Speaker-Francesco Bonaccorso
Francesco Bonaccorso gained the PhD from the University of Messina. In 2009 he was awarded a Royal Society Newton International Fellowship at Cambridge University, and elected to a Research Fellowship at Hughes Hall, Cambridge, where he also obtained a MA. He is the Scientific Director of BeDimensional SpA and visiting Scientist at the Istituto Ital-iano di Tecnologia. He is author of 17 patent families and more than 200 publications that have been cited more than 41600 times. He was featured as 2016 Emerging Investigator by J. Mater. Chem. A and in 2019 by ChemPlusChem. In 2018 he was recognized as Highly cited Scientist by Clarivate Analytics. In 2019 he received the Magister Peloritanus by Accademia Peloritana dei Pericolanti and ExAllievi Eccellenti by the University of Messina. He co-founded Cambridge Graphene Ltd and BeDimensional SpA.
In this presentation we will provide an overview on the use of 2D materials as interfaces in energy storage and conversion devices.[1-5]
In the first part of the presentation, we will present our industrial, scalable, reliable, and inexpensive production of 2D materials,[6-8] involving a balance between final product quality and ease of fabrication. We will show the efficiency of the manufacturing of high-quality 2D materials by wet-jet milling[6] and the path towards industrial production.
Afterward, we will provide an overview on a few key applications of the as-produced 2D materials as interfaces and electrodes in energy related applications. We will show how the production of 2D materials in liquid phase by wet-jet milling[6] represents a powerful pathway towards the development of 2D materials-based devices,[1-5,9-12] offering massive integration flexibility compared to other production methodologies.
References
[1] F. Bonaccorso, et. al., Science, 347, (2015), 1246501.
[2] E. Pomerantseva, et al., Science 366, (2019), eaan8285.
[3] S. Pescetelli et al., Nature Energy 7, (2022), 597-607.
[4] P. Mariani, et al., Nature Comm. 15, (2024), 4552.
[5] L. Najafi et al., ACS Nano 12, (2018), 10736.
[6] F. Bonaccorso, et al., Materials Today, 15, (2012), 564.
[7] A. E. Del Rio Castillo et. al., Mater. Horiz. 5, (2018), 890.
[8] F. Bonaccorso, et. al., Adv. Mater. 28, (2016), 6136.
[9] L. Najafi et al., Adv. Ener. Mater. 8, (2018), 1703212.
[10] E. Lamanna et al., Joule 4, (2020), 865-881.
[11] M. Garakani, et al., Energy Storage Materials 34, (2020), 1-11.
[12] S. Bellani et al., Advanced Functional Materials 29 (2019), 1807659.
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