Mr. Shewa Getachew Mamo | Best Researcher Award

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Mr. Shewa Getachew Mamo | Best Researcher Award

Wolkite University | Ethiopia

Shewa Getachew is a physicist at Wolkite University with an MSc in Physics and an emerging research profile in plasmonics, nonlinear optics, and nanocomposite photonics. With an h-index of 2, eight indexed documents, and ten citations from four sources, his work focuses on the optical properties of core–shell nanostructures, including refractive index engineering, group velocity modulation, optical bistability, and local field enhancement in metal–dielectric composites. His publications span reputable journals such as Physica E, Brazilian Journal of Physics, Applied Physics B, Optical Review, Canadian Journal of Physics, and The European Physical Journal D. His research explores size-, geometry-, and dielectric-dependent plasmonic responses in nanomaterials, contributing to slow- and fast-light applications, nonlinear optical switching, and photonic device optimization. He has also conducted interdisciplinary studies in phytochemistry and higher education pedagogy. As a physics lecturer, he integrates theoretical modeling with computational simulation to advance understanding of nano-optical phenomena. His contributions were recognized with the World Research Awards (WRA) Best Innovation Award (Physics and Astronomy) in 2024. Overall, his work continues to support the development of advanced photonic materials with tunable optical responses for next-generation nanotechnology applications.

Profiles : Orcid | Scopus

Featured Publications

Getachew, S. (2026). Size and dielectric-dependent plasmonic resonances in CdS@Ag core–shell quantum dots: Field enhancement, dispersion, and slow-light effects. Physica E: Low-Dimensional Systems and Nanostructures. https://doi.org/10.1016/j.physe.2025.116371

Getachew, S. (2025). Size-dependent dispersion and slow-light effects in CdS@Ag core-shell quantum dots: A theoretical study of plasmonic resonances and group velocity modulation. Brazilian Journal of Physics. https://doi.org/10.1007/s13538-025-01906-7

Getachew, S. (2025). Geometric and dielectric engineering of linear optical response in CdS@Ag core–shell quantum dots: A theoretical study of plasmonic enhancement and host effects. Applied Physics B. https://doi.org/10.1007/s00340-025-08578-w

Getachew, S. (2025). Geometric shape’s impact on core-shell nanocomposites’ optical properties. Journal of Computational Electronics. https://doi.org/10.1007/s10825-025-02388-1

Assoc. Prof. Dr. Chao Mei | Best Researcher Award

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Assoc. Prof. Dr. Chao Mei | Best Researcher Award

Ningbo University | China

Chao Mei is an Associate Professor at the School of Physical Science and Technology, Ningbo University, recognized for his significant contributions to nonlinear optics, ultrafast spectroscopy, and strong-field physics. With an h-index of 16, over 600+ citations, and more than 40 peer-reviewed documents, his research has advanced pulse compression, photonic crystal fibers, mid-infrared photonics, and plasmonic sensing technologies. He received strong foundational training in optics and photonics through graduate studies and has accumulated extensive academic and research experience through sustained collaborations across leading photonics laboratories. Dr. Mei’s work integrates theoretical modeling, materials design, and experimental ultrafast photonics, with impactful achievements such as high-temperature hollow-core fiber interferometry, advanced mid-infrared pulse compression, and high-sensitivity plasmonic fiber sensors. His research interests span χ(3) nonlinear processes, supercontinuum generation, silicon-based photonic waveguides, parabolic pulse evolution, fiber-based sensing, and the development of ultrafast light sources. He has contributed to high-impact journals including Journal of Lightwave Technology, Optics Letters, Optics Express, and Physical Review A. Dr. Mei has been recognized through multiple research grants and collaborative project awards that underscore his influence in the field. Overall, his body of work continues to advance next-generation ultrafast photonic devices and integrated nonlinear optical systems.

Profile : Google Scholar

Featured Publications

Liu, D., Wu, Q., Mei, C., Yuan, J., Xin, X., Mallik, A. K., … Han, W. (2018). Hollow core fiber based interferometer for high-temperature (1000° C) measurement. Journal of Lightwave Technology, 36(9), 1583–1590.

Qu, Y., Yuan, J., Zhou, X., Li, F., Mei, C., Yan, B., … Long, K. (2019). A V-shape photonic crystal fiber polarization filter based on surface plasmon resonance effect. Optics Communications, 452, 1–6.

Mei, C., Li, F., Yuan, J., Kang, Z., Zhang, X., Wang, K., … Yan, B. (2016). High degree picosecond pulse compression in chalcogenide-silicon slot waveguide taper. Journal of Lightwave Technology, 34(16), 3843–3852.

Zhang, J., Yuan, J., Qu, Y., Qiu, S., Mei, C., Zhou, X., … Wang, K. (2022). A surface plasmon resonance-based photonic crystal fiber sensor for simultaneously measuring the refractive index and temperature. Polymers, 14(18), 3893.

Prof. Dr. Motoichi Ohtsu | Best Researcher Award

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Prof. Dr. Motoichi Ohtsu | Best Researcher Award

Research Origin for Dressed Photon | Japan

Motoichi Ohtsu is a distinguished researcher in nanophotonics and dressed-photon science, currently affiliated with the Research Origin for Dressed Photon in Yokohama, Japan. His scientific influence is reflected in his extensive Scopus record, which documents 596 publications, 9,084 citations, and an h-index of 47, demonstrating his long-standing impact across photonics and optical materials research. His works span journal articles, conference papers, book chapters, and major monographs, covering themes such as dressed photons, near-field optical science, SiC-based magneto-optical devices, polarization control, and the theoretical foundations connecting dressed photons with off-shell quantum fields. His recent ORCID-listed contributions include Perspective on an Emerging Frontier of Nanoscience Opened up by Dressed Photon Studies, Drastic Advancement in Nanophotonics Achieved by a New Dressed Photon Study, and influential papers on phase delay, polarization rotation, and cosmological links to dressed-photon theory. Ohtsu’s research interests encompass nanophotonics, near-field interactions, magneto-optical effects, optical phase phenomena, and advanced semiconductor photonics. With decades of academic and research leadership, including serving as Chief Director at the Research Origin for Dressed Photon, he has significantly shaped the evolution of modern optical science. In conclusion, his body of work continues to define new directions in dressed-photon technology and next-generation nanophotonic systems.

Profiles : Orcid | Scopus

Featured Publications

Sakuma, H., Ojima, I., & Ohtsu, M. (2023). Perspective on an emerging frontier of nanoscience opened up by dressed photon studies. Nanoarchitectonics.

Sakuma, H., Ojima, I., & Ohtsu, M. (2021). Drastic advancement in nanophotonics achieved by a new dressed photon study. Journal of the European Optical Society Rapid Publications.

Ohtsu, M., et al. (2020). SiC transmission-type polarization rotator using a large magneto-optical effect boosted and stabilized by dressed photons. Scientific Reports.

Ohtsu, M., et al. (2020). Off-shell quantum fields to connect dressed photons with cosmology. Symmetry.

Assist. Prof. Dr. Bhuvneshwer Suthar | Best Researcher Award

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Assist. Prof. Dr. Bhuvneshwer Suthar | Best Researcher Award

Government Dungar College, Bikaner | India

Dr. Bhuvneshwer Suthar is a distinguished physicist known for his impactful contributions to photonic crystals, optical sensors, photonic switching technologies, and advanced metamaterial-based devices. With an impressive research record comprising 110 documents, an h-index of 29, and more than 1,713 citations, he has established a strong scholarly presence in computational photonics and optical engineering. He holds advanced academic qualifications in physics and has accumulated extensive teaching and research experience as an active academic and scientist. His research interests span one-dimensional and two-dimensional photonic crystals, optical filters, biosensing mechanisms, temperature sensors, terahertz photonics, and waveguide-integrated photonic devices. Dr. Suthar’s work has led to notable advancements in ultra-compact optical components, defect-mode engineering, and high-sensitivity biosensors for biomedical and environmental applications. He has collaborated widely and contributed to several international conferences and editorial activities within the photonics community. His achievements include recognition for high-quality research outputs and influential publications that continue to support innovations in photonic device design. In conclusion, Dr. Suthar stands as a highly productive researcher whose scientific contributions significantly advance modern photonic technologies and inspire continued progress in optical sensing and photonic crystal engineering.

Profiles : Google ScholarScopus

Featured Publications

Ankita, & Suthar, B., & Bhargava, A. (2021). Biosensor application of one-dimensional photonic crystal for malaria diagnosis. Plasmonics, 16(1), 59–63.

Kumar, N., & Suthar, B. (2019). Advances in photonic crystals and devices. CRC Press.

Radhouene, M., Chhipa, M. K., Najjar, M., Robinson, S., & Suthar, B. (2017). Novel design of ring resonator based temperature sensor using photonics technology. Photonic Sensors, 7(4), 311–316.

Gharsallah, Z., Najjar, M., Suthar, B., & Janyani, V. (2018). High sensitivity and ultra-compact optical biosensor for detection of urea concentration. Optical and Quantum Electronics, 50(6), 249.

Suthar, B., & Bhargava, A. (2021). Pressure sensor based on quantum well-structured photonic crystal. Silicon, 13(6), 1765–1768.

Dr. Jian Lei | Editorial Board Member

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Dr. Jian Lei | Editorial Board Member

Chongqing Three Gorges Medical College | China

Dr. Jian Lei is a promising researcher in organic optoelectronic materials with a PhD in Chemistry from National Tsing Hua University, where he specialized in advanced molecular engineering for high-performance organic emitters. He currently serves at Chongqing Three Gorges Medical College, contributing to research and foundational science education. Dr. Lei has established a strong publication record, with an h-index of 21, more than 20 research documents, and over 240 citations. His work focuses on thermally activated delayed fluorescence (TADF), azepine-modulated emitters, multiple-resonance molecular systems, and strategies for suppressing nonradiative decay to achieve efficient, stable, and narrowband OLED emission. He has authored impactful papers in top-tier journals such as Materials Horizons, Chemical Science, ACS Materials Letters, JACS Au, and The Journal of Physical Chemistry C. His contributions include breakthroughs in azepine engineering, high-EQE blue OLEDs, and molecular strategies for boosting afterglow and upconversion performance. Although early in his career, his rapidly growing citation record and consistent publications underscore his rising influence in materials chemistry and optoelectronic device research. In conclusion, Dr. Lei is an emerging scientist whose innovative molecular designs hold strong potential for advancing next-generation OLED technologies.

Profile : Orcid

Featured Publications

Chen, Y.-K., Lei, J., Chao, Y.-C., Kung, Y.-C., Hung, W.-Y., Hsu, L.-Y., & Wu, T.-L. (2025). Strategic azepine engineering realizes highly efficient and stable blue narrowband light-emitting diodes. Materials Horizons.

Lei, J., Chen, Y.-K., Wang, M.-J., Ko, C.-L., Hung, W.-Y., Hsu, L.-Y., Cheng, C.-H., & Wu, T.-L. (2025). Azepine modulation in thermally activated delayed fluorescence emitters for OLEDs achieving nearly 40% EQE. ACS Materials Letters.

Liu, P.-C., Lei, J., Liu, C.-C., Fan, Y.-T., & Wu, T.-L. (2025). Rational molecular design for boosting afterglow efficiency in nonplanar carbazolocarbazoles. JACS Au.

Chen, Y.-K., Lei, J., & Wu, T.-L. (2024). Elevating the upconversion performance of a multiple resonance thermally activated delayed fluorescence emitter via an embedded azepine approach. Chemical Science.

Lei, J., Chang, C.-W., Chen, Y.-K., Chou, P.-Y., Hsu, L.-Y., Cheng, C.-H., & Wu, T.-L. (2024). Strategy of modulating nonradiative decay for approaching efficient thermally activated delayed fluorescent emitters. The Journal of Physical Chemistry C.

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.

Dr. Ashish Varma | Young Scientist Award

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Dr. Ashish Varma | Young Scientist Award

K. N. Government P. G. College, Gyanpur, Bhadohi | India

Dr. Ashish Varma is an accomplished physicist and Assistant Professor at K. N. Government P. G. College, Gyanpur, Bhadohi, India. He earned his Ph.D. in Physics from the University of Allahabad in 2022 and has established himself as an emerging researcher in plasma physics, laser–matter interaction, and nanostructured materials. With 31 publications, over 447 citations from 117 documents, and an h-index of 13, Dr. Varma’s work demonstrates significant impact in nonlinear laser-plasma interactions, electron Bernstein wave excitation, and nanocluster plasma dynamics. His recent studies focus on laser beam–assisted plasma heating, surface plasma wave generation, and nonlinear absorption in arrays of vertically aligned carbon nanotubes. Dr. Varma has contributed to leading journals such as Optik, Laser Physics, Journal of the Korean Physical Society, and Optical and Quantum Electronics. He has also explored computational condensed matter physics, investigating electronic, structural, and optical properties of advanced materials. A recipient of the UGC Junior Research Fellowship (JRF), he continues to advance fundamental understanding of laser-plasma coupling phenomena with applications in photonics and nanotechnology. Through his active research, Dr. Varma is contributing to the development of next-generation optical and plasma-based materials and technologies.

Profile: Google Scholar | Orcid | Scopus

Featured Publications

Varma, A., Kumar, A., Mishra, S. P., Kumar, A., & Kumar, A. (2025). Surface plasma wave aided Laguerre–Gaussian laser beam second harmonic generation in arrays of vertically aligned carbon nanotube over metal surface. Journal of Laser Applications, 37(8), 7–12. https://doi.org/10.2351/7.0001819

Vishwakarma, M. K., Mishra, S. P., Kumar, A., Kumar, A., & Varma, A. (2025). Enhanced electron heating by electron plasma wave assisted beat wave of two different profile laser beams in magnetized collisional plasma with density rippled. Journal of the Korean Physical Society, 86(7), 1–8. https://doi.org/10.1007/s40042-025-01446-y

Ali, K., Kumar, S., Kumar, A., & Varma, A. (2025). Influence of field optimization property of Hermite cosh-Gaussian laser beam on nonlinear absorption in arrays of vertically aligned cylindrical carbon nanotubes. Radiation Effects and Defects in Solids, 180(4), 245–259. https://doi.org/10.1080/10420150.2025.2484740

Ansari, A., Patel, M. S., Mishra, S. P., Kumar, A., Kumar, A., & Varma, A. (2025). Excitation of large-amplitude electron plasma wave by counterpropagation of two laser beams in spherical nanoparticles. Laser Physics, 35(4), 046001. https://doi.org/10.1088/1555-6611/adc559

Kumar, S., Ali, K., Kumar, A., Kumar, A., Mishra, S. P., & Varma, A. (2025). Langmuir wave-assisted two-photon decay of an amplitude-modulated Gaussian laser beam in rippled density plasma. Arabian Journal for Science and Engineering, 50(1), 112–122. https://doi.org/10.1007/s13369-024-09234-9

Prof. Afzal S. M. | Best Researcher Award

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Prof. Afzal S. M. | Best Researcher Award

Physics Department, Aligarh Muslim University | India

Prof. S. M. Afzal is a Professor of Physics at Aligarh Muslim University, India, with over 25 years of experience in teaching and research. He obtained his Ph.D. in Physics from Aligarh Muslim University in 1997, specializing in atomic and laser spectroscopy. His research focuses on high-resolution spectroscopy, nonlinear optics, photonic materials, and optoelectronic applications. Prof. Afzal has made significant contributions to the development of experimental facilities and has conducted extensive studies on light–matter interactions using advanced laser and optical techniques. He has published more than 54 research papers in reputed international journals, achieving over 542 citations, an h-index of 12, and an i10-index of 17, reflecting the strong impact of his scholarly work. In addition, he has successfully completed five funded research projects and guided more than twenty postgraduate theses. His work integrates experimental and computational approaches for exploring nonlinear optical properties of organic and inorganic systems, contributing to advancements in photonics and laser technology. Through his dedicated research and mentorship, Prof. Afzal continues to play a vital role in advancing modern optical physics and inspiring the next generation of scientists.

Profiles : Research GateGoogle Scholar

Featured Publications

El-Shishtawy, R. M., Al-Zahrani, F. A. M., Afzal, S. M., Razvi, M. A. N., & Al-amshany, Z. M. (2016). Synthesis, linear and nonlinear optical properties of a new dimethine cyanine dye derived from phenothiazine. RSC Advances, 6(94), 91546–91556.

Kamaal, S., Mehkoom, M., Ali, A., Afzal, S. M., Alam, M. J., Ahmad, S., & Ahmad, M. (2021). Potential third-order nonlinear optical response facilitated by intramolecular charge transfer in a simple Schiff base molecule: Experimental and theoretical exploration. ACS Omega, 6(9), 6185–6194.*

Khan, S. A., Razvi, M. A. N., Bakry, A. H., Afzal, S. M., Asiri, A. M., & El-Daly, S. A. (2015). Microwave assisted synthesis, spectroscopic studies and nonlinear optical properties of bis-chromophores. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 137, 685–692.*

Fatima, A., Ali, A., Shabbir, S., Khan, M., Mehkoom, M., Afzal, S. M., Ahmad, M., & Ahmad, S. (2022). Synthesis, crystal structure, characterization, Hirshfeld analysis, molecular docking and DFT calculations of 5-phenylamino-isophthalic acid: A good NLO material. Journal of Molecular Structure, 132791.

Mehkoom, M., Afzal, S. M., Ahmad, S., & Khan, S. A. (2021). Physicochemical and nonlinear optical properties of novel environmentally benign heterocyclic azomethine dyes: Experimental and theoretical studies. PLOS ONE, 11(9), e0161613.*

Assist. Prof. Dr. Fikadu Geldasa | Best Researcher Award

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Assist. Prof. Dr. Fikadu Geldasa | Best Researcher Award

Walter Sisulu University | South Africa

Dr. Fikadu Takele Geldasa is an Assistant Professor of Physics at Walter Sisulu University, South Africa, and Oda Bultum University, Ethiopia. He has published 19 Scopus-indexed research papers, received more than 323 citations, and holds an h-index of 6. He obtained his Ph.D. in Materials Physics from Adama Science and Technology University. His research focuses on experimental and computational studies of functional nanomaterials using density functional theory (DFT) and materials characterization techniques. Dr. Geldasa works on the structural, electronic, and optical properties of doped metal oxides, perovskites, and semiconductor materials for applications in photocatalysis, energy conversion, and environmental remediation. His recent works on doped TiO₂ and α-NiS nanostructures provide insights into bandgap engineering and defect tuning for enhanced visible-light photocatalytic activity. He has published his research in leading journals such as Scientific Reports, Nanomaterials, Materials, and Physica Scripta. His interdisciplinary research integrates theory and experiment to develop advanced materials for renewable energy and sustainable technology. Through his scientific contributions, Dr. Geldasa is establishing himself as a promising researcher in materials physics and computational materials science, contributing significantly to the progress of clean energy and environmental technologies.

Profiles : ScopusOrcid | Research GateGoogle Scholar

Featured Publications

Geldasa, F. T., Dejene, F. B., Kebede, M. A., Hone, F. G., & Jira, E. T. (2025). Density functional theory study of chlorine, fluorine, nitrogen, and sulfur doped rutile TiO₂ for photocatalytic application. Scientific Reports, 15(1), 3390. https://doi.org/10.1038/s41598-024-84316-0

Geldasa, F. T., & Dejene, F. B. (2025). Transition metal doping effects on the structural, mechanical, electronic, and optical properties of α-NiS for photocatalysis applications via DFT + U insights. Applied Physics A. https://doi.org/10.1007/s00339-025-08942-9

Geldasa, F. T., & Dejene, F. B. (2025). First principles investigation of niobium and carbon-doped titanium dioxide for enhanced visible light photocatalytic activity. ChemistrySelect. https://doi.org/10.1002/slct.202504529

Geldasa, F. T., & Dejene, F. B. (2025). Exploration of vanadium and rhenium co-doped TiO₂ for enhanced photocatalytic performance via first principle density functional theory investigation. Physica Scripta. https://doi.org/10.1088/1402-4896/adf156

Geldasa, F. T., & Dejene, F. B. (2025). Density functional theory based exploration of structural, electronic, mechanical, thermodynamic, and optical properties of α-NiS for CO₂ adsorption. Journal of Physics: Condensed Matter. https://doi.org/10.1088/1361-648X/aded5f

Mr. Weijiang Xu | Best Researcher Award

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Mr. Weijiang Xu | Best Researcher Award

Guilin University of Electronic Technology | China

Dr. Weijiang Xu is a Lecturer at the School of Optoelectronic Engineering, Guilin University of Electronic Technology. He earned his Doctor of Science (2024) and Master of Science (2018) in Physics from Harbin Institute of Technology, following his Bachelor’s degree from Lingnan Normal University in 2016. His research centers on optical fiber sensors, quantum dot photonics, and upconversion luminescence for multifunctional sensing applications. Dr. Xu has authored 17 scientific documents with over 120 citations and maintains an h-index of 8, reflecting his growing influence in the field of optical materials and photonic sensing. His representative works, published in leading journals such as Optics Express, Optics Letters, Journal of Lightwave Technology, and Optics Communications, explore innovative fiber-based devices for temperature, curvature, and flow sensing. He has also contributed to the development of several patented optical fiber sensing technologies in China. Dr. Xu’s recent advancements include bubble-tunable and calibration-free optical fiber sensors employing quantum dots-filled liquid cores. His research continues to bridge nanomaterials with optical engineering for advanced environmental and biomedical sensing. With a record of impactful publications and technological innovation, Dr. Xu is emerging as a promising scholar in the field of optoelectronic sensing.

Profile :  Scopus 

Featured Publications

Xu, W., Li, Y., Shang, J., Wang, Y., Hou, L., Liu, Y., & Qu, S. (2022). Optical fiber sensor based on upconversion luminescence for synchronous temperature and curvature sensing. Optics Express, 30(18), 33136–33136.

Xu, W., Qu, J., Liu, Y., Bai, J., Li, Y., & Qu, S. (2023). Optical fiber inclinometer with dynamically controllable excitation length of quantum dots liquid-core waveguide based on a photo-controlled bubble. Optics Letters, 48(6), 1403–1406.

Xu, W., Qu, J., Liu, Y., Bai, J., Li, Y., & Qu, S. (2023). A calibration-free fiber sensor based on CdZnSe/ZnSe/ZnS quantum dots for real-time monitoring of human thermal activities. Measurement, 206, 112315.

Xu, W., Liu, Y., Li, Y., & Qu, S. (2024). Horizontal clinometer based on a movable bubble in the arc-shaped quantum dots liquid cavity. Journal of Lightwave Technology, 42(6), 2193–2199.

Qu, J., Zhang, Y., Ling, M., & Xu, W.* (2025). Heat-typed fiber liquid flow sensor with wide sensing range and high sensitivity. Journal of Lightwave Technology, 43(1), 369–375.