Marianna Vályi Nagy | Sustainability in Cryogenic Technologies | Best Researcher Award

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Ms. Marianna Vályi Nagy | Sustainability in Cryogenic Technologies | Best Researcher Award

Research assistant at Hungarian University of Agriculture and Life Sciences | Hungary

Marianna Vályi Nagy is a research assistant at the Hungarian University of Agriculture and Life Sciences (MATE), Institute of Agronomy, whose academic journey and professional career have been devoted to advancing sustainable agricultural practices. With a strong foundation in horticultural engineering, plant protection, and agronomy, she has established herself as a dedicated researcher focusing on mixed cropping systems, crop interactions, and climate-resilient agricultural methods. Her work bridges fundamental agricultural sciences with applied research, producing impactful results that contribute both to academic knowledge and to real-world agricultural innovations.

Professional Profile

ORCID

Education

Marianna began her academic journey at Corvinus University in Budapest, where she graduated as a Horticultural Engineer. Her interest in crop science and plant interactions motivated her to pursue further qualifications, and she later obtained a specialized degree in Plant Protection Engineering from the University of Szeged. Her commitment to higher learning led her to doctoral studies at the Hungarian University of Agriculture and Life Sciences, supported by the Young Researcher Training Program. Throughout her academic development, Marianna demonstrated a keen ability to integrate multiple disciplines within plant sciences, aligning her expertise with the pressing challenges of climate change, food security, and sustainable farming systems.

Experience

Marianna’s professional experience is rooted in her contributions to both research and applied agricultural innovation. She began her research career at the National Agricultural Research and Innovation Centre, where she gained valuable experience in experimental design and crop management practices. Later, she joined the Applied Agronomy Research Station, which became part of MATE, and contributed to experiments that combined scientific rigor with industry-driven needs. Over the years, she has participated in numerous commissioned research projects, collaborating with agricultural companies to test crop varieties, seeding strategies, and sustainable cultivation methods. This blend of academic and industry engagement has allowed her to create a research portfolio that is both scientifically robust and practically relevant.

Research Focus

Marianna’s primary research interests revolve around mixed cropping systems, with a particular emphasis on winter wheat–winter pea interactions. She explores the development process of companion crops, analyzing both their quantitative and qualitative characteristics. Her studies extend beyond traditional yield-focused research by considering plant development, interaction dynamics, seeding rates, and variety selection, providing a comprehensive understanding of crop coexistence. These investigations address one of the greatest challenges in modern agriculture: identifying cultivation methods that are environmentally sustainable, resilient to climate change, and adaptable to market fluctuations. Through her research, Marianna contributes to shaping agricultural practices that balance productivity with ecological responsibility.

Publication Top Notes

Title: Yield and Quality Parameters of Winter Wheat in a Wheat–Pea Mixed Cropping System
Authors: Marianna Vályi-Nagy, István Kristó, Melinda Tar, Attila Rácz, Lajos Szentpéteri, Katalin Irmes, Csaba Gyuricza, Márta Ladányi
Summary: This study evaluated wheat–pea intercropping, showing improved grain yield, protein content, and crop resilience, highlighting ecological and economic advantages compared to monoculture wheat cultivation.

Title: Competition Indices and Economic Benefits of Winter Wheat and Winter Peas in Mixed Cropping
Authors: Marianna Vályi-Nagy, István Kristó, Melinda Tar, Attila Rácz, Lajos Szentpéteri, Katalin Irmes, Gergő Péter Kovács, Márta Ladányi
Summary: Research analyzed competition indices and profitability of wheat–pea mixtures, concluding intercropping enhances land-use efficiency and offers greater economic sustainability than sole cropping systems.

Title: The Effect of Foliar Zinc Application on the Leaf Chlorophyll Concentrations and Grain Yields of the Winter Wheat (Triticum aestivum L.) in the Field Experiments of Two Seasons
Authors: Katalin Irmes, István Kristó, Lajos Szentpéteri, Attila Rácz, Marianna Vályi-Nagy, Mária Katalin Kassai, Klára Veresné Valentinyi, Melinda Tar
Summary: Two-season field trials revealed foliar zinc application increased chlorophyll levels and grain yields in winter wheat, emphasizing zinc’s critical role in improving crop productivity.

Title: Effects of Winter Cereals (Triticum aestivum L., Hordeum vulgare L., Triticosecale Wittmack) and Winter Pea (Pisum sativum L.) Intercropping on Weed Cover in South-Eastern and Central Hungary
Authors: Attila Rácz, Marianna Vályi-Nagy, Melinda Tar, Katalin Irmes, Lajos Szentpéteri, Apolka Ujj, Klára Veresné Valentinyi, Márta Ladányi, István Kristó
Summary: Field experiments demonstrated cereal–pea intercropping significantly reduced weed cover, promoting ecological weed management and enhancing sustainability in Hungarian winter cropping systems.

Conclusion

Marianna Vályi Nagy stands out as a promising researcher whose dedication to sustainable agriculture is evident in her academic achievements, applied research, and innovative contributions. Her expertise in mixed cropping systems addresses one of the most urgent agricultural challenges of our time—developing cultivation methods that align with ecological principles while ensuring productivity and resilience. With a growing body of publications, patents, and industry collaborations, she exemplifies the qualities of a forward-thinking researcher who bridges science and practice. Her membership in professional associations and recognition through national research programs further reinforce her position as an emerging leader in agricultural sciences. Marianna’s work holds significant potential to guide future research directions and agricultural policies, making her a strong candidate for the Best Researcher Award.

Yuanyuan Ma | Energy Storage | Best Researcher Award

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Dr. Yuanyuan Ma | Energy Storage | Best Researcher Award

Associate Professor, Donghua University, China

Dr. Yuanyuan Ma is a distinguished Associate Professor and Master’s Supervisor at the College of Materials Science and Engineering, Donghua University, and is affiliated with the State Key Laboratory of Advanced Fiber Materials. A rising star in the field of materials science, Dr. Ma has made significant contributions to energy storage, electrocatalysis, and sustainable materials development. Since earning her Ph.D. in 2019, she has demonstrated exceptional leadership in research and innovation, with over 50 SCI-indexed publications, including 29 as first or corresponding author. 📈 Her work has earned her an h-index of 30, a testament to the global impact and recognition of her research.

🔹Professional Profile

ORCID

Google Scholar

🏆Strengths for the Award

  • High Research Productivity:
    Dr. Ma has published 50 SCI papers, with 29 as first or corresponding author in top-tier journals such as Angewandte Chemie International Edition, Advanced Energy Materials, Chemical Society Reviews, and Nano-Micro Letters. This demonstrates her consistent, high-level contribution to cutting-edge research.

  • Research Impact and Recognition:
    An h-index of 30 at her career stage is an impressive metric, reflecting a strong citation record and influence in the field of materials science and energy research.

  • Leadership in Research Projects:
    She has successfully led national and regional research projects, including funding from the National Natural Science Foundation of China and the Natural Science Foundation of Shanghai, indicating her ability to secure competitive grants and lead research teams.

  • Strong Academic Credentials and Progression:
    Earning a Ph.D. from Fudan University, followed by a rapid promotion from Lecturer to Associate Professor at Donghua University, underlines her strong academic background and recognition by her institution.

  • Focused and Relevant Research Area:
    Her research in electrocatalysis, energy storage, and hydrogen production is not only scientifically important but also aligned with global energy and sustainability goals, increasing its practical and societal relevance.

🎓 Education

Dr. Ma earned her Ph.D. in Chemistry from Fudan University in 2019, where she conducted cutting-edge research under the supervision of the esteemed. During her doctoral studies, she developed a strong foundation in electrochemical energy storage, organic-inorganic hybrid materials, and molecular-level material design. Her academic training equipped her with both deep theoretical knowledge and strong experimental skills in advanced materials science.

👩‍🔬 Experience

Immediately after completing her Ph.D., Dr. Ma joined Donghua University as a Lecturer in July 2019. In recognition of her remarkable academic output and research leadership, she was promoted to Associate Professor within a short span—an exceptional achievement in academia. At Donghua, she serves as a Master’s Supervisor, guiding graduate students in breakthrough material innovation. She also plays a key role in managing and executing several national and provincial research projects, including grants from the National Natural Science Foundation of China and the Natural Science Foundation of Shanghai. 🏅

🔬 Research Focus On Energy Storage

Dr. Ma’s research is centered on the design and development of advanced materials for sustainable energy solutions. Her work spans several critical areas of materials science. One key focus is the tailoring of inorganic nanomaterials to achieve high-performance electrocatalysis and energy storage, where she strategically engineers nanostructures to enhance catalytic activity and improve energy efficiency. Another major area involves the molecular-level design of organic electrode materials specifically for aqueous battery applications, aiming to develop safer, more environmentally friendly alternatives to conventional batteries. In addition, Dr. Ma is at the forefront of efforts to innovate water electrolysis systems for clean and efficient hydrogen production, contributing to the advancement of hydrogen as a viable alternative energy source.

📚 Publications Top Notes

Electrocatalytic Reduction of Nitrate – A Step Towards a Sustainable Nitrogen Cycle

Authors: H. Xu, Y. Ma, J. Chen, W. Zhang, J. Yang
Summary:
This highly cited review outlines recent advances in nitrate electroreduction technologies. It discusses catalyst materials, mechanisms, and system designs that enable conversion of nitrate into valuable products like ammonia. The work is a key resource for researchers tackling water pollution and aiming for a sustainable nitrogen cycle.

An Environmentally Friendly and Flexible Aqueous Zinc Battery Using an Organic Cathode

Authors: Z. Guo, Y. Ma, X. Dong, J. Huang, Y. Wang, Y. Xia
Summary:
This pioneering paper presents a safe, flexible zinc-ion battery with an organic cathode, offering a green alternative to conventional batteries. The battery system demonstrates strong performance, stability, and environmental compatibility—ideal for wearable electronics and sustainable storage.

Recent Progress of Rechargeable Batteries Using Mild Aqueous Electrolytes

Authors: J. Huang, Z. Guo, Y. Ma, D. Bin, Y. Wang, Y. Xia
Summary:
This review covers technological and chemical advancements in rechargeable batteries with aqueous electrolytes, focusing on improving safety, cost, and performance. It serves as a guide for future battery development with an emphasis on green and scalable energy systems.

High-Energy Rechargeable Metallic Lithium Battery at −70°C Enabled by a Cosolvent Electrolyte

Authors: X. Dong, Y. Lin, P. Li, Y. Ma, J. Huang, D. Bin, Y. Wang, Y. Qi, Y. Xia
Summary:
This study introduces a lithium-metal battery that operates at extreme cold (−70°C) using a cosolvent electrolyte. The battery maintains high energy density and reliability under frigid conditions, making it a breakthrough for aerospace and military applications.

Residual Chlorine Induced Cationic Active Species on a Porous Copper Electrocatalyst for Highly Stable Electrochemical CO₂ Reduction to C₂⁺

Authors: M. Li, Y. Ma, J. Chen, R. Lawrence, W. Luo, M. Sacchi, W. Jiang, J. Yang
Summary:
This paper develops a chlorine-modified porous copper catalyst that boosts the CO₂ reduction reaction to form C₂⁺ hydrocarbons like ethylene. It offers insights into catalyst design and stability, aiding progress toward carbon capture and utilization technologies.

🏁 Conclusion

Dr. Yuanyuan Ma exemplifies excellence in research, mentorship, and scientific innovation. Her impactful work in the design of sustainable materials and clean energy systems has received wide acclaim, positioning her as a leader in materials science. With a proven track record of high-impact publications, successful research grants, and student supervision, Dr. Ma is not only advancing science but also shaping the next generation of researchers. Her commitment to solving global energy challenges makes her an ideal candidate for any prestigious research or academic award. 🏆🌍