Arianna Marchioro
EPFL STI IBI-STI LBP
BM 4113 (Bâtiment BM)
Station 17
1015 Lausanne
+41 21 693 61 80
Office: BM 4113
EPFL › STI › IBI-STI › LBP
Website: https://lbp.epfl.ch
+41 21 693 61 80
Office: BM 4113
EPFL › VPA › VPA-AVP-DLE › AVP-DLE-EDOC › EDCH-ENS
Education
PhD Thesis
| Interfacial Charge Transfer Dynamics in Solid-State Hybrid Organic-Inorganic Solar Cells
2010 – 2014
EPFL
Directed by
Prof. J.-E. Moser and Prof. M. Grätzel
MSc in Molecular and Biological Chemistry
|2008 – 2010 EPFL and Imperial College London (exchange program)
BSc in Chemistry
|2005 – 2008 EPFL
Professionals experiences
Postdoctoral Research Associate
Selected publications
Unravelling the mechanism of photoinduced charge transfer processes in lead iodide perovskite solar cells
Marchioro, A., Teuscher, J., Friederich, D., Kunst, M., van de Krol, R., Moehl T., Gr�tzel, M., Moser, J.-E.
Published in Nature Photonics, advanced online publications, 2014 in
Water Orientation at the Anatase TiO2 Nanoparticle Interface: A Probe of Surface pKa Values
Arianna Marchioro
Published in Journal of Physical Chemistry Letters in 2022
Evolution of the electrical double layer with electrolyte concentration probed by second harmonic scattering
Arianna Marchioro
Published in Faraday Discussions in 2023
Surface Potential and Interfacial Water Order at the Amorphous TiO2 Nanoparticle/Aqueous Interface
Arianna Marchioro
Published in Journal of Physical Chemistry C in 2020
Teaching & PhD
Past EPFL PhD Students as codirector
Igor Nahálka, Marie Bischoff, Bingxin Chu
Courses
Electron & energy transfer in organic & hybrid systems
ChE-614
Electron and energy transfer processes are vital to biological functions. In synthetic molecular and hybrid systems, they are key to device efficiency. Advances in understanding and control of these processes continue to drive innovation across scientific and technological fields.
Materials:from chemistry to properties
MSE-101(b)
This class will teach the fundamental concepts regarding materials and their micro-structure, as well as the equilibrium and dynamics of chemical reactions. A link will be made between these concepts and the mechanical, thermal, electrical, magnetic and optical properties of materials.
Optical properties of materials
MSE-482
Students will study fundamental principles of light-matter interaction and apply classical and quantum mechanical models for quantitative estimates. Optical phenomena in glasses, organic/inorganic semiconductors, liquid crystals, quantum dots as well as device applications will be treated.