2009
DOI: 10.1063/1.3226654
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Shear effects in lateral piezoresponse force microscopy at 180° ferroelectric domain walls

Abstract: In studies using piezoresponse force microscopy, we observe a nonzero lateral piezoresponse at 180°d omain walls in out-of-plane polarized, c-axis-oriented tetragonal ferroelectric Pb͑Zr 0.2 Ti 0.8 ͒O 3 epitaxial thin films. We attribute these observations to a shear strain effect linked to the sign change of the d 33 piezoelectric coefficient through the domain wall, in agreement with theoretical predictions. We show that in monoclinically distorted tetragonal BiFeO 3 films, this effect is superimposed on the… Show more

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Cited by 35 publications
(33 citation statements)
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“…However, in both PMN-32%PT and PMN-35%PT crystals one can observe a clear correspondence between the vertical and lateral domains so that the domain walls in both images coincide. This behavior is consistent with LPFM behavior at 180°-domain walls [28][29][30] and thus can be ascribed to a crosscoupling with the vertical signal. Based on the examination of the images, we conclude that the in-plane component contribution to the LPFM signal is below the detection limit ͑less than ϳ20% of vertical signal͒.…”
Section: A Static Domain Pfm Imagingsupporting
confidence: 85%
“…However, in both PMN-32%PT and PMN-35%PT crystals one can observe a clear correspondence between the vertical and lateral domains so that the domain walls in both images coincide. This behavior is consistent with LPFM behavior at 180°-domain walls [28][29][30] and thus can be ascribed to a crosscoupling with the vertical signal. Based on the examination of the images, we conclude that the in-plane component contribution to the LPFM signal is below the detection limit ͑less than ϳ20% of vertical signal͒.…”
Section: A Static Domain Pfm Imagingsupporting
confidence: 85%
“…[109][110][111][112][113][114][115] Similar approaches were pursued by other groups. [116][117][118][119][120] These analyses were extended to quantitatively describe a ferroelectric domain wall profile in vertical and lateral PFM 115,121,122 , orientational dependence of the PFM signal, 112,123 and to quantify piezoresponse spectroscopy 124 , as will be discussed below. Perhaps even more importantly, the PFM signal (more rigorously, electromechanical surface displacement) was shown to be independent of contact area, ensuring that PFM, unlike force based SPMs, can be an intrinsically quantitative technique.…”
Section: Iia Basic Pfmmentioning
confidence: 99%
“…PFM thus allows the position of individual ferroelectric domain walls to be mapped with sub-10 nm resolution over areas essentially limited only by the scan range (10s-100s µm). Moreover, novel domain-wall-specific functional properties can be readily identified, including characteristic lateral piezoresponse features in out-of-plane polarised samples [69,70,71], and, with additional conductive tip current measurements, domain wall electrical conduction in these otherwise insulating materials [72,73,74,75,76].…”
Section: Using Pfm To Study Individual Ferroelectric Domain Wallsmentioning
confidence: 99%