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Article Abstract
The introduction of dislocations is a recently proposed strategy to tailor the functional and especially the electrical properties of ceramics. While several works confirm a clear impact of dislocations on electrical conductivity, some studies raise concern in particular when expanding to dislocation arrangements beyond a geometrically tractable bicrystal interface. Moreover, the lack of a complete classification on pertinent dislocation characteristics complicates a systematic discussion and hampers the design of dislocation-modified electrical conductivity. We proceed by mechanically introducing dislocations with three different mesoscopic structures into the model material single-crystal SrTiO and extensively characterizing them from both a mechanical as well as an electrical perspective. As a final result, a deconvolution of and enables us to obtain the complete picture of the effect of dislocations on functional properties, focusing here on electric properties.
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| http://dx.doi.org/10.1021/acsnano.0c04491 | DOI Listing |
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