Władysław Papacz | Engineering | Research Excellence Award

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Prof. Dr. Władysław Papacz | Engineering | Research Excellence Award

University of Zielona Góra | Poland

Prof. Dr. Władysław Papacz is a researcher affiliated with Uniwersytet Zielonogórski, Poland, specializing in materials engineering, recycling technologies, and sustainable material development. With 10 publications, 27 citations, and an h-index of 3, he has contributed to applied research on the mechanical properties of recycled materials, particularly in transforming industrial cable waste into usable engineering products. His work integrates experimental analysis with sustainability-focused approaches, supporting the advancement of circular economy practices. Collaborating with a network of co-authors, his research holds societal significance by promoting resource efficiency, reducing environmental waste, and contributing to the development of eco-friendly engineering materials and sustainable industrial solutions.

Citation Metrics (Scopus)

27
20
15
10
0

Citations

27

Documents

10

h-index

3

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Documents

h-index

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Nazish Abid | Engineering | Research Excellence Award

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Dr. Nazish Abid | Engineering | Research Excellence Award

Lecturer | University of Bahrain | Bahrain

Dr. Abid, Nazish is a researcher affiliated with the University of Bahrain, Zallaq, Bahrain, with expertise in social sciences, urban studies, and the analysis of public spaces. With 14 scholarly publications and 30 citations, the researcher has established a growing academic profile, reflected in an h-index of 3. Their work emphasizes the intersection of built environments and societal dynamics, including recent contributions on public open spaces in academic campuses. Actively engaged in collaborative research with international co-authors, Abid’s studies contribute to sustainable urban development and community well-being, demonstrating a commitment to addressing real-world societal challenges through evidence-based research.

Citation Metrics (Scopus)

30
20
10
5
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Citations

30

Documents

14

h-index

3

Citations

Documents

h-index

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Samyar Sarraf | Engineering | Young Innovator Award

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Dr. Samyar Sarraf | Engineering | Young Innovator Award

Lab Assistant | Sharif University of Technology | Iran

Dr. Samyar Sarraf is a Ph.D. graduate in Mechanical Engineering from Sharif University of Technology, with recognized expertise spanning offshore and marine engineering, civil engineering, and applied hydrodynamics. His research focuses on experimental and numerical investigation of squat submarine hydrodynamic performance and ship–submarine interactions, with multiple peer-reviewed publications in the high-impact journal Ocean Engineering. He has authored several scholarly works, accumulating 16 citations and an h-index of 2, reflecting a growing research influence. In addition to marine hydrodynamics, his interdisciplinary contributions include innovative solutions in geotechnical and earthquake engineering, such as the development of an underground earthquake isolation system and advanced dynamic soil modeling methods. His work demonstrates strong experimental rigor, numerical proficiency, and collaborative engagement with multidisciplinary research teams, offering practical societal impact in maritime safety, offshore operations, and resilient infrastructure design at an international level.

Citation Metrics (Scopus)

16
12
8
4
0

Citations

16

h-index

2

Citations

h-index

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Yao Ni | Engineering | Editorial Board Member

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Dr. Yao Ni | Engineering | Editorial Board Member

Researcher | Guangdong University of Technology | China

Dr. Ni Yao is a distinguished researcher at the Guangdong University of Technology, Guangzhou, China, widely recognized for his contributions to advanced materials, neuromorphic engineering, and intelligent sensing–processing systems. With an interdisciplinary focus spanning materials science, flexible electronics, artificial intelligence hardware, and intelligent control mechanisms, his research advances next-generation photonic synaptic transistors, in-sensor reservoir computing architectures, and flexible neuromorphic devices capable of multidimensional shape morphing. Dr. Yao has authored 65 peer-reviewed publications, achieved 1,679 citations, and maintains an h-index of 23, reflecting the depth, continuity, and global influence of his scholarly work. His recent high-impact contributions include crystallized conjugated polymer-based photonic synaptic transistors, paper-based perovskite artificial neuromorphic retinas, free shape-morphing neuromorphic devices published in Nature Communications, as well as novel methodologies for industrial control deadlock avoidance, frequency-aware transformers for pipeline leak detection, and symmetric optimization models for delivery duration forecasting. Engaging in collaborations with over 160 co-authors, Dr. Yao actively contributes to multidisciplinary research communities, promoting scientific advancement across materials innovation, industrial automation, computational sensing, and AI-driven systems engineering. His work delivers broad societal impact by enabling energy-efficient intelligent devices, enhancing autonomous perception capabilities, and driving innovations that support safer, more sustainable, and technologically advanced industrial ecosystems. Through continuous innovation, rigorous scholarship, and extensive international collaboration, Dr. Ni Yao remains at the forefront of shaping future directions in intelligent materials, neuromorphic computing, and integrated sensing technologies.

Profiles: Scopus | ORCID | ResearchGate

Featured Publications

1. Wei, H., Yang, J., Fu, C., Li, Z., Ni, Y., Wang, B., He, B., Jiang, S., & He, G. (2025). ALD-driven ultra-thin ZnO channels for flexible electrolytic neuromorphic devices. IEEE Electron Device Letters.

2. Ni, Y., Zhang, Y., Lin, J., Liu, X., Yu, Y., Liu, L., Zhong, W., Chen, Y., Chen, R., Kwok, H. S., et al. (2025). Transistor-structured artificial dendrites for spatiotemporally correlated reservoir computing. IEEE Electron Device Letters.

3. Guan, X., Wu, W., & Ni, Y. (2025). A novel methodology to deadlock analysis and avoidance for automatic control systems based on Petri Net. Processes, 13(10).

4. Chen, M., Lu, Y., Wu, W., Ye, Y., Wei, B., & Ni, Y. (2025). Multi-scale frequency-aware transformer for pipeline leak detection using acoustic signals. Sensors, 25(20).

5. Ji, Z., Liu, J., He, Y., Yang, H., Zhang, L., Guan, S., Ni, Y., & Wu, T. (2025). Stretchable synaptic device with photonic–electric dual mode for sign language recognition. Advanced Materials Technologies

Farouk Zouari | Engineering | Editorial Board Member

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Assist. Prof. Dr. Farouk Zouari | Engineering | Editorial Board Member

Ecole Nationale d’Ingénieurs de Tunis | Tunisia

Dr. Farouk Zouari is a distinguished researcher at Université de Tunis El Manar, Tunisia, known for his significant contributions to control systems engineering and intelligent autonomous technologies. His research encompasses neural network–based adaptive control, nonlinear optimal control, MIMO systems, time-varying delay systems, and finite-time fuzzy synchronization of fractional-order and chaotic systems, with a strong focus on bridging theoretical advancements and real-world applications in automation, robotics, and intelligent transportation. Over his career, Dr. Zouari has produced 37 peer-reviewed publications and established a solid scholarly presence supported by 735 citations and an h-index of 17, indicating substantial impact and sustained relevance in his field. His recent works spanning robust adaptive output feedback control for time-delay MIMO systems, optimal control strategies for multi-axle autonomous vehicles, and chattering-free synchronization methods demonstrate his commitment to addressing emerging engineering challenges. With collaborations involving 30 co-authors, Dr. Zouari actively contributes to interdisciplinary progress, fostering innovation across global research communities. His work continues to support the advancement of intelligent control methodologies and their integration into next-generation dynamic and autonomous systems, contributing to both technological development and societal benefit.

Profiles: Google Scholar | Scopus | ORCID

Featured Publications

1. Zouari, F., Ibeas, A., Boulkroune, A., Cao, J., & Arefi, M. M. (2018). Adaptive neural output-feedback control for nonstrict-feedback time-delay fractional-order systems with output constraints and actuator nonlinearities. Neural Networks, 105, 256–276. Cited by: 82

2. Zouari, F., Ibeas, A., Boulkroune, A., Cao, J., & Arefi, M. M. (2021). Neural network controller design for fractional-order systems with input nonlinearities and asymmetric time-varying pseudo-state constraints. Chaos, Solitons & Fractals, 144, Article 110742. Cited by: 65

3. Boubellouta, A., Zouari, F., & Boulkroune, A. (2019). Intelligent fuzzy controller for chaos synchronization of uncertain fractional-order chaotic systems with input nonlinearities. International Journal of General Systems, 48(3), 211–234. Cited by: 65

4. Zouari, F., Boulkroune, A., & Ibeas, A. (2017). Neural adaptive quantized output-feedback control-based synchronization of uncertain time-delay incommensurate fractional-order chaotic systems with input nonlinearities. Neurocomputing, 237, 200–225. Cited by: 64

5. Zouari, F., Ibeas, A., Boulkroune, A., Cao, J., & Arefi, M. M. (2019). Neuro-adaptive tracking control of non-integer order systems with input nonlinearities and time-varying output constraints. Information Sciences, 485, 170–199. Cited by: 56

Yong Xu | Engineering | Research Excellence Award

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Mr. Yong Xu | Engineering | Research Excellence Award

Associate Researcher | Aerospace Technology Institute of CARDC | China

Dr. Yong Xu is a researcher specializing in intelligent sensing, autonomous systems, and advanced signal processing, with a particular focus on drone vision systems and radar-based environmental perception. His research integrates computer vision, machine learning, and adaptive signal normalization techniques to enhance the reliability, efficiency, and resilience of autonomous aerial and maritime systems in complex real-world environments. Dr. Xu has authored several high-impact publications, including An Air-to-Ground Visual Target Persistent Tracking Framework for Swarm Drones (Automation) and Adaptive Clustering-Based Marine Radar Sea Clutter Normalization (Journal of Sensors), showcasing his expertise in persistent target tracking, swarm coordination, and environmental noise reduction. These works demonstrate his ability to bridge theoretical innovation with practical engineering solutions, improving both sensor performance and system-level autonomy. Throughout his career, Dr. Xu has collaborated extensively with interdisciplinary teams, including researchers such as Shuai Guo, Hongtao Yan, An Wang, Tao Jia, Dong Cao, Pengyu Guo, Yue Ma, Tian Yao, and Jaime Lloret, highlighting his strong engagement in international and cross-institutional research. His contributions support real-world applications in autonomous drone navigation, maritime surveillance, environmental monitoring, and defense technologies, promoting safer and more efficient operational systems. By advancing methodologies for persistent tracking and adaptive radar signal processing, Dr. Xu’s research contributes significantly to the fields of robotics, unmanned systems, and intelligent sensing, offering societal benefits in areas such as public safety, disaster monitoring, and infrastructure protection, while reinforcing the development of next-generation autonomous technologies on a global scale.

Profile: ORCID

Featured Publications

1. Xu, Y., Guo, S., Yan, H., Wang, A., Ma, Y., Yao, T., & Song, H. (2025). An Air‑to‑Ground Visual Target Persistent Tracking Framework for Swarm Drones. Automation, 6(4), 81. https://doi.org/10.3390/automation6040081 MDPI

2. Xu, Y., Jia, T., Cao, D., Guo, P., Ma, Y., & Yan, H. (2021). Adaptive Clustering‑Based Marine Radar Sea Clutter Normalization. Journal of Sensors, 2021, Article 2938251 (11 pages). https://doi.org/10.1155/2021/2938251

Jia Jinlong | Engineering | Research Excellence Award

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Assoc. Prof. Dr. Jia Jinlong | Engineering | Research Excellence Award

Head of the Mining Department | Wuhan Institute of Technology | China

Dr. Jinlong Jia is a researcher at the Lanzhou Institute of Technology, China, specializing in coal engineering, gas extraction technologies, and energy-related geomechanics with a focus on improving safety, efficiency, and sustainability in coal mining operations. With 24 scientific publications, 434 citations, and an h-index of 12, he has established a strong research profile in the fields of coal pore structure evolution, borehole optimization, and fluid–rock interactions under complex geological conditions. His recent work includes developing numerical simulation models to quantitatively evaluate effect factors in multi-branch pinnate borehole gas extraction in high-gas thick coal seams, and investigating the influence of CO₂–H₂O interaction time on coal pore morphology and water migration, published in Energy and already earning citations for its contributions to clean energy and mine safety. Dr. Jia’s research integrates computational modeling, experimental coal chemistry, and engineering applications to address critical challenges in methane extraction, gas-solid coupling mechanisms, and geological hazard prevention. Over his career, he has collaborated with more than 67 co-authors, demonstrating extensive engagement in multidisciplinary and multi-institutional research teams working across geology, mining engineering, and energy science. His findings contribute to national and global efforts toward safer mining environments, enhanced gas utilization, reduced greenhouse gas emissions, and improved resource recovery efficiency. Through advancing both theoretical understanding and practical solutions in coalbed methane extraction and pore-scale mechanisms, Dr. Jia continues to play a significant role in supporting sustainable energy development and improving engineering practices within the mining and geoscience sectors.

Profile: Scopus 

Featured Publications

Zhu, X., Jia, J., Zhang, L., Ma, Z., Qin, Z., Zhang, H., & Liu, Z. (2025). Study on the numerical simulation model for quantitative evaluation on effect factors of multi‑branch pinnate borehole gas extraction in high‑gas thick coal seams. Himalayan Geology, 46(2), 125–135.

Xu, H., Hu, J., Liu, H., Ding, H., Zhang, K., Jia, J., Fang, H., & Gou, B. (2024). Effect of the interaction time of CO₂–H₂O on the alterations of coal pore morphologies and water migration during wetting. Energy, 294, Article 130944. https://doi.org/10.1016/j.energy.2024.130944

Sümeyye Sınır | Engineering | Research Excellence Award

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Dr. Sümeyye Sınır | Engineering | Research Excellence Award

Lecturer | İzmir Katip Çelebi University | Turkey

Dr. Sümeyye Sınır is a researcher at İzmir Kâtip Çelebi University in Izmir, Turkey, specializing in applied mechanics, nonlinear systems, and fractional calculus, with a focus on developing innovative mathematical and computational methods for analyzing complex dynamical behaviors. She has authored 3 peer-reviewed publications, which have collectively received 63 citations, and holds an h-index of 2, reflecting her emerging influence in the field of applied mechanics and nonlinear dynamics. Among her notable contributions is the development of a general solution procedure for nonlinear single-degree-of-freedom systems incorporating fractional derivatives, providing critical insights for engineering applications, physics modeling, and mechanical system simulations. Dr. Sınır actively collaborates with colleagues across mathematics, engineering, and computational mechanics, demonstrating a commitment to interdisciplinary research and advancing methodologies that bridge theoretical developments with practical applications. Her work enhances the understanding and prediction of complex nonlinear behaviors, supporting innovations in structural engineering, robotics, energy systems, and other technologically relevant domains. Through her research, she contributes to improved simulation accuracy, efficient system design, and the development of tools that address real-world engineering challenges, translating theoretical insights into tangible societal benefits. Committed to scientific rigor, innovation, and collaboration, Dr. Sınır continues to expand her research portfolio, strengthen academic partnerships, and advance methodologies in nonlinear mechanics, promoting both the theoretical foundation and applied solutions in engineering and physics, while fostering technological progress and contributing to the broader scientific community through impactful research and interdisciplinary engagement.

Profiles: Google Scholar | Scopus | ResearchGate

Featured Publications

1. Sınır, S., Çevik, M., & Sınır, B. G. (2018). Nonlinear free and forced vibration analyses of axially functionally graded Euler-Bernoulli beams with non-uniform cross-section. Composites Part B: Engineering, 148, 123–131. (Cited by 76)

2. Sınır, S., Yıldız, B., & Sınır, B. G. (2021). Approximate solutions of nonlinear pendulum with fractional damping. In 5th International Students Science Congress Proceedings Book (p. 295). (Cited by 3)

3. Sınır, S., & Çevik, M. (2013). Taylor matrix solution of Euler-Bernoulli beam equation subjected to static loads. In Proceedings of the Fourth International Conference on Mathematical and …. (Cited by 3)

4. Sınır, S., Yıldız, B., & Sınır, B. G. (2025). A general solution procedure for nonlinear single degree of freedom systems including fractional derivatives. International Journal of Non-Linear Mechanics, 169, 104966. (Cited by 2)

5. Küzün, D., Yıldız, B., & Sınır, S. (2023). Euler-Bernoulli beam with fractional viscoelastic boundary conditions. 18. UBAK Kongresi. (Cited by 1)

Nokulunga Xolile Mashwama | Engineering | Best Researcher Award

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Prof. Nokulunga Xolile Mashwama | Engineering | Best Researcher Award

Head of Department | Walter Sisulu University | South Africa

Prof. Nokulunga Xolile Mashwama is a South African Associate Professor and registered Quantity Surveyor (SACPCMP-A426/2014 & SACQSP-IT6878) with a distinguished academic and professional trajectory in construction management, dispute resolution, and sustainable infrastructure delivery. She earned her Ph.D. in Quantity Surveying from the University of Johannesburg in 2021, following a Master’s in Construction Management (2016, Distinction) and a B-Tech in Quantity Surveying (2013) from the same institution, demonstrating a consistent record of academic excellence. Professionally, Dr. Mashwama has engaged in extensive research projects locally and internationally, including JSPS-SA Bilateral and Thuthuka Fund initiatives, contributing significantly to improving service delivery, occupational health and safety, and minimizing construction disputes in Southern Africa. Her research interests encompass construction dispute resolution, public-private partnerships, cost of poor quality, stakeholder management, and sustainable construction practices. She possesses advanced research skills in project evaluation, stakeholder analysis, alternative dispute resolution, occupational health and safety assessment, and infrastructure service delivery analysis. Dr. Mashwama has published over 32 high-quality documents in reputed international journals and conference proceedings, including Springer, IEOM, Procedia Engineering, and Scopus-indexed outlets, presenting her work in global forums across the USA, UK, Europe, and Africa. She has demonstrated leadership through mentorship, community engagement, and active participation in professional bodies such as SACQSP, SACPCMP, IEEE, and Thuthuka-funded initiatives. Her awards and honors include competitive research grants such as the African Research Funding Accelerator and Future Professor Programme, reflecting her scholarly impact and professional recognition. Through her sustained contributions to research, education, and professional practice, Dr. Mashwama is positioned to lead high-impact, internationally recognized projects in construction management, sustainable infrastructure, and stakeholder-driven research, fostering knowledge transfer and innovation in the built environment globally. Her academic influence is supported by 106 citations across 32 documents, with an h-index of 5.

Profiles: Scopus | ORCID

Featured Publications

  1. Mashwama, N. X., & Madubela, B. (2025). Harnessing technology and research innovations for sustainable educational development in Southern Africa. E-Journal of Humanities, Arts and Social Sciences, 2025, Article 647.

  2. Mashwama, N. X. (2025). Innovations in pedagogy and technology for engineering education: A systematic review. Interdisciplinary Journal of Education Research, 7(S1), Article 10.

  3. Mashwama, N. X., & Thwala, D. W. (2025). Educational institutions as catalysts for economic growth in South Africa. E-Journal of Humanities, Arts and Social Sciences, 2025, Article 643.

  4. Mashwama, N. X., Dywili, S., Phaladi, G., & Aigbavboa, C. (2023). The learning curve and benefit of artificial intelligence for the built environment. In Human Interaction & Emerging Technologies (IHIET 2023): Artificial Intelligence & Future Applications (pp. 31).

  5. Mashwama, N. X. (2022). A theoretical assessment of causes for deferred maintenance of public buildings in developing countries: The Kingdom of Eswatini. In 12th International Conference on Construction in the 21st Century (pp. 16–19).

Guozhen Liang | Engineering | Best Researcher Award

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Prof. Guozhen Liang | Engineering | Best Researcher Award

Professor at Wuhan University, China

Prof. Guozhen Liang is a distinguished expert in optics, photonics, and laser technologies, currently serving as a professor at the School of Electronic Information, Wuhan University. He earned his Ph.D. in Electrical and Electronic Engineering from Nanyang Technological University, Singapore, in 2015, following a B.S. in Physics from the University of Science and Technology of China. His research spans quantum cascade lasers, mid-infrared photonics, integrated modulators, and LiDAR systems. With over 2,100 citations and an h-index of 17, his work has been featured in top-tier journals such as Nature Photonics and Materials Today. He has held research positions at Columbia University and KLA-Tencor, contributing to global innovations in laser systems. Prof. Liang also holds multiple U.S. patents, reflecting his strength in both academic and applied research. His career demonstrates a commitment to advancing photonic technologies with strong potential for leadership in international research and interdisciplinary collaboration.

Professional Profile 

Education🎓

Prof. Guozhen Liang has a strong academic background rooted in two of the world’s leading institutions. He earned his Bachelor of Science degree in Physics from the University of Science and Technology of China (USTC) in 2010, a university renowned for its rigorous scientific training and research excellence. Driven by a passion for photonics and laser technologies, he pursued his doctoral studies at Nanyang Technological University (NTU), Singapore, where he obtained his Ph.D. in Electrical and Electronic Engineering in 2015. During his Ph.D., he focused on the development of terahertz quantum cascade lasers and advanced photonic systems, laying the groundwork for his future research career. His educational journey combined strong theoretical foundations with hands-on experimental research, enabling him to transition seamlessly into high-impact roles in academia and industry. This solid and internationally recognized educational background continues to support his research contributions and leadership in the fields of optics and optoelectronics.

Professional Experience📝

Prof. Guozhen Liang has amassed a diverse and impactful professional experience across top-tier academic institutions and industry leaders in photonics. He is currently a Professor at the School of Electronic Information, Wuhan University (since May 2024), where he leads research in optics and laser technologies. Prior to this, he served as a Laser Research Scientist in the CTO group at KLA-Tencor Singapore (2019–2024), focusing on the development of high-power, highly stable DUV–VUV solid-state lasers for industrial applications. From 2017 to 2019, he was a Postdoctoral Research Scientist at Columbia University, working on silicon photonics and LiDAR technologies. His early postdoctoral and project officer roles at Nanyang Technological University (2014–2017) involved pioneering work on mid-infrared and terahertz quantum cascade lasers. His blend of academic and industrial experience positions him as a well-rounded researcher with deep technical expertise and a strong record of innovation in optoelectronic systems.

Research Interest🔎

Prof. Guozhen Liang’s research interests lie at the forefront of optics, photonics, and laser technologies, with a particular focus on quantum cascade lasers, integrated photonic devices, and mid-infrared and terahertz optoelectronics. He is passionate about developing advanced laser systems, including DUV–VUV solid-state lasers, for high-precision industrial and scientific applications. His work also explores graphene-based modulators, nano-photonic structures, and LiDAR systems, aiming to miniaturize and enhance the performance of optical devices for next-generation communication and sensing technologies. Prof. Liang is deeply interested in bridging fundamental research with practical applications, contributing to innovations in both academic and commercial settings. His interdisciplinary research combines materials science, nanotechnology, and electronic engineering to tackle challenges in photonics integration, light–matter interaction, and waveguide design. With a global outlook and experience in collaborative international research, his ongoing efforts aim to shape the future of ultrafast optics, photonic chips, and compact laser systems.

Award and Honor🏆

Prof. Guozhen Liang has received notable recognition for his impactful research in the fields of optics and photonics, with his work being featured in prestigious journals such as Nature Photonics, Materials Today, and ACS Photonics. Several of his research articles have been highlighted in Nature Photonics and Laser Focus World, signifying their innovation and influence in the global scientific community. His contributions have also led to multiple U.S. patents, reflecting his excellence in applied research and technology transfer. He has been invited to present at major international conferences, including the Conference on Lasers and Electro-Optics (CLEO) and SPIE Photonics Asia, often selected for post-deadline or high-impact sessions. These invitations underscore his standing as a respected voice in the photonics field. While formal titles or specific awards were not listed, the consistent visibility and impact of his work across both academia and industry highlight his strong qualifications and growing recognition as a leader in photonic innovation.

Research Skill🔬

Prof. Guozhen Liang possesses a comprehensive and advanced set of research skills in the fields of optics, photonics, and optoelectronic device engineering. He has extensive expertise in the design, fabrication, and characterization of quantum cascade lasers, DUV–VUV solid-state lasers, and mid-infrared photonic systems. His hands-on proficiency in nanofabrication techniques, waveguide design, and integrated photonic circuit development enables him to drive innovations in compact, high-performance optical devices. Additionally, he is skilled in materials analysis, particularly with 2D materials like graphene for optoelectronic applications. Prof. Liang also excels in simulation and modeling of light–matter interaction using advanced computational tools. His research acumen is complemented by strong project management and interdisciplinary collaboration capabilities, allowing him to lead international research efforts across academia and industry. His ability to translate fundamental research into practical technologies is evident in his numerous patents and high-impact publications, making him a versatile and innovative photonics researcher.

Conclusion💡

Prof. Guozhen Liang is a highly deserving candidate for the Best Researcher Award due to his outstanding contributions to the fields of optics, photonics, and laser technology. With a strong foundation in both academia and industry, he has advanced research in quantum cascade lasers, integrated photonic devices, and next-generation laser systems, with work published in globally recognized journals such as Nature Photonics and Materials Today. His innovations hold significant potential for real-world applications in sensing, communication, and imaging technologies. As a newly appointed professor and experienced international collaborator, Prof. Liang is well-positioned to lead pioneering research initiatives and mentor the next generation of scientists, further amplifying his impact on science and society.

Publications Top Noted✍️

  • Title: 2D perovskite-based metasurfaces for enhanced plasmonic sensing
    Authors: S. Zen, G. Liang, A. Gheno, S. Vedraine, N. Yu
    Year: 2019
    Citations: 3

  • Title: A metal–dielectric–graphene sandwich for surface enhanced Raman spectroscopy
    Authors: X. Yu, J. Tao, Y. Shen, G. Liang, T. Liu, Y. Zhang, Q.J. Wang
    Year: 2014
    Citations: 27

  • Title: Amorphous random lasing at terahertz frequency
    Authors: Y. Zeng, G. Liang, H. Liang, S. Mansha, B. Meng, T. Liu, X. Hu, J. Tao, L. Li, …
    Year: 2016
    Citations: 2

  • Title: Amplitude and phase light modulator based on miniature optical resonators
    Authors: G. Liang, H. Huang, M. Lipson, N. Yu
    Year: 2023
    Citations: 3

  • Title: Broadband high photoresponse from pure monolayer graphene photodetector
    Authors: B.Y. Zhang, T. Liu, B. Meng, X. Li, G. Liang, X. Hu, Q.J. Wang
    Year: 2013
    Citations: 1113

  • Title: Broadband saturable absorption of graphene oxide thin film and its application in pulsed fiber lasers
    Authors: X. Li, Y. Tang, Z. Yan, Y. Wang, B. Meng, G. Liang, H. Sun, X. Yu, Y. Zhang, …
    Year: 2014
    Citations: 119

  • Title: Broadly continuously tunable slot waveguide quantum cascade lasers based on a continuum-to-continuum active region design
    Authors: B. Meng, Y.Q. Zeng, G. Liang, J. Tao, X.N. Hu, E. Rodriguez, Q.J. Wang
    Year: 2015
    Citations: 7

  • Title: Coherent emission from integrated Talbot-cavity quantum cascade lasers
    Authors: B. Meng, B. Qiang, E. Rodriguez, X.N. Hu, G. Liang, Q.J. Wang
    Year: 2017
    Citations: 36

  • Title: Designer multimode localized random lasing in amorphous lattices at terahertz frequencies
    Authors: Y. Zeng, G. Liang, H.K. Liang, S. Mansha, B. Meng, T. Liu, X. Hu, J. Tao, L. Li, …
    Year: 2016
    Citations: 32

  • Title: Efficient pure phase optical modulator based on strongly over-coupled resonators
    Authors: G. Liang, H. Huang, S. Shrestha, I. Datta, M. Lipson, N. Yu
    Year: 2019
    Citations: 5

  • Title: Electrically Pumped Mid‐Infrared Random Lasers
    Authors: H.K. Liang, B. Meng, G. Liang, J. Tao, Y. Chong, Q.J. Wang, Y. Zhang
    Year: 2013
    Citations: 66