Title: Kosmas Prassides: Emergent electronic phenomena in all-carbon π-electron molecular systems
Number: 22/21
Status: Closing date exceeded
Begin: Středa, 14.04. 2021, 10:10
Tutor: Ross H. Colman & Vladimír Sechovský
Location: ZOOM Meeting ID: 958 0426 7376

new logo


We have a pleasure to invite you to attend the joint seminar
of the Department of Condensed Matter Physics (DCMP)
and the Materials Growth and Measurement Laboratory (MGML)




Emergent electronic phenomena in all-carbon π-electron molecular systems

lecture given by:

Kosmas Prassides

Tohoku University and Osaka Prefecture University, Japan
Meeting ID: 958 0426 7376 

on Wednesday, 14.4. 2021 from 10:10 CET (8.10 UTC) 

Passcode will be provided on request at  Tato emailová adresa je chráněna před spamboty, abyste ji viděli, povolte JavaScript


Ross H. Colman & Vladimír Sechovský
On behalf of the DCMP and MGML


Superconductors and magnets in which the electronically-active components are molecules rather than atoms often consist of π-electron open-shell molecular units as the main component of the electronic conduction and spin network, respectively. Current best-in-class materials are the all-carbon π-electron fullerides–these show the highest known superconducting critical temperature, Tc at 38 K coupled with a record upper critical magnetic field, Hc2 in excess of 90 T. The dominance of strong electron correlations in defining their behavior poses significant challenges for understanding the highly robust superconducting response to both temperature and magnetic field in these highly correlated molecular systems. In addition, we have recently unveiled other extended molecular carbon-based π-systems such as ionic polyaromatic hydrocarbons (PAHs) as new electronic materials platforms beyond C60–here alkali metal phenacenes have provided the first example of a 3D quantum spin-liquid state to 50 mK arising purely from π-electrons, while at the same time harboring orbitally entangled states, prerequisites of the emergence of quantum magnetism and exotic superconductivity. Here I will attempt to trace the development of this field of science to date with emphasis on its current status and future prospects.