Highly conducting SrMoO3 thin films for microwave applications

Radetinac, Aldin; Mani, Arzhang; Melnyk, Sergiy; Nikfalazar, Mohammad; Ziegler, Jürgen; Zheng, Yelong; Jakoby, Rolf; Alff, Lambert; Komissinskiy, Philipp

doi:10.1063/1.4896339

Cited by 33 publications

(25 citation statements)

References 37 publications

(47 reference statements)

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“…3(a)). A broad satellite was also observed next to the sharp peaks, which is likely Mo 4+ 3d emission of unscreened final states 9,10,28,29 . We also collected a spectrum at a lower photon energy (600 eV), which is more sensitive for the film near the surface, and observed additional features at 233.1 eV and 236.4 eV.…”

Section: Resultsmentioning

confidence: 94%

“…The room temperature (RT) resistivity ρ of singlecrystalline SrMoO 3 is as low as 5 µΩ cm, which is much lower than typical oxide materials 4 and is rather close to those of nearly free electron systems such as sodium and copper. The utmost feature of this oxide has stimulated intensive studies to grow epitaxial films [5][6][7][8][9] for applications, for example, electrodes between oxide interfaces 5,10 and transparent conductors 6,11 . Unfortunately, all the films, so far prepared by pulsed laser deposition (PLD) [7][8][9][10][11][12] or sputtering 5,6 , show rather poor resistivity (27-150 µΩ cm) than that of the bulk single crystal, possibly due to the presence of defects or inclusion of impurity phases.…”

Section: Introductionmentioning

confidence: 99%

“…The high-quality of the film is verified by X-ray diffraction (XRD) and angle resolved photoemission spectroscopy (ARPES) measure-ments. The film with the SrTiO 3 buffer layer exhibited an improved resistivity of 24 µΩ cm at RT as compared with the SrMoO 3 films by other techniques 5,[7][8][9]11,15,16 .…”

Section: Introductionmentioning

confidence: 99%

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Molecular beam epitaxy growth of the highly conductive oxide SrMoO3

Takatsu

Yamashina

Shiga

et al. 2020

Journal of Crystal Growth

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SrMoO3 is a promising material for its excellent electrical conductivity, but growing high-quality thin films remains a challenge. Here we synthesized epitaxial films of SrMoO3 using molecular beam epitaxy (MBE) technique under low oxygen-flow rate. Introduction of SrTiO3 buffer layers of 4-8 unit cells between the film and the (001)-oriented SrTiO3 or KTaO3 substrate was crucial to remove impurities and/or roughness of the film surface. The obtained film shows improved electrical conductivities as compared with films obtained by other techniques. The high quality of the SrMoO3 film is also verified by angle resolved photoemission spectroscopy (ARPES) measurements showing a clear Fermi surfaces.

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Section: Resultsmentioning

confidence: 94%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Molecular beam epitaxy growth of the highly conductive oxide SrMoO3

Takatsu

Yamashina

Shiga

et al. 2020

Journal of Crystal Growth

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“…Dense ceramic targets of SrMoO 4 and CaMoO 4 were prepared via conventional solid state synthesis. A reducing environment of 2.5% H 2 in Ar was used at 0.3 mTorr in order to reduce the Mo 6+ oxidation state of the target to the Mo 4+ state of the targeted perovskite phase as demonstrated in previous reports . A nominal substrate temperature of 650 °C was used with a laser fluence of 1.3 J cm −2 at a rate of 1 Hz.…”

Section: Methodsmentioning

confidence: 99%

“…SrMoO 3 is a cubic perovskite (inset of Figure a) and is one of the most conducting metallic oxides with a room temperature resistivity of 5.1 μΩ.cm . Recent thin film studies have focused on its application for plasmonic and microwave technologies. To assess the influence of replacing 3d 1 V 4+ with 4d 2 Mo 4+ on the performance of correlated metal transparent conductors, we have grown SrMoO 3 films with a thickness of 47 nm and root mean square (RMS) surface roughness of 0.3 nm (Figure S1, Supporting Information) and studied their electrical transport and optical properties which are compared with density functional theory (DFT) calculations (Figure ).…”

Section: Electrical and Optical Properties Of Epitaxial Srmoo3 And Camentioning

confidence: 99%

Chemical Control of Correlated Metals as Transparent Conductors

Stoner

Murgatroyd

O’Sullivan

et al. 2019

Adv Funct Materials

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Correlated metallic transition metal oxides offer a route to thin film transparent conductors that is distinct from the degenerate doping of broadband wide gap semiconductors. In a correlated metal transparent conductor, interelectron repulsion shifts the plasma frequency out of the visible region to enhance optical transmission, while the high carrier density of a metal retains sufficient conductivity. By exploiting control of the filling, position, and width of the bands derived from the B site transition metal in ABO 3 perovskite oxide films, it is shown that pulsed laser deposition-grown films of cubic SrMoO 3 and orthorhombic CaMoO 3 based on the second transition series cation 4d 2 Mo 4+ have superior transparent conductor properties to those of the first transition series 3d 1 V 4+ -based SrVO 3 . The increased carrier concentration offered by the greater bandfilling in the molybdates gives higher conductivity while retaining sufficient correlation to keep the plasma edge below the visible region. The reduced binding energy of the n=4 frontier orbitals in the second transition series materials shifts the energies of oxide 2p to metal nd transitions into the near-ultraviolet to enhance visible transparency. The A site sizedriven rotation of MoO 6 octahedra in CaMoO 3 optimizes the balance between plasma frequency and conductivity for transparent conductor performance.

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Giant Critical Thickness in Highly Conducting Epitaxial SrMoO₃ Electrodes Investigated by Lift‐Off Membranes

Ruan,

Schreyer,

Jiang

et al. 2024

Adv Funct Materials

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Within the huge perovskite materials family, thin films of highly conducting materials such as SrMoO3, SrNbO3, and SrVO3 are candidates for low‐loss bottom electrodes in epitaxial all‐oxide devices, in particular for high‐frequency applications. Recently, the fully coherent growth of more than 5 µm thick SrMoO3 electrodes in a varactor device prototype epitaxial heterostructure has been reported. This result raises the question of the strain mechanism in such anomalously thick coherent epitaxial layers. Here, this question is addressed by comparing the lattice constants of coherently strained layers and their free‐standing membranes. SrMoO3 is mainly elastically strained within the heterostructure and fully relaxed after removal of the substrate. These results indicate a giant critical thickness, making highly conducting perovskites even more outstanding materials for high‐frequency applications that require electrode thicknesses beyond the skin depth. The described technology of lifting off thick SrMoO3 membranes joins the emerging field of freestanding oxide layer technology, opening unexplored avenues for single crystal investigations, novel perovskite nanostructures, and wafer transfer of functional oxides, walking in the footsteps of recent developments in van der Waals epitaxial heterostructures.

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Highly conducting SrMoO3 thin films for microwave applications

Cited by 33 publications

References 37 publications

Molecular beam epitaxy growth of the highly conductive oxide SrMoO3

Molecular beam epitaxy growth of the highly conductive oxide SrMoO3

Chemical Control of Correlated Metals as Transparent Conductors

Giant Critical Thickness in Highly Conducting Epitaxial SrMoO₃ Electrodes Investigated by Lift‐Off Membranes

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Highly conducting SrMoO3 thin films for microwave applications

Cited by 33 publications

References 37 publications

Molecular beam epitaxy growth of the highly conductive oxide SrMoO3

Molecular beam epitaxy growth of the highly conductive oxide SrMoO3

Chemical Control of Correlated Metals as Transparent Conductors

Giant Critical Thickness in Highly Conducting Epitaxial SrMoO3 Electrodes Investigated by Lift‐Off Membranes

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Giant Critical Thickness in Highly Conducting Epitaxial SrMoO₃ Electrodes Investigated by Lift‐Off Membranes