Imaging and tuning polarity at SrTiO3 domain walls

Frenkel, Yiftach; Haham, Noam; Shperber, Yishai; Bell, C. H.; Xie, Yanwu; Chen, Zhuoyu; Hikita, Yasuyuki; Hwang, Harold Y.; Salje, Ekhard K. H.; Kalisky, Beena

doi:10.1038/nmat4966

Cited by 79 publications

(81 citation statements)

References 39 publications

(77 reference statements)

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“…The surface termination can only switch at ferroelectric domain walls, which, at the surface, are associated with very large steps. The observed domain size is in the few µm range, and the orientation of the steps is consistent with observations made on various thin films grown on SrTiO 3 , where the domain walls run along the main crystallographic directions and linear combinations thereof [27][28][29].…”

supporting

confidence: 88%

Incipient ferroelectricity: A route towards bulk-terminated SrTiO3

Sokolović

Schmid

Diebold

et al. 2019

Phys. Rev. Materials

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Perovskite oxides attract increasing attention due to their broad potential in many applications [1][2][3]. Understanding their surfaces is challenging, though, because the ternary composition of the bulk allows for multiple stable surface terminations [4]. We demonstrate a simple procedure for preparing the bulk-terminated (001) surface of SrTiO 3 , a prototypical cubic perovskite. Controlled application of strain on a SrTiO 3 single crystal results in a flat cleavage with micrometer-size domains of SrO and TiO 2 . Distribution of these two terminations is dictated by ferroelectric domains induced by strain [5] during the cleavage process. Atomically-resolved scanning tunneling microscopy/atomic force microscopy (STM/AFM) measurements reveal the presence of point defects in a well-defined concentration of (14±2)%; Sr vacancies form at the SrO termination and complementary Sr adatoms appear at the TiO 2 termination. These intrinsic defects are induced by the interplay between ferroelectricity, surface polarity, and surface charge.SrTiO 3 is the prototypical cubic perovskite oxide, interesting for its catalytic and photocatalytic properties [6], potential use in oxide electronics [7][8][9][10], and fundamental questions including the appearance of twodimensional electron gas at its surfaces [11][12][13] and interfaces [3]. The SrTiO 3 (001) surface plays a key role in all these functionalities, but the available surface studies of this facet illustrate a general problem of approaching perovskite materials: A plethora of various surface terminations can form, depending on the preparation technique and on slight changes in the surface stoichiometry. The centre of interest typically lies in bulk-terminated perovskite surfaces, because wet chemical preparation methods typically provide surfaces with a (1×1) diffraction pattern [9]. Yet this issue is contoversial due to the possible presence of amorphous structures [14] or contaminants [15].Cleaving a single crystal would be an obvious solution for obtaining a pristine surface. Despite numerous attempts [16-18], we are not aware of any successful work leading to atomically flat bulk-terminated SrTiO 3 . The main impediment is that cubic perovskites typically do not possess a natural cleaving plane. Instead they exhibit so called conchoidal fracture (see Figure S1 in Supplementary Information). An alternative technique for surface preparation is applying cycles of sputtering and high-temperature annealing -a standard procedure used for preparing oxide surfaces in ultrahigh vacuum (UHV). For perovskite surfaces, however, this methods results into a series of complex reconstructions [4,19,20], which are very stable and chemically inert; exactly the opposite to the behaviour of perovskites in most applications.Our previous study on KTaO 3 [21] indicated that ferroelectricity induced in a perovskite can create a natural cleavage plane oriented perpendicular to the electric polarization. SrTiO 3 is an incipient ferroelectric material: Its ferroelectric Curie temperature lies...

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supporting

confidence: 88%

Incipient ferroelectricity: A route towards bulk-terminated SrTiO3

Sokolović

Schmid

Diebold

et al. 2019

Phys. Rev. Materials

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“…To explore this route, however, one first needs to understand whether (and how) the ferroelastic degrees of freedom can be harnessed via a suitable external field. As the ferroelastic domain walls have recently been shown to be polar [16][17][18][19][20][21][22], it is reasonable to expect that they will respond to an electrical bias. A detailed study on the evolution of the domain wall topology upon application of a voltage is currently missing, leaving the above question largely unanswered.…”

Section: Low-temperature Dielectric Anisotropy Driven By An Antiferromentioning

confidence: 99%

Low-Temperature Dielectric Anisotropy Driven by an Antiferroelectric Mode in SrTiO3

et al. 2018

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“…However, the spatial resolution is not sufficient to simultaneously image the current paths and the domain boundaries; the size of the latter does not exceed 500-600 nm. Estimations of the wall (twins, dislocations) widths in the bundles reported by several authors are between few tens of nanometers [44,45] and 1-10 nm [48,49]. If the conducting channel consists of a bundle of filaments of micrometer size, one could consider each filament as forming a junction neighbouring filaments being separated by 10 nm walls.…”

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confidence: 99%

Bimodal Phase Diagram of the Superfluid Density in LaAlO3/SrTiO3 Revealed by an Interfacial Waveguide Resonator

et al. 2019

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We explore the superconducting phase diagram of the two-dimensional electron system at the LaAlO 3 /SrTiO 3 interface by monitoring the frequencies of the cavity modes of a coplanar waveguide resonator fabricated in the interface itself. We determine the phase diagram of the superconducting transition as a function of the temperature and electrostatic gating, finding that both the superfluid density and the transition temperature follow a dome shape but that the two are not monotonically related. The ground state of this two-dimensional electron system is interpreted as a Josephson junction array, where a transition from long-to short-range order occurs as a function of the electronic doping. The synergy between correlated oxides and superconducting circuits is revealed to be a promising route to investigate these exotic compounds, complementary to standard magnetotransport measurements.

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Imaging and tuning polarity at SrTiO3 domain walls

Cited by 79 publications

References 39 publications

Incipient ferroelectricity: A route towards bulk-terminated SrTiO3

Incipient ferroelectricity: A route towards bulk-terminated SrTiO3

Low-Temperature Dielectric Anisotropy Driven by an Antiferroelectric Mode in SrTiO3

Bimodal Phase Diagram of the Superfluid Density in LaAlO3/SrTiO3 Revealed by an Interfacial Waveguide Resonator

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