Talk - Alla Chikina: "Photoemission insight into the electronic properties of oxide interfaces"

09.11.2018 | Mette Alstrup Lie

Dato tir 20 nov
Tid 14:15 15:00
Sted 1520-737

Alla Chikina
Leibniz Institute for Solid State Research, IFW Dresden, D-01171 Dresden, Germany

Photoemission insight into the electronic properties of oxide interfaces

Abstract:

Interfacing transition metal generates the huge potential for achieving new physical properties tuning the interplay of electron, spin, orbital and lattice degrees of freedom. Indeed, the two-dimensional electron system (2DES) emergent at the interface between two wide band-gap insulators LaAlO3 (LAO) and SrTiO3 (STO) has opened new perspectives of oxide electronics.  Oxygen vacancies (VOs) play an important role in the electronic and magnetic properties of this interface due to the formation of a dichotomic electron system where strongly correlated localized electrons in the in-gap states (IGSs) coexist with less correlated ones constituting the mobile two-dimensional electron system (2DES)1.

Using resonant soft-X-ray ARPES experiments at the ADRESS beamline of Swiss Light Source, we establish orbital character of the mobile and localized electron states at the LAO/STO interface created by the VOs. We identify the predominantly Ti eg- vs t2g-derived orbital character of these two electron systems. Furthermore, we have distinguished different chemical states of the in-gap electrons and an additional crosstalk between the localized and mobile electron systems2.

Since VOs releases electrons to the system and, at the same time, assist increase the defect scattering rate, the separation of doped electrons and the source of doping can considerably increase the mobility of the system3. We consider this effect on the example of γ-Al2O3/STO, focusing on the unique band structure and carriers scattering on the VOs.

In the end, we provide fundamental understanding of X-ray induced oxygen migration at the STO-based interfaces. The controlled redox reaction results in formation of the interfacial metallicity which stays stable at ambient conditions. Our discovery of the X-ray pattering for the STO-based interfaces offers a technology of stable charge patterning for future oxide-based electronic devices.

 

[1]  F. Lechermann et al., Physical Review B 90, 85125 (2014).

[2] A. Chikina et al., ACS Nano 12, 7927–7935 (2018).

[3] C. Cancellieri et al., Nature Communications 7, 10386 (2016).

Institut for Fysik og Astronomi, Offentligheden / Pressen