Amit Kumar Verma | Surface Engineering | Young Scientist Award

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Dr. Amit Kumar Verma | Surface Engineering | Young Scientist Award

Ph.D. Research Scholar at University of Lucknow | India

Amit Kumar Verma is a passionate researcher in the field of advanced materials and gas sensor technology. He is currently pursuing his Ph.D. at the University of Lucknow in the Department of Physics, working under the guidance of Prof. N. K. Pandey. His research is centered on the synthesis and characterization of metal oxide-based thin films for humidity and gas sensing applications. With a strong foundation in physics, he has developed expertise in nanostructured materials, ion beam irradiation, and hydrogen sensing. He has actively contributed to multiple high-impact research publications and has presented his work at numerous national and international conferences. Amit is dedicated to the development of energy-efficient, environmentally responsive sensor technologies. His commitment to interdisciplinary collaboration and scientific innovation continues to drive his work forward. As an emerging scholar, he is also involved in supervising postgraduate research, contributing to the next generation of scientific inquiry.

Professiona Profiles

Scopus

Education

Amit Kumar Verma began his academic journey with a Bachelor of Science in Physics and Mathematics from the University of Allahabad, followed by a Master of Science in Physics with a specialization in Electronics. He achieved a high academic standing during his postgraduate studies. Currently, he is pursuing a Ph.D. in Physics at the University of Lucknow, focusing on the development of metal oxide-based gas sensors. His doctoral thesis involves the synthesis and structural analysis of nanostructured metal oxides using ion beam irradiation and various deposition techniques. Amit’s educational path reflects a consistent dedication to the physical sciences, with a strong emphasis on applied materials research. Through his academic training, he has developed proficiency in spectroscopy, microscopy, and advanced thin-film technologies. His hands-on experience with analytical techniques and research instrumentation underpins his contributions to sensor technology and nanomaterials development for practical applications.

Experience

Amit Kumar Verma has cultivated a strong research background in materials science, particularly within the field of gas sensors and nanostructured thin films. As a doctoral researcher at the University of Lucknow, he has been involved in the fabrication and analysis of metal oxide-based chemiresistors for environmental and hydrogen sensing. He has gained practical experience through workshops and internships at institutions such as IIT Jodhpur, IITRAM, and the Inter-University Accelerator Centre in New Delhi. His research focuses on thin film deposition techniques, ion beam modification, and characterization methods like XRD, SEM, TEM, and XPS. In addition to his technical work, he has mentored postgraduate students, guiding them in nanomaterial synthesis and device development. Amit has presented his research at several national conferences, contributing actively to the academic community. His collaborative work with multidisciplinary teams has resulted in impactful publications and practical advancements in sensor technology.

Awards & Honors

Amit Kumar Verma has received several recognitions for his academic and scientific contributions. He was awarded the Karmayogi Fellowship at the University of Lucknow in recognition of his research potential and academic performance. During his early academic years, he was honored as a gold medalist in high school and has consistently maintained strong academic results. In addition to academic achievements, he was elected as the Science Faculty Representative in the Student Union Election at the University of Allahabad, highlighting his leadership and peer recognition. Amit has participated in prestigious training programs and workshops, including sessions on ion beams in energy materials and hydrogen gas sensors. His work has earned him multiple opportunities to present at national-level conferences and symposia. These accolades reflect his commitment to excellence in both scientific research and academic service, positioning him as a promising young researcher in the field of advanced materials and sensor applications.

Research Focus

Amit Kumar Verma’s research is centered on the synthesis, modification, and characterization of nanostructured metal oxide thin films for gas sensing applications. His work explores the effects of ion beam irradiation and doping techniques on the structural, optical, and sensing properties of materials such as WO3, MoO3, SnO2, and CuO. He focuses particularly on hydrogen sensing, developing high-performance chemiresistors for environmental and industrial safety. His interdisciplinary approach combines material synthesis using sol-gel, spin coating, and sputtering with advanced characterization techniques including XRD, SEM, TEM, and UV-Vis spectroscopy. He also investigates structural modifications using ion irradiation and studies their impact on gas sensitivity and selectivity. His work aims to address the global need for efficient, reliable, and cost-effective gas detection systems. By integrating knowledge of materials science, physics, and electrical properties, Amit is contributing to the development of next-generation sensor devices for real-world applications.

Publication Top Notes

Title: Slope stability assessment of the section along Balipara–Charduar–Tawang Road, Arunachal Pradesh, India
Year: 2025

Title: Tailoring the properties of WO3 via 120 MeV Ni7+ beam irradiation: A pathway to high-performance hydrogen sensor
Year: 2025

Title: Effect of Elevated Temperature on Mechanical and Structural Properties of Bentonite from Barmer, Rajasthan
Year: 2025

Title: Enhanced hydrogen gas sensing performance with Ag-doped WO3 thin film
Year: 2025
Citations: 9

Title: Effect of pore water pressure on slope stability in a heavy-haul railway embankment using a deep learning approach
Year: 2025
Citations: 1

Title: An extensive analysis: Impact of 120 MeV Ni7 + beam irradiation on the structural, morphological, and optical properties of WO3 thin films
Year: 2025
Citations: 2

Title: Cutting-Edge OER Electrocatalysts for Sustainable Seawater Electrolysis: Progress, Obstacles, and Future Prospects
Year: Not specified
Citations: 5

Conclusion

Amit Kumar Verma is a strong and suitable candidate for the Research for Young Scientist Award. His focused work on gas sensors and nanostructured materials, supported by strong publication metrics and technical depth, demonstrate exceptional promise as a young researcher. With ongoing research contributions, mentorship, and increasing academic visibility, he represents the next generation of scholars poised to make impactful advancements in materials and sensor technology.

Pengchao Kang | Al Matrix | Best Researcher Award

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Prof. Dr. Pengchao Kang | Al Matrix | Best Researcher Award

Professor at Harbin Institute of Technology | China

Dr. Pengchao Kang is a distinguished professor in the Department of Materials Science at the School of Materials Science and Engineering, Harbin Institute of Technology, China. With a strong foundation in engineering and innovation, Dr. Kang has dedicated his career to advancing materials research, especially in carbon matrix composites and energy materials. He earned his B.Sc. and M.Sc. degrees from the Northeast Heavy Machinery Institute and completed his Ph.D. at Harbin Institute of Technology. In 2011, he expanded his global academic collaboration as a visiting scholar at North Carolina State University, USA. With over 90 research papers published in peer-reviewed journals and active involvement in scientific reviewing across major publications, Dr. Kang continues to impact the materials science community. His areas of interest include ablation-resistant materials, aluminum matrix composites, and next-generation energy storage systems.

Professional Profiles

ORCID

Scopus

Education 

Dr. Kang’s academic journey began at the prestigious Northeast Heavy Machinery Institute, where he obtained both his Bachelor’s and Master’s degrees in materials science and engineering. These formative years laid a solid technical foundation for his later research excellence. His academic pursuit culminated with a Ph.D. from Harbin Institute of Technology, one of China’s leading institutions in advanced engineering research. With a strong commitment to academic growth, Dr. Kang also participated in international academic exchange as a Visiting Scholar at North Carolina State University in 2011. This diverse and robust academic background supports his research in high-performance composites, carbon materials, and functional nanostructures. His education, enriched with hands-on research, advanced theoretical understanding, and international exposure, uniquely positions him to tackle pressing challenges in materials design and processing.

Experience

Dr. Pengchao Kang brings extensive professional experience from both domestic and international academic spheres. As a Professor in the Department of Materials Science at Harbin Institute of Technology, he has spearheaded numerous research projects related to composite materials, nanostructures, and energy systems. His role also involves mentoring graduate students and fostering collaborative research with interdisciplinary teams. In 2011, Dr. Kang served as a Visiting Scholar at North Carolina State University, USA, where he deepened his expertise in advanced materials and expanded his global academic network. Over the years, he has also contributed as a peer reviewer for over 10 international journals, including Carbon, Intermetallics, Ceramics International, and Materials & Design. His academic and research excellence continues to inspire innovation in carbon composites, ablation resistance, and functional materials across various industrial and academic applications.

Awards and Honors

Dr. Kang has received multiple accolades recognizing his outstanding contributions to materials science and engineering. Although specific award titles are not listed in the available information, his track record—publishing over 90 peer-reviewed research articles and serving as a reviewer for prestigious international journals—attests to his excellence and high standing in the global research community. His invitation as a Visiting Scholar to North Carolina State University highlights international recognition of his work. His sustained participation in cutting-edge research and peer-review activities in journals such as Carbon, Ceram Int, Materials & Design, and Journal of Alloys and Compounds further underscores his authority and credibility in the field. Dr. Kang is often regarded as a thought leader in the development of carbon matrix composites and energy storage materials, where his innovations continue to receive appreciation both nationally and internationally.

Research Focus

Dr. Kang’s research primarily revolves around carbon matrix ablation-resistant materials, carbon fiber-reinforced aluminum composites, and advanced energy storage materials. His work in ablation resistance is particularly critical for aerospace and defense applications, where thermal protection systems are key. Additionally, his exploration of carbon fiber/aluminum composites contributes to the development of lightweight, high-strength materials used in automotive and structural components. In the field of energy storage, Dr. Kang investigates novel electrode materials and structural designs to improve battery capacity, efficiency, and thermal stability. By bridging fundamental materials science with practical engineering solutions, he addresses real-world challenges in sustainability, durability, and performance. His interdisciplinary research impacts both academia and industry, providing insights into the thermomechanical behavior, microstructure-property relationships, and fabrication techniques of advanced materials.

Publications to Notes

The influence of TiN coatings on the microstructure and mechanical properties of continuous titanium fiber‑reinforced aluminum matrix composites
Year: 2025

Tribological performance and mechanism of the titanium fiber‑SiC whisker hybrid reinforced aluminum matrix composites prepared by pressure infiltration
Year: 2024

First‑Principles Study on the Influence of Crystal Structures on the Interface Properties of Graphene/Titanium Composites
Year: 2024

In‑situ synthesis of SiC/SiO₂ nanowires by catalyst‑free thermal evaporation of silicon powder and their photoluminescence properties
Year: 2024
Citations: 4

Research on low flow stress and quantitative DRX analysis in B₄C/Al composites with interfacial amorphous B₂O₃ layer
Year: 2024
Citations: 9

High‑Yield Synthesis of SiC@SiO₂ Core‑Shell Nanowires on Graphite Substrates for Energy Applications
Year: 2023
Citations: 4

Conclusion

Dr. Pengchao Kang is a strong contender for the Best Researcher Award, backed by a prolific publication record, specialized expertise in metallurgical and composite materials, and international research engagement. While his credentials reflect research excellence, the nomination could be further enhanced by providing metrics on impact, recognitions, and research leadership. Overall, he is highly suitable for this award category and stands as a role model in the academic materials science community.

Rui Nie | Tribology | Best Researcher Award

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Assoc. Prof. Dr. Rui Nie | Tribology | Best Researcher Award

Associate Researcher at Ningbo Institute of Technology, China.

Dr. Rui Nie is a distinguished researcher at the Ningbo Institute of Technology, Beihang University, specializing in mechanical tribology and surface engineering. His work addresses the pressing challenges in aerospace actuation systems and spacecraft interfaces. Through interdisciplinary approaches, Dr. Nie has significantly advanced understanding of friction, wear, and lubrication behaviors in high-performance environments. He has contributed to projects like the “973 Program” and the Chang’e lunar missions. With deep insight into ultrasonic motors, piston pumps, and tribological systems, Dr. Nie has developed dynamic models, predictive algorithms, and innovative surface treatments. His contributions extend from theory to real-world application, exemplified by his involvement in multiple prototype generations of aerospace electro-hydraulic actuation systems. His collaborative research has been published in high-impact journals and recognized through competitive funding from major national foundations. A dynamic contributor to China’s cutting-edge aerospace innovation, Dr. Nie remains committed to pushing boundaries in tribology and material performance.

Professional Profiles📖

Scopus

ORCID

Education📚

Dr. Rui Nie has a rich academic background grounded in mechanical engineering and tribology. He earned his undergraduate and master’s degrees from the School of Mechanical Engineering, Shenyang University of Technology (2005–2019). During this period, he served as an intern at the Huachen Group and in the State Key Lab for Tunnel Boring Machines. From 2013 to 2019, he pursued his Ph.D. at Shenyang University of Technology, supported by joint training under the prestigious 973 Program at Nanjing University of Aeronautics and Astronautics. He expanded his international experience as a special research student at the Muroran Institute of Technology in Japan (2017–2018). Following this, he undertook a postdoctoral fellowship at NUAA’s School of Aeronautics and Astronautics (2019–2021). This diverse and intensive academic journey equipped Dr. Nie with multidisciplinary skills in surface mechanics, aerospace tribology, and machine learning applications.

Professional Experience💼

Dr. Rui Nie currently serves at Ningbo Institute of Technology, Beihang University, where he leads advanced research in tribology and aerospace surface systems. He has played key roles in projects involving ultrasonic motors for spacecraft, aviation electric pumps, and EHA systems, contributing to the development of three generations of aerospace prototypes. His work has addressed real-world challenges in high-speed oil-lubricated interfaces, solid-liquid composite lubrication, and surface texturing. Dr. Nie employs high-precision simulation, mechanical characterization, and machine learning to study friction behavior, wear resistance, and lubrication mapping. His collaborative research has led to patented technologies and has been published in top Q1 journals. He has been a core team member on major national projects, including the 973 Program, and his ultrasonic motor technology has been applied in Chang’e-4, Chang’e-5, and Mozi missions. He is an emerging leader in tribo-mechanical design and aerospace system optimization.

Research Focus 🔍

🔧 Dr. Rui Nie’s research centers on mechanical tribology, 🧪surface coating technologies, and 🚀aerospace actuation components. He explores three major areas:
1️⃣ Frictional behavior at interfaces — investigating the wear and lubrication mechanisms in high-speed, heavy-duty aerospace components such as aviation piston pumps.
2️⃣ Motion conversion mechanisms — modeling dynamic vibration and displacement behaviors in ultrasonic motor interfaces used in spacecraft.
3️⃣ Material-friction property mapping — using machine learning to correlate mechanical material properties with wear performance and friction coefficients.
His research also includes 🧴 coatings (DLC, nitrides), 🧬 nanolubricants (MXene, MoS₂, graphene), and 🖋️ texture design based on bio-mimetic and stress field analysis. These innovations are applied in low-wear friction pair systems, enhancing performance and durability. Dr. Nie’s goal is to deliver precision surface engineering solutions that improve reliability and energy efficiency in extreme environments.

Awards and Honors🏆

Dr. Rui Nie’s excellence in tribology and aerospace engineering has earned him multiple national and regional research grants, including two projects funded by the National Natural Science Foundation of China (52475048 & 52105062) and two from the Ningbo Natural Science Foundation (2024S001 & 2021J013). His contributions to the 973 Program, a landmark national scientific initiative, highlight his deep involvement in strategic technological advancements. Dr. Nie’s work on aerospace friction pairs and ultrasonic motors has directly supported Chang’e lunar missions and other high-profile projects in both aerospace and biomedical sectors. He has received institutional honors for innovation in mechanical design and contributions to tribology science, and he frequently serves as a reviewer for top-tier journals. His ability to translate theoretical research into applied technologies sets him apart in the Chinese engineering community. These achievements reflect his dedication to bridging the gap between academic rigor and engineering impact.

Conclusion ✅

Dr. Rui Nie undoubtedly qualifies as a top-tier candidate for the Best Researcher Award in Friction and Sealing. His multi-disciplinary research, experimental depth, and real-world contributions to aerospace systems make him a benchmark figure in tribology. Minor enhancements in international outreach and technology transfer visibility could elevate his already distinguished profile even further.

Publications to Noted📚

A prediction model of fluid–solid erosion wear in hydraulic spool valve orifice (Wear, 2024)

Authors: Li, D.; Liu, X.; Liao, H.; Bing, L.; Hou, P.; Nie, R.; Jiao, Z.

Citations: 12

Adaptive robust motion control for hydraulic load sensitive systems considering displacement dynamic compensation (ISA Transactions, 2024)

Authors: Qiu, Z.; Liu, X.; Wang, Z.; Chen, X.; Nie, R.

Citations: 1

Cascade control method for hydraulic secondary regulation drive system based on adaptive robust control (ISA Transactions, 2024)

Authors: Liu, X.; Wang, Z.; Qiu, Z.; Jiao, Z.; Chen, X.; Nie, R.

Comparative study on thermal-oxygen aging and tribological properties of carbon nanotubes and graphene sheet reinforced hydrogenated nitrile rubber composite materials (Journal of Materials Research and Technology, 2024)

Authors: Qian, C.; Wang, S.; Li, Y.; Nie, R.; Song, S.

Design and preparation of sulfur vulcanized polyamide 66 cross-linked nitrile butadiene rubber networked and its application in blending with graphene oxide (Materials Today Communications, 2024)

Authors: Li, X.; Li, Y.; Qian, C.; Wang, S.; Nie, R.

Experimental investigation of the annular gradient process for circular channels using laser powder bed fusion (Optics and Laser Technology, 2024)

Authors: Li, D.; Liu, X.; Hou, P.; Liao, H.; Yu, R.; Nie, R.; Jiao, Z.

Extended-state-observer-based pressure compensation anti-disturbance control method for hydraulic secondary regulation system (Nonlinear Dynamics, 2024)

Authors: Wang, Z.; Liu, X.; Mou, Q.; Qiu, Z.; Nie, R.; Jiao, Z.

Extended-State-Observer-Based Pressure Compensation Anti-Disturbance Control Method for Hydraulic Secondary Regulation System (SSRN, 2024)

Authors: Wang, Z.; Liu, X.; Mou, Q.; Qiu, Z.; Nie, R.; Jiao, Z.

Molecular dynamics and experimental study of mechanical and tribological properties of graphene-reinforced nitrile butadiene rubber–phenolic resin composites (Polymer Composites, 2024)

Authors: Li, Y.; Chen, Z.; Qian, C.; Wang, S.; Nie, R.

Simulation Analysis on Flow Field of Aircraft Hydraulics Bent Pipe with Guide Vane (Lecture Notes in Electrical Engineering, 2024)

Authors: Li, D.; Liu, X.; Nie, R.; Hou, P.; Liao, H.

Cheng Qian | Friction and Sealing | Best Researcher Award

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Prof. Dr. Cheng Qian | Friction and Sealing | Best Researcher Award

Research Associate at Ningbo Institute of Technology, China.

🎓 Qian Cheng is a dedicated Ph.D. candidate in Mechanical Engineering at Shenyang University of Technology, under the mentorship of Dr. Shijie Wang. He specializes in advanced material design, surface engineering, and tribology. His research integrates nanotechnology, molecular simulations, and experimental validation to enhance polymer composites’ mechanical and aging properties. Qian Cheng has a multidisciplinary approach, combining engineering principles with data-driven methodologies such as machine learning 🤖. With 9 SCI-indexed papers as a first/corresponding author and ongoing cutting-edge projects, he continues to make impactful contributions in the fields of polymer science and mechanical systems 🔬⚙️. Known for his rigorous analytical skills and international academic exposure, including time spent in Germany, Cheng aims to innovate smarter, more resilient materials for modern mechanical systems 🌍🧪.

Professional Profiles📖

Scopus

ORCID

Education📚

📚 Qian Cheng’s academic journey reflects a strong foundation in mechanical and materials engineering. He began his undergraduate studies in Mechanical Design, Manufacturing, and Automation at Shenyang University of Aeronautics and Astronautics (2011–2015) ✈️🔧. He then pursued a Master’s degree (2016–2019) and is now completing a Ph.D. in Mechanical Engineering (2019–2024) at Shenyang University of Technology 🏫⚙️. During his Master’s, he was selected for an international exchange program at the University of Ahlen, Germany (2018–2019) 🇩🇪, where he specialized in polymer science 🧫. His educational path combines theoretical knowledge and hands-on experimentation with simulation-based analysis. Cheng’s passion for learning and innovation is evident in his commitment to pushing boundaries in materials science and mechanical systems development. His global perspective and interdisciplinary training empower him to tackle complex engineering challenges using both traditional and advanced tools 🌐🛠️.

Professional Experience💼

Qian Cheng has built his research experience around a comprehensive integration of simulation and experimental mechanics. He has actively contributed to research projects focusing on improving tribological behavior and thermal-oxidative aging resistance in polymer nanocomposites. During his Ph.D., Cheng designed and conducted molecular dynamics simulations to analyze the influence of nanomaterial structures on rubber composites. He also participated in lab-based experiments for materials testing and validation, bridging theory with practice. His stint at the University of Ahlen gave him hands-on experience in international research and polymer analysis. In parallel with his research, he has collaborated with fellow researchers on developing machine learning models for material property prediction. His professional trajectory is marked by academic rigor, publication success, and technical fluency, preparing him to contribute significantly to the field of mechanical and materials engineering.

Research Focus 🔍

Qian Cheng’s research 🔍 revolves around mechanical engineering, polymer nanocomposites, and material simulation. His work focuses on thermo-oxidative aging, mechanical durability, and tribological properties of rubber-based nanomaterials 🧪🛞. Using molecular dynamics simulations, he evaluates how different nanofillers—like carbon nanotubes, graphene oxide, and molybdenum disulfide—impact the performance of nitrile butadiene rubber (NBR) composites 🔄🧬. In addition, Cheng incorporates machine learning to model material behavior, enabling predictive design for future applications 🤖📊. His studies aim to improve the reliability and efficiency of components used in high-friction, high-temperature environments—critical in aerospace, automotive, and machinery sectors ✈️🚗⚙️. He also explores surface engineering and multi-scale materials research, developing systems that integrate nano-level innovation with macro-level function. His ambition is to pioneer sustainable and smart materials for next-generation mechanical equipment 🌿🔧.

Awards and Honors🏆

While specific award names are not provided, Qian Cheng’s prolific publication record in JCR Q1 and Q2 journals like Journal of Materials Research and Technology (IF=6.4), Journal of Polymer Science, and Polymer Composites indicates scholarly excellence 📚🏅. His acceptance as a visiting scholar at the University of Ahlen, Germany , reflects international academic recognition. The consistent acceptance of his work in high-impact journals suggests his research is well-regarded in the scientific community. His research outputs contribute to major areas like nanomaterials, surface modification, and tribological enhancement—critical fields within mechanical and polymer engineering. Cheng’s work has been cited and used as reference for tribological material improvement and molecular simulation techniques, showcasing his growing influence 🌟📖. He is expected to be a strong contender for future research fellowships and innovation awards in engineering science and materials research 🏆🔬.

Conclusion ✅

Cheng Qian demonstrates outstanding potential and current achievements as a researcher in advanced polymer nanocomposites and material science. His deep understanding of simulation-driven material design, backed by strong experimental work and publication output, positions him as a highly deserving candidate for the Best Researcher Award 🏆. While areas like project leadership and industry engagement can be further developed, his profile is well-rounded, ambitious, and aligned with future-ready scientific innovation.

Publications to Noted📚

Synergistic Enhancement of Mechanical and Tribological Properties of Nitrile Butadiene Rubber With RD‐Modified GO and CNTs as Antioxidants: Experiments and Molecular Dynamics Simulations

Authors: Cheng Qian; Xiaochao Liu; Wenfu Zeng; Guofeng Zhang; Rui Nie

Year: 2025

Comparative Study of the Tribological Properties of Diamond-Like Carbon and Nitride Coatings Deposited on 40Cr Surfaces

Authors: Rui Nie; Zhuobiao Li; Wenfu Zeng; Cheng Qian; Yunlong Li

Year: 2025

Comparative study on thermal-oxygen aging and tribological properties of carbon nanotubes and graphene sheet reinforced hydrogenated nitrile rubber composite materials

Authors: Qian C.; Wang S.; Li Y.; Nie R.; Song S.

Year: 2024

Design and preparation of sulfur vulcanized polyamide 66 cross-linked nitrile butadiene rubber networked and its application in blending with graphene oxide

Authors: Li X.; Li Y.; Qian C.; Wang S.; Nie R.

Year: 2024

Molecular dynamics investigation on the thermal-oxidative aging and mechanical properties of nitrile butadiene rubber composites with molybdenum disulfide

Authors: Qian C.; Chen J.; Wang S.; Wang M.; Song S.

Year: 2024

Relationship between the aging thermal oxygen and mechanical properties of nitrile butadiene rubber reinforced by RD-loaded carboxylated carbon nanotubes

Authors: Wang M.; Li Y.; Qian C.; Wang S.; Liu D.

Year: 2024

Review on stator rubber of progressive cavity pump for oil extraction,采油螺杆泵定子橡胶研究综述

Authors: Wang S.; Chen Z.; Li Y.; Qian C.; Yang B.

Year: 2024

Molecular dynamics and experimental study of mechanical and tribological properties of graphene‐reinforced nitrile butadiene rubber–phenolic resin composites

Authors: Yunlong Li; Zhiju Chen; Cheng Qian; Shijie Wang; Rui Nie

Year: 2024

A fine-tuning deep residual convolutional neural network for emotion recognition based on frequency-channel matrices representation of one-dimensional electroencephalography

Authors: Chen J.; Cui Y.; Qian C.; He E.

Year: 2023

A Study on the Relationship between the Aging Thermal Oxygen and Mechanical Properties of Nitrile Rubber Reinforced by Rd Load Carboxylated Carbon Nanotubes

Authors: Wang M.; Li Y.; Qian C.; Wang S.; Liu D.

Year: 2023