Hi there! I’m a research project manager with a passion for green technology, holding an MSc in Physics from the University of Pavia and a PhD from Utrecht University. I love working on projects that bring innovative solutions to life, especially in the fields of energy and sustainability. Since joining Uniresearch in 2021, I have led proposal development and managed European research projects, particularly in sustainability and innovation. In the GREENCAP project, I support the coordination of day-to-day operations, ensuring smooth collaboration among partners. I also lead the dissemination, communication, and exploitation efforts to maximize the impact of GREENCAP’s innovative supercapacitors technology.
What was your original motivation to become a research project manager?
My original motivation to become a research project manager stemmed from my passion for bridging scientific research and practical implementation. During my academic journey, I enjoyed not only conducting experiments and theoretical research focused on NMR method development but also collaborating with multidisciplinary teams across borders. I realized that one of my strengths lies in organizing, coordinating, and facilitating the seamless execution of complex projects. The opportunity to contribute to impactful innovations, such as next-generation sustainable supercapacitors and clean energy (storage) solutions, while leveraging my skills in proposal development, international collaboration, and Open Science practices, inspired me to transition into this dynamic role. It’s incredibly fulfilling to support researchers in turning their ideas into reality and ensuring the projects succeed on a European and global scale.
What is your (main) research area today?
My work is deeply rooted in advancing innovation within the fields of battery and energy storage, PV, and clean fuels development. I oversee R&D proposal design, project management, and the implementation of Open Science practices to ensure impactful and sustainable outcomes. Additionally, I actively contribute to the exploitation and dissemination of research results, helping to bridge the gap between scientific advancements and their practical applications in energy and sustainability.
What is the main objective of your team in GREENCAP?
With over 30 years of experience, the main objective of our team in the GREENCAP project is to ensure the smooth management, coordination, and administration of the project while maximizing its overall impact. We focus on facilitating communication among all partners, ensuring timely dissemination of project results, and leading exploitation activities to promote the implementation of project advancements. By efficiently managing dissemination, communication, and exploitation tasks, we aim to ensure that GREENCAP’s innovative and eco-friendly supercapacitor technology reaches their full potential in addressing global energy challenges.
Which aspects of your research at GREENCAP do you believe are the most innovative and what unique opportunities offer GREENCAP to yourself and/or your organisation?
The most innovative aspect of GREENCAP is the focus on developing critical raw material (CRM)-free technology to produce high-performance and sustainable supercapacitors. The project’s integration of cutting-edge techniques sets it apart as a new solution to energy challenges. For Uniresearch, GREENCAP offers a unique opportunity to deepen our expertise in the renewable energy sector, especially in the areas of energy-efficient technologies and sustainable innovation. It allows us to expand our knowledge, strengthen our position in managing and coordinating large-scale European projects, and broaden our network by connecting with leading experts and organizations in the field. Additionally, we can advance our skills in the dissemination and exploitation of research outcomes to maximize their real-world impact.
- How do you see the future use of the GREENCAP results and the impact of GREENCAP project in our daily lives?
By developing sustainable, CRM-free supercapacitors based on advanced 2D materials like graphene and MXenes, GREENCAP could enable high-performance energy storage devices that are safer, longer-lasting, and more environmentally friendly. In practical terms, this could lead to greener electronics and transport: Lighter, more efficient supercapacitors could power electric vehicles, portable electronics, and renewable energy systems with lower environmental impact; and reduced reliance on critical raw materials: By eliminating scarce or hazardous materials, GREENCAP supports a more sustainable and resilient supply chain for energy storage. Overall, GREENCAP results could make sustainable energy storage more accessible, practical, and integrated into everyday life, supporting both environmental goals and technological innovation.
