Peijia Bai | Nanotechnology and Materials Science | Best Researcher Award

Published on by New Scientists

Dr. Peijia Bai | Nanotechnology and Materials Science | Best Researcher Award

Assistant Research Fellow | Beihang University | China

Dr. Peijia Bai is an emerging materials scientist whose research significantly advances high-efficiency thermal management, electrothermal conversion, and radiative cooling technologies. His work centers on electrocaloric materials and devices, ultrafast-response phase-change materials (PCMs), thermal system design, and protective color radiative-cooling coatings. With a strong focus on bridging fundamental materials science with practical applications, he has contributed to establishing next-generation energy-efficient cooling strategies and improving heat-dissipation performance for electronic and aerospace systems. Dr. Peijia Bai has published more than 30 peer-reviewed journal articles across leading platforms including Advanced Materials, Nature Communications, Science, and Joule, with over 812 Scopus citations, 24 documents and an h-index of 14. His publications include more than 10 papers as first or corresponding author, highlighting his prominent role in driving independent innovations. He has also contributed to one research monograph and authored multiple high-impact conference papers that extend his work to global scientific communities. A major contribution of his research is the development of a standardized electrothermal-effect measurement protocol, which has been widely adopted by both academia and industry. This standardized method has been cited extensively in top-tier journals and is now considered an important benchmark for evaluating electrothermal device performance. His work has also yielded seven patented technologies covering thermal-functional materials and device architectures, demonstrating strong translational potential. Dr. Peijia Bai has led and contributed to multiple funded research projects related to thermal management materials, advanced cooling devices, and energy-conversion technologies. His innovations have earned him the prestigious SAMPE International Award and recognition within professional societies such as the Zhejiang Society for Materials Progress. He also serves on the young editorial boards of cScience and Renewable and Sustainable Energy, reflecting his growing influence in the field. Dr. Peijia Bai’s research continues to advance innovative thermal strategies, contributing impactful solutions for sustainable energy technologies, aerospace materials, and advanced electronic systems.

Profiles: Scopus | ORCID | ResearchGate

Featured Publications

1. Bai, P., Yang, Q., & Yu, S. (2025). Electrocaloric refrigeration utilizing lead-free multilayer ceramics with high heat transfer efficiency. Applied Thermal Engineering. https://doi.org/10.1016/j.applthermaleng.2025.128927

2. Bai, P., Yang, Q., & Yu, S. (2025). Integration of efficient photothermal and flexible solid-solid PCM for personal thermoregulation in cold environments. iScience. https://doi.org/10.1016/j.isci.2025.114032

3. Wang, G., Bai, P., Yuan, S., Bo, Y., Zhang, D., & Ma, R. (2025). Flexible electrocaloric polymer stack driven by one AA battery for highly efficient personalized thermoregulation. Nano Letters, 25. https://doi.org/10.1021/acs.nanolett.5c03730

4. Wang, G., Bai, P., Yuan, S., Bo, Y., Zhou, Z., Zhang, D., & Ma, R. (2025). Highly efficient cooling via synergistic electro‐thermal phase changes. Advanced Materials. https://doi.org/10.1002/adma.202506006

5. Ma, W., Liu, X., Yang, T., Wang, J., Qiu, Z., Cai, Z., Bai, P., Ji, X., & Huang, Y. (2025). Strong magnetic–dielectric synergistic gradient metamaterials for boosting superior multispectral ultra‐broadband absorption with low‐frequency compatibility. Advanced Functional Materials. https://doi.org/10.1002/adfm.202314046

Noor Zeb Khan | Nanotechnology and Materials Science | Editorial Board Member

Published on by New Scientists

Dr. Noor Zeb Khan | Nanotechnology and Materials Science | Editorial Board Member

Lecturer | Air University Islamabad | Pakistan

Dr. Noor Zeb Khan is an active researcher in Computational Fluid Dynamics (CFD), Nanotechnology, and Materials Science, contributing extensively to advanced numerical modeling and simulation. With 33 SCI-indexed publications and a cumulative impact factor of 106.50, his research is widely recognized, supported by 187 Scopus citations, 23 documents, and an h-index of 7 (Scopus) and 9 (Google Scholar). His work spans fluid–structure interaction, nanofluid dynamics, heat and mass transfer, magnetohydrodynamics (MHD), porous media flows, and hybrid numerical–AI methodologies integrating FEM, ANN, LBM, and COMSOL/MATLAB-based modeling. Dr. Noor Zeb Khan has produced influential research on wake dynamics, flow interference, and entropy generation analysis, including recent open-access studies such as his lattice Boltzmann investigation of dual rectangular cylinders and his FEM–ANN hybrid modeling of magnetized wavy enclosures. His findings contribute to improving predictive accuracy in thermal systems, microfluidic engineering, and energy-transport applications. He has delivered impactful contributions through high-quality journal publications, computational modelling advancements, and methodological innovations in machine-learning-assisted numerical simulations. His scholarly achievements include research awards, peer recognition, and growing citation influence. Dr. Noor Zeb Khan also provides reviewer services for multiple international SCI journals, supporting the advancement of CFD, applied mathematics, and nanofluid research communities. His ongoing work focuses on developing high-fidelity multiphysics models, optimizing thermo-hydrodynamic systems, and advancing smart computational frameworks that integrate physics-based solvers with artificial intelligence for next-generation engineering solutions.

Profiles: Scopus | ORCID | Google Scholar | Sci Profiles

Featured Publications

1. Bilal, S., Shah, M. I., Khan, N. Z., Akgül, A., & Nisar, K. S. (2022). Onset about non-isothermal flow of Williamson liquid over exponential surface by computing numerical simulation in perspective of Cattaneo–Christov heat flux theory. Alexandria Engineering Journal, 61(8), 6139–6150.

2. Shah, I. A., Bilal, S., Akgül, A., Omri, M., Bouslimi, J., & Khan, N. Z. (2022). Significance of cold cylinder in heat control in power law fluid enclosed in isosceles triangular cavity generated by natural convection: A computational approach. Alexandria Engineering Journal, 61(9), 7277–7290.

3. Bilal, S., Khan, N. Z., Shah, I. A., Awrejcewicz, J., Akgül, A., & Riaz, M. B. (2022). Numerical study of natural convection of power law fluid in a square cavity fitted with a uniformly heated T-fin. Mathematics, 10(3), 342.

4. Khan, N. Z., Bilal, S., Kolsi, L., Shflot, A. S., & Malik, M. Y. (2024). A case study on entropy generation in MHD nanofluid flow in L-shaped triangular corrugated permeable enclosure. Case Studies in Thermal Engineering, 59, 104487.

5. Khan, N. Z., Mahmood, R., Bilal, S., Akgül, A., Abdullaev, S., Mahmoud, E. E., … (2023). Mixed convective thermal transport in a lid-driven square enclosure with square obstacle. Alexandria Engineering Journal, 64, 981–998.

 

Bo Liu | Materials Science | Best Researcher Award

Published on by New Scientists

Dr. Bo Liu | Materials Science | Best Researcher Award

Dr. Bo Liu | Materials Science – Lecturer at Xi’an Shiyou University, China.

Dr. Bo Liu has dedicated his academic and professional career to the research of corrosion and protection of oil pipelines. Since 2013, he has accumulated over a decade of hands-on experience and has become a recognized contributor to the field of materials corrosion and degradation. He has published more than 20 academic papers in reputable domestic and international journals, including 7 SCI-indexed articles as the first author and 4 papers in key Chinese core journals. His work has appeared in highly regarded publications such as Corrosion Science, Construction and Building Materials, npj Materials Degradation, and Bioelectrochemistry. Dr. Liu’s academic path has been strengthened by his active participation in national-level platforms like the National Materials Environmental Corrosion Platform and the National Materials Corrosion and Protection Science Data Center. His field experience includes corrosion investigations along the China-Thailand Railway and in the Sichuan-Tibet region. In addition to his research, Dr. Liu has also gained recognition through participation in national conferences and receipt of multiple academic awards. His current leadership in three funded research projects at the national, provincial/ministerial, and departmental levels underscores his continued influence and leadership in corrosion science and engineering.

Publication Profile

Scopus

Orcid

Education

Dr. Bo Liu obtained his doctoral degree from the University of Science and Technology Beijing (USTB), one of China’s top institutions for materials science and engineering. His doctoral research focused on corrosion mechanisms and protective strategies for oil pipelines under complex environmental conditions. During his doctoral studies, he was extensively involved in collaborative research through the National Materials Environmental Corrosion Platform and the National Materials Corrosion and Protection Science Data Center. These collaborations provided him with a solid foundation in multidisciplinary approaches to corrosion research, including advanced analytical techniques and field-based studies. His graduate education emphasized both theoretical understanding and practical application, allowing him to develop innovative solutions for pipeline corrosion issues. In addition to coursework and laboratory work, Dr. Liu participated in multiple high-impact field investigations, which further enriched his educational experience. His time at USTB also included extensive writing and publishing of scientific research, laying the groundwork for his future career as a lead author in peer-reviewed publications. Throughout his academic training, Dr. Liu received several prestigious scholarships and awards, highlighting his academic excellence and commitment to advancing the field of corrosion science and engineering.

Professional Experience

Dr. Bo Liu has more than a decade of experience in the research and practical application of corrosion protection in oil pipelines. Since 2013, he has consistently contributed to both academic and industrial sectors, bridging theoretical science and field-based engineering. His professional journey began with deep involvement in national-level projects during his doctoral studies at the University of Science and Technology Beijing. He played a key role in multiple initiatives such as the National Materials Environmental Corrosion Platform and the National Materials Corrosion and Protection Science Data Center. These experiences provided him with valuable insights into large-scale corrosion testing, data analysis, and infrastructure evaluation. He also took part in two major environmental corrosion investigations: one along the proposed China-Thailand Railway and another in the Sichuan-Tibet region, where he contributed to materials testing and long-term degradation monitoring. Currently, Dr. Liu is leading three major research projects: one funded at the national level, one at the provincial or ministerial level, and another at the departmental or bureau level. These projects focus on cutting-edge corrosion protection technologies and their implementation in real-world oil transportation systems. His ongoing work highlights his leadership and expertise in directing multidisciplinary research teams and advancing materials protection strategies.

Research Interest

Dr. Bo Liu’s research interests center around corrosion mechanisms, protective coatings, and material degradation in complex environments, particularly in relation to oil and gas pipeline infrastructure. He is deeply engaged in understanding how various environmental factors—such as soil composition, humidity, temperature, and atmospheric pollutants—affect the long-term performance of metallic materials. His work also explores the development and evaluation of advanced protective coatings, cathodic protection systems, and corrosion inhibitors. Dr. Liu is particularly interested in large-scale corrosion mapping and predictive modeling using data from field investigations. His involvement in projects related to the China-Thailand Railway and Sichuan-Tibet environmental studies has expanded his focus to include corrosion behavior in extreme terrains, such as alpine and tropical zones. He also investigates the interaction between microbiologically influenced corrosion (MIC) and conventional corrosion mechanisms. These interests align with national and international priorities for pipeline safety, materials longevity, and infrastructure resilience. Dr. Liu’s multidisciplinary approach combines chemical analysis, electrochemical testing, materials science, and environmental engineering to create holistic solutions for corrosion challenges. His goal is to contribute to the design of more sustainable, durable, and safe infrastructure through innovation in corrosion prevention and materials protection.

Research Skills

Dr. Bo Liu possesses a robust set of research skills that span laboratory analysis, field investigation, and data-driven modeling, all focused on corrosion and protection of materials. He is highly proficient in electrochemical techniques such as electrochemical impedance spectroscopy (EIS), potentiodynamic polarization, and localized corrosion analysis. He has experience with surface characterization tools including scanning electron microscopy (SEM), energy dispersive spectroscopy (EDS), and X-ray diffraction (XRD), enabling detailed analysis of corrosion products and microstructural changes. Dr. Liu is also skilled in designing accelerated corrosion testing protocols and simulating long-term material degradation under diverse environmental conditions. His fieldwork experience includes site sampling, corrosion rate monitoring, and deployment of long-term corrosion sensors. In addition, he is well-versed in data interpretation using software tools such as Origin, MATLAB, and COMSOL for modeling corrosion behavior and predicting material lifespan. He has also contributed to national corrosion databases, showcasing his capacity for systematic data integration. Dr. Liu’s comprehensive skills are essential to his leadership in multiple ongoing research projects, and they enable him to bridge fundamental research with practical engineering solutions for pipeline integrity and safety.

Awards and Honors

Throughout his academic and professional journey, Dr. Bo Liu has received numerous awards and honors recognizing his excellence in corrosion science and materials protection. Notably, he won the “Outstanding Paper Award” at the 16th Youth Corrosion and Protection Science and Technology Conference, reflecting the high quality and impact of his research contributions. His academic merit has also been acknowledged through prestigious scholarships such as the “Xiao Jimei – Anke Scholarship,” the “Wu Peifang – President’s Scholarship,” and the “Dazheng Scholarship.” These awards highlight his outstanding academic record, dedication to scientific advancement, and contributions to national research priorities. Dr. Liu has also been invited to present at major national conferences, including the 11th and 12th National Corrosion and Protection Conferences, further demonstrating his leadership and reputation in the corrosion research community. These accolades underscore not only his technical expertise but also his ability to communicate complex findings to a broad audience. His honors serve as strong indicators of his growing influence within both academic and industrial sectors, particularly in fields related to materials degradation, pipeline protection, and corrosion mitigation strategies.

Author Metrics

  • Total Citations: 163

  • Number of Citing Documents: 139

  • Total Documents: 11

  • h-index: 6

Top Noted Publication

  • Interpreting microbiologically influenced stress corrosion with machine learning and theoretical analysis
    Journal: Corrosion Communications
    Year: 2025

  • Enhancement resistance to microbiologically influenced stress corrosion of Cu-bearing steel against Bacillus cereus
    Journal: npj Materials Degradation
    Year: 2024

  • Characteristic and Mechanistic Investigation of Stress-Assisted Microbiologically Influenced Corrosion of X80 Steel in Near-Neutral Solutions
    Journal: Materials
    Year: 2023

  • Stress corrosion cracking of X80 steel heat-affected zone in a near-neutral pH solution containing Bacillus cereus
    Journal: npj Materials Degradation
    Year: 2023

  • Elucidating the effect of titanium alloying on the pitting corrosion of ferritic stainless steel
    Journal: Journal of Materials Research and Technology
    Year: 2023

Conclusion

Dr. Bo Liu is a dedicated researcher and emerging leader in the field of corrosion science and materials protection. With over a decade of focused research since 2013, he has built a distinguished portfolio of academic publications, including first-author contributions in leading journals. His educational background from the University of Science and Technology Beijing and his fieldwork experience across China’s critical infrastructure projects have equipped him with a deep understanding of corrosion phenomena in complex environments. He combines theoretical expertise with hands-on technical skills, from laboratory techniques to field investigations and project management. Currently spearheading three research projects at various administrative levels, Dr. Liu demonstrates strong leadership and a commitment to advancing both fundamental and applied aspects of corrosion protection. His awards, including national scholarships and conference recognitions, further affirm his contributions to the field. Moving forward, Dr. Liu aims to continue bridging academic research with engineering solutions to ensure the safety, efficiency, and longevity of oil and gas pipeline systems. His multidisciplinary and pragmatic approach makes him a valuable contributor to national materials protection strategies and international advancements in corrosion science.