Zhang Xuexue | Experimental methods | Best Researcher Award

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Ms. Zhang Xuexue | Experimental methods | Best Researcher Award

Student at Anhui University of Technology, China

Zhangxuexue is a dedicated graduate student at Anhui University of Technology, specializing in the field of absorbing materials. With a passion for materials science and nanotechnology, she has already made meaningful academic contributions during her academic journey. Her standout work involves the development of air/SiO₂@Fe/C yolk-shell nanospheres, which has been published in the prestigious Journal of Alloys and Compounds. Zhangxuexue demonstrates a strong foundation in research methodology and is positioning herself as a rising researcher in electromagnetic wave absorption materials.

Author Profile 

Scopus

Education

Zhangxuexue is currently pursuing her graduate studies at Anhui University of Technology, majoring in Materials Science and Engineering. Her coursework and academic training have provided her with a robust foundation in material synthesis, nanotechnology, and electromagnetic wave interaction. Throughout her studies, she has engaged in laboratory work and collaborative research projects, gaining hands-on experience in materials characterization techniques such as SEM, XRD, and VSM. The interdisciplinary curriculum at Anhui University of Technology has equipped her with both theoretical knowledge and practical skills in designing advanced functional materials. Her thesis work focuses on yolk-shell nanostructures for electromagnetic wave absorption, where she integrates material chemistry with electromagnetic theory.

Professional Experience

As a graduate researcher at Anhui University of Technology, Zhangxuexue has actively participated in experimental and theoretical research related to electromagnetic wave absorbing materials. Her most notable contribution is the successful design and fabrication of air/SiO₂@Fe/C yolk-shell nanospheres, which she co-developed and characterized using advanced techniques. This research resulted in a peer-reviewed publication, marking an early milestone in her academic career. She has also contributed to various lab-based projects involving the synthesis of hybrid materials, dielectric analysis, and the simulation of microwave absorption behavior. Through this work, she has developed a deep understanding of composite design, material interfaces, and the mechanisms behind wave attenuation.

Awards and Honors

While pursuing her graduate studies at Anhui University of Technology, Zhangxuexue has demonstrated academic excellence and research potential. She has received internal recognition from her department for outstanding performance in materials research and laboratory work. Her paper titled Construction of air/SiO₂@Fe/C yolk-shell nanospheres for boosted low-frequency electromagnetic wave absorption, published in the prestigious Journal of Alloys and Compounds, earned her commendation from faculty and peers alike.

Research Focus

Zhangxuexue’s research focus lies in the field of electromagnetic wave absorbing materials, with a specific interest in yolk-shell nanostructures and hybrid composites. Her work targets the development of lightweight, high-performance materials capable of attenuating low-frequency electromagnetic radiation. By manipulating composition, morphology, and interface properties, she aims to enhance the dielectric and magnetic losses of the absorbing materials. Her flagship study involves air/SiO₂@Fe/C yolk-shell nanospheres, designed to optimize internal scattering and impedance matching for efficient absorption. Beyond microwave absorption, she is also interested in the broader implications of these materials for stealth technology, electronic packaging, and electromagnetic interference (EMI) shielding.

Notable Publication

Construction of air/SiO₂@Fe/C yolk-shell nanospheres for boosted low-frequency electromagnetic wave absorption

Authors: Xuexue Zhang¹, Jing Wang¹, Weiwei Wang, Cao Wu, Chang Liu, Hailiang Deng, Liyan Wei, Weihua Gu, Wenbo Du, Yanning Chen, Hongwei Liu, Xun Cao

Journal: Journal of Alloys and Compounds

Year: 2025

Conclusion

Zhangxuexue is an emerging researcher in the field of electromagnetic wave absorbing materials, with a solid academic foundation and a growing record of scientific contribution. Her innovative work on yolk-shell nanostructures demonstrates both creativity and technical skill in material design. As a graduate student at Anhui University of Technology, she has shown strong potential for impactful research and future academic advancement. With a keen interest in nanomaterials and their real-world applications, Zhangxuexue aims to further explore advanced absorption mechanisms and scalable solutions for electromagnetic interference control. Her dedication and accomplishments position her as a promising talent in materials science.

 

 

Abdelmounaim Chetoui | Experimental methods | Academic Excellence in Applied Physics Award

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Dr. Abdelmounaim Chetoui | Experimental methods | Academic Excellence in Applied Physics Award

Research assistant, CRTSE, Algeria

Dr. Abdelmounaim Chetoui is a dedicated researcher in materials physics, specializing in semiconductors, thin films, and nanostructures. With over six years of research experience, he is currently affiliated with the Research Center in Semiconductor Technology for Energetics (CRTSE) in Algiers. He holds a Ph.D. in Materials Physics from USTHB, Algeria, and has pursued academic training in both Algeria and France. His expertise includes photoluminescence, spray pyrolysis, and nanomaterials for photovoltaics and gas sensors. Dr. Chetoui has an excellent grasp of interdisciplinary research and experimental design.

👨‍🎓Profile

Google scholar

Scopus

ORCID

🎓 Early Academic Pursuits

Dr. Chetoui began his academic journey with a Bachelor’s in Fundamental Physics from the University of Sétif, followed by a Maitrise and Master’s in Materials Engineering from the University of Strasbourg, France. His academic focus was on solid-state physics and materials science, laying a strong foundation for his research career. He culminated this phase with a Doctorate in Materials Physics from USTHB, where his doctoral work explored the optical and structural behavior of semiconductor thin films, especially in photovoltaics and gas sensing.

🏢 Professional Endeavors

Dr. Chetoui has held research positions at prestigious Algerian institutions including CDTA and CRTSE, contributing extensively to semiconductor research and device engineering. As a Research Engineer Advisor, he led multiple projects on metallic oxide synthesis, spray pyrolysis device design using SolidWorks, and thin film characterization. His current role at CRTSE involves cutting-edge material synthesis for energy applications. From 2013 to 2014, he also served as an Assistant Teacher at USTHB, mentoring students in electricity and mechanics, showcasing his dedication to both research and education.

🔬 Contributions and Research Focus

Dr. Chetoui’s research revolves around nanostructured semiconductors, luminescent materials, and thin-film deposition techniques. He has made significant contributions to the study of ZnS, ZrO₂, V₂O₅, NiO, and perovskite-based materials through both experimental and DFT (density functional theory) studies. His work integrates photoluminescence, photocatalysis, and nanocomposites for energy conversion and environmental remediation. A key focus of his work is the use of spray pyrolysis, a cost-effective technique for fabricating high-performance thin films for solar energy and sensing applications.

🌍 Impact and Influence

Dr. Chetoui’s research has contributed to the development of nanomaterials with enhanced optical and photocatalytic properties, impacting fields such as renewable energy, environmental cleanup, and nanoelectronics. His collaborative studies on Zn1−xMgxS, SiNx, and rGO-based nanostructures offer valuable insights into material optimization for visible-light-driven photocatalysis. His role in cross-disciplinary teams and international publication record helps bridge theoretical understanding with practical applications. These contributions make him a valuable asset in advancing sustainable nanotechnology in the MENA region and beyond.

📚 Academic Cites

Dr. Chetoui has co-authored over 20 international publications in reputable journals like Applied Physics A, Physica B, Solid State Sciences, and Diamond & Related Materials. His work on photocatalytic nanocomposites, luminescent thin films, and solid-state phosphors has attracted attention in the materials science and semiconductor communities. Notable studies include his 2024 research on ZrV₂O₇ nanoparticles, Eu³⁺-doped phosphors, and graphene-based heterojunctions, contributing to an increasing citation index and strengthening his global scientific footprint.

🧪 Research Skills

Dr. Chetoui has hands-on expertise in spray pyrolysis, solvothermal synthesis, and solid-state reactions. His technical arsenal includes XRD, SEM, AFM, FTIR, and photoluminescence spectroscopy. Adept in software like SolidWorks, he has designed customized deposition systems and analyzed complex materials using optical and structural simulation tools. His research merges materials chemistry, device engineering, and physics, demonstrating analytical precision, instrumental knowledge, and problem-solving ability critical for experimental physics and nanotechnology development.

👨‍🏫 Teaching Experience

As an Assistant Teacher at USTHB, Dr. Chetoui taught physics tutorials in electricity and mechanics, demonstrating strong pedagogical skills. His teaching involved hands-on lab supervision, conceptual instruction, and assessment design, providing foundational physics knowledge to undergraduate students. His bilingual fluency in French and English further enhances his communication in diverse academic settings. He is well-prepared to deliver graduate-level lectures on semiconductors, thin film physics, and optical materials, making him a valuable educator and mentor in higher education.

🏅 Awards and Honors

While explicit awards are not listed, Dr. Chetoui’s academic journey through international institutions, his research output, and consistent participation in scientific events demonstrate high merit and recognition in his field. Presenting at over 10 national and international conferences, including ICASE, EMS, and ICMS, he has contributed valuable insights on ZnS-based nanomaterials, luminescent oxides, and environmental applications of nanotechnology. His selection to present at these forums reflects peer acknowledgment and research credibility in applied materials science.

🌟 Legacy and Future Contributions

Dr. Chetoui’s work positions him to make impactful contributions to next-generation nanomaterials for energy harvesting, environmental monitoring, and photonics. He is expected to lead collaborative research, initiate international projects, and expand into emerging materials platforms like 2D materials and hybrid perovskites. With a commitment to sustainable innovation and scientific mentorship, he is poised to leave a lasting legacy in applied physics and nanotechnology. His future efforts will likely strengthen the scientific community’s ability to tackle climate, energy, and material efficiency challenges.

Publications Top Notes


Band Structure Engineering in InVO₄/g-C₃N₄/V₂O₅ Heterojunctions for Enhanced Type II and Z-Scheme Charge Transfer

  • Authors: Abdelmounaim Chetoui, Ilyas Belkhettab, Amal Elfiad, Ismail Bencherifa, Messai Youcef
    Journal: Vacuum
    Year: 2025

Effect of Li⁺ Co-doping on Structural, Morphological and Photoluminescence Spectroscopy of ZnO: Eu³⁺ Nanocrystal Powders

  • Authors: Wafia Zermane, Lakhdar Guerbous, Widad Bekhti, Ahmed Rafik Touil, Mohamed Taibeche, Abdelmounaim Chetoui, Lyes Benharrat, Nadjib Baadji, Mustapha Lasmi, Abdelmadjid Bouhemadou
    Journal: Ceramics International
    Year: 2025

An In-Depth Photoluminescence Investigation of Charge Carrier Transport in ZrO₂|V₂O₅ Type I Junction: Probing the Production of Hydroxyl Radicals

  • Authors: Abdelmounaim Chetoui, Ilyas Belkhettab, Amal Elfiad, Youcef Messai, Aicha Ziouche, Meftah Tablaoui
    Journal: Applied Surface Science
    Year: 2024

Elaboration and Characterization of Amorphous Silicon Carbide Thin Films (a-SiC) by Sputtering Magnetron Technique for Photoelectrochemical CO₂ Conversion

  • Authors: Abdelmounaim Chetoui
    Journal: Silicon
    Year: 2022

Physicochemical Investigation of Pure Cadmium Hydroxide Cd(OH)₂ and Cd(OH)₂–CdO Composite Material Deposited by Pneumatic Spray Pyrolysis Technique

  • Authors: Abdelmounaim Chetoui
    Journal: Applied Physics A
    Year: 2022

 

Hailang Dai | Experimental methods | Best Researcher Award

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Assist. Prof. Dr. Hailang Dai | Experimental methods | Best Researcher Award

Associate research fellow, Shanghai Jiao Tong University, China

Dr. Hailang Dai is an Associate Researcher at Shanghai Jiao Tong University and a rising expert in the fields of advanced optics, micro-lasers, and biomedical photonics. After completing his studies under the mentorship of renowned professors Xianfeng Chen and Zhuangqi Cao, Dr. Dai has become a pivotal figure in interdisciplinary research that merges optical technologies with medical applications. He has led and participated in numerous nationally funded projects, built the first interdisciplinary biomedical photonics laboratory at the university, and published over 50 high-impact research articles in journals like Physical Review Letters, Optics Letters, and Photonics Research.

👨‍🎓Profile

Scopus

ORCID

🎓 Early Academic Pursuits

Dr. Dai began his academic journey at the School of Physics and Astronomy at Shanghai Jiao Tong University, where he studied under esteemed mentors, laying a strong foundation in theoretical and experimental optics. Early in his career, he demonstrated outstanding academic potential, receiving multiple prestigious scholarships, including the National Scholarship, CICIFSA, and Huawei Scholarship. His deep curiosity in light–matter interactions and functional materials led him to focus on optoelectronic devices. His consistent excellence earned him admission to the highly competitive Shanghai Super Postdoctoral Talent Support Program, marking a significant step in his scholarly development.

🧪 Professional Endeavors

Dr. Dai’s professional path has been defined by interdisciplinary innovation and academic leadership. As an Associate Researcher and doctoral supervisor, he has guided research in advanced functional optoelectronics and biomedical optics. He established the first biomedical photonics laboratory at the Institute of Optical Science and Technology and has successfully led several China Postdoctoral Science Foundation projects. In collaboration with leading academics, he has contributed as first or co-author in top-tier journals. Dr. Dai is currently the Principal Investigator of the National Natural Science Foundation of China Youth Fund Project, showcasing his research leadership and forward-looking vision.

🔬 Contributions and Research Focus

Dr. Dai’s research has focused on micro-lasers, nonlinear optics, biomedical diagnostics, and integrated photonic devices. His groundbreaking work involves optical waveguides, high-Q cavities, and laser-based biomedical applications that address real-world challenges such as disease detection and therapeutic solutions. He uniquely combines optical science with biomedicine, exploring novel mechanisms for treating diseases using photonics-based technologies. His ability to connect fundamental physics with practical solutions has placed him at the forefront of interdisciplinary research, with work featured in journals like Physical Review Applied and Biomedical Optics Express.

🌍 Impact and Influence

Dr. Dai’s interdisciplinary research has had a transformational impact on the development of optical medical diagnostics and next-generation optoelectronic devices. His innovations in micro-laser technology and waveguide systems have contributed to both academic advancement and industrial application. His publications have been widely cited, reflecting the relevance and scientific merit of his work. Beyond his own research, he has inspired emerging scholars and helped shape a new generation of researchers in optical physics. His research bridges fundamental science and applied biomedical engineering, cementing his reputation as a pioneer in photonics-driven medical solutions.

📊 Academic Cites

Dr. Dai’s body of work is well-recognized in the academic community, garnering hundreds of citations across highly respected journals. His articles in Physical Review Letters, Nano Letters, Optics Express, and ACS Photonics are frequently cited by peers working in optics, material science, and biomedical engineering. This citation record underscores the broad applicability of his work and his standing as a credible, high-impact researcher. His collaborations with international scholars and consistent contributions to cutting-edge research ensure continued visibility and academic influence, positioning him as a thought leader in his interdisciplinary field.

🧠 Research Skills

Dr. Dai exhibits a wide spectrum of research skills including theoretical modeling, experimental design, nanofabrication, optical simulation, and biomedical instrumentation. His command of nonlinear optics, laser physics, and optical materials is complemented by his ability to integrate optical platforms into clinical research settings. He is adept in using tools such as COMSOL, Lumerical, and FDTD for photonic simulations. His ability to conceptualize and execute multidisciplinary projects makes him highly valuable in collaborative research. Furthermore, his experience in establishing laboratories and managing research teams showcases his strong leadership and project execution abilities.

📚 Teaching Experience

As a doctoral supervisor, Dr. Dai has actively mentored graduate students and postdoctoral researchers, integrating them into his research on micro-lasers and biophotonics. His teaching philosophy emphasizes hands-on learning, critical thinking, and interdisciplinary exploration. He has also contributed to curriculum development in photonics and optical instrumentation, and frequently delivers seminars and research talks within the university and at academic conferences. His mentorship has resulted in student-led publications and project awards, underlining his role in academic development. Dr. Dai continues to foster a supportive learning environment, cultivating future leaders in optics and biomedical science.

🏅 Awards and Honors

Dr. Dai’s academic journey is marked by prestigious accolades such as the Shanghai Super Postdoctoral Fellowship, National Scholarship, Huawei Scholarship, and the CICIFSA Doctoral Scholarship. He has also secured funding from the China Postdoctoral Science Foundation and is currently leading a Youth Fund Project from the National Natural Science Foundation of China. These recognitions not only highlight his scientific excellence but also acknowledge his dedication to national research goals. His consistent record of scholarships and grants reflects a career built on merit, innovation, and academic contribution.

🔮 Legacy and Future Contributions

Dr. Hailang Dai is well-positioned to leave a lasting legacy in the fields of biophotonics and functional optics. With an established research infrastructure and a growing team, his next steps likely involve expanding international collaboration, exploring AI-integrated optical diagnostics, and commercializing his biomedical technologies. His vision includes making optical solutions more accessible for healthcare diagnostics and pioneering next-generation optoelectronic materials. As a mentor, innovator, and leader, his ongoing work will continue to inspire future scientists and impact both academic research and real-world healthcare applications, making him a strong contender for prestigious global research awards.

Publications Top Notes

📄 High-quality factor in a symmetrical metal-cladding optical waveguide

  • Authors: Yi Lai, Zhangchi Sun, Dan Ru, Chenhuan Ding, Ling Ding, Chen Wang, Cenxin Luo, Hailang Dai, He Li

  • Journal: Journal of Nonlinear Optical Physics & Materials

  • Year: 2025

📄 Manipulation of Rare-Earth-Ion Emission by Nonlinear-Mode Oscillation in a Lithium Niobate Microcavity

  • Authors: Jiangwei Wu, Yuxuan He, Qilin Yang, Xueyi Wang, Xiangmin Liu, Yong Geng, Guangcan Guo, Qiang Zhou, Xianfeng Chen, Yuping Chen

  • Journal: Nano Letters

  • Year: 2025

📄 Analysis of the key signaling pathway of baicalin that induces autophagy in papillary thyroid cancer via an optical resonator

  • Authors: Yi Lai, Dan Ru, Chenhuan Ding, Chen Wang, Ling Ding, Cenxin Luo, Yujie Qi, Xianfeng Chen, Hailang Dai, He Li

  • Journal: Biomedical Optics Express

  • Year: 2025

📄 Ultralow-Threshold Lithium Niobate Photonic Crystal Nanocavity Laser

  • Authors: Xiangmin Liu, Chengyu Chen, Rui Ge, Jiangwei Wu, Xianfeng Chen, Yuping Chen

  • Journal: Nano Letters

  • Year: 2025

📄A Sixteen‐user Time‐bin Entangled Quantum Communication Network With Fully Connected Topology

  • Authors: Yiwen Huang, Zhantong Qi, Yilin Yang, Yuting Zhang, Yuanhua Li, Yuanlin Zheng, Xianfeng Chen

  • Journal: Laser & Photonics Reviews

  • Year: 2025

 

Suresh Kumar | Experimental methods | Best Researcher Award

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Dr. Suresh Kumar | Experimental methods | Best Researcher Award

Associate Professor at MMEC, Maharishi Markandeshwar (Deemed to be University) Mullana | India

Dr. Suresh Kumar is an accomplished Associate Professor (Grade-II) at Maharishi Markandeshwar (Deemed to be University), Mullana, Haryana. With over 11 years of post-Ph.D. experience, he is widely recognized for his research in nanomaterials, dilute magnetic semiconductors, and photocatalysis. A prolific researcher and educator, he has authored 51 research publications, holds six patents, and actively supervises PG and Ph.D. research. His academic presence is validated across platforms such as Scopus, Web of Science, Google Scholar, and Vidwan. He is deeply committed to institutional development, student mentorship, and innovative science education in India.

👨‍🎓Profile

Google scholar

Scopus

ORCID

📘 Early Academic Pursuits

Dr. Suresh Kumar’s academic journey began with a B.Sc. in Non-Medical Sciences from Himachal Pradesh University in 1998. He further pursued M.Sc. Physics (2002), followed by B.Ed and M.Ed degrees, reinforcing his strong foundation in both science and education. His interest in research led him to complete an M.Phil in Physics, and later, a Ph.D. in Physics & Materials Science from Jaypee University of Information Technology in 2014. His doctoral work on transition metal-doped CdS nanofilms marked a turning point, setting the stage for a career rooted in cutting-edge nanotechnology and materials research.

💼 Professional Endeavors

Dr. Kumar has held various academic roles, beginning as a Lecturer in 2007, advancing through positions like Teaching Assistant, Assistant Professor, and Associate Professor. Currently serving at MM(DU), Mullana, his journey reflects a steady progression in leadership, teaching, and research responsibility. He has contributed to institutional quality enhancement by coordinating activities such as NAAC Criteria III, FDPs, curriculum revision, and lab management. His previous affiliations include Jaypee University of Information Technology, Kalpi Institute of Technology, and Shivalik Institute of Engineering & Technology, contributing across UG, PG, and Ph.D. levels.

🔬 Contributions and Research Focus

Dr. Suresh Kumar’s research revolves around II-VI semiconductors, dilute magnetic semiconductors (DMS), photovoltaics, and photocatalysis. His work has pioneered advancements in the green synthesis of nanomaterials, particularly using plant extracts for nanoparticle synthesis, and has practical applications in energy and environmental remediation. His six patents include innovations in nanostructured thin films, solar energy tools, and beekeeping equipment, demonstrating a clear alignment with sustainable and applied science. With consistent publications in indexed journals (WOS, Scopus) and supervision of multiple research scholars, Dr. Kumar’s contributions deeply influence emerging material science trends.

🌍 Impact and Influence

Dr. Kumar’s research has made a measurable global impact, evidenced by 665 citations on Google Scholar, 524 on Web of Science, and 471 on Scopus. His h-index ranges from 11 to 14, reflecting both quality and relevance of his work. He has guided multiple dissertations and Ph.D. theses, and his innovations in solar-powered devices and eco-friendly nanoparticle synthesis have real-world value. He is a regular speaker and session chair at international conferences, such as the Halich Congress, Turkey, and his leadership has helped shape young researchers’ careers, affirming his academic and scientific influence both nationally and abroad.

📚 Academic Cites and Recognition

Dr. Kumar’s scholarly visibility is reinforced through profiles on Google Scholar, Scopus, Web of Science, ORCID, ResearchGate, and Vidwan. His 51 peer-reviewed publications span reputed journals with a combined impact factor of 75.74. These platforms showcase his interdisciplinary reach, from nanotechnology and materials characterization to renewable energy innovations. His academic identity is globally recognized, and his works are often referenced in the domains of thin film physics, green nanotechnology, and semiconductors. This strong digital footprint cements his role as a credible and referenced authority in his research areas.

🧪 Research Skills

Dr. Kumar possesses advanced expertise in material synthesis and characterization techniques, including Chemical Bath Deposition (CBD), vacuum and spin coating, and tools such as XRD, SEM, AFM, TEM, UV-Vis-NIR, EDX, FTIR, and VSM. His experimental precision is matched by a theoretical understanding of optical, structural, and magnetic properties of nanomaterials. He has a strong command over green synthesis methods and is skilled at translating laboratory research into patents and prototypes. His versatile research abilities are applied across diverse sectors—energy, healthcare, agriculture, and education technology making him a valuable asset in interdisciplinary scientific exploration.

🎓 Teaching Experience

Dr. Kumar brings 17+ years of teaching experience, including over 11 years post-Ph.D., spanning UG, PG, and Ph.D. programs. At MM(DU), he teaches B.Sc. Physics (Honors), M.Sc. Physics, and Ph.D. coursework, while also mentoring research students. Known for his engaging, student-centered teaching style, he integrates technology (Moodle, Swayam MOOCs) and hands-on lab work to foster experiential learning. As Lab In-charge and academic coordinator, he ensures high standards in curriculum delivery and laboratory safety. His commitment to academic excellence and student mentorship is a hallmark of his teaching legacy.

🏆 Awards and Honors 

Dr. Suresh Kumar has received numerous accolades, such as the Chanakya Award 2024 and Indo-Global Education Excellence Award 2024 from ICERT. He was honored with a session headship at the Halich Congress, Turkey, and received a Teacher Innovation Award during the pandemic from Rakshita Welfare Society. Earlier in his career, he secured a Best Poster Prize at RTMS-2011 and was awarded a Research Assistantship during his Ph.D. His academic diligence also earned him a merit certificate during B.Ed. These recognitions affirm his dedication to innovation, research impact, and educational leadership.

🔮 Legacy and Future Contributions

Dr. Kumar’s legacy lies in his innovative, sustainable, and interdisciplinary research, as well as his devotion to student growth and institutional advancement. Looking ahead, he aims to secure international collaborations, government-funded research projects, and explore technology transfer opportunities for his patented innovations. He envisions contributing to national science missions through eco-friendly materials research, renewable energy systems, and academic policy reform. His future work will likely expand into translational research, benefiting industries and communities alike. Dr. Kumar’s trajectory marks him as a thought leader and changemaker in the realms of science, innovation, and education.

Publications Top Notes

Solvothermal synthesis of PVP-assisted CuS structures for sunlight-driven photocatalytic degradation of organic dyes

  • Authors: Vishal Dhiman, Suresh Kumar, Abhishek Kandwal, Pankaj Sharma, Ankush Thakur, Sanjay Kumar Sharma
    Journal: Physica B: Condensed Matter
    Year: 2025

Enhanced photoconversion efficiency in dye-sensitized solar cells through Ag and La modified ZnO photoanodes

  • Authors: Aman Kumar, Suresh Kumar, Virender Singh Kundu, Kirti Hooda, Anil Vohra, Suresh Kumar, Mohit Podia, Abhishek Kandwal, Praveen Vummadisetty Naidu
    Journal: Physica Scripta
    Year: 2025

Photocatalytic Activity of ZnO Nanostructures

  • Authors: Anu Kapoor, Naveen Kumar, Suresh Kumar
    Journal: Book Chapter – In: Advanced Nanomaterials for Environmental Applications (Taylor & Francis)
    Year: 2025

Green Synthesis of Nanoparticles using Pea Peel Biomass and Their Assessment on Seed Germination of Tomato, Chilli and Brinjal Crop

  • Authors: Anjali Kanwal, Bikram Jit Singh, Suresh Kumar, Rippin Sehgal, Sushil Kumar Upadhyay, Raj Singh
    Journal: Indian Journal of Agricultural Research
    Year: 2025

A comprehensive review of bismuth, lanthanum and strontium based double perovskites − Unravelling structural, magnetic, and dielectric properties

  • Authors: Jagadish Parsad Nayak, Rohit Jasrotia, Avi Kumar Sharma, Abhishek Kandwal, Pratiksha Agnihotri, Mika Sillanpää, Suman, M. Ramya, Vaseem Raja, Suresh Kumar, et al.
    Journal: Inorganic Chemistry Communications
    Year: 2024

 

Khaled Ali | Experimental methods | Best Researcher Award

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Dr. Khaled Ali | Experimental methods | Best Researcher Award

South Valley University| Egypt

Khaled Ali is an accomplished nuclear physicist and academic with a wealth of experience in both research and education. He obtained his PhD in Nuclear Physics from the Institute of Advanced Energy at Kyoto University, Japan in 2022. With a focus on radiation physics, nuclear imaging technologies, and health physics, Khaled has become a leading researcher in his field. He has been a Lecturer and Researcher at the Faculty of Science, South Valley University, Egypt, since 2008, where he teaches, mentors, and supervises students at various academic levels.

👨‍🎓Profile

Google Scholar

Scopus

📘 Early Academic Pursuits

Dr. Ali’s academic journey began at South Valley University, Egypt, where he earned a Bachelor’s degree in Physics (2007) with Excellent with Honor status, ranking first in his class. He continued his studies at the same institution with a Diploma in Nuclear and Radiation Physics (2010), again graduating as the top student. In 2014, he completed a Master’s degree (M.Sc.) in Radiation Physics, laying the groundwork for his later research in environmental and medical radiation physics.

👨‍🔬 Professional Endeavors

Since 2008, Dr. Ali has held a long-standing academic position at South Valley University. His responsibilities span teaching undergraduate and postgraduate physics courses, supervising MSc and PhD theses, and engaging in cutting-edge experimental research. He has also been a visiting researcher at prestigious institutions such as Florida State University (USA) and JINR Dubna (Russia), reflecting a globally recognized career trajectory.

🔬 Contributions and Research Focus

Dr. Ali’s research lies at the intersection of nuclear technology, environmental safety, and medical imaging. He has developed 3D isotope-selective CT imaging techniques using Nuclear Resonance Fluorescence (NRF) and laser Compton scattering, contributing to non-destructive detection of nuclear materials. His studies also address natural radionuclide contamination in water, particularly in Egypt, offering public health insights and policy relevance. These works have been published in top-tier journals like Scientific Reports, IEEE Transactions on Nuclear Science, and Phys. Rev. Accel. Beams.

🌍 Impact and Influence

Dr. Ali’s research has both academic and societal impact. His work on radiological health risks in groundwater and lake systems informs environmental monitoring and water safety policy in Egypt and beyond. His NRF-CT imaging innovations are relevant for homeland security, nuclear nonproliferation, and advanced medical diagnostics. He is frequently invited to present at international conferences such as IEEE NSS/MIC and IPAC, and his research has been featured at global events including COP27.

📈 Academic Citations

Dr. Ali’s scholarly contributions are supported by an extensive publication record, with at least 9 high-impact journal papers and over 16 international conference presentations. His works are widely cited in the fields of radiation detection, environmental physics, and nuclear imaging. Metrics like h-index and total citations (not provided here) would likely reflect a solid academic footprint, given the DOIs and journal impact levels.

🧪 Research Skills

Dr. Ali is highly proficient in advanced nuclear instrumentation, gamma-ray imaging, NRF methods, and neutron activation analysis. He excels in both experimental design and data interpretation, with strong collaborative work in multinational research teams. His technical proficiency spans radioisotope quantification, radiation safety modeling, and simulation-based visualization techniques.

📚 Teaching Experience

With over 15 years of academic teaching, Dr. Ali has instructed a wide range of physics courses at the undergraduate level and specialized nuclear physics modules at the postgraduate level. His role in supervising graduate theses underlines his ability to mentor emerging scientists and support research-led education.

🏆 Awards and Honors

  • Best Student Award in both BSc (2007) and Diploma (2010) programs

  • MEXT PhD Scholarship, Government of Japan (2018)

  • Scientific Research Travel Fellowships to Russia (2011) and USA (2012)

  • Multiple Best Presentation Awards at national and international conferences, including COP27 (2022) and Basic Sciences and Sustainable Development Conference (2023)

🧭 Legacy and Future Contributions

Dr. Khaled Ali is poised to leave a lasting legacy in the realm of radiation physics and nuclear imaging. His contributions not only strengthen academic understanding but also offer practical solutions to global challenges in environmental safety and non-invasive inspection technologies. Looking forward, his continued work on fused imaging systems and isotope detection is expected to influence next-generation diagnostic tools, nuclear safety systems, and public health frameworks across the globe.

Publications Top Notes

Radiological Risks in Nasser Lake Water and their Health and Environmental Implications

  • Authors: Khaled Ali, Ahmed Abu-Taleb, Abd El-Baset Abbady, Shaban Harb

  • Journal: Scientific Reports

  • Year: 2025

Generation of flat-laser Compton scattering

  • Authors: Hideaki Ohgaki, Khaled Ali, Toshiteru Kii, Heishun Zen, Takehito Hayakawa, Toshiyuki Shizuma, Masaki Fujimoto, Yoshitaka Taira

  • Journal: Physical Review Accelerators and Beams, Vol. 26, No. 9, p. 093402

  • Year: 2023

Fusion Visualization Technique to Improve a Three-Dimensional Isotope-Selective CT Image Based on Nuclear Resonance Fluorescence with a Gamma-CT Image

  • Authors: Khaled Ali, Heishun Zen, Hideaki Ohgaki, Toshiteru Kii, Takehito Hayakawa, Toshiyuki Shizuma, Masaki Fujimoto, Yoshitaka Taira, Masahiro Katoh, Hiroyuki Toyokawa

  • Journal: Applied Sciences, Vol. 11, Article 11866

  • Year: 2021

Three-Dimensional Nondestructive Isotope-Selective Tomographic Imaging of 208Pb Distribution via Nuclear Resonance Fluorescence

  • Authors: Khaled Ali, Hideaki Ohgaki, Heishun Zen, Toshiteru Kii, Takehito Hayakawa, Toshiyuki Shizuma, Hiroyuki Toyokawa, Yoshitaka Taira, Masaki Fujimoto, Masahiro Katoh

  • Journal: Applied Sciences, Vol. 11, No. 8, p. 3415

  • Year: 2021

Natural radionuclides in groundwater from Qena governorate, Egypt

  • Authors: Khaled Salahel Din, Khaled Ali, Shaban Harb, Abdel Baset Abbady

  • Journal: Environmental Forensics, Vol. 22, No. 1–2, pp. 48–55

  • Year: 2020

 

 

Changjun Chen | Experimental methods | Best Researcher Award

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Prof. Changjun Chen | Experimental methods | Best Researcher Award

Director at Soochow University | China

Prof. Changjun Chen is a renowned expert in laser materials processing and holds a professorship at the Laser Processing Research Center, School of Mechanical and Electric Engineering, Soochow University, Suzhou, China. He is also the Secretary General of both the Laser Industry Alliance of G60 S&T Innovation Valley of Yangtze River and the Jiangsu Province Laser Innovation. Prof. Chen’s research spans a variety of cutting-edge applications, particularly in laser welding, laser metal deposition, laser-assisted material removal, and surface modification. He has significantly contributed to the development of new techniques in these areas that are pivotal for industrial applications, especially in aerospace, automotive, and energy sectors.

👨‍🎓Profile

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📚 Early Academic Pursuits

Prof. Chen began his academic journey by obtaining his Bachelor’s degree (BE) in 2000 from Northeastern University in Shenyang, China. He further advanced his education by earning a Ph.D. in 2007 from the Institute of Metal Research, Chinese Academy of Sciences, specializing in materials science. His early academic pursuits laid a strong foundation for his later contributions to laser processing and materials science.

💼 Professional Endeavors

Prof. Chen’s professional career began in 2007 when he joined Wuhan University of Science and Technology, where he served as an associate professor until 2011. His career took a major leap when he joined Soochow University in 2011, attaining the title of Professor. His academic journey also includes a significant research visit to Columbia University in 2013-2014, supported by the China Scholarship Council. This international exposure has allowed him to collaborate and interact with leading researchers across the globe.

🔬 Contributions and Research Focus

Prof. Chen’s research is focused on laser materials processing and its industrial applications. His group explores a range of cutting-edge topics, including:

  • Laser Metal Deposition: Particularly for superalloys and high-strength steels like high-speed steel, which are essential for both remanufacturing and manufacturing processes.

  • Laser-Forming of Metallic Foam: For applications in aerospace and automotive industries, focusing on shock absorption, weight reduction, and sustainability.

  • Laser Cladding for Gas Turbines: Optimizing superalloys for use in extreme environments.

  • Laser Welding/Sealing of Glass to Metal/Alloy: A highly specialized area of industrial processing.

His group’s novel experimental setups, combined with materials characterization and theoretical/numerical models, aim to improve quality and productivity in manufacturing processes.

🌍 Impact and Influence

Prof. Chen’s work has had a profound impact on both academia and industry. His research in laser processing has directly contributed to increased productivity, improved quality, and enhanced efficiency in manufacturing and remanufacturing industries. Prof. Chen’s involvement in laser innovation not only benefits industrial applications but also supports sustainable practices, notably through the development of metal foams for weight reduction in transportation and aerospace sectors.

📑 Academic Cites

With over 200 peer-reviewed papers published, Prof. Chen’s work is highly regarded in the scientific community. His contributions have earned him significant recognition, with over 100 of these papers cited in SCI-indexed journals. His publications reflect his deep expertise in materials science and laser processing technology.

🛠️ Research Skills

Prof. Chen’s research is characterized by his innovative approach to laser material interactions, which involves a balance of theoretical investigation and hands-on experimentation. His skills in materials characterization, numerical simulations, and process optimization have enabled him to make significant advancements in laser welding, cladding, and deposition processes. Furthermore, his expertise in foam shaping via laser forming has contributed to the development of sustainable manufacturing techniques for industries like automotive and aerospace.

🏅 Teaching Experience

In addition to his research, Prof. Chen has a long history of mentoring students and professionals in the field of materials science and laser processing. As a professor at Soochow University, he has played a pivotal role in shaping the careers of countless graduate and post-graduate students. His teaching style emphasizes the integration of theoretical knowledge with practical application, ensuring that his students are well-prepared for careers in both academia and industry.

🌱 Legacy and Future Contributions

Prof. Chen’s work has laid a solid foundation for future advancements in laser processing technologies. His contributions to sustainable manufacturing through laser-assisted foam shaping and metal deposition are expected to shape the future of the aerospace, automotive, and energy industries. His research group continues to push the boundaries of what is possible in laser-based manufacturing, and his global collaborations ensure that his influence will continue to grow, benefiting industries worldwide.

Publications Top Notes

Effect of composite adding Ta and Mo on microstructure and properties of W-Mo-Cr high-speed steel prepared by laser metal deposition

  • Authors: M. Zhang, C. Chen (Changjun)
    Journal: Applied Physics A: Materials Science and Processing
    Year: 2025

The influence of anodization on laser transmission welding between high borosilicate glass and TC4 titanium alloy

  • Authors: L. Li (Lei), C. Chen (Changjun), C. Li (Chunlei), C. Tian (Chen), W. Zhang (Wei)
    Journal: Optics and Laser Technology
    Year: 2025

Effect of High-Temperature Oxidation on Laser Transmission Welding of High Borosilicate Glass and TC4 Titanium Alloy

  • Authors: M. Xu (Mengxuan), C. Chen (Changjun), J. Shao (Jiaqi), M. Zhang (Min), W. Zhang (Wei)
    Journal: Journal of Materials Engineering and Performance
    Year: 2025

Comparative Study of the Effects of Different Surface States During the Laser Sealing of 304 Steel/High-Alumina Glass

  • Authors: C. Chen (Changjun), B. Bao (Bei), J. Shao (Jiaqi), M. Zhang (Min), H. Liu (Haodong)
    Journal: Coatings
    Year: 2025

Effects of Different Surface Treatment Methods on Laser Welding of Aluminum Alloy and Glass

  • Authors: C. Chen (Changjun), L. Li (Lei), M. Zhang (Min), W. Zhang (Wei)
    Journal: Coatings
    Year: 2024

 

Sheng Hsiung Chang | Experimental methods | Best Researcher Award

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Prof. Sheng Hsiung Chang | Experimental methods | Best Researcher Award

Professor at National Taiwan Ocean University | Taiwan

Dr. Sheng Hsiung Chang is a Professor at the National Taiwan Ocean University. His extensive career in academia and research is marked by significant roles in leading institutions such as Chung Yuan Christian University (CYCU) and National Central University. Dr. Chang’s work has spanned across several pivotal research areas, particularly in semiconductor physics, optical physics, and perovskite optoelectronic devices. His achievements not only demonstrate his technical expertise but also highlight his commitment to academic leadership, mentorship, and advancing scientific knowledge.

👨‍🎓Profile

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Early Academic Pursuits 🎓

Dr. Chang’s academic journey began with his postdoctoral research roles, first at Academia Sinica (2008-2010) and later at National Central University (2010-2012), where he gained foundational experience in semiconductor and optical physics. During these early years, he developed a strong interest in light-material interactions and functional thin films, fields that would shape his future research directions. His foundational work in nanotechnology and optoelectronics established the groundwork for his later academic and research career.

Professional Endeavors 🌍

Dr. Chang has held pivotal roles in academia, including Associate Professor and Professor at CYCU, where he also served as the Director of the Career Service Center (2020-2021). These positions reflect his commitment to fostering both the research and professional development of students. Additionally, he has contributed to the scientific community as an Editorial Board Member for journals such as Nanotechnology and Physics Bimonthly.

He has also demonstrated leadership in academic societies, serving as Vice Chairman (2021-2024) and Secretary General (2019-2020) of the Taiwan Vacuum Society. This involvement shows his dedication not only to research but also to promoting collaboration and innovation within the scientific community.

Contributions and Research Focus 🔬

Dr. Chang’s research is centered around perovskite optoelectronic devices, light-material interactions, plasmonic devices, nonlinear optics, and functional thin films. He is currently the Principal Investigator for various research projects funded by the National Science and Technology Council (NSTC) and the Ministry of Science and Technology (MOST). His groundbreaking work on perovskite thin films and their applications in photovoltaic cells is pushing the boundaries of renewable energy technologies. Through projects that explore optical coupling, material interfaces, and energy harvesting, Dr. Chang’s research is expected to revolutionize the optoelectronics field.

Impact and Influence 🌍

Dr. Chang’s contributions to the scientific community have had far-reaching implications, particularly in the area of perovskite solar cells. His work on improving photovoltaic performance and investigating interfacial contacts between organic and inorganic materials has the potential to enhance solar cell efficiency and sustainability. He is a key player in advancing technologies related to energy conversion, helping to foster sustainable solutions to global energy challenges. His leadership roles in academic societies have also expanded his influence and outreach in the scientific community.

Academic Citations 📈

Dr. Chang has an impressive publication record, with recent articles in high-impact journals such as Nanotechnology, Synthetic Metals, and Materials Science in Semiconductor Processing. His work is frequently cited by fellow researchers in the field of optoelectronics, particularly his studies on perovskite materials and their optical properties. These citations underscore the significance and influence of his research in both academia and industry.

Research Skills 🧑‍🔬

Dr. Chang possesses an extensive skill set in semiconductor physics, optical physics experiments, and theoretical computations. His research involves complex techniques such as material synthesis, thin film fabrication, and optical characterization. He has a deep understanding of light-matter interactions and their application to next-generation devices like solar cells and plasmonic devices. Additionally, his ability to bridge experimental techniques with theoretical models allows him to tackle complex challenges in material design and optoelectronic applications.

Teaching Experience 🏫

In his roles as a Professor and Associate Professor, Dr. Chang has mentored numerous graduate and postgraduate students in their research pursuits. His teaching approach is centered around encouraging critical thinking, innovation, and hands-on experimentation. His experience in guiding students and fostering academic growth aligns with his belief in the importance of collaboration and mentorship within academic settings. He also plays an active role in career development, helping students transition into the professional world with a strong foundation in research and industry-related skills.

Awards and Honors 🏆

Throughout his career, Dr. Chang has been the recipient of several prestigious awards and honors, recognizing his contributions to the fields of optical physics, semiconductor research, and perovskite optoelectronics. His ongoing recognition as a leader in nanotechnology and materials science reflects his consistent pursuit of excellence in both academic research and scientific innovation.

Legacy and Future Contributions 🔮

Dr. Chang’s work is poised to leave a lasting impact on the scientific community, particularly in the field of renewable energy and optoelectronics. As the principal investigator of major research projects, he is advancing the efficiency and sustainability of perovskite-based technologies, paving the way for affordable and efficient solar energy solutions. Dr. Chang’s future contributions to nanomaterials and functional thin films will likely continue to inspire scientific innovation, technological advancements, and environmental sustainability for years to come.

Publications Top Notes

Long room-temperature valley lifetimes of localized excitons in MoS2 quantum dots

  • Authors: H. Wang, Y. Chen, T.Y. Pan, Y. Lee, J. Shen
    Journal: Optics Express
    Year: 2024

Structural and excitonic properties of the polycrystalline FAPbI3 thin films, and their photovoltaic responses

  • Authors: Y. Huang, I.J. Yen, C. Tseng, A. Chandel, S.H. Chang
    Journal: Nanotechnology
    Year: 2024

Observations of two-dimensional electron gases in AlGaN/GaN high-electron-mobility transistors using up-converted photoluminescence excitation

  • Authors: Y. Chen, L. Chen, C.B. Wu, Y.J. Lee, J. Shen
    Journal: Optics Express
    Year: 2024

Efficient Optical Coupling between Dielectric Strip Waveguides and a Plasmonic Trench Waveguide

  • Authors: J. Wu, A. Chandel, C. Chuang, S.H. Chang
    Journal: Photonics
    Year: 2024

Enhancing the photovoltaic responses of MAPbI3 poly-crystalline perovskite films via adjusting the properties of PEDOT:PSS hole transport material with a low-polarity solvent treatment process

  • Authors: C. Tsai, S.N. Manjunatha, M. Sharma, L.B. Chang, C. Chang
    Journal: Materials Science in Semiconductor Processing
    Year: 2024

 

Ramadevi Suguru Pathinti | Experimental methods | Best Researcher Award

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Mrs. Ramadevi Suguru Pathinti | Experimental methods | Best Researcher Award

Research Scholar at National Institute of Technology Warangal | India

Ramadevi Suguru Pathinti is currently pursuing her Ph.D. in Physics at the National Institute of Technology, Warangal, India, specializing in Materials Science with a focus on soft matter research. Her academic journey spans from her M.Sc. in Physics to her ongoing doctoral studies. Ramadevi has made significant contributions in the field of nanomaterials and smart materials, particularly in integrating liquid crystals with metal oxides for the development of advanced gas sensors and UV photodetectors.

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Early Academic Pursuits 🎓

Ramadevi’s academic journey began at Rayalaseema University, Kurnool, India, where she pursued her M.Sc. in Physics with a specialization in Electronics, securing a CGPA of 9.1/10. She also holds a B.Sc. in Mathematics, Physics, and Computer Science. Her strong academic foundation laid the groundwork for her pioneering research in Materials Science during her doctoral studies at NIT, Warangal.

Professional Endeavors 💼

In her professional journey, Ramadevi has excelled in scientific research within both academic and industrial contexts. She has contributed to the development of thin film devices for smart window technologies, gas sensors, and photodetectors. Her Ph.D. research focuses on integrating liquid crystal-functionalized metal oxides to enhance the optical properties and responsivity of sensors, enabling advancements in environmental sensing and optoelectronic devices.

Contributions and Research Focus 🔬

Ramadevi’s research is centered on the synthesis of nanomaterials and their integration into innovative smart materials. She has worked extensively on fabricating gas sensors and UV photodetectors using liquid crystal-metal oxide hybrids. Notably, her work on smart windows is groundbreaking, where she has discovered novel optical switching behaviors and light modulation techniques, paving the way for energy-saving technologies. Furthermore, her synthesis methods like sol-gel and hydrothermal techniques have contributed to enhanced material properties for sensing applications.

Impact and Influence 🌍

Her research has already made a considerable impact in the fields of environmental sensing and smart material development, particularly in the energy-efficient technologies sector. Ramadevi’s work has the potential to revolutionize how we detect gases, modulate light, and develop self-powered sensors, with applications ranging from smart windows to sensitive environmental monitoring systems. Through her research, she aims to bring forth sustainable technologies that are adaptable to changing global needs.

Academic Cites 📚

Ramadevi has authored several impactful publications in top-tier peer-reviewed journals, contributing to the fields of materials science and optoelectronics. Her articles in journals like the Journal of Molecular Liquids, Journal of Alloys and Compounds, and Advanced Material Technology have contributed to the scientific community’s understanding of the integration of nanomaterials and liquid crystals for innovative devices. She has also presented her research at national and international conferences, further strengthening her academic profile.

Research Skills 🛠

Ramadevi has developed extensive technical expertise in nanomaterial synthesis using methods like sol-gel and hydrothermal techniques. She is proficient in device fabrication, particularly thin film devices for gas sensing and UV photodetector applications. Additionally, she has hands-on experience with advanced research instruments, including optical polarizing microscopes, fluorescence microscopes, and spin coating systems, which enhance her ability to conduct high-quality research and device development.

Teaching Experience 📚

In addition to her research, Ramadevi has taught practical sessions for both M.Sc. (Tech) Physics and B.Tech students. She has handled laboratory work, where she imparted valuable knowledge on experimental techniques and device characterization to budding scientists. This experience has helped her develop strong interpersonal and communication skills, which are essential for future academic and industrial collaborations.

Awards and Honors 🏆

Ramadevi’s excellence has been acknowledged through the Joint CSIR-UGC National Eligibility Test (NET) for Junior Research Fellowship (JRF) in 2017, where she secured an impressive All India Rank of 57. This achievement is a testament to her academic aptitude and research potential.

Legacy and Future Contributions 🌟

Looking forward, Ramadevi aims to make lasting contributions to the field of materials science and nanotechnology. Her research is poised to drive innovations in smart materials, sustainable technologies, and energy-efficient devices, with far-reaching implications for environmental sensing, smart window technologies, and optoelectronics. With her interdisciplinary approach and collaborative nature, she is well-positioned to make significant advancements in both academic and industrial research.

Publications Top Notes

Label-free detection of Aβ-42: a liquid crystal droplet approach for Alzheimer’s disease diagnosis

  • Authors: Saumya Ranjan Pradhan, Ramadevi Suguru Pathinti, Ramesh Kandimalla, Krishnakanth Chithari, Madhava Rao Veeramalla N., Jayalakshmi Vallamkondu
    Journal: RSC Advances
    Year: 2024

Enhanced ethanol gas detection using TiO2 nanorods dispersed in cholesteric liquid crystal: Synthesis, characterization, and sensing performance

  • Authors: Ramadevi Suguru Pathinti, Sunil Gavaskar Dasari, Buchaiah Gollapelli, Sreedevi Gogula, Ramana Reddy M.V., Jayalakshmi Vallamkondu
    Journal: Journal of Alloys and Compounds
    Year: 2024

Enhanced security through dye-doped cholesteric liquid crystal shells for anti-counterfeiting

  • Authors: Chris Mathew, Ramadevi Suguru Pathinti, Saumya Ranjan Pradhan, Buchaiah Gollapelli, Krishnakanth Chithari, Mrittika Ghosh, Ashok Nandam, Jayalakshmi Vallamkondu
    Journal: Optical Materials
    Year: 2024

ZnO nanoparticles dispersed cholesteric liquid crystal based smart window for energy saving application

  • Authors: Ramadevi Suguru Pathinti, Arun Kumar Tatipamula, Jayalakshmi Vallamkondu
    Journal: Journal of Alloys and Compounds
    Year: 2023

Energy saving, transparency changing thermochromism in dye-doped cholesteric liquid crystals for smart windows

  • Authors: Ramadevi Suguru Pathinti, Buchaiah Gollapelli, Saumya Ranjan Pradhan, Jayalakshmi Vallamkondu
    Journal: Journal of Photochemistry and Photobiology A: Chemistry
    Year: 2023

 

Jianwen Yang | Experimental methods | Best Researcher Award

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Assoc. Prof. Dr. Jianwen Yang | Experimental methods | Best Researcher Award

Associate Professor, Master’s Supervisor, Deputy Head of the Physics Department at Shanghai Normal University | China

Dr. Jianwen Yang is an Associate Professor at Shanghai Normal University, holding a Ph.D. in Physical Electronics from Fudan University. His primary research focus lies in oxide semiconductors and information display technologies. With significant experience in addressing instability issues in industrial devices, he has contributed to analyzing the performance of a-IGZO TFTs in companies like TSMC and AUOtronics. His innovative work in n-type tin oxide-based TFTs and indium-free doped tin oxide-based TFTs has led to breakthroughs in the field, providing devices with superior electrical characteristics.

👨‍🎓Profile

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Early Academic Pursuits 📚

Dr. Yang’s academic journey began with a solid foundation in Physical Electronics, completing his Ph.D. at Fudan University. During his early studies, he developed a keen interest in the intersection of material science and electronics, which led him to explore oxide thin-film transistors (TFTs) as a promising avenue for future advancements. His focus on new materials and material simplification laid the groundwork for his later innovations in tin oxide-based TFTs, a critical area in the development of modern information display technologies.

Professional Endeavors 💼

Dr. Yang’s professional career has been marked by collaborations with prominent industry leaders like TSMC and AUOtronics, where he contributed to solving the instability challenges in industrialized a-IGZO TFTs. These efforts have provided valuable insights into the performance optimization of thin-film transistors, further driving the industry forward. His participation in national projects, such as those funded by the National Natural Science Foundation of China (NSFC), also highlights his commitment to advancing the field through both academic research and real-world applications.

Contributions and Research Focus 🔬

Dr. Yang’s pioneering research in n-type tin oxide-based TFTs led to the introduction of novel indium-free doped tin oxide materials like SnWO, SnSiO, and SnNiO, which have all exhibited superior electrical characteristics. His work on comparing top/bottom-gate a-IGZO TFTs under varying stress conditions provided valuable insights into threshold voltage shifts and carrier concentration variations, significantly impacting the design and stability of oxide semiconductors in practical applications. He has consistently pushed the boundaries of material research, particularly in the flexible electronics sector.

Impact and Influence 🌍

Dr. Yang’s groundbreaking research has had a profound impact on the development of oxide semiconductor devices, particularly in TFT technology. His innovative approaches have been cited in multiple review articles, and his work continues to influence both academic researchers and industry practitioners. His research on indium-free tin oxide-based TFTs has not only enriched academic literature but also paved the way for more sustainable and efficient solutions in the information display industry. The superior electrical characteristics of his materials have positioned them as viable alternatives to traditional indium-based materials, which are costly and scarce.

Academic Cites 📈

Dr. Yang has published over 38 journals in top-tier scientific databases, including SCI and Scopus, with his work receiving 11 citations. His innovative research has been referenced in numerous review articles, further establishing him as a thought leader in his field. These citations reflect the widespread recognition of his research’s significance, and his publications continue to influence the academic community’s understanding of oxide semiconductors and TFT stability.

Research Skills 🛠️

Dr. Yang’s research skills span a wide range of disciplines, from material science to electronic device engineering. His expertise in thin-film transistor design, instability analysis, and new material development has allowed him to push the envelope in semiconductor research. He is particularly skilled in analyzing the electrical performance of TFTs under various stress conditions, demonstrating an acute understanding of the intricate relationship between material properties and device functionality. Additionally, his work in flexible electronics is a testament to his ability to innovate in emerging areas.

Teaching Experience 👩‍🏫

As an Associate Professor at Shanghai Normal University, Dr. Yang has been involved in educating and mentoring the next generation of scientists and engineers. He brings his extensive research experience into the classroom, enriching students’ learning experiences. Dr. Yang’s teaching focuses on semiconductor physics, material science, and electronics. His dedication to student development is evident in his guidance of graduate students and the collaborative environment he fosters for academic exploration.

Awards and Honors 🏅

Dr. Yang’s contributions have been recognized by several prestigious national research organizations, including the National Natural Science Foundation of China. His research projects, such as the Study on the Instability of Flexible Amorphous SnSiO Thin Film Transistors, have earned him respect in the academic community and have helped elevate Shanghai Normal University‘s status in the field of electronic materials research.

Legacy and Future Contributions 🔮

Dr. Yang’s research legacy lies in his innovative contributions to oxide semiconductor technology and his dedication to finding sustainable solutions for the electronics industry. His ongoing research projects, including his work on the 345GHz Submillimeter Wave Sideband Separation Receiver for LCT Telescope, show his commitment to exploring cutting-edge technologies. Moving forward, Dr. Yang plans to continue refining indium-free tin oxide-based TFTs and explore their industrial scalability. His work has the potential to impact a variety of industries, from flexible displays to advanced sensors, shaping the future of electronic materials.

Publications Top Notes

Exploring soil-buoyancy interactions: experimental designs and educational implications for enhancing students’ scientific inquiry skills

  • Authors: Zijian Gu, Jianwen Yang
    Journal: Physics Education
    Year: 2025

Fast-response IWO/Si heterojunction photodetectors

  • Authors: Xiaochuang Dai, Jianwen Yang, Huishan Wang, Yunxi Luo, Jinying Zeng, Wangzhou Shi, Feng Liu
    Journal: Journal of Physics D: Applied Physics
    Year: 2025

Enhancement of electrical characteristics of SnGaO thin-film transistors via argon and oxygen plasma treatment

  • Authors: Yinli Lu, Xiaochuang Dai, Jianwen Yang, Ying Liu, Duo Cao, Fangting Lin, Feng Liu
    Journal: Vacuum
    Year: 2024

Preparation of chalcogenide perovskite SrHfS3 and luminescent SrHfS3:Eu2+ thin films

  • Authors: Yanbing Han, Jiao Fang, Yurun Liang, Han Gao, Jianwen Yang, Xu Chen, Yifang Yuan, Zhifeng Shi
    Journal: Applied Physics Letters
    Year: 2024

Degradation Behavior of Etch-Stopper-Layer Structured a-InGaZnO Thin-Film Transistors Under Hot-Carrier Stress and Illumination

  • Authors: Dong Lin, Wan-Ching Su, Ting-Chang Chang, Hong-Chih Chen, Yu-Fa Tu, Kuan-Ju Zhou, Yang-Hao Hung, Jianwen Yang, I-Nien Lu, Tsung-Ming Tsai et al.
    Journal: IEEE Transactions on Electron Devices
    Year: 2021

 

 

Marcin Szczęch | Experimental methods | Excellence in Innovation

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Assoc. Prof. Dr. Marcin Szczęch | Experimental methods | Excellence in Innovation

AGH University of Krakow | Poland

Marcin Szczęch is a professor at the AGH University of Krakow in Poland, specializing in the study of magnetic fluids (both magnetorheological and ferrofluid) and their applications, particularly in sealing technology. With an academic career dedicated to exploring fluid dynamics and material science, Szczęch’s work has influenced several engineering fields, contributing both to theoretical studies and practical solutions. His groundbreaking contributions, particularly in magnetic fluid sealing, have earned him a reputation as a leading researcher in his field.

👨‍🎓Profile

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Early Academic Pursuits 🎓

Marcin Szczęch’s academic journey began at the AGH University of Krakow, where he earned both his Bachelor’s and Ph.D. in Mechanical Engineering. His Ph.D. thesis focused on the durability of rotary ferrofluid seals in water environments, setting the foundation for his expertise in magnetic fluid applications. After earning his Doctor of Philosophy in 2014, he further advanced his research by exploring the continuity behavior of liquid rings formed by magnetic liquids, which earned him a post-doctoral degree in 2021.

Professional Endeavors 💼

Since 2011, Szczęch has been a faculty member at the AGH University of Krakow, currently holding the position of Professor at the Faculty of Mechanical Engineering and Robotics. In this role, he has not only continued to drive forward his research on magnetic fluids but also contributed significantly to the academic environment by mentoring over 40 students and supervising doctoral research projects. His main research areas focus on magnetorheological and ferrofluids and their use in various industrial applications, especially for fluid seals, vibration isolators, and lubrication systems.

Contributions and Research Focus 🔬

Marcin Szczęch’s research is primarily focused on magnetic fluids and their practical applications. His work has explored the use of these fluids in various contexts, such as magnetic fluid sealing systems, lubrication systems, and vibration isolators. Some of his most notable projects include the development of the Compact Magnetic Fluid Seal (CMFS) and research into biocompatible coatings for medical applications. He has also worked extensively on magnetic fluid lubricated bearings, contributing to the understanding of how these materials operate under magnetic field conditions.

Impact and Influence 🌍

Marcin Szczęch has made a significant impact in both academia and industry. His published research in prominent journals and his extensive patent portfolio (24 patents granted by the Polish Patent Office) underscores his ability to not only advance the scientific understanding of magnetic fluids but also provide practical solutions for industries such as machine design, materials science, and bioengineering. His multidisciplinary research continues to push the boundaries of engineering, positioning him as a key influencer in the development of innovative fluid dynamics solutions.

Academic Cites and Scholarly Recognition 📚

Szczęch’s scholarly work has earned him a strong reputation, as evidenced by his 52 publications on the AGH BaDAP list and 23 indexed in the Web of Science database. With an H-index of 9, Szczęch’s work has been cited numerous times, indicating its relevance and importance in the academic community. His contributions to magnetic fluid dynamics have gained recognition in a wide array of engineering disciplines, cementing his status as a thought leader in the field.

Research Skills and Expertise ⚙️

Szczęch is proficient in a variety of engineering programs such as SolidWorks, AutoCAD, Matlab, Mathcad, Ansys, and LabVIEW, and is well-versed in operating specialized research equipment like rotational rheometers, particle distribution analyzers, and 3D scanners. His expertise in magnetic fluids, coupled with his command of these advanced tools, allows him to carry out both theoretical and experimental studies that bridge the gap between research and industrial application.

Teaching Experience 📖

As a professor, Szczęch teaches a wide range of courses, including Fundamentals of Machine Construction, Machine Design, Modern Engineering Materials, and Computer-Aided Design. His teaching has positively impacted numerous students, with more than 40 thesis works realized under his supervision. He plays an active role in shaping the next generation of engineers and researchers, fostering a deep understanding of both fundamental principles and practical applications of magnetic fluid technologies.

Awards and Honors 🏆

Marcin Szczęch’s work has been recognized through various grants, patents, and research projects. He has received numerous accolades for his contributions to engineering, particularly in the areas of magnetic fluid sealing systems and lubrication technologies. His 24 patents and participation in several innovative research projects underscore his commitment to pushing the envelope of applied research. Additionally, he has been recognized for his role in supervising and mentoring students, further establishing his credibility as an academic leader.

Legacy and Future Contributions 🌱

Marcin Szczęch’s legacy is shaped by his contributions to magnetic fluid technology, especially in the development of advanced seals, lubricants, and vibration isolators. Looking forward, Szczęch is poised to expand his research into sustainable and eco-friendly applications of magnetic fluids, particularly in the context of green engineering and biotechnology. His future contributions could bridge the gap between advanced materials and sustainability, aligning his work with the growing global focus on environmentally conscious engineering solutions.

Publications Top Notes

Research into the pressure capability and friction torque of a rotary lip seal lubricated by ferrofluid

  • Authors: Marcin Szczęch
    Journal: Journal of Magnetism and Magnetic Materials
    Year: 2025

Analysis of a new type of electric power steering gear with two pinions engaged on the same set of teeth on the rack

  • Authors: Marcin Szczęch, Marcin Nakielski, Jaroslaw Bujak
    Journal: Tribologia: teoria i praktyka
    Year: 2024

Comparative study of models and a new model of ferrofluid viscosity under magnetic fields and various temperatures

  • Authors: Marcin Szczęch, Tarasevych Yuliia
    Journal: Tribologia: teoria i praktyka
    Year: 2024

Research into the properties of magnetic fluids produced by milling technology

  • Authors: Wojciech Horak, Marcin Szczęch
    Journal: Tribologia: teoria i praktyka
    Year: 2024

The influence of printing parameters on leakage and strength of fused deposition modelling 3D printed parts

  • Authors: Marcin Szczęch, Wojciech Sikora
    Journal: Advances in Science and Technology Research Journal
    Year: 2024