Dr. Peyman Keyhanvar | Applied Nanomaterials for Regenerative Medicine | Research Excellence Award

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Dr. Peyman Keyhanvar | Applied Nanomaterials for Regenerative Medicine | Research Excellence Award

Associated Professor | Tabriz University of Medical Sciences | Iran

Dr. Peyman Keyhanvar stands as a distinguished figure in medical nanotechnology and regenerative research, widely recognized for his impactful scientific contributions and translational leadership. His work reflects a persistent emphasis on Applied Nanomaterials for Regenerative Medicine, integrating nanotechnology, exosomes, smart biomaterials, microfluidics, and clinical translation into practical therapeutic solutions. With a portfolio of numerous indexed publications, patents, clinical trial involvement, technology development, startup leadership, and national-level innovation initiatives, Applied Nanomaterials for Regenerative Medicine Dr. Peyman Keyhanvar demonstrates exceptional authority in the advancement of biomaterial-based therapeutics and next-generation regenerative products. His research output reveals a consistent focus on Applied Nanomaterials for Regenerative Medicine, particularly in cellular therapy interfaces, wound care systems, hydrogel engineering, exosome-based treatment platforms, bio-scaffold development, and nanocarrier-driven drug delivery. As an associated professor and a pioneer in translational biomedical innovation, he has actively led laboratories, commercialization programs, research centers, accelerators, and clinical-innovation pipelines, showing a refined ability to connect Applied Nanomaterials for Regenerative Medicine with real-world patient outcomes. His influence extends across multidisciplinary frameworks through academic leadership, startup incubation, technology transfer, product development, and policy-aligned regenerative healthcare expansion. His scholarly presence demonstrates strong collaborative engagement with specialists in nanomedicine, materials science, tissue engineering, and precision-health technology, frequently positioning Applied Nanomaterials for Regenerative Medicine as a core catalyst for next-stage therapeutic evolution. His scientific productivity and innovation strategy continue to reinforce global dialogue around Applied Nanomaterials for Regenerative Medicine, enabling significant societal impact through clinical translation, interdisciplinary growth, and forward-looking medical technology pathways. Such contributions confirm the standing of Applied Nanomaterials for Regenerative Medicine Dr. Peyman Keyhanvar as a leading authority within regenerative nanotechnology. Google Scholar profile of 929 Citations, 17 h-index, 21 i10-index.

Profiles: Google Scholar | ORCID

Featured Publications

1. Moballegh Nasery, M., Abadi, B., Poormoghadam, D., Zarrabi, A., Keyhanvar, P., … (2020). Curcumin delivery mediated by bio-based nanoparticles: A review. Molecules, 25(3), 689.

2. Noureddini, M., Verdi, J., Mortazavi-Tabatabaei, S. A., Sharif, S., Azimi, A., … (2012). Human endometrial stem cell neurogenesis in response to NGF and bFGF. Cell Biology International, 36(10), 961–966.

3. Adel, M., Zahmatkeshan, M., Akbarzadeh, A., Rabiee, N., Ahmadi, S., … (2022). Chemotherapeutic effects of Apigenin in breast cancer: Preclinical evidence and molecular mechanisms; enhanced bioavailability by nanoparticles. Biotechnology Reports, 34, e00730.

4. Sarvari, R., Nouri, M., Agbolaghi, S., Roshangar, L., Sadrhaghighi, A., … (2022). A summary on non-viral systems for gene delivery based on natural and synthetic polymers. International Journal of Polymeric Materials and Polymeric Biomaterials, 71, 1–?.

5. Rahmani, A., Shoae-Hassani, A., Keyhanvar, P., Kheradmand, D., … (2013). Dehydroepiandrosterone stimulates nerve growth factor and brain derived neurotrophic factor in cortical neurons. Advances in Pharmacological and Pharmaceutical Sciences, 2013(1), 506191.

Dr. Naeem Ullah | Fluid Dynamics | Research Excellence Award

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Dr. Naeem Ullah | Fluid Dynamics | Research Excellence Award

Research Associate | Yangzhou University | China

Dr. Naeem Ullah is a dedicated researcher with growing contributions in Fluid Dynamics, where his work reflects strong command in Computational Mathematics, numerical modeling, and complex fluid flow phenomena. His research primarily advances understanding within Fluid Dynamics, including thin film behavior, hybrid nanofluids, nonlinear kinematics, entropy optimization, heat and mass transfer, and numerical schemes applied to Newtonian and non-Newtonian flows. As an active scholar in Fluid Dynamics, he has authored numerous peer-reviewed articles in reputable international journals, addressing contemporary problems in porous media flows, thermal transport, radiative effects, and Machine-Learning-assisted simulation of physical systems. His work in Fluid Dynamics extends to investigations using neural networks, finite-volume computing, and advanced simulation techniques that improve predictive accuracy and enhance engineering applications. Dr. Naeem Ullah consistently collaborates with multidisciplinary researchers across various countries, enriching scientific progress through joint modeling of nanofluid systems and Fluid Dynamics-based thermal processes. His publication record shows steady expansion, demonstrating research depth in entropy-driven transport, convective flow modeling, and Fluid Dynamics mechanisms within geometric and asymmetric flow domains. As a reviewer for high-impact journals, he contributes to scholarly development in Applied Mathematics, Chemical Engineering, and Fluid Dynamics. His research has introduced significant insights regarding Darcy–Forchheimer media, Cattaneo–Christov heat flux, and boundary layer controls, strengthening global understanding of Fluid Dynamics. His academic contributions continue to support industrial, biomedical, energy, and environmental problem-solving through mathematical structure and computational representation of Fluid Dynamics. With a strong professional presence, Dr. Naeem Ullah remains engaged in expanding high-performance algorithms and analytical frameworks in Fluid Dynamics, bridging applied models with real-world heat-mass transfer behavior. His research impact continues to rise with sustained contribution to Fluid Dynamics, advancing predictive solutions, physical simulations, and numerical stability for advanced engineering systems. Google Scholar profile of 144 Citations, 7 h-index, 5 i10-index.

Profile: Google Scholar

Featured Publications

1. Khan, N. S., Shah, Q., Sohail, A., Ullah, Z., Kaewkhao, A., Kumam, P., & Zubair, S., et al. (2021). Rotating flow assessment of magnetized mixture fluid suspended with hybrid nanoparticles and chemical reactions of species. Scientific Reports, 11(1), 11277.

2. Khan, N. S., Usman, A. H., Sohail, A., Hussanan, A., Shah, Q., Ullah, N., & Kumam, P., et al. (2021). A framework for the magnetic dipole effect on the thixotropic nanofluid flow past a continuous curved stretched surface. Crystals, 11(6), 645.

3. Abidin, M. Z., Marwan, M., Ullah, N., & Mohamed Zidan, A. (2023). Well-posedness in variable-exponent function spaces for the three-dimensional micropolar fluid equations. Journal of Mathematics, 2023(1), 4083997.

4. Ibrahim, S., Marwat, D. N. K., Ullah, N., & Nisar, K. S. (2023). Investigation of fluid flow pattern in a 3D meandering tube. Frontiers in Materials, 10, 1187986.

5. Abidin, M. Z., Ullah, N., Hussain, A., Saadaoui, S., Mohamed, M. M. I., & Deifalla, A. (2023). Case study of entropy optimization with the flow of non-Newtonian nanofluid past converging conduit with slip mechanism: An application of geothermal engineering. Case Studies in Thermal Engineering, 52, 103764.

Prof. Wei Ma | Robotics and Automation | Research Excellence Award

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Prof. Wei Ma | Robotics and Automation | Research Excellence Award

Associate Professor | Tianjin University | China

Prof. Wei Ma is a distinguished researcher recognized for significant contributions to underwater glider development within the domain of Robotics and Automation, where Robotics and Automation remain central to his scientific endeavors. As an Associate Professor at Tianjin University, Prof. Wei Ma has advanced Robotics and Automation through intelligent operation, hydrodynamic modelling and control of unmanned marine platforms. His research encompasses the optimization of underwater glider mechanics, variational mode decomposition for marine data processing and model based multi objective control, each contributing to a growing impact on Robotics and Automation applied to ocean engineering. With a record of ten indexed publications and fifteen patents published or under processing, Prof. Wei Ma continues to demonstrate excellence in Robotics and Automation research with high quality outputs featured in reputable journals including Physics of Fluids, Chaos, Ocean Engineering, Journal of Marine Science and Engineering and Journal of Mechanical Engineering Science. His work on air droppable underwater glider water entry, virtual prototype modelling and shape memory alloy based buoyancy systems remains widely noted in Robotics and Automation due to innovative approaches to control, sensing, networking technologies and AI driven data analytics. Prof. Wei Ma further supports the Robotics and Automation community as a reviewer for respected journals, reflecting recognition of his scholarly authority and scientific judgement. His achievements include major technology progress recognition for water surface glider engineering and an outstanding contribution award for glider system product deployment, strengthening the relevance of Robotics and Automation to maritime applications and marine intelligence systems. Through ongoing projects, expanding research themes and growing publication strength, Prof. Wei Ma continues to shape Robotics and Automation innovation with strong societal and technological relevance. Scopus profile of 231 Citations, 35 Documents, 8 h-index.

Profiles: Scopus | ORCID

Featured Publications

1. Yang, P., Wang, Y., Ma, W., Niu, W., Song, Y., & Li, Q. (2025). Fused spatial–temporal graph convolutional networks for ocean currents forecasting using underwater glider measurements. IEEE Journal of Oceanic Engineering.

2. Xi, H., Ma, W., Song, Y., Fa, S., Song, J., & Yang, M. (2025). Energy consumption prediction and endurance optimization for underwater gliders based on data-model fusion. Engineering Applications of Artificial Intelligence.

3. Lyu, G., Wu, S., Song, J., Fa, S., Wang, W., Miao, Z., Gong, F., Ma, W., & Wang, C. (2025). Model and data-driven hydrodynamic identification and prediction for underwater gliders. Physics of Fluids.

4. Ma, W., Wang, Y., Wang, S., Li, G., & Yang, S. (2019). Optimization of hydrodynamic parameters for underwater glider based on the electromagnetic velocity sensor. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science.

Dr. Muhammad Asif | Optics | Young Scientist Award

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Dr. Muhammad Asif | Optics | Young Scientist Award

Postdoctoral Researcher | Shenzhen University | China

Dr. Muhammad Asif is a dedicated researcher with recognized expertise in the field of Optics, contributing actively to advancements in electromagnetic wave absorption and photonic device design. His work centers on computational modeling, simulation, and the development of next-generation Optics-based metamaterials, where a strong emphasis is placed on terahertz, infrared, and visible spectrum applications. With progressive contributions in Optics, he remains focused on enhancing absorber performance, improving device efficiency, and strengthening the scientific foundation of materials engineered for communication, sensing, and energy-harvesting technologies. The research record of Dr. Muhammad Asif reflects meaningful outcomes, including innovative ultra-wideband absorber structures that offer enhanced operational bandwidths, marking substantial relevance to modern Optics-driven industries and scientific frameworks. His publications demonstrate international visibility with multiple works featured in high-impact journals related to Optics, photonic materials, and terahertz absorbers, highlighting sustained productivity and scholarly depth. The collaborative efforts of Dr. Muhammad Asif extend globally across premier laboratories and institutions, reinforcing a dynamic research pipeline in applied Optics and computational photonics. He maintains active associations with advanced laboratories working in radio frequency integration, photonic information technologies, and Optics device engineering, where his contributions support technological growth, academic knowledge transfer, and cross-disciplinary innovation. His research outcomes underscore measurable scientific influence not only within theoretical Optics, but also in material engineering, metasurface development, and practical photonic implementation, thereby supporting the progression of sensing platforms, solar absorption systems, and terahertz technologies. This consistent engagement in Optics has positioned him among emerging scholars contributing significantly to the modern wave-interaction landscape through carefully engineered design strategies and simulation-based discoveries. Google Scholar profile of 76 Citations, 5 h-index, 2 i10-index.

Profile: Google Scholar

Featured Publications

1. Abdullah, M., Younis, M., Sohail, M. T., Wu, S., Zhang, X., Khan, K., Asif, M., & Yan, P. (2024). Recent progress of 2D materials‐based photodetectors from UV to THz waves: Principles, materials, and applications. Small, 20(47), 2402668.

2. Asif, M., Munir, R. M., & Wang, Q., Ouyang, Z. (2024). Graphene-based polarization insensitive structure of ultra-wideband terahertz wave absorber. Optical Materials, 154, 115759.

3. Asif, M., Ali, K., Munir, R. M., Anwar, S., Abdullah, M., Ouyang, Z., & Wang, Q. (2024). Ultra-wideband solar absorber via vertically structured GDPT metamaterials. Solar Energy, 282, 112957.

4. Asif, M., Wang, Q., Ouyang, Z., Lin, M., & Liang, Z. (2023). Ultra-wideband terahertz wave absorber using vertically structured IGIGIM metasurface. Crystals, 14(1), 22.

5. Abdullah, M., Younis, M., Sohail, M. T., Asif, M., Jinde, Y., Peiguang, Y., Junle, Q., ... (2025). Recent advancements in novel quantum 2D layered materials hybrid photodetectors from IR to THz: From principles to performance enhancement strategies. Chemical Engineering Journal, 504, 158917.

Assoc. Prof. Dr. Mohammad Silani | Engineering | Research Excellence Award

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Assoc. Prof. Dr. Mohammad Silani | Engineering | Research Excellence Award

Associate Professor | Isfahan University of Technology | Iran

Assoc. Prof. Dr. Mohammad Silani is a distinguished figure in Engineering research, widely recognized for his contributions to computational mechanics, multiscale material modeling, fracture mechanics, and advanced numerical simulations. With an extensive background in Engineering applications, his work integrates molecular dynamics, finite element analysis, stochastic modeling, and phase-field theory to address complex material behavior in composite and nanocomposite structures. His Engineering research extends across multiscale modeling, machine learning–assisted simulations, and high-fidelity experimentation, establishing him as a leading contributor to Engineering innovation in computational materials science. He has served in multiple advanced academic and scientific capacities, has supervised doctoral and postgraduate research, and has actively collaborated internationally with institutions and Engineering research groups across Europe, Asia, and Australia. His scholarly output reflects a strong Engineering foundation, comprising many high-impact journal publications, conference contributions, and collaborations that have advanced computational Engineering and numerical methodology. His work on nanostructures, wear modeling, fatigue crack propagation, and hydrogen embrittlement demonstrates a deep Engineering perspective in bridging theory, simulation, and physical behavior. As a reviewer for numerous international journals, his expertise supports the global Engineering community through critical evaluation and scientific refinement. His research continues to influence structural integrity, biomaterial mechanics, lattice optimization, composites Engineering, mechanical design, and simulation-driven material development at multi-scale and multi-physics levels. His sustained contributions to Engineering research, academic leadership, and scientific cooperation reflect a career dedicated to advancing knowledge, improving computational frameworks, and developing reliable Engineering tools for industrial and scientific application. His work stands as a reference point for emerging researchers in Engineering modeling and mechanical material characterization, highlighting precision, innovation, and impactful academic leadership in modern Engineering science. Google Scholar profile of 3041 Citations, 22 h-index, 32 i10-index.

Profile: Google Scholar

Featured Publications

1. Koupaei, F. B., Javanbakht, M., Silani, M., Mosallanejad, M. H., & Saboori, A. (2026). Mechanics-based phase-field model for directional microstructure evolution: Multiscale finite element simulation of IN718 in DED process. Computational Materials Science, 261, 114342.

2. Sabetghadam-Isfahani, A., Silani, M., Javanbakht, M., & others. (2025). Molecular dynamics analysis of temperature and shear stress effects on nickel bi-crystal amorphization. Iranian Journal of Chemistry and Chemical Engineering, e732047.

3. Varshabi, N., Jafari, M., Jamshidian, M., Silani, M., Thamburaja, P., & Rabczuk, T. (2025). Phase-field modeling of stressed grain growth in nanocrystalline metals. International Journal of Mechanical Sciences, 110951.

4. Saffari, M. M., Javanbakht, M., Silani, M., & Jafarzadeh, H. (2025). Stress analysis of nanostructures including nanovoids and inclusions based on nonlocal elasticity theory with different kernels. International Journal of Applied Mechanics, 17(6), 2550041.

5. Sabetghadam-Isfahani, A., Javanbakht, M., & Silani, M. (2025). Atomistic-informed phase-field modeling of edge dislocation evolution in Σ3, Σ9, and Σ19 silicon bi-crystals. Computational Materials Science, 254, 113893.

Dr. Ricardo Alberto Rodríguez Carvajal | Engineering | Excellence in Innovation

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Dr. Ricardo Alberto Rodríguez Carvajal | Engineering | Excellence in Innovation

Professor | University of Guanajuato | Mexico

Dr. Ricardo Alberto Rodríguez Carvajal is a distinguished academic whose multidisciplinary contributions have significantly advanced Engineering research, technological innovation, and applied knowledge transfer across institutional, industrial, and social environments. His extensive trajectory reflects leadership in Engineering project development, Engineering management, Engineering innovation, and Engineering-based problem-solving applied to solar energy systems, digital transformation, organizational sustainability, and technology transfer. With a strong record of publications in Engineering journals, collaborative research networks, and participation in national and international Engineering associations, he has demonstrated a consistent capacity to connect Engineering theory with practice through strategic collaborations, patent development, and impactful industrial partnerships. His work spans solar-energy Engineering, materials Engineering, industrial Engineering, and computational Engineering, integrating these fields into high-value technological ecosystems. His role in developing prototypes, coordinating multidisciplinary Engineering teams, and guiding projects from conceptualization to market transfer has strengthened regional innovation capabilities and supported industry-focused research agendas. Through leadership in academic committees, graduate program coordination, and supervision of numerous postgraduate theses in Engineering and innovation, he has also contributed to shaping new generations of specialists capable of applying Engineering principles to emerging societal challenges. His intellectual production includes articles, books, and chapters addressing Engineering processes, knowledge management, and innovation systems, while his participation in collaborative networks has enhanced knowledge circulation across Engineering communities. His societal impact is evident in applied research projects for renewable energy, agro-industrial transformation, technology-based entrepreneurship, and sustainable development, all grounded in rigorous Engineering methodologies. This consolidated profile reflects an academic committed to expanding the frontiers of Engineering and advancing technological solutions with broad social relevance. Google Scholar profile of 200 Citations, 8 h-index, 8 i10-index.

Profiles: Google Scholar | ORCID

Featured Publications

1. Herrera-Zamora, D. M., Lizama-Tzec, F. I., Santos-González, I., & others. (2020). Electrodeposited black cobalt selective coatings for application in solar thermal collectors: Fabrication, characterization, and stability. Solar Energy, 207, 1132–1145.

2. Pitalúa-Díaz, N., Herrera-López, E. J., Valencia-Palomo, G., & others. (2015). Comparative analysis between conventional PI and fuzzy logic PI controllers for indoor benzene concentrations. Sustainability, 7(5), 5398–5412.

3. León Lara, J. D., & Rodríguez Carvajal, R. A. (2014). Customer relationship management (CRM), a tool for creating competitive strategies. Epistemus (Sonora), 8(17), 81–87.

4. Isiordia-Lachica, P. C., Valenzuela, A., Rodríguez-Carvajal, R. A., & others. (2020). Identification and analysis of technology and knowledge transfer experiences for the agro-food sector in Mexico. Journal of Open Innovation: Technology, Market, and Complexity, 6(3), 59.

5. Romero-Hidalgo, J. A., Isiordia-Lachica, P. C., Valenzuela, A., & others. (2021). Knowledge and innovation management model in the organizational environment. Information, 12(6), 225.

Prof. Eui-chan Jeon | Engineering | Research Excellence Award

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Prof. Eui-chan Jeon | Engineering | Research Excellence Award

Professor | Sejong University | South Korea

Prof. Eui-chan Jeon is a distinguished scholar whose extensive contributions to Engineering and environmental science have positioned him as a leading global authority in climate change mitigation, atmospheric emissions, and sustainable policy development. With a long-standing career marked by influential leadership roles, Prof. Jeon has advanced national and international frameworks through his work with major climate organizations, including key positions related to the IPCC, national carbon-neutrality committees, and major environmental research councils. His expertise spans the Engineering dimensions of greenhouse gas inventories, air-pollution management, emission-factor development, and short-lived climate forcers, and he has consistently shaped policies and methodologies that guide both scientific communities and governmental bodies. His Engineering-driven research portfolio encompasses more than a hundred documents, demonstrating impactful collaborations across academia, industry, and government institutions, while his applied investigations into ammonia emissions, particulate-matter sources, and industrial greenhouse-gas abatement technologies have significantly strengthened environmental decision-making. Prof. Jeon’s work in Engineering has also contributed to advanced modeling systems, emission-characterization frameworks, and mitigation strategies utilized across sectors such as agriculture, waste management, semiconductor manufacturing, and energy industries. His numerous authored and co-authored publications reflect a sustained commitment to Engineering innovation, methodological rigor, and interdisciplinary problem-solving, offering solutions that translate complex scientific insights into practical societal benefits. Prof. Jeon’s Engineering achievements extend to textbook authorship, national consulting, and international project leadership, establishing him as a pivotal figure whose research reshapes climate governance and emission-management standards. His reliable scientific output, strong Engineering foundation, and broad collaborative networks continue to influence sustainable-development pathways and evidence-based environmental reforms. This professional summary is supported by his Scopus profile of 2,082 Citations, 110 Documents, and a 22 h-index.

Profiles: Scopus | ORCID

Featured Publications

1. Effects of Plasma Power on By-Product Gas Formation from CHF₃ and CH₂F₂ Process Gases in Semiconductor Etching Processes. (2025). Applied Sciences Switzerland.

2. Understanding the correlation between the structural and photoluminescent properties of Ca₃(PO₄)₂:Eu³⁺, M⁺ (M⁺ = Li⁺, Na⁺, K⁺) phosphors. (2025). Ceramics International.

3. Thermoelectric properties of SiC nanoparticle-dispersed Bi₁.₉₂₅Ba₀.₀₇₅Sr₂Co₂Oy. (2025). Journal of Alloys and Compounds.

4. A study on the application of an estimated ammonia emission factor reflecting the operating characteristics of open laying hen houses in Korea. (2025). Atmosphere.

5. The impact of plasma intensity on the unused rate in semiconductor manufacturing: Comparative analysis across intensity ranges from 30 to 3000. (2025). Applied Sciences Switzerland.

Prof. Dr. Xiaochun Sun | Mathematics | Research Excellence Award

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Prof. Dr. Xiaochun Sun | Mathematics | Research Excellence Award

Doctoral Advisor | Northwest Normal University | China

Prof. Dr. Xiaochun Sun is a distinguished scholar recognized for extensive contributions to Mathematics, with a research profile that demonstrates strong analytical depth and sustained academic impact. His work in Mathematics spans complex fluid dynamics, fractional differential equations, harmonic analysis, and operator theory, reflecting a long standing commitment to advancing theoretical and applied Mathematics. He has authored numerous publications that address fundamental questions in Mathematics, contributing significantly to well posedness theory, dispersive structures, and the behavior of solutions within advanced functional spaces. His collaborations with national and international researchers highlight his influence across multiple domains of Mathematics, supporting interdisciplinary growth and strengthening global research networks in Mathematics. Prof. Dr. Xiaochun Sun has also played major academic leadership roles, contributing to institutional development while mentoring young scholars in Mathematics. His involvement in several competitive scientific research projects further demonstrates his capability to integrate Mathematics with emerging scientific problems, resulting in outcomes that support the broader scientific community. His academic service, teaching excellence, and recognition through various awards underscore his dedication to Mathematics and to strengthening educational quality. His collective achievements illustrate a career deeply rooted in Mathematics, consistently contributing to the expansion of knowledge, the development of research infrastructure, and the promotion of high standard scholarship. Prof. Dr. Xiaochun Sun continues to elevate the role of Mathematics in addressing contemporary scientific challenges, ensuring that his research outputs maintain both theoretical rigor and societal relevance. His contributions remain influential in shaping future advancements in Mathematics. Scopus profile of 31 Citations, 9 Documents, 4 h-index.

Profiles: Scopus | ORCID

Featured Publication

1. Global Well-Posedness for the Fractional Magneto-Micropolar Equations in Variable Exponent Fourier–Besov Spaces. (2025). Computational Mathematics and Mathematical Physics.

Dr. Xiaoguang Liu | Particle Experiments | Research Excellence Award

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Dr. Xiaoguang Liu | Particle Experiments | Research Excellence Award

Associate Professor | University of Science and Technology Beijing | China

Dr. Xiaoguang Liu is a distinguished researcher whose work reflects a strong commitment to advancing materials science through the continuous integration of Particle Experiments that shape modern understanding of high temperature ceramics and catalytic systems. Dr. Xiaoguang Liu has built a research profile centered on the development of high temperature ceramic coatings designed for extreme operational environments, while also contributing to high efficiency catalysts applied in wastewater treatment, a field where Particle Experiments consistently guide both conceptual progress and practical outcomes. Through extensive engagement with Particle Experiments that support investigations of electron transfer mechanisms in Z scheme semiconductor catalysts, Dr. Xiaoguang Liu has strengthened fundamental knowledge and broadened technological applications across academic and industrial collaborations. With publications across journals indexed in global databases and contributions that extend to consultancy and industry oriented projects, Dr. Xiaoguang Liu has demonstrated how Particle Experiments reinforce the reliability, precision, and societal relevance of innovative research outputs. Editorial appointments further reflect scientific leadership shaped by meticulous Particle Experiments that validate results across catalytic and ceramic systems. Patents, authored works, and research projects also highlight the consistent integration of Particle Experiments as a methodological core that enhances the robustness of experimental design and the credibility of research conclusions. Professional engagements and collaborative activities continue to expand the impact of Particle Experiments within interdisciplinary frameworks, demonstrating sustained contributions to material enhancement, environmental improvement, and scientific advancement. With ongoing research inspired by Particle Experiments that support both theoretical insight and experimental validation, Dr. Xiaoguang Liu remains a significant contributor to globally relevant innovations. Scopus profile of 1,643 Citations, 54 Documents, 21 h index.

Profile: Scopus

Featured Publications

1. Synergistic design of a novel Z-Scheme M-r-MIL-88A(Fe)/Bi₅O₇I-OVs with Fe²⁺/Fe³⁺ and oxygen vacancies for high-efficiency peroxymonosulfate activation and pollutant degradation: Mechanisms and DFT calculation. Separation and Purification Technology. (2026).

2. Polyvinyl alcohol and methyl cellulose composite membrane for efficient degradation of methylene blue. Materials Chemistry and Physics. (2025).

3. Supramolecular perylene diimides for photocatalytic hydrogen production. (2025).

4. Research progress and development trends in the anti-oxidation mechanism and performance enhancement of uranium nitride as an accident-resistant nuclear fuel. Gongcheng Kexue Xuebao / Chinese Journal of Engineering. (2025).

5. Preparation of Co/S co-doped carbon catalysts for excellent methylene blue degradation. International Journal of Minerals, Metallurgy and Materials. (2025).

Ruizhu Wang | Innovation | Research Excellence Award

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Ms. Ruizhu Wang | Innovation | Research Excellence Award

Ruizhu Wang | Xinjiang Agricultural University | China

Ms. Ruizhu Wang is an emerging researcher whose work reflects a strong commitment to advancing food science through continuous Innovation, methodical experimentation, and meaningful scientific contributions. Her research activity demonstrates Innovation in the study of fruit and vegetable processing, specifically focusing on drying, frying, and the development of value-added food products. Through her recent publication in an international SCI-indexed journal, she has introduced Innovation in coating pretreatment strategies that enhance sensory quality while supporting healthier processing pathways. Her scientific contribution highlights Innovation in understanding volatile compound behavior, offering mechanistic insights that strengthen industrial applications. Ms. Wang’s work embodies Innovation by integrating practical laboratory methodologies with analytical precision, enabling improved food quality outcomes. She has consistently demonstrated Innovation in identifying low-fat processing solutions and optimizing vacuum-frying systems to meet evolving consumer expectations. Her collaborations with co-authors further reflect Innovation in interdisciplinary teamwork aimed at producing healthier, scientifically validated food products. With her growing publication record and citation visibility, she continues to build a research profile shaped by Innovation, problem-solving, and technical expertise. Her contributions show Innovation in addressing both scientific and societal needs, offering actionable knowledge that benefits food technology sectors and supports sustainable processing approaches. Through her active participation in funded research and her dedication to refining food processing techniques, Ms. Wang’s scholarly journey exemplifies Innovation that aligns with global research standards. Her work contributes to the broader impact of improving food quality, enhancing aroma profiles, and promoting healthier consumer products, reinforcing her role as a promising contributor to the scientific community. Scopus profile of 2 Documents.

Profile: Scopus

Featured Publication

1. Effect of coating pretreatment on sensory quality of vacuum low temperature fried crisp jujube. (2025). International Journal of Gastronomy and Food Science.