Maria Pogojeva | Synthetic Fibers | Innovative Research Award

Published on by Fiber-Reinforced Polymer

Innovative Research Award

Maria Pogojeva
Affiliation Moscow State University
Country Russia
Scopus ID 57204501206
Documents 21
Citations 572
h-index 7
Subject Area Synthetic Fibers
Event International Research Awards on Fiberreinforced Polymer
ORCID 0000-0002-4763-2422

Maria Pogojeva

Moscow State University, Russia

The Innovative Research Award recognizes the scholarly contributions of Maria Pogojeva in environmental and marine pollution research, particularly in the investigation of marine macro-litter and microplastic distribution in Arctic and Black Sea environments. Her research profile demonstrates sustained contributions to understanding anthropogenic debris transport mechanisms and the environmental implications of synthetic materials in marine ecosystems. Through peer-reviewed publications and collaborative scientific initiatives, her work has contributed to baseline assessments and environmental monitoring frameworks for marine pollution studies.[1]

Abstract

Maria Pogojeva’s research focuses on the occurrence, transport and environmental distribution of floating macro-litter and microplastics in marine systems. Her studies in the Arctic and Black Sea regions provide scientific evidence regarding the pathways and accumulation of anthropogenic debris and support the development of monitoring strategies for marine pollution management.[2]

Keywords

Marine pollution; Microplastics; Macro-litter; Synthetic fibers; Arctic seas; Environmental monitoring; Oceanography.

Introduction

The increasing prevalence of plastic contamination in marine environments has become an important research priority in environmental science. Studies of macro-litter and microplastics contribute to understanding pollution sources, ecological consequences and mitigation strategies. Maria Pogojeva’s work addresses these challenges through empirical investigations of floating debris distribution and oceanographic influences on pollutant transport.[3]

Research Profile

With a Scopus profile containing 21 indexed documents and more than 570 citations, Maria Pogojeva has developed an interdisciplinary research portfolio integrating marine science, environmental chemistry and pollution assessment methodologies. Her scholarly activities have focused on the distribution of marine debris across Arctic seas and the establishment of reference datasets for future environmental assessments.[1]

Research Contributions

  • Investigated floating marine macro-litter distribution in Arctic and Black Sea ecosystems.
  • Contributed to baseline assessments for large-scale marine pollution monitoring.
  • Examined seasonal variations of microplastic pollution in the Kara Sea.
  • Explored relationships between oceanographic processes and debris transport mechanisms.

Publications

  • Author Correction: Floating macrolitter leaked from Europe into the ocean.
  • Floating marine macro litter in the Black Sea: Toward baselines for large scale assessment.
  • Microplastic pollution of the Kara Sea surface in different seasons.
  • Floating marine macro-litter distribution in the Russian Arctic Seas in relation to oceanographic characteristics.

Research Impact

The research outcomes produced by Maria Pogojeva contribute to marine conservation policies and environmental management practices by providing evidence-based assessments of debris accumulation and transport pathways. Her publications are frequently referenced in studies concerning plastic pollution and Arctic environmental monitoring, illustrating the relevance of her scientific contributions.[4]

Award Suitability

The Innovative Research Award acknowledges researchers who demonstrate originality, scientific rigor and measurable impact. Maria Pogojeva’s publication record, citation performance and contributions to understanding marine pollution align with the objectives of the International Research Awards on Fiberreinforced Polymer, particularly through her investigations of synthetic materials and their environmental consequences.[5]

Conclusion

Maria Pogojeva’s research profile reflects a sustained commitment to advancing knowledge on marine debris and synthetic material pollution. Her work provides important scientific insights that support environmental assessment and conservation initiatives, making her a notable candidate for academic recognition through the Innovative Research Award.[6]

References

  1. Elsevier. (n.d.). Scopus author details: Maria Pogojeva, Author ID 57204501206. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=57204501206
  2. Pogojeva, M. (2022). Floating marine macro litter in the Black Sea: Toward baselines for large scale assessment. Environmental Pollution.
    https://doi.org/10.1016/j.envpol.2022.119816
  3. Pogojeva, M. (2022). Microplastic pollution of the Kara Sea surface in different seasons.
    https://doi.org/10.5194/egusphere-egu22-425
  4. Pogojeva, M. (2021). Floating marine macro-litter distribution in the Russian Arctic Seas in relation to oceanographic characteristics.
    https://doi.org/10.5194/egusphere-egu21-2028
  5. Nature Sustainability. (2023). Author Correction: Floating macrolitter leaked from Europe into the ocean.
    https://doi.org/10.1038/s41893-022-01009-0
  6. ORCID. (n.d.). Maria Pogojeva Research Profile.
    https://orcid.org/0000-0002-4763-2422

Lijuan He | Synthetic Fibers | Best Researcher Award

Published on by Fiber-Reinforced Polymer

Prof. Lijuan He | Synthetic Fibers | Best Researcher Award

Professor, University Of Science and Technology Of The Inner Mongol, China

Prof. He Lijuan is a distinguished Professor at the Inner Mongolia University of Science and Technology with a strong academic and research background in refrigeration and cryogenic engineering. She earned her Bachelor’s degree in HVAC from Baotou Iron and Steel Institute in 1994, followed by a Master’s degree (2001) and PhD (2009) in Refrigeration and Cryogenic Engineering from Zhejiang University, and later completed postdoctoral research in Mechanical Engineering at University College London in 2015. Her career began as an engineer at Baotou Iron and Steel Co., Ltd. before moving into academia, where she progressed from Associate Professor (2009–2015) to Professor. She has taught undergraduate courses such as Heat Transfer, Professional English, and Refrigeration Technology for Air Conditioning, and graduate courses including Advanced Engineering Thermodynamics and Advanced Heat and Mass Transfer. Her research focuses on low-grade heat transfer and application technology, refrigeration and heat pump system optimization, and refrigerant replacement and recycling technology. Prof. He has authored over 52 indexed papers with 157 citations and an H-index of 6, and holds 14 invention patents and 17 utility model patents. She has received four provincial and ministerial awards, published a monograph, and actively contributes as an expert in multiple national and regional academic, innovation, and policy platforms. Recognized as Grassland Talent in 2019 and an Outstanding Communist Party member, she continues to play an influential role in advancing sustainable energy technologies while mentoring students and contributing to the academic community.

Profile:  Scopus

Featured Publications

  • He, L., Yang, W., Han, Y., et al. (2023). Vapor-liquid equilibrium experiment and prediction of excess property of new working pair CO₂-[BMP][Tf₂N] in absorption refrigeration system. International Journal of Refrigeration, 145, 407–416.

  • He, L., Sun, N. Y., Han, Y. Z., Yang, W. X., & Huang, J. H. (2022). Experimental investigation on the effect of equipment structure on refrigeration performance of combined magnetic refrigeration system. Thermal Science, 26(5B), 1–11.

  • He, L., Wang, S., Liu, S., & Wu, X. (2019). Numerical and experimental evaluation of the performance of a couple vapor absorption-compression refrigeration configuration. International Journal of Refrigeration, 99, 429–439.

  • He, L., Tang, L., & Chen, G. M. (2009). Performance prediction of refrigerant-DMF solutions in a single-stage solar-powered absorption refrigeration system at low generating temperatures. Solar Energy, 83, 2029–2038.

  • He, L., Chen, G., & Cui, X. (2008). Vapor-liquid equilibria for R22 + N,N-dimethylformamide system at temperatures from 283.15 to 363.15 K. Fluid Phase Equilibria, 266, 84–89.