Design and performance of hafnium optical and near-IR kinetic inductance detectors

Zobrist, Nicholas; Coiffard, G.; Bumble, B.; Swimmer, Noah; Steiger, Sarah; Daal, M.; Collura, G.; Walter, Alex; Bockstiegel, Clint; Fruitwala, Neelay; Lipartito, Isabel; Mazin, Benjamin A.

doi:10.1063/1.5127768

Cited by 24 publications

(21 citation statements)

References 34 publications

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“…It is striking that most substrate-based MKIDs with a high enough R SN are all limited to R ≈ 10 − 20 3,[12][13][14]16,17 . Here we conclusively show that in Al MKIDs on substrate R is limited by hot phonon loss.…”

Section: B Towards a Fano-limited Resolving Powermentioning

confidence: 99%

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Phonon-Trapping-Enhanced Energy Resolution in Superconducting Single-Photon Detectors

et al. 2021

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A noiseless, photon-counting detector, which resolves the energy of each photon, could radically change astronomy, biophysics, and quantum optics. Superconducting detectors promise an intrinsic resolving power at visible wavelengths of R = E/δE ≈ 100 due to their low excitation energy. We study superconducting energy-resolving microwave kinetic inductance detectors (MKIDs), which hold particular promise for larger cameras. A visible and near-infrared photon absorbed in the superconductor creates a few thousand quasiparticles through several stages of electron-phonon interaction. Here we demonstrate experimentally that the resolving power of MKIDs at visible to near-infrared wavelengths is limited by the loss of hot phonons during this process. We measure the resolving power of our aluminum-based detector as a function of photon energy using four lasers with wavelengths between 1545-402 nm. For detectors on thick SiN/Si and sapphire substrates the resolving power is limited to 10-21 for the respective wavelengths, consistent with the loss of hot phonons. When we suspend the sensitive part of the detector on a 110-nm-thick SiN membrane, the measured resolving power improves to 19-52, respectively. The improvement is equivalent to a factor 8 ± 2 stronger phonon trapping on the membrane, which is consistent with a geometrical phonon propagation model for these hot phonons. We discuss a route towards the Fano limit by phonon engineering.

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Section: B Towards a Fano-limited Resolving Powermentioning

confidence: 99%

“…For PtSi, with T c = 0.9 K, R = 5.8 − 8.1 at wavelengths of 1310-808 nm (a best δE = 0.16 eV) [13]. For Hf with T c = 0.4 K, R = 6.8 − 9.4 (best δE = 0.14 eV) for the same wavelengths [14]. In devices optimized for photon-number resolution using TiN/Ti/TiN trilayers R = 3.6 at 1550 nm [15].…”

Section: Introductionmentioning

confidence: 97%

Phonon-Trapping-Enhanced Energy Resolution in Superconducting Single-Photon Detectors

et al. 2021

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“…The error bars represents the standard deviation over the wafer. The data point from N. Zobrist et al [10] is also shown for comparison even though a different sputter system was used. The superconducting transition temperature (Bottom Left) and calculated kinetic inductance using equation 1 (Bottom Right) for the same films are also given.…”

Section: Hafnium Film Depositionmentioning

confidence: 99%

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

Coiffard

Daal

Zobrist

et al. 2020

Supercond. Sci. Technol.

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Hafnium is an elemental superconductor which crystallizes in a hexagonal close packed structure, has a transition temperature T C 400 mK, and has a high normal state resistivity around 90 µΩ cm. In Microwave Kinetic Inductance Detectors (MKIDs), these properties are advantageous since they allow for creating detectors sensitive to optical and near infra-red radiation. In this work, we study how sputter conditions and especially the power applied to the target during the deposition, affect the hafnium T C , resistivity, stress, texture and preferred crystal orientation. We find that the position of the target with respect to the substrate strongly affects the orientation of the crystallites in the films and the internal quality factor, Q i , of MKIDs fabricated from the films. In particular, we demonstrate that a DC magnetron sputter deposition at a normal angle of incidence, low pressure, and low plasma power promotes the growth of compressive (002)-oriented films and that such films can be used to make high quality factor MKIDs with Q i up to 600,000.

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“…A photon's energy, then, can be extracted from the overall size of the signal. These types of MKIDs are called single photon counting, and examples of them include lumped element optical to near-IR detectors, [2][3][4][5][6] X-ray thermal kinetic inductance detectors, [7][8][9][10] and position dependent strip detectors. 11,12 The properties of an MKID are encoded in the forward scattering matrix element, S 21 , of the resonator.…”

Section: Introductionmentioning

confidence: 99%

Improving the dynamic range of single photon counting kinetic inductance detectors

Zobrist,

Klimovich,

Eom

et al. 2020

Preprint

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We develop a simple coordinate transformation which can be employed to compensate for the nonlinearity introduced by a Microwave Kinetic Inductance Detector's (MKID) homodyne readout scheme. This coordinate system is compared to the canonically used polar coordinates and is shown to improve the performance of the filtering method often used to estimate a photon's energy. For a detector where the coordinate nonlinearity is primarily responsible for limiting its resolving power, this technique leads to increased dynamic range, which we show by applying the transformation to data from a hafnium MKID designed to be sensitive to photons with wavelengths in the 800 to 1300 nm range. The new coordinates allow the detector to resolve photons with wavelengths down to 400 nm, raising the resolving power at that wavelength from 6.8 to 17.

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Design and performance of hafnium optical and near-IR kinetic inductance detectors

Cited by 24 publications

References 34 publications

Phonon-Trapping-Enhanced Energy Resolution in Superconducting Single-Photon Detectors

Phonon-Trapping-Enhanced Energy Resolution in Superconducting Single-Photon Detectors

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

Improving the dynamic range of single photon counting kinetic inductance detectors

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