International Panels/Scientific EvaluationĢ017-2021-Advisory Panel Board and Surface Science work package coordinator of A-LEAF (one of the largest funded EU project on Artificial Photosynthesis)Ģ021-Panel Chair Nanotechnology representing Swiss National Science Foundation for Southeast Asia – Europe Joint Funding SchemeĢ021-Panel member Nanotechnology for portuguese Fundação para a Ciência e a Tecnologia (FCT).Ģ019- Fellowships Austrian Academy of Sciences.Ģ020, 2016- Research Foundation Flanders (FWO) Belgium.Ģ010- American Chemical Society Petroleum Research Fund, USA.Ģ020-2015 PhD Jury in 8 PhD Thesis (3 students in Chemistry, 3 in Physics, 2 in Materials Science). Nanoscale Surface Self-Assembly a EuCheMS Conference, 19-23 of S June Stockholm Sweden. Awards/distictionsĢ018 Included in the Royal Society of Chemistry collection “Celebrating Excellence in Research: 100 Women of Chemistry”.Ģ011 Milstein Fellow, Argentinean Ministry of Science.Ģ008 Otto Hahn medal of the Max Planck Society (Best PhD thesis).Ģ005 1st Soft Materials Prize. for Molecular Nanoscience, École Polytechnique Fédérale de Lausanne (EPFL)Ģ011-2012 Post-Doctoral Fellow at the Molecular Foundry, Lawrence Berkeley National Laboratory, Berkeley, USA.Ģ011 Invited Lecturer, Instituto Balseiro, Centro Atómico Bariloche, Argentina.Ģ009-2011 Post-Doctoral Fellow at Institut de Ciència de Materials de Barcelona, Spain (European Project RESOLVE).Ģ004-2008 Research Assistant, PhD student at the Max Planck Institute for Solid State Research, Stuttgart, Germany. Professional experienceĢ013-present Group Leader Max Planck-EPFL Lab. Fields of expertiseīioNanoarchitectonics, operando surface science at solid/liquid interfaces, Self-assembly, Scanning Probe Microscopy, Chirality, X-Ray Photoelectron Spectroscopy, 2D materials, Antimicrobial surfaces. Mentoring scientists in a nurturing environment, focusing in scientific integrity, creativity and appreciation of their unique contribution to science. Exploring fundamental concepts that connect nanoscale phenomena with applicable interfaces, to address urgent technological and societal problems. In 2018, the Royal Society of Chemistry included her work in the first collection “Celebrating Excellence in Research: 100 Women of Chemistry”. She advocates for problem-oriented interdisciplinary research: she is pioneering the emerging field of BioNanoarchitectonics, she led 5 international research consortiums, delivered over 40 invited presentations, and organized 9 conferences and 4 doctoral schools. She is a committed mentor, and since her relocation from Berkeley to EPFL in 2013, she directed 3 MSc theses, 4 PhD theses, and 4 postdocs. In her quest to study molecular recognition going from 2D to 3D complex systems, she made postdoctoral stays at the Institute of Materials Sciences in Barcelona, and at the Molecular Foundry of the Lawrence Berkeley National Lab in the US. ![]() She continued with her doctoral studies in Physics, and received the Otto Hahn medal of the Max Planck Society in 2008 for the microscopic understanding of the chiral recognition process with submolecular resolution. In 2003 she finished her MSc thesis at the Max Planck Institute for the Solid State Research (MPI-FKF in Stuttgart, Germany) with seminal contributions to the field of metal-organic coordination networks on solid surfaces. She studied physical and biological chemistry at the National University of Córdoba in Argentina. Her vision is to create atomically tailored interfaces for applications in two distinct areas of urgent technological and societal relevance: energy conversion and antimicrobial interfaces. Magalí Lingenfelder is currently leading the Max Planck-EPFL Laboratory for Molecular Nanoscience in Lausanne, Switzerland. We thank HORIZON 2020, SERI, CONICET, MinCyT and MPI and the US Department of Energy for supporting our research! ![]() Our group is based at EPFL campus, 90% financed by external resources. To access the nanoscale, our group uses a combination of cutting edge scanning probe microscopy and solid state spectroscopy, allowing the study of kinetic processes in-situ under liquid flow and potential control conditions. Our vision is to create atomically tailored interfaces for applications in two distinct areas of urgent technological relevance: energy conversion and antimicrobial interfaces. ![]() We see the surface as the skin of the material, the way it communicates and interfaces with the environment. We mimic nature to create sustainable materials and devices. Nature creates dynamic and responsive systems across different time and length scales.
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