Journal Article

FZJ-2018-03698

http://join2-wiki.gsi.de/foswiki/pub/Main/Artwork/join2_logo100x88.png Local surface conductivity of transition metal oxides mapped with true atomic resolution

Rodenbücher, C. (Corresponding author)FZJ* ; Bihlmayer, G.FZJ* ; Speier, W.FZJ*RWTH* ; Kubacki, J. ; Wojtyniak, M. ; Rogala, M. ; Wrana, D. ; Krok, F. ; Szot, K.FZJ*

2018
RSC Publ. Cambridge

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Please use a persistent id in citations: doi:10.1039/C8NR02562B

Abstract: The introduction of transition metal oxides for building nanodevices in information technology promises to overcome the scaling limits of conventional semiconductors and to reduce global power consumption significantly. However, oxide surfaces can exhibit heterogeneity on the nanoscale e.g. due to relaxation, rumpling, reconstruction, or chemical variations which demands for direct characterization of electronic transport phenomena down to the atomic level. Here we demonstrate that conductivity mapping is possible with true atomic resolution using the tip of a local conductivity atomic force microscope (LC-AFM) as the mobile nanoelectrode. The application to the prototypical transition metal oxide TiO2 self-doped by oxygen vacancies reveals the existence of highly confined current paths in the first stage of thermal reduction. Assisted by density functional theory (DFT) we propose that the presence of oxygen vacancies in the surface layer of such materials can introduce short range disturbances of the electronic structure with confinement of metallic states on the sub-nanometre scale. After prolonged reduction, the surfaces undergo reconstruction and the conductivity changes from spot-like to homogeneous as a result of surface transformation. The periodic arrangement of the reconstruction is clearly reflected in the conductivity maps as concluded from the simultaneous friction force and LC-AFM measurements. The second prototype metal oxide SrTiO3 also reveals a comparable transformation in surface conductivity from spot-like to homogeneous upon reduction showing the relevance of nanoscale inhomogeneities for the electronic transport properties and the utility of a high-resolution LC-AFM as a convenient tool to detect them.

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Contributing Institute(s):

1. Elektronische Materialien (PGI-7)
2. Quanten-Theorie der Materialien (PGI-1)
3. Quanten-Theorie der Materialien (IAS-1)
4. JARA-FIT (JARA-FIT)
5. JARA - HPC (JARA-HPC)

Research Program(s):

1. 142 - Controlling Spin-Based Phenomena (POF3-142) (POF3-142)
2. Magnetic Anisotropy of Metallic Layered Systems and Nanostructures (jiff13_20131101) (jiff13_20131101)

Appears in the scientific report 2018

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Database coverage:
; Current Contents - Physical, Chemical and Earth Sciences ; IF >= 5 ; JCR ; NCBI Molecular Biology Database ; SCOPUS ; Science Citation Index ; Science Citation Index Expanded ; Thomson Reuters Master Journal List ; Web of Science Core Collection

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