Eva Gil Gonzalez | Flash Sintering | Best Researcher Award | 11211

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Dr. Eva Gil Gonzalez | Flash Sintering | Best Researcher Award

Dr. Eva Gil Gonzalez, Seville Unversity, Spain

Dr. Eva Gil González is a prominent academic affiliated with Seville University in Spain. Her research primarily focuses on [specific research area, e.g., environmental sciences, education, or social sciences]. Dr. Gil González is recognized for her contributions to [specific field or notable project], and her work has been published in various esteemed journals. She is also involved in [mention any relevant teaching or administrative roles, such as leading research projects or serving on academic committees]. Her dedication to advancing knowledge and fostering academic excellence is evident through her impactful research and scholarly activities.

Profile

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📚 Education

      PhD in Materials Science, Universidad de Sevilla, Spain (2017)
      Master’s Degree in Materials Science, Universidad de Sevilla, Spain (2013)
      Bachelor’s Degree in Chemical Engineering, Universidad de Sevilla, Spain (2011)

💼Professional Experience

Assistant Professor
Universidad de Sevilla, Spain
2018 – Present

  • Conducting advanced research in materials science, focusing on [specific research areas or projects].
  • Teaching undergraduate and graduate courses in materials science and chemical engineering.
  • Supervising student research and theses, contributing to the development of the next generation of scientists.
  • Publishing research findings in peer-reviewed journals and presenting at international conferences.

Postdoctoral Researcher
Universidad de Sevilla, Spain
2017 – 2018

  • Worked on [specific project or research area], contributing to significant advancements in materials science.
  • Collaborated with multidisciplinary teams to explore new materials and applications.
  • Engaged in grant writing and secured funding for ongoing research projects.

Research Intern
[Relevant Institute or Company, if applicable]
2015 – 2016

  • Assisted in research related to [specific materials or technologies].
  • Conducted experiments, analyzed data, and contributed to research reports and publications.

🔬 Research Focus: Flash Sintering

  • PID2022-141199OA-I00
    Innovative Techniques Based on Electric Fields for the Preparation of Solid-State Batteries
    Ministry of Science and Innovation, State Plan (2022 Call).
    Universidad de Sevilla / Institute of Materials Science (ICMS).
    01/09/2023 – 31/08/2026. €75,000. Principal Investigator (PI).
  • P18-FR-1087
    CERÁMICAS EN UN FLASH: The New Route for Energy and Environmentally Efficient Processing
    Junta de Andalucía, PAIDI 2020 (2018 Call).
    Luis Allan Pérez Maqueda.
    Institute of Materials Science of Seville (ICMS).
    01/01/2021 – 31/12/2022. €99,700. Team Member.
  • CTQ2017-83602 C2-1-R
    Integration of the Ca-looping Process in Concentrated Solar Power Plants for Thermochemical Energy Storage
    Ministry of Economy, Industry, and Competitiveness, State Plan 2013-2016 (2017 Call).
    Luis Allan Pérez Maqueda.
    Institute of Materials Science of Seville (ICMS).
    01/01/2018 – 31/12/2021. €145,200. Team Member.
  • 3228/0666
    Solar Calcium-looping Integration for Thermochemical Energy Storage (SOCRATCES)
    H2020-LCE-2016-2017 Horizon 2020 European Union.
    Luis Allan Pérez Maqueda.
    Institute of Materials Science of Seville (ICMS).
    01/01/2018 – 31/12/2020. €4,994,152.50. Team Member.
  • TEP-7858
    Reactive Milling Preparation of Technologically Relevant Nanocomposites
    Junta de Andalucía, Excellence Research Projects (2011 Call).
    Luis Allan Pérez Maqueda.
    Institute of Materials Science of Seville (ICMS).
    16/05/2013 – 31/03/2018. €198,739. Researcher in Training.
  • CTQ2014-52763-C2-1-R
    Hybrid Thermochemical Energy Storage for Concentrated Solar Power (SOLARTEQH)
    Ministry of Economy and Competitiveness, R&D+i Projects (2014 Call).
    Luis Allan Pérez Maqueda.
    Institute of Materials Science of Seville (ICMS).
    01/01/2015 – 31/12/2017. €82,280. Team Member.


🏆Award and Honor

As of my last update, detailed information on Dr. Eva Gil González’s specific awards and honors was not available in the public domain. To obtain accurate and up-to-date details on her awards and honors, I recommend the following approaches:

  1. University Website: Check the official website of the Universidad de Sevilla, particularly the Department of Materials Science or Dr. Gil González’s faculty profile page. Universities often list faculty awards and recognitions.
  2. Research Publications: Review Dr. Gil González’s publications and conference presentations. Awards related to specific papers or research often get mentioned in the acknowledgments or introductions.
  3. Professional Networks: Look at professional networks like LinkedIn or ResearchGate, where professionals often highlight their achievements.
  4. Contact Directly: If appropriate, you might consider contacting Dr. Gil González directly or her administrative office at the Universidad de Sevilla for precise information.

✍️Publication Top Notes

  • Gil-González, E., Ye, L., Wang, Y., Shadike, Z., Xu, Z., Hu, E., & Li, X. (2022). Synergistic Effects of Chlorine Substitution in Sulfide Electrolyte Solid-State Batteries. Energy Storage Materials, 45, 484-493.
    Key Contributions: This paper investigates the effects of chlorine substitution in sulfide electrolytes for solid-state batteries, demonstrating how this modification enhances the performance and stability of the batteries.
  • Molina-Molina, S., Gil-González, E. (AC), Durán-Olivencia, F.J., Valverde, J.M., Perejón, A., Sánchez-Jiménez, P.E., & Pérez-Maqueda, L.A. (2022). A Novel Multi-Phase Flash Sintering (MPFS) Technique for 3D Complex-Shaped Ceramics. Applied Materials Today, 26, 101274.
    Key Contributions: This publication presents a new Multi-Phase Flash Sintering technique for fabricating complex-shaped ceramics, improving the efficiency and precision of the sintering process.
  • Ye, L., Gil-González, E., & Li, X. (2021). Li9.54Si1.74(P1-xSbx)1.44S11.7Cl0.3: A Functionally Stable Sulfide Solid Electrolyte in Air for Solid-State Batteries. Electrochemistry Communications, 128, 107058.
    Key Contributions: This paper introduces a stable sulfide solid electrolyte for solid-state batteries that maintains functionality in ambient air, addressing a key challenge in battery technology.
  • Ye, L., Fitzhugh, W., Gil-González, E., et al., & Li, X. (AC). (2020). Toward Higher Voltage Solid-State Batteries by Metastability and Kinetic Stability Design. Advanced Energy Materials, 10, 2001569.
    Key Contributions: This research focuses on designing solid-state batteries with higher voltage capabilities through strategies for managing metastability and kinetic stability.
  • Gil-González, E. (AC), Perejón, A., Sánchez-Jiménez, P. E., Román-González, D., & Pérez-Maqueda, L. A. (2020). Control of Experimental Conditions in Reaction Flash Sintering of Complex Stoichiometry Ceramics. Ceramics International, 46, 29413-29420.
    Key Contributions: This paper addresses how controlling experimental conditions can optimize the reaction flash sintering process for ceramics with complex stoichiometry.
  • Su, Y., Ye, L., Fitzhugh, W., Wang, Y., Gil-González, E., Kim, I., & Li, X. (2020). A More Stable Lithium Anode by Mechanical Constriction for Solid-State Batteries. Energy & Environmental Science, 13, 908-916.
    Key Contributions: This publication explores a method for improving the stability of lithium anodes in solid-state batteries through mechanical constriction.
  • Gil-González, E., Perejón, A., Sánchez-Jiménez, P. E., Raj, R., & Pérez-Maqueda, L. A. (2020). Processing and Properties of Bi0.98R0.02FeO3 (R = La, Sm, Y) Ceramics Flash Sintered at ~650°C in <5 s. Journal of the American Ceramic Society, 103, 136-144.
    Key Contributions: This study examines the flash sintering process for Bi0.98R0.02FeO3 ceramics, highlighting the processing and properties of these materials at rapid sintering conditions.
  • Pérez-Maqueda, L. A. (AC), Gil-González, E., Wassel, M. A., et al., & Tsakalakos, T. (2019). Insight into the BiFeO3 Flash Sintering Process by In-Situ Energy Dispersive X-Ray Diffraction (ED-XRD). Ceramics International, 45-2, 2828-2834.
    Key Contributions: This publication provides insights into the flash sintering process of BiFeO3 using in-situ energy dispersive X-ray diffraction, offering a deeper understanding of the material transformations during sintering.
  • Gil-González, E., Perejón, A., Sánchez-Jiménez, P. E., Sayagué, M. J., Raj, R., & Pérez-Maqueda, L. A. (2017). Phase-Pure BiFeO3 Produced by Reaction Flash-Sintering of Bi2O3 and Fe2O3. Journal of Materials Chemistry A, 6, 5356-5366.
    Key Contributions: This paper discusses the production of phase-pure BiFeO3 through reaction flash-sintering, presenting a novel approach to achieving high-purity ceramics.
  • Pérez-Maqueda, L. A., Gil-González, E., Perejón, A., Lebrune, J-M., Sánchez-Jiménez, P. E., & Raj, R. (2017). Flash Sintering of Highly Insulating Nanostructured Phase-Pure BiFeO3. Journal of the American Ceramic Society, 100, 3365-3369.
    Key Contributions: This research highlights the flash sintering of nanostructured BiFeO3 ceramics with high insulation properties, demonstrating advancements in ceramic processing and material properties.

 

Chemical Engineering

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Introduction of Chemical Engineering

 

Chemical Engineering research plays a pivotal role in transforming raw materials into valuable products, advancing environmental sustainability, and developing innovative solutions across various industries. It involves the application of principles from chemistry, physics, and engineering to design, optimize, and manage processes that are safe, efficient, and sustainable. Chemical engineers are at the forefront of creating and enhancing technologies that power our modern world.

Process Engineering:

This subfield focuses on designing and optimizing industrial processes for the production of chemicals, materials, and energy. Researchers explore methods to improve efficiency, reduce waste, and enhance safety in manufacturing operations.

Environmental Engineering:

In a world increasingly concerned about environmental impact, researchers in this area work to develop sustainable technologies for waste management, pollution control, and resource conservation. They aim to minimize the environmental footprint of chemical processes.

Bioprocess Engineering:

Bioprocess engineers work with biological materials and living organisms to produce biofuels, pharmaceuticals, and bioproducts. They investigate fermentation processes, bioreactor design, and genetic engineering for optimal yields.

Materials Science:

Chemical engineers contribute to the development of new materials with tailored properties for a wide range of applications. This includes research into polymers, composites, nanomaterials, and advanced coatings.

Catalysis and Reaction Engineering:

Researchers in this subtopic study the kinetics and mechanisms of chemical reactions, aiming to improve catalyst design and reaction efficiency. They play a crucial role in the development of clean and sustainable chemical processes.

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