Yang Liu | Innovation| Best Researcher Award

Dr.Yang Liu | Innovation| Best Researcher Award

Dr , Yang Liu, Xi’an Jiaotong University,China .

Dr. Yang Liu is a prominent scholar at Xi’an Jiaotong University in China. With a focus on advanced research in [specific field or discipline], Dr. Liu has made significant contributions to [mention any specific areas or projects]. Dr. Liu’s work is widely recognized in both national and international circles, demonstrating a strong commitment to academic excellence and innovation. Dr. Liu is actively engaged in various research collaborations, contributing to the advancement

Summary:

Liu’s research focuses on Human-Computer/AI Interaction, Virtual and Augmented Reality (VR/AR), AI Governance, and the societal impacts of information systems. Liu has secured significant research funding, including a National Natural Science Foundation of China grant and a Hong Kong Research Grants Council grant, for projects exploring virtual reality interaction design and mobile touch experience design.

Professional Profiles:

Scopus

Education :

Yang Liu earned his Ph.D. in Information Systems & Analytics from the National University of Singapore in 2018. Prior to that, he completed his M.Sc. in Information Resources Management at Renmin University of China in 2013, and his B.Mgt. in Information Systems at Renmin University of China in 2011. His strong academic background laid the foundation for his research and teaching in Information Systems, Human-Computer Interaction, and AI governance.

Work Experience:

Yang Liu is currently serving as an Associate Professor in the Department of Information Systems and Intelligent Business at the School of Management, Xi’an Jiaotong University, a position he has held since July 2023. Before that, he worked as an Assistant Professor in the same department from October 2020 to June 2023. His academic journey also includes a Research Fellowship at the National University of Singapore, where he contributed to both the School of Computing and the School of Business from March 2018 to September 2020.

Skills:

Dr. Liu is proficient in a variety of statistical software, including SPSS, STATA, Tobii Studio, AMOS, and SmartPLS. His programming skills span Python, R, SQL, HTML/CSS, and JavaScript. Additionally, he is adept at utilizing survey platforms such as Prolific, Amazon Mechanical Turk, Qualtrics, and Credamo. Fluent in Mandarin (native) and English (proficient), Dr. Liu is well-equipped to engage in both local and international research collaborations.

Research Focus:

Dr. Liu’s research interests lie at the intersection of Human-Computer/AI Interaction, Virtual and Augmented Reality (VR/AR), and the societal impacts of information systems. He is particularly interested in AI governance, the digital economy, and experimental methods that examine how technology interfaces influence behavior. His recent work has explored Blockchain-Driven Decentralized Identity Management and the effects of mobile touch modes on user self-regulation, pushing the boundaries of our understanding of digital engagement.

Awards and Recognitions:

Yang Liu has received multiple prestigious research grants, including being the Principal Investigator for the National Natural Science Foundation of China (2023-2025), with a project focused on Virtual Reality Embodied Interaction Design and its impact on consumer online and offline purchase behavior. He also co-led a Hong Kong Research Grants Council project (2021-2024), investigating healthy behavior through mobile touch experience design. His research excellence is further recognized through his numerous editorial roles and service as Track Chair for international conferences.

Conclusion:

Yang Liu’s comprehensive educational background, significant research contributions, and active involvement in academic service make them a standout candidate for the Research for Best Researcher Award. Their innovative work in human-computer interaction, coupled with successful research grants and editorial responsibilities, underscores their impact on the field and their potential for continued contributions to the research community.

Publications :

 

  • Schisandrin Inhibits VSMCs Proliferation and Migration
    • Authors: Huang, Q., Liu, X., Yu, J., Niu, X., Li, W.
    • Journal: Tissue and Cell
    • Year: 2024
    • Abstract: This study explores how Schisandrin affects vascular smooth muscle cell (VSMC) proliferation and migration by arresting the cell cycle and targeting JAK2 to regulate the JAK2/STAT3 signaling pathway.

 

  • Novel Disulfidptosis-Derived Gene Blueprint Stratifying Patients with Breast Cancer
    • Authors: Tang, X., Ping, B., Liu, Y., Zhou, Y.
    • Journal: Environmental Toxicology
    • Year: 2024
    • Abstract: This research introduces a gene blueprint derived from disulfidptosis to stratify breast cancer patients, potentially improving personalized treatment strategies.

 

  • Distinctive Cortical Morphological Patterns in Primary Trigeminal Neuralgia
    • Authors: Xu, H., Liu, Y., Zeng, W.-T., Fan, Y.-X., Wang, Y.
    • Journal: Neuroradiology
    • Year: 2024
    • Abstract: This cross-sectional study examines cortical morphological patterns in patients with primary trigeminal neuralgia, aiming to enhance diagnostic accuracy and treatment approaches.

 

  • The Inhibitory Impact of Schisandrin on Inflammation and Oxidative Stress Alleviates LPS-Induced Acute Kidney Injury
    • Authors: Liu, X., Huang, Q., Li, W., Niu, X., Li, W.
    • Journal: Biotechnology and Applied Biochemistry
    • Year: 2024
    • Abstract: This article investigates how Schisandrin reduces inflammation and oxidative stress to mitigate acute kidney injury induced by lipopolysaccharides (LPS).

 

  • The Prognostic Significance of Further Axillary Dissection for Sentinel Lymph Node Micrometastases in Female Breast Cancer
    • Authors: Zhou, Y., Pu, S., Jiang, S., Ren, Y., Hao, N.
    • Journal: Frontiers in Oncology
    • Year: 2022
    • Abstract: This study assesses the prognostic value of further axillary dissection for sentinel lymph node micrometastases in female breast cancer using data from the SEER database.

 

  • Identification of Necroptosis-Related Subtypes and Prognosis Model in Triple Negative Breast Cancer
    • Authors: Pu, S., Zhou, Y., Xie, P., He, J., Hao, N.
    • Journal: Frontiers in Immunology
    • Year: 2022
    • Article ID: 964118
    • Abstract: This paper identifies necroptosis-related subtypes in triple-negative breast cancer and proposes a prognosis model based on these subtypes.

 

  • MicroRNA-4487 Regulates Vascular Smooth Muscle Cell Proliferation, Migration, and Apoptosis by Targeting RAS p21 Protein Activator 1
    • Authors: Liang, X., Hu, M., Yuan, W., Bai, C., Yuan, Z.
    • Journal: Pathology Research and Practice
    • Year: 2022
    • Article ID: 153903
    • Abstract: This study reveals how MicroRNA-4487 modulates vascular smooth muscle cell behaviors through the targeting of RAS p21 protein activator 1.

 

  • Mining the Prognostic Significance and Immune Infiltration of STAT Family Members in Human Breast Cancer by Bioinformatics Analysis
    • Authors: Zhou, Y., Jiang, S., Yu, S., Hao, N., Ren, Y.
    • Journal: Gland Surgery
    • Year: 2022
    • Abstract: This bioinformatics study explores the prognostic significance and immune infiltration of STAT family members in breast cancer.

 

  • Ultrasound Targeted Microbubble Destruction-Mediated SOCS3 Attenuates Biological Characteristics and Epithelial-Mesenchymal Transition (EMT) of Breast Cancer Stem Cells
    • Authors: Tang, X., Hao, N., Zhou, Y., Liu, Y.
    • Journal: Bioengineered
    • Year: 2022
    • Abstract: This article investigates how ultrasound targeted microbubble destruction affects SOCS3 to alter breast cancer stem cell characteristics and EMT.

 

  • Bacteriophage Twort Protein Gp168 is a β-Clamp Inhibitor by Occupying the DNA Sliding Channel
    • Authors: Liu, B., Li, S., Liu, Y., Wang, Y., Zhang, K.
    • Journal: Nucleic Acids Research
    • Year: 2021
    • Abstract: This study details how the Twort bacteriophage protein Gp168 functions as a β-clamp inhibitor by binding to the DNA sliding channel.

Dr . Luis Cedeño-Viveros | Manufacturing processes | Best Researcher Award

Dr . Luis Cedeño-Viveros | Manufacturing processes | Best Researcher Award

Dr . Luis Cedeño-Viveros ,Tecnológico de Monterrey,Ecuador

Dr. Luis Cedeño-Viveros is a distinguished academic and researcher at Tecnológico de Monterrey in Ecuador. With a profound expertise in his field, Dr. Cedeño-Viveros has contributed significantly to the academic community through his research and publications. He is known for his innovative approaches and dedication to advancing knowledge. Dr. Cedeño-Viveros has a robust background in engineering, reflected in his numerous scholarly articles and conference presentations. His commitment to education and research excellence makes him a valuable asset to Tecnológico de Monterrey and the broader academic community.

Professional Profiles:

Scopus

Education :

Ph.D. in Advanced Manufacturing, Tecnológico de Monterrey, Mexico
M.Sc. in Mechanical Engineering, Tecnológico de Monterrey, Mexico
B.Sc. in Mechanical Engineering, Universidad Católica del Ecuador, Quito, Ecuador

Work Experience:

Postdoctoral Researcher, Institute of Advanced Materials for Sustainable Manufacturing – Tecnológico de Monterrey (May 2022 – May 2024),Led research on innovative sustainable additive manufacturing methods.,Conducted design and topology optimization of LPBF preforms.,Collaborated on developing innovative stents for magnesium and NiTi alloys.,Delivered guest lectures and served as a co-advisor for master’s theses.,Managed research activities including securing funding and acquiring materials and equipment.,Part-time physics lecturer in the School of Engineering and Sciences,Advanced Manufacturing Consultant, HERA Diagnostics (Nov 2021 – May 2023),Optimized design for the fabrication of medical devices.,Conducted design and preliminary laboratory evaluations for regulatory clearance.,Graduate Research Assistant, Advanced Manufacturing Research Group, Centro de Innovación en Diseño y Tecnología (CIDyT) – Tecnológico de Monterrey (Aug 2017 – Dec 2021),Specialized in laser micro-welding and micro-cutting of metallic alloys.,Conducted benchmarking research for innovative medical implants.,Trained personnel and graduate students in advanced laser techniques.,Internship Trainee, BOCAR Group, Toluca-Mexico (Sep 2014 – Dec 2014),Developed FEM simulations for designing casting molds for aluminum auto parts.

Skills :

  • Technical: Laser micro-welding, 3D printing, FEM simulations, CAD/CAM software (NX Unigraphics, Altair platforms, Fusion 360), MATLAB, Wolfram programming languages.
  • Languages: Spanish (native), English (IELTS 8, C1), German (Goethe Institute A1).
  • Research and Development: Medical device innovation, sustainable manufacturing, laser fabrication processes, topology optimization, tissue engineering.

Awards:

  • Candidate level at the National Research System (CONACYT, Mexico), Jan 2023 – Dec 2026.
  • Member of the Optica Society, Early Career Member, July 2024 – July 2027.
  • First Place in ASME Old Guard Technical Web Page Design Competition, Salamanca, México, 2013.
  • President of the Mechanical Engineers Society of Tecnológico de Monterrey, Toluca, 2013—2014

Research Focus:

  • Medical Devices: Development of cutting-edge medical devices using fiber laser technologies, innovative cancer screening methods based on optical and electrical spectroscopy.
  • Laser Manufacturing: Laser Powder Bed Fusion (LPBF) techniques, laser micro-welding of magnesium alloys, stainless steels, and NiTi alloys.
  • Sustainable Manufacturing: Development of sustainable additive manufacturing methods, including Joining Stacking Laser Micro-Spot Welding (JS-LMSW).

Patents:

  • Method for obtaining personalized scaffolds for tissue regeneration, Application submitted, April 2021.
  • Energy collector system applicable to combustion engines, Patent granted, June 2016.

Publications :

  1. A Novel Mathematical Model for Predicting a Sustainable Selective Laser Melting and Controlled Densification
    International Journal of Sustainable Energy, March 2024.
    DOI: 10.1080/19397038.2024.2327386.
  2. Numerical Analysis of Static and Dynamic Heat Source Model Approaches in Laser Micro-Spot Welding
    International Journal of Advanced Manufacturing Technology, April 2024.
    DOI: 10.1007/s00170-024-13645-1.
  3. A Novel Method for the Fabrication of Tubular WE43 Magnesium Scaffold Based on Laser Micro-Spot Welding
    Engineering Science and Technology, an International Journal, January 2022.
    DOI: 10.1016/j.jestch.2022.101096.
  4. Characterization of Porous Scaffolds Fabricated by Joining Stacking Based Laser Micro-Spot Welding (JS-LMSW) for Tissue Engineering Applications
    Materials, December 2021.
    DOI: 10.3390/ma15010099.
  5. Influence of Process Parameters for Sheet Lamination Based on Laser Micro-Spot Welding of Austenitic Stainless Steel Sheets for Bone Tissue Applications
    International Journal of Advanced Manufacturing Technology, April 2021.
    DOI: 10.1007/s00170-021-07113-3.

Conference Proceedings

  1. A Process Chain Study for the Manufacturing of Nitinol Stents
    Presented on June 11, 2024, at the CIRP BioManufacturing 2024, Dresden, Germany. In press.
  2. A Novel Additive Manufacturing Method for the Fabrication of Porous Structures: Tube Stack Layering (TSL)
    Presented online on October 20, 2022, at the International Conference on Design for 3D Printing 2022. In press.
  3. Laser Micro-Welding of AZ92A Magnesium Wires Using a Fiber-Laser: A Preliminary Study
    CIRP BioManufacturing 2019.
    DOI: 10.1016/j.procir.2019.12.002.
  4. Laser Micro-Spot Welding of AISI 302 Stainless Steel Sheets
    SPIE Photonics West 2018.
    DOI: 10.1117/12.2290003.
  5. An Immersive 3D Virtual Learning Environment for Analyzing the Atomic Structure of MIMS Relevant Materials
    VARI 2015.
    DOI: 10.1016/j.procs.2015.12.265.

 

 

Igor Artyukov | Carbon composites| Best Researcher Award

Dr . Igor Artyukov | Carbon composites| Best Researcher Award

 Dr . Igor Artyukov ,P.N. Lebedev Physical Institute RAS,Russia

Dr. Igor Artyukov is a distinguished scientist at the P.N. Lebedev Physical Institute of the Russian Academy of Sciences (RAS) in Russia. Specializing in the field of physics, Dr. Artyukov’s research contributions span various areas within physical sciences. The P.N. Lebedev Physical Institute, renowned for its pioneering research in physics, provides a robust platform for his work. Dr. Artyukov’s affiliation with this prestigious institution highlights his standing in the scientific community and his commitment to advancing knowledge in his field.

 

Professional Profiles:

Scopus

Education 🎓

University: National Research Nuclear University MEPhI – Moscow Engineering & Physics Institute (Moscow, Russia)

  • Year of Graduation: 1988 (Honors Diploma)
  • Degree: M.Sc.
  • Faculty: Special Faculty of Physics (SFF)
  • Specialty: Solid State Physics and Quantum Electronics

University: National Research Nuclear University MEPhI – Moscow Engineering & Physics Institute (Moscow, Russia)

  • Year of Graduation: 1992
  • Degree: N/A (Post-graduate education diploma)
  • Specialty: Radiophysics

Management Training and Courses

  • Project Manager Training by the US Industry Coalition (USIC): Minsk, Belorussia, 1999.
  • Project Manager Training by the US Civil R&D Foundation (CRDF) and the International Science and Technology Center (ISTC): Moscow, 2001-2005 (on a regular basis).

Scientific Degree

Organization: P.N. Lebedev Physical Institute of the Russian Academy of Sciences (Moscow, Russia)

  • Degree: Ph.D.
  • Year: 1993
  • Specialty: Optics
  • Ph.D. Thesis: “X-ray Optics for Microscopy and Lithography”

Awards:

  • Honors Diploma: Graduation from the Moscow Engineering & Physics Institute, 1988.
  • Pavlov Award and Bronze Pin: International Academy of Sciences ISCD (Commission for Ecology and Healthcare, Munich, Germany), 2000.
  • Basov Award:
    • For “Development and application of the reflective optics for the wavelength range 35-60 nm” (P.N. Lebedev Physical Institute of the Russian Academy of Sciences), 2007.
    • For “Design and simulation of an X-ray beam for laser-electron generator in material and life sciences” (P.N. Lebedev Physical Institute of the Russian Academy of Sciences), 2017.
    • For “Direct and Inverse diffraction problems for in-vlines surfaces in application for X-ray microscopy and lithography” (P.N. Lebedev Physical Institute of the Russian Academy of Sciences), 2021.

Fields of Expertise:

Theoretical Studies:

  • Design and simulation of optical systems
  • Optical design of high-resolution optical systems for X-ray and EUV lithography and microscopy
  • Monte Carlo simulation of optical and physical processes
  • Development of laser-electron X-ray sources based on inverse Compton scattering
  • Development of X-ray/EUV reflective optical systems for scientific applications

Experimental Studies:

  • Investigation of biological and composite materials with methods of X-ray microtomography
  • X-ray fluorescence spectromicroscopy using synchrotron radiation
  • Soft X-ray/EUV imaging with laser plasma X-ray source and multilayer mirrors

Supervising:

  • K.M. Krymsky: M.Sc., Ph.D. student
  • S.A. Romanova: M.Sc., Ph.D. student
  • M.A. Zotova: M.Sc. student
  • K.V. Gorodnischev: M.Sc. student
  • N.N. Irtuganov: M.Sc, Ph.D. student
  • I.D. Mikheev: B.Sc. student
  • D.A. Paneke: B.Sc., M.Sc., Ph.D. student
  • A.A. Danilov: B.Sc., M.Sc., Ph.D. student

Publications 📚

    1. A. V. Vinogradov, I. A. Artyukov, S. S. Borisova, N. N. Zorev, I. V. Kozhevnikov, I. F. Mikhailov, S. I. Sagitov, and A. I. Fedorenko, “Investigation Of Superpolished Surfaces By X-Ray Scattering,” Proceedings Of SPIE – The International Society For Optical Engineering 1140, 490-501 (1989).
    2. I. Artyukov, A. Vinogradov, and I. Kozhevnikov, “Efficiency Of Grazing-Incidence Optics – The Spiral Collimator,” Applied Optics 30, 4154-4157 (1991).
    3. I. Artyukov, A. Vinogradov, And I. Kozhevnikov, “Maximum Efficiency Of Moving Incidence X-Ray Optics – Spiral Collimators,” Izvestiya Akademii Nauk Sssr Seriya Fizicheskaya 55, 824-828 (1991).
    4. I. Artyukov, L. Balakireva, F. Bijkerk, A. Vinogradov, N. Zorev, I. Kozhevnikov, V. Kondratenko, O. Ogurtsov, A. Ponomarenko, and A. Fedorenko, “Projection X-Ray-Lithography On The Basis Of Point Sources,” Kvantovaya Elektronika 19, 114-127 (1992).
    5. I. Artyukov, A. Vinogradov, And S. Suckewer, “Ray Tracing Computer-Simulation For X-Ray Applications,” In Ultrashort-Wavelength Lasers (1992), Pp. 161-165.
    6. I. A. Artyukov, A. I. Fedorenko, V. V. Kondratenko, S. A. Yulin, And A. V. Vinogradov, “Soft X-Ray Submicron Imaging Experiments With Nanosecond Exposure,” Optics Communications 102, 401-406 (1993).
    7. B. Alaudinov, I. Artyukov, V. Asadchikov, A. Karabekov, And I. Kozhevniikov, “An Optical-Model Of A Surface In The X-Ray Range,” Kristallografiya 39, 605-616 (1994).
    8. I. Artioukov, I. Kozhevnikov, And F. Abeles, “Effects Of Near-Surface Transition Layer On X-Ray Reflection And Scattering,” In Optical Interference Coatings, Pts 1 And 2 (1994), Pp. 692-703.
    9. I. Artyukov, A. Vinogradov, A. Fedorenko, V. Kondratenko, S. Yulin, And S. Suckewer, “Soft-X-Ray Submicron Imaging Experiments With Nanosecond Exposure,” In Ultrashort Wavelength Lasers Ii (1994), Pp. 190-197.
    10. I. A. Artyukov, A. Y. Karabekov, I. V. Kozhevnikov, B. M. Alaudinov, And V. E. Asadchikov, “Experimental Observation Of The Near Surface Layer Effects On X-Ray Reflection And Scattering,” Physica B: Physics Of Condensed Matter 198, 9-12 (1994).
    11. I. Artioukov, A. Vinogradov, V. Asadchikov, Y. Kasyanov, R. Serov, A. Fedorenko, V. Kondratenko, and S. Yulin, “Schwarzschild Soft-X-Ray Microscope For Imaging Of Nonradiating Objects,” Optics Letters 20, 2451-2453 (1995).
    12. I. A. Artioukov And I. V. Kozhevnikov, “Effects Of Near-Surface Transition Layer On X-Ray Reflection And Scattering,” In Proceedings Of SPIE – The International Society For Optical Engineering, 1995), 154-175.
    13. I. A. Artyukov, V. E. Asadchikov, A. V. Vinogradov, Y. S. Kas?Yanov, V. V. Kondratenko, R. V. Serov, A. I. Fedorenko, And S. A. Yulin, “Reflective Soft X-Ray Microscope For The Investigation Of Objects Illuminated By Laser-Plasma Radiation,” Quantum Electronics 25, 919-922 (1995).
    14. I. A. Artioukov, V. E. Asadchikov, And I. V. Kozhevnikov, “Effects Of A Near-Surface Transition Layer On X-Ray Reflection And Scattering,” Journal Of X-Ray Science And Technology 6, 223-243 (1996).
    15. I. A. Artyukov, A. V. Vinogradov, V. V. Kondratenko, A. I. Fedorenko, And S. A. Yulin, “Soft X-Ray Imaging Of Submicron Structures,” Russian Microelectronics 25, 48-53 (1996).