BEGIN:VCALENDAR VERSION:2.0 PRODID:www.dresden-science-calendar.de METHOD:PUBLISH CALSCALE:GREGORIAN X-MICROSOFT-CALSCALE:GREGORIAN X-WR-TIMEZONE:Europe/Berlin BEGIN:VTIMEZONE TZID:Europe/Berlin X-LIC-LOCATION:Europe/Berlin BEGIN:DAYLIGHT TZNAME:CEST TZOFFSETFROM:+0100 TZOFFSETTO:+0200 DTSTART:19810329T030000 RRULE:FREQ=YEARLY;INTERVAL=1;BYMONTH=3;BYDAY=-1SU END:DAYLIGHT BEGIN:STANDARD TZNAME:CET TZOFFSETFROM:+0200 TZOFFSETTO:+0100 DTSTART:19961027T030000 RRULE:FREQ=YEARLY;INTERVAL=1;BYMONTH=10;BYDAY=-1SU END:STANDARD END:VTIMEZONE BEGIN:VEVENT UID:DSC-22604 DTSTART;TZID=Europe/Berlin:20260127T090000 SEQUENCE:1769495761 TRANSP:OPAQUE DTEND;TZID=Europe/Berlin:20260127T100000 URL:https://www.dresden-science-calendar.de/calendar/de/detail/22604 LOCATION:IFW\, Helmholtzstraße 2001069 Dresden SUMMARY:Svanidze: Bridging the gap between physics and chemistry – design of new materials CLASS:PUBLIC DESCRIPTION:Speaker: Dr. Eteri Svanidze\nInstitute of Speaker: Max Planck I nstitute for Chemical Physics of Solids\, Dresden\nTopics:\n\n Location:\n Name: IFW (D2E.27\, IFW Dresden)\n Street: Helmholtzstraße 20\n City: 01069 Dresden\n Phone: \n Fax: \nDescription: Over the past decades\, q uantum materials – materials in which quantum phenomena govern physical p roperties – have become essential to everyday applications. In most cases \, technological advances are driven by the discovery of new solid-state m aterials and by a deeper understanding of existing ones. In this talk\, I will present several families of solid-state materials discovered in our g roup. Our approach is guided not only by intuition\, but also by a close d ialogue between chemistry and physics\, and between theory and experiment. First\, I will discuss some of the empirical tools for targeting new mat erials with desired properties. From a chemical perspective\, we are looki ng at diverse compounds\, ranging from crystallographically simple to fair ly complex – with as many as 444 atoms per unit cell. While the former ca n be supported by theoretical insights\, the only way to establish the pro perties of the latter is to make and experimentally study them. By employi ng new methodology\, we can access materials that so far remained out of r each due to their toxicity\, radioactivity\, or air sensitivity. Furthermo re\, we develop new ways to extract properties from micro-scale grains\, e xtracted from multi-phase samples. In superconductors\, we tune the critic al temperature by making minute changes in the crystal structure. Among ma gnetic compounds\, we examine not only strongly correlated systems that ho st exceptionally heavy electron masses at low temperatures\, but also room temperature magnets that have application potential. Our experimental exp lorations go hand-in-hand with theory – we have targeted and confirmed a plethora of topological features. DTSTAMP:20260628T142903Z CREATED:20260121T063936Z LAST-MODIFIED:20260127T063601Z END:VEVENT END:VCALENDAR