TY - JOUR
T1 - Conductivity control via minimally invasive anti-Frenkel defects in a functional oxide
AU - Evans, Donald M.
AU - Holstad, Theodor S.
AU - Mosberg, Aleksander B.
AU - Småbråten, Didrik R.
AU - Vullum, Per Erik
AU - Dadlani, Anup L.
AU - Shapovalov, Konstantin
AU - Yan, Zewu
AU - Bourret, Edith
AU - Gao, David
AU - Akola, Jaakko
AU - Torgersen, Jan
AU - van Helvoort, Antonius T.J.
AU - Selbach, Sverre M.
AU - Meier, Dennis
N1 - Publisher Copyright:
© 2020, The Author(s), under exclusive licence to Springer Nature Limited.
PY - 2020/11/1
Y1 - 2020/11/1
N2 - Utilizing quantum effects in complex oxides, such as magnetism, multiferroicity and superconductivity, requires atomic-level control of the material’s structure and composition. In contrast, the continuous conductivity changes that enable artificial oxide-based synapses and multiconfigurational devices are driven by redox reactions and domain reconfigurations, which entail long-range ionic migration and changes in stoichiometry or structure. Although both concepts hold great technological potential, combined applications seem difficult due to the mutually exclusive requirements. Here we demonstrate a route to overcome this limitation by controlling the conductivity in the functional oxide hexagonal Er(Mn,Ti)O3 by using conductive atomic force microscopy to generate electric-field induced anti-Frenkel defects, that is, charge-neutral interstitial–vacancy pairs. These defects are generated with nanoscale spatial precision to locally enhance the electronic hopping conductivity by orders of magnitude without disturbing the ferroelectric order. We explain the non-volatile effects using density functional theory and discuss its universality, suggesting an alternative dimension to functional oxides and the development of multifunctional devices for next-generation nanotechnology.
AB - Utilizing quantum effects in complex oxides, such as magnetism, multiferroicity and superconductivity, requires atomic-level control of the material’s structure and composition. In contrast, the continuous conductivity changes that enable artificial oxide-based synapses and multiconfigurational devices are driven by redox reactions and domain reconfigurations, which entail long-range ionic migration and changes in stoichiometry or structure. Although both concepts hold great technological potential, combined applications seem difficult due to the mutually exclusive requirements. Here we demonstrate a route to overcome this limitation by controlling the conductivity in the functional oxide hexagonal Er(Mn,Ti)O3 by using conductive atomic force microscopy to generate electric-field induced anti-Frenkel defects, that is, charge-neutral interstitial–vacancy pairs. These defects are generated with nanoscale spatial precision to locally enhance the electronic hopping conductivity by orders of magnitude without disturbing the ferroelectric order. We explain the non-volatile effects using density functional theory and discuss its universality, suggesting an alternative dimension to functional oxides and the development of multifunctional devices for next-generation nanotechnology.
UR - http://www.scopus.com/inward/record.url?scp=85089493457&partnerID=8YFLogxK
U2 - 10.1038/s41563-020-0765-x
DO - 10.1038/s41563-020-0765-x
M3 - Article
C2 - 32807925
AN - SCOPUS:85089493457
SN - 1476-1122
VL - 19
SP - 1195
EP - 1200
JO - Nature Materials
JF - Nature Materials
IS - 11
ER -