Synthesis science of SrRuO3 and CaRuO3 epitaxial films with high residual resistivity ratios

Nair, Hari P.; Liu, Yang; Ruf, Jacob; Schreiber, Nathaniel J.; Shang, Shun Li; Baek, David J.; Goodge, Berit H.; Kourkoutis, Lena F.; Liu, Zhe; Shen, Kyle; Schlom, Darrell G.

doi:10.1063/1.5023477

Cited by 70 publications

(63 citation statements)

References 107 publications

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“…In a recent work, high‐quality SRO films were demonstrated on STO‐templated Si . Wang et al optimized the SRO crystalline quality by implementing a self‐limiting growth window . The growth conditions required for obtaining high quality SRO include high temperatures and high oxygen reactivity, which result in a thin amorphous SiO x layer at the STO/Si interface (Figure a).…”

Section: Materials and Functional Propertiessupporting

confidence: 83%

“…SRO/STO/Si structures showing a) close‐ups on the STO/Si (left) and SRO/STO (right) interfaces, b) resistivity–temperature curve showing a high residual resistivity ratio indicative of high quality SRO films. Reproduced under the terms and conditions of the Creative Commons Attribution license . Copyright 2018, The Authors, published by AIP Publishing LLC YBCO/STO/Si structure showing c) the entire stack (inset shows a close‐up of the YBCO/STO interface) and d) resistivity–temperature curves showing the critical superconducting temperature in comparison to YBCO grown on STO substrates (insets shows a close‐up of the transition region).…”

Section: Materials and Functional Propertiesmentioning

confidence: 99%

“…In a recent work, high‐quality SRO films were demonstrated on STO‐templated Si . Wang et al optimized the SRO crystalline quality by implementing a self‐limiting growth window .…”

Section: Materials and Functional Propertiesmentioning

confidence: 99%

See 2 more Smart Citations

Epitaxial Oxides on Semiconductors: From Fundamentals to New Devices

Kumah

Ngai

Kornblum

2019

Adv Funct Materials

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Functional oxides are an untapped resource for futuristic devices and functionalities. These functionalities can range from high temperature superconductivity to multiferroicity and novel catalytic schemes. The most prominent route for transforming these ideas from a single device in the lab to practical technologies is by integration with semiconductors. Moreover, coupling oxides with semiconductors can herald new and unexpected functionalities that exist in neither of the individual materials. Therefore, oxide epitaxy on semiconductors provides a materials platform for novel device technologies. As oxides and semiconductors exhibit properties that are complementary to one another, epitaxial heterostructures comprised of the two are uniquely poised to deliver rich functionalities. This review discusses recent advancements in the growth of epitaxial oxides on semiconductors, and the electronic and physical structure of their interfaces. Leaning on these fundamentals and practicalities, the material behavior and functionality of semiconductor-oxide heterostructures is discussed, and their potential as device building blocks is highlighted. The culmination of this discussion is a review of recent advances in the development of prototype devices based on semiconductor-oxide heterostructures, in areas ranging from silicon photonics to photocatalysis. This overview is intended to stimulate ideas for new concepts of functional devices and lay the groundwork for their realization.

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Section: Materials and Functional Propertiessupporting

confidence: 83%

Section: Materials and Functional Propertiesmentioning

confidence: 99%

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Epitaxial Oxides on Semiconductors: From Fundamentals to New Devices

Kumah

Ngai

Kornblum

2019

Adv Funct Materials

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“…Despite the fundamental interest and potential applications, the growth of high quality ruthenate thin films has proven to be very challenging due to the nature of ruthenium and its oxides 10,[14][15][16][17][18][19] . In fact, the high volatility of ruthenium oxides (RuO x=2,3,4 ) leads to ruthenium deficiency, as shown in numerous reports 14,15,[20][21][22][23] . The ruthenium deficiency increases the resistivity and reduces the Curie temperature of SrRuO 3 and is detrimental to superconductivity in Sr 2 RuO 4 .…”

Section: Introductionmentioning

confidence: 99%

“…Superconductivity in Sr 2 RuO 4 is extremely sensitive to defects, such as nonmagnetic impurities and lattice imperfections and thus it requires high quality samples 24,25 . In order to overcome the volatility of ruthenium oxides, some of us have recently used an adsorption-controlled growth technique to synthesize ruthenate thin films showing superconductivity and unprecedentedly high residual resistivity ratios, defined as the ratio of the resistivities at 300 and 4K 14,15 . Related results have also been reported by other groups where the growth of Sr 2 RuO 4 films was carried out by means of molecular beam epitaxy 16,18 .…”

Section: Introductionmentioning

confidence: 99%

Electronic and vibrational signatures of ruthenium vacancies in Sr2RuO4 thin films

Kim

Suyolcu

Herrero‐Martín

et al. 2019

Phys. Rev. Materials

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The synthesis of stoichiometric Sr2RuO4 thin films has been a challenge because of the high volatility of ruthenium oxide precursors, which gives rise to ruthenium vacancies in the films. Ru vacancies greatly affect the transport properties and electronic phase behavior of Sr2RuO4, but their direct detection is difficult due to their atomic dimensions and low concentration. We applied polarized X-ray absorption spectroscopy at the oxygen K-edge and confocal Raman spectroscopy to Sr2RuO4 thin films synthesized under different conditions. The results show that these methods can serve as sensitive probes of the electronic and vibrational properties of Ru vacancies, respectively. The intensities of the vacancy-related spectroscopic features extracted from these measurements are well correlated with the transport properties of the films. The methodology introduced here can thus help to understand and control the stoichiometry and transport properties in films of Sr2RuO4 and other ruthenates.

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Realization of Epitaxial Thin Films of the Topological Crystalline Insulator Sr₃SnO

Edgeton

Paik

et al. 2020

Advanced Materials

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Topological materials are derived from the interplay between symmetry and topology. Advances in topological band theories have led to the prediction that the antiperovskite oxide Sr3SnO is a topological crystalline insulator, a new electronic phase of matter where the conductivity in its (001) crystallographic planes is protected by crystallographic point group symmetries. Realization of this material, however, is challenging. Guided by thermodynamic calculations, a deposition approach is designed and implemented to achieve the adsorption‐controlled growth of epitaxial Sr3SnO single‐crystal films by molecular‐beam epitaxy (MBE). In situ transport and angle‐resolved photoemission spectroscopy measurements reveal the metallic and electronic structure of the as‐grown samples. Compared with conventional MBE, the used synthesis route results in superior sample quality and is readily adapted to other topological systems with antiperovskite structures. The successful realization of thin films of Sr3SnO opens opportunities to manipulate topological states by tuning symmetries via strain engineering and heterostructuring.

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Synthesis science of SrRuO3 and CaRuO3 epitaxial films with high residual resistivity ratios

Cited by 70 publications

References 107 publications

Epitaxial Oxides on Semiconductors: From Fundamentals to New Devices

Epitaxial Oxides on Semiconductors: From Fundamentals to New Devices

Electronic and vibrational signatures of ruthenium vacancies in Sr2RuO4 thin films

Realization of Epitaxial Thin Films of the Topological Crystalline Insulator Sr₃SnO

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Synthesis science of SrRuO3 and CaRuO3 epitaxial films with high residual resistivity ratios

Cited by 70 publications

References 107 publications

Epitaxial Oxides on Semiconductors: From Fundamentals to New Devices

Epitaxial Oxides on Semiconductors: From Fundamentals to New Devices

Electronic and vibrational signatures of ruthenium vacancies in Sr2RuO4 thin films

Realization of Epitaxial Thin Films of the Topological Crystalline Insulator Sr3SnO

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Product

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Realization of Epitaxial Thin Films of the Topological Crystalline Insulator Sr₃SnO