological advancement. As materials physics evolves, Dr. Tsamo remains committed to exploring new frontiers, proving that the field holds limitless potential for innovation and societal impact.

Ran Wang | Materials Science | Women Researcher Award

Published on by Physicist Particle

Ms. Ran Wang | Materials Science | Women Researcher Award

Student at Beijing Institute of Technology, China

Wang Ran is a dedicated master’s student in Materials Science and Engineering at Beijing Institute of Technology. She completed her undergraduate studies at Shandong University. With a keen interest in absorbing materials, she is committed to advancing research in this field. Though at an early stage in her academic journey, she is eager to contribute to scientific advancements. Wang Ran aspires to explore innovative materials with potential applications in energy absorption and electromagnetic shielding. Her passion for scientific discovery drives her ambition to make significant contributions to materials engineering. She is applying for the Women Research Award or Young Scientist Award. 🌟

Professional Profile 

Education & Experience 📚🔍

  • 🎓 Master’s Degree (Ongoing) – Beijing Institute of Technology, Materials Science and Engineering
  • 🎓 Bachelor’s Degree – Shandong University, Materials Science and Engineering

Professional Development 📖🔬

Wang Ran is in the early stages of her academic career, focusing on developing expertise in absorbing materials. She actively engages in coursework, laboratory experiments, and independent research projects to build a strong foundation in material science. Passionate about innovation, she continuously explores the latest advancements in materials engineering. Though she has not yet published any journals or patents, she is eager to collaborate with experts in her field. Her long-term goal is to contribute groundbreaking research that enhances the performance of absorbing materials in practical applications such as stealth technology and electromagnetic interference shielding. 🚀

Research Focus🏗️🔬

Wang Ran’s research interests lie in the field of absorbing materials, a crucial area in materials science that plays a significant role in energy dissipation, stealth technology, and electromagnetic shielding. She is particularly interested in developing new materials that can efficiently absorb electromagnetic waves and reduce interference in electronic devices. By studying the structural and compositional properties of these materials, she aims to optimize their absorption efficiency and enhance their performance in real-world applications. Her research has potential implications in defense, aerospace, and communication industries, where advanced absorbing materials are essential for improving stealth and signal integrity. 📡🛡️

Awards & Honors 🏆🎖️

  • 🌟 Nominee – Women Research Award (2025)
  • 🌟 Nominee – Young Scientist Award (2025)
  • 🎓 Bachelor’s Degree Completion – Shandong University
  • 📖 Master’s Degree Pursuit – Beijing Institute of Technology

Publication Top Notes

  • “Resonantly pumped acousto-optic Q-switched Er:YAG lasers at 1617 and 1645 nm”

    • Authors: R. Wang, Q. Ye, C. Gao
    • Journal: Applied Optics, 2014
    • Citations: 5
    • Summary:
      • Discusses the development of acousto-optic Q-switched Er:YAG lasers emitting at 1617 nm and 1645 nm.
      • The lasers are resonantly pumped, enhancing efficiency.
      • These wavelengths are valuable for medical, LIDAR, and optical communication applications.

  • “Single-frequency operation of a resonantly pumped 1.645μm Er:YAG Q-switched laser”

    • Authors: R. Wang, Q. Ye, Y. Zheng, M. Gao, C. Gao
    • Type: Conference Paper
    • Citations: 13
    • Summary:
      • Focuses on achieving single-frequency operation of an Er:YAG laser at 1645 nm.
      • Uses resonant pumping and a Q-switching technique for better performance.
      • Suitable for high-precision applications such as spectroscopy and atmospheric sensing.

Conclusion

While Wang Ran shows potential in her research field, she currently lacks the extensive academic contributions and professional engagement necessary to compete for a “Best Researcher” or “Women Researcher” award. She would be a more suitable candidate for a “Young Scientist Award” in the future, provided she enhances her publication record, citations, collaborations, and industry engagement.