2012
DOI: 10.1103/physrevb.85.014406
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Effect of gadolinium doping on the electronic band structure of europium oxide

Abstract: B.; Yakovkin, I. N.; and Dowben, Peter A., "Effect of gadolinium doping on the electronic band structure of europium oxide" (2012 [111]. Angular-resolved photoemission spectroscopy reveals electron pockets around the X points in Gd-doped EuO, indicating that the band gap in EuO is indirect. Combined photoemission and inverse photoemission measurements show an apparent transition from n-type to p-type behavior, which is likely due to band bending near the polar (111) surface.

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Cited by 25 publications
(29 citation statements)
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“…Recent results of angular-resolved photoemission spectroscopy on Gd and Ce doped EuO show filling of electron pockets in an otherwise empty conduction band, which is not observed in undoped EuO 1-x presented here. 24,45 This further suggests bound magnetic polaron is a more appropriate model than models based on exchange-split conduction bands or RKKY interaction to describe the magnetic ordering of EuO 1-x above 69 K, although it is not to say magnetic polarons do not exist in Gd and Ce doped EuO. Since the Eu local spins are fully aligned only at the very low temperature, the magnetic polaron state can be stable below 69 K extending over quite a large temperature range.…”
Section: Resultsmentioning
confidence: 99%
“…Recent results of angular-resolved photoemission spectroscopy on Gd and Ce doped EuO show filling of electron pockets in an otherwise empty conduction band, which is not observed in undoped EuO 1-x presented here. 24,45 This further suggests bound magnetic polaron is a more appropriate model than models based on exchange-split conduction bands or RKKY interaction to describe the magnetic ordering of EuO 1-x above 69 K, although it is not to say magnetic polarons do not exist in Gd and Ce doped EuO. Since the Eu local spins are fully aligned only at the very low temperature, the magnetic polaron state can be stable below 69 K extending over quite a large temperature range.…”
Section: Resultsmentioning
confidence: 99%
“…[23][24][25][26][27] In this context, the study of the magnetic properties of EuO, including the critical exponents, on a ferroelectric substrate is of especial interest because EuO as an insulator has few free carriers. On the other hand, the sizeable energy dispersion of Eu 4f state 18,28 is inconsistent with the Heisenberg model. 28 To investigate the magnetic properties of EuO under extrinsic doping, we have investigated EuO/BaTiO 3 /SrTiO 3 (EuO/ BTO/STO) heterostructures.…”
mentioning
confidence: 79%
“…16 Metal-toinsulator transition and colossal magneto-resistance have been reported in EuO systems with electron doping. 14,[17][18][19][20] Much effort has been put into investigating the influence of the substrate on the magnetic properties of EuO [2][3][4][5][6]11,12,21,22 including changes to the Curie temperature (T c ) and critical exponents. Ferroelectric (FE) substrates are unique due to the potential for electric modulation, coming from the ferroelectric polarization reversal, which can be considered as a form of extrinsic electrostatic doping at the FM-FE interfaces.…”
mentioning
confidence: 99%
“…Therefore, d = 2.2Å can be used to simulate the transport properties of n-type EuO, as obtained for O-deficient barriers. [46][47][48] In the remainder of this paper, we will present the transport properties for both d = 2.4Å and d = 2.8Å, in order to illustrate the effect of a shift of E F induced by interface modifications. Importantly, we will demonstrate that for any position of E F , EuO always shows excellent spin-filter characteristics up to high bias voltages.…”
Section: Spin Transport Properties Of the Euo Junction At Zero Biasmentioning
confidence: 99%