Single-crystalline Sr2MoO4 films as prepared by pulsed laser deposition

“…23 Single crystals of SrMoO 3 (SMO) exhibit the lowest resistivity of 5.1 lXÁcm among all known perovskite oxides. [25][26][27] Previously, the growth of SMO and Sr 2 MoO 4 thin films have been studied in detail. 26,27 Using a reductive atmosphere during PLD, it is possible to fabricate SMO single crystalline films with a DC resistivity below 20 lXÁcm at room temperature.…”

“…[25][26][27] Previously, the growth of SMO and Sr 2 MoO 4 thin films have been studied in detail. 26,27 Using a reductive atmosphere during PLD, it is possible to fabricate SMO single crystalline films with a DC resistivity below 20 lXÁcm at room temperature. 28 Here, we present a study of the highfrequency properties of SMO thin films in order to investigate their possible use in microwave applications.…”

Highly conducting SrMoO3 thin films for microwave applications

“…23 Single crystals of SrMoO 3 (SMO) exhibit the lowest resistivity of 5.1 lXÁcm among all known perovskite oxides. [25][26][27] Previously, the growth of SMO and Sr 2 MoO 4 thin films have been studied in detail. 26,27 Using a reductive atmosphere during PLD, it is possible to fabricate SMO single crystalline films with a DC resistivity below 20 lXÁcm at room temperature.…”

“…[25][26][27] Previously, the growth of SMO and Sr 2 MoO 4 thin films have been studied in detail. 26,27 Using a reductive atmosphere during PLD, it is possible to fabricate SMO single crystalline films with a DC resistivity below 20 lXÁcm at room temperature. 28 Here, we present a study of the highfrequency properties of SMO thin films in order to investigate their possible use in microwave applications.…”

Highly conducting SrMoO3 thin films for microwave applications

“…SrMoO 4 is one of the most important metal molybdates with scheelite-type tetragonal structure, and is also widely used in typical areas as photoluminescent materials [2][3][4][5][6][7], high active catalysts [8,9], and hosts for lanthanide activated lasers [10,11] and so on. For SrMoO 4 micro/nanostructures, many researches have performed on the synthesis of the material via various methods such as solid-state process [12,13], microwave radiation [3,[14][15][16], hydrothermal/solvothermal process [3,4,[17][18][19], microemulsion synthesis [5,20,21], co-precipitation method [22,23], sonochemical technology [7,24], electrochemical process [25][26], combining sol-gel and solid-state route [6], and pulsed laser deposition [27]. Compared with these methods, microwave radiation processing has received intense attention owing to the obvious merits: [28][29][30][31][32][33][34][35][36][37] (1) improved the diffusion process for the products through absorbing the electromagnetic energy, (2) gained very fast heating rates with little temperature gradient ...…”

Synthesis of SrMoO₄ microstructures by the microwave radiation‐assisted chelating agent method

Growth and interface engineering in thin-filmBa0.6Sr0.4TiO3

Radetinac

¹

,

Ziegler

²

,

Vafaee

³

et al. 2017

Journal of Crystal Growth

20

0

4

0

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