Characterization of sputtered hafnium thin films for high quality factor microwave kinetic inductance detectors

Coiffard, G.; Daal, M.; Zobrist, Nicholas; Swimmer, Noah; Steiger, Sarah; Bumble, B.; Mazin, Benjamin A.

doi:10.1088/1361-6668/ab8d99

Cited by 18 publications

(25 citation statements)

References 28 publications

(40 reference statements)

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“…hafnium [185], indium [186], molybdenium-rhenium alloys [187], compounds that exhibit the A15 crystal structure [188] and even heavily-doped silicon [189], that have been demonstrated or proposed for use in quantum computing. While some of these materials also possess superconducting transition temperatures above 10 K, the primary motivation of their incorporation is not necessarily associated with Tc, since the temperature necessary to reach the qubit ground state (kBT << hf) is substantially lower.…”

Section: Compositionmentioning

confidence: 99%

Material matters in superconducting qubits

Murray

2021

Materials Science and Engineering: R: Reports

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Section: Compositionmentioning

confidence: 99%

Material matters in superconducting qubits

Murray

2021

Materials Science and Engineering: R: Reports

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“…L K scales linearly with the nanobridge's aspect ratio L/W . This tunability and magnitude of L K , together with its nonlinearity make our MoGe nanobridges extremely suitable for many applications, ranging from magnetic memories [11] to microwave detectors [12,13]. Furthermore, the measured L K can be maximized further by limiting the device thickness.…”

Section: Discussionmentioning

confidence: 95%

“…Moreover, the kinetic inductance is nonlinear in both current and temperature. These unique properties of high kinetic inductance nanobridges and nanowires result in their application as scalable key elements in many recently demonstrated device applications ranging from single-photon detectors [4] to qubit readout and qubit architectures [5][6][7][8][9], magnetic memories and sensors [10,11] and superconductor microwave detectors [12,13]. Despite the technical relevance and many applications of high kinetic inductance devices, it is complicated to precisely measure the kinetic inductance value.…”

Section: Introductionmentioning

confidence: 99%

The impact of kinetic inductance on the critical current oscillations of nanobridge SQUIDs

Dausy,

Nulens,

Raes

et al. 2021

Preprint

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In this work, we study the current phase relation (CΦR) of lithographically fabricated molybdenum germanium (MoGe) nanobridges, which is intimately linked to the nanobridge kinetic inductance. We do this by imbedding the nanobridges in a SQUID. We observe that for temperatures far below Tc, the CΦR is linear as long as the condensate is not weakened by the presence of supercurrent. We demonstrate lithographic control over the nanobridge kinetic inductance, which scales with the nanobridge aspect ratio. This allows to tune the SQUID Ic(B) characteristic. The SQUID properties that can be controlled in this way include the SQUID sensitivity and the positions of the critical current maxima. These observations can be of use for the design and operation of future superconducting devices such as magnetic memories or flux qubits.

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“…For β -Ta, TiN, PtSi, and Hf absorption is limited to around 50% in the visible and 30% in the IR range, as illustrated by Fig. 1 and presented in [2]. To increase the power absorbed in the KID, we embed it in an optical stack consisting of a back short (cavity) and one or multiple matching layers.…”

Section: Introductionmentioning

confidence: 99%

Model and Measurements of an Optical Stack for Broadband Visible to Near-IR Absorption in TiN KIDs

Kouwenhoven,

Elwakil,

van Wingerden

et al. 2021

Preprint

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Typical materials for optical Kinetic Inductance Detetectors (KIDs) are metals with a natural absorption of 30-50% in the visible and near-infrared. To reach high absorption efficiencies (90-100%) the KID must be embedded in an optical stack. We show an optical stack design for a 60 nm TiN film. The optical stack is modeled as sections of transmission lines, where the parameters for each section are related to the optical properties of each layer. We derive the complex permittivity of the TiN film from a spectral ellipsometry measurement. The designed optical stack is optimised for broadband absorption and consists of, from top (illumination side) to bottom: 85 nm SiO x , 60 nm TiN, 23 nm of SiO x , and a 100 nm thick Al mirror. We show the modeled absorption and reflection of this stack, which has > 80% absorption from 400 nm to 1550 nm and near-unity absorption for 500 nm to 800 nm. We measure transmission and reflection of this stack with a commercial spectrophotometer. The results are in good agreement with the model.

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Characterization of sputtered hafnium thin films for high quality factor microwave kinetic inductance detectors

Cited by 18 publications

References 28 publications

Material matters in superconducting qubits

Material matters in superconducting qubits

The impact of kinetic inductance on the critical current oscillations of nanobridge SQUIDs

Model and Measurements of an Optical Stack for Broadband Visible to Near-IR Absorption in TiN KIDs

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