Cationic-vacancy-induced room-temperature ferromagnetism in transparent, conducting anatase Ti
 
 1−
 x
 
 Ta
 
 x
 
 O
 2
 (
 x
 ∼0.05) thin films

Rusydi, Andrivo; Dhar, S.; Barman, A. Roy; Ariando, Ariando; Qi, Dongchen; Motapothula, M.; Yi, Jiabao; Santoso, Iman; Feng, Yuan Ping; Yang, Kesong; Dai, Yatang; Yakovlev, N.L.; Ding, Jun; Wee, Andrew Thye Shen; Neuber, G.; Breese, Mark B. H.; Ruebhausen, M.; Hilgenkamp, H.; Venkatesan, T.

doi:10.1098/rsta.2012.0198

Cited by 32 publications

(20 citation statements)

References 41 publications

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“…In addition, cationic vacancies in oxide films are expected to be more in high oxygen pressure depositions [33] and STO films deposited at various oxygen partial pressures (10 -2~1 0 -5 Torr) exhibit similar bandgap (see Figure S5 of the Supporting Information), which further supports that the bandgap enhancement is not due to cationic vacancies. Figure S6 of the Supporting Information).…”

supporting

confidence: 59%

Bandgap Control of the Oxygen‐Vacancy‐Induced Two‐Dimensional Electron Gas in SrTiO₃

Liu

Zeng

Deng

et al. 2014

Adv Materials Inter

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STO is central to modern oxide electronics since it serves as the main workhorse for complex functional oxide heterostructure fabrications. After the two-dimensional electron gas (2DEG) at the interface between STO and LAO had been unveiled, [7] a large number of exotic properties of the 2DEG were revealed such as a critical thickness for the appearance of conductivity, [8] Kondo effect, [9] interface superconductivity, [10] an electrically tunable ground state, [11,12] electronic phase separation [5] and recently discovered high-temperature superconductor-like gap behavior. [13] In addition, the practicability of monolithically integrated oxide electronics based on the LAO/STO interface system has been demonstrated. [14] As the research on the LAO/STO interface system is going on, the properties of STO itself have become a center of attention. For example, oxygen vacancies in STO have been a longstanding issue of debate in understanding the emergence of novel electronic and magnetic phases in the 2DEG. Additionally, a fundamental issue related to STO remaining up to now is that although STO single crystals are easy to make metallic with oxygen vacancies, [15,16] it is rather difficult to make an insulating STO thin film completely metallic via oxygen vacancies. Instead, oxygen-deficient STO films are typically semiconducting at low temperatures. [17][18][19][20] Besides, the 2DEG at the LAO/STO interface fabricated on STO films [21][22][23][24] is more localized at low temperatures than that fabricated on STO single crystals; [7] it was found that the insertion of a STO film layer degrades the LAO/STO interface significantly; [25,26] the fully metallic state of the LAO/STO interface based on STO films is achieved when STO films are deposited at a very high temperature of 1100 °C. [27] These perhaps indicate the presence of point defects/disorder in the STO films deposited at the typical temperature range of 600-800 °C.A 2DEG in STO-based heterostructures can be created via oxygen vacancies (2DEG-V) when the overlayer contains elements such as Al which have a strong affinity for oxygen. [28][29][30] Hence the 2DEG-V can be easy to realize by depositing an amorphous, nonpolar LAO (aLAO) film onto STO at room temperature. In this work, our focus is on the 2DEG-V at the interface between amorphous LAO films and STO films, and its relation to the bandgap of STO films, which was found to significantly increase due to the defective nature of STO thin films.In this work, we fabricated 2DEG-V heterostructures by depositing aLAO films on STO films that were pre-deposited on LAO single-crystal substrates. STO films of 150 nm thickness were deposited from a single-crystal STO target on (100)-oriented LAO singlecrystal substrates, using pulsed laser deposition (KrF laser λ = 248 nm) in 10 -2 Torr oxygen partial pressure at various temperatures ranging from 30 to 750 °C. After deposition, the STO films were cooled to room temperature in the deposition oxygen pressure. Amorphous 25-nm-thick LAO films were subsequently deposit...

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confidence: 59%

Bandgap Control of the Oxygen‐Vacancy‐Induced Two‐Dimensional Electron Gas in SrTiO₃

Liu

Zeng

Deng

et al. 2014

Adv Materials Inter

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“…[ 12 ] Although such a result is expected from defect chemistry considerations, the exact mechanisms underlying this process and involving different phenomena (crystallization, oxygen incorporation) are still debated especially in the case of donor-doped TiO 2 . [20][21][22][23][24][25][26][27] In this contribution, we focus on how the post-deposition annealing treatments performed in different atmospheres and different heating/cooling rates affect the electrical properties of undoped as well as tantalum doped anatase TiO 2 thin fi lms. More importantly, we investigate the role of the change of the microstructure (from amorphous to crystalline) and of the oxygen exchange with the surroundings on the fi nal electrical conductivity of the material.…”

Section: Introductionmentioning

confidence: 99%

Controlling the Electrical Properties of Undoped and Ta‐Doped TiO₂ Polycrystalline Films via Ultra‐Fast‐Annealing Treatments

Mazzolini

Acartürk

Chrastina

et al. 2016

Adv Elect Materials

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“…The ferromagnetism has strong correlation with the defects induced by the deposition under low oxygen partial pressure, such as oxygen vacancies. In doped or modified TiO 2 materials, Ti 3+ state is supposed to play an important role in the room temperature ferromagnetism and also other physical properties …”

Section: Introductionmentioning

confidence: 99%

XPS study of cobalt doped TiO₂ films prepared by pulsed laser deposition

Gong

Luo

Bao

et al. 2014

Surface & Interface Analysis

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Five percent Co‐doped TiO2 films have been prepared under an oxygen partial pressure from 10−6 to 10−4 Torr. The samples were stored for two weeks under ambient conditions prior to X‐ray photoelectron spectroscopy investigation. The X‐ray photoelectron spectra of Ti 2p and 3p, as well as X‐ray induced Auger electron spectrum Ti L3M23V all show evidence for Ti3+ at the surface of the film grown in 10−6 Torr O2 partial pressure. The curve fitted Ti 2p3/2 spectrum indicates a concentration of 6.5% Ti3+. The films grown in higher O2 pressure do not show Ti3+ state clearly. Surface‐enriched cobalt in Co2+ state has been noted. Such Co2+ enrichment can be removed by in‐situ annealing at 650 °C for 45 min resulting in elemental state cobalt at the annealed surface. The annealed film still shows Ti3+ state in the surface region but the concentration becomes lower. The Ti3+ concentration was lowered to the detection limit after the annealed sample was exposed to atmosphere for 30 min. The surface enrichment of cobalt may play some role in preventing the Ti3+ species in the uppermost surface layer from being quickly oxidized in atmosphere. Copyright © 2014 John Wiley & Sons, Ltd.

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Cationic-vacancy-induced room-temperature ferromagnetism in transparent, conducting anatase Ti _{1−
x} Ta _x O ₂ ( x ∼0.05) thin films

Cited by 32 publications

References 41 publications

Bandgap Control of the Oxygen‐Vacancy‐Induced Two‐Dimensional Electron Gas in SrTiO₃

Bandgap Control of the Oxygen‐Vacancy‐Induced Two‐Dimensional Electron Gas in SrTiO₃

Controlling the Electrical Properties of Undoped and Ta‐Doped TiO₂ Polycrystalline Films via Ultra‐Fast‐Annealing Treatments

XPS study of cobalt doped TiO₂ films prepared by pulsed laser deposition

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Cationic-vacancy-induced room-temperature ferromagnetism in transparent, conducting anatase Ti 1− x Ta x O 2 ( x ∼0.05) thin films

Cited by 32 publications

References 41 publications

Bandgap Control of the Oxygen‐Vacancy‐Induced Two‐Dimensional Electron Gas in SrTiO3

Bandgap Control of the Oxygen‐Vacancy‐Induced Two‐Dimensional Electron Gas in SrTiO3

Controlling the Electrical Properties of Undoped and Ta‐Doped TiO2 Polycrystalline Films via Ultra‐Fast‐Annealing Treatments

XPS study of cobalt doped TiO2 films prepared by pulsed laser deposition

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Product

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Cationic-vacancy-induced room-temperature ferromagnetism in transparent, conducting anatase Ti _{1−
x} Ta _x O ₂ ( x ∼0.05) thin films

Bandgap Control of the Oxygen‐Vacancy‐Induced Two‐Dimensional Electron Gas in SrTiO₃

Bandgap Control of the Oxygen‐Vacancy‐Induced Two‐Dimensional Electron Gas in SrTiO₃

Controlling the Electrical Properties of Undoped and Ta‐Doped TiO₂ Polycrystalline Films via Ultra‐Fast‐Annealing Treatments

XPS study of cobalt doped TiO₂ films prepared by pulsed laser deposition