2016
DOI: 10.1088/1367-2630/18/4/043015
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Robustness of magnetic and electric domains against charge carrier doping in multiferroic hexagonal ErMnO3

Abstract: We investigate the effect of chemical doping on the electric and magnetic domain pattern in multiferroic hexagonal ErMnO 3 . Hole-and electron doping are achieved through the growth of Er 1−x Ca x MnO 3 and Er 1−x Zr x MnO 3 single crystals, which allows for a controlled introduction of divalent and tetravalent ions, respectively. Using conductance measurements, piezoresponse force microscopy and nonlinear optics we study doping-related variations in the electronic transport and image the corrsponding ferroele… Show more

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Cited by 30 publications
(30 citation statements)
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“…Aliovalent doping of h-RMnO 3 has been demonstrated to strongly modify the conductivity of charged DWs, without perturbating the DW pattern [42][43][44]. Donor doping enhances the conductivity of head-to-head DWs, while acceptor doping promotes the conductivity of tail-to-tail DWs, fully in agreement with our presented model.…”
Section: Point Defects and Aliovalent Dopantssupporting
confidence: 87%
“…Aliovalent doping of h-RMnO 3 has been demonstrated to strongly modify the conductivity of charged DWs, without perturbating the DW pattern [42][43][44]. Donor doping enhances the conductivity of head-to-head DWs, while acceptor doping promotes the conductivity of tail-to-tail DWs, fully in agreement with our presented model.…”
Section: Point Defects and Aliovalent Dopantssupporting
confidence: 87%
“…The electrostatic potential at the walls shifts the Fermi level into the broad valence band where the effective mass is low, leading to an enhanced conduction at the walls [105]. In order to control and optimize the electronic domain wall properties in hexagonal manganites, effects related to off-stoichiometry [118,[123][124][125][126][127][128] and aliovalent cation substitution on the A-and B-site were studied systematically [129,130]. Interestingly, recent studies suggest that the emergence of anomalous conductance is not restricted to isolated head-to-head and tail-to-tail walls in RMnO 3 : Wherever the walls intersect in the characteristic cloverleaf-like arrangement [106,116], ferroelectric vortex cores with emergent U(1) symmetry form [131][132][133].…”
Section: Conduction In Domain Wallsmentioning
confidence: 99%
“…Since the first direct observation of conducting DWs in BiFeO 3 [9], significant progress has been made on the fundamental science behind DWs. It has been established that their local properties are largely dominated by the interplay of local polarization states [25,26] and available charge carriers [27,28]. Despite this progress, the research trying to produce a functional device is still * donald.evans@ntnu.no in an early stage [29][30][31]: one of the key challenges is the optimization of emergent electronic DW behavior beyond the as-grown properties [22].…”
Section: Introductionmentioning
confidence: 99%