Dr. Daniel P. Cunnane Profile

Dr. Daniel P. Cunnane

at Jet Propulsion Lab

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Author

Publications (4)

Proceedings Article | 16 August 2024 Presentation + Paper

NEW-MUSIC: The Next-generation Extended-Wavelength MUltiband Sub/millimeter Inductance Camera

Sunil Golwala, Andrew Beyer, Daniel Cunnane, Peter Day, Fabien Defrance, Clifford Frez, Xiaolan Huang, Junhan Kim, Jean-Marc Martin, Jack Sayers, Shibo Shu, Shiling Yu

Proceedings Volume 13102, 1310202 (2024) https://doi.org/10.1117/12.3021175

KEYWORDS: Aluminum, Antennas, Design, Niobium, Resonators, Windows, Capacitors, Sensors, Mirrors, Tunable filters

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Proceedings Article | 13 December 2020 Presentation

A four kilopixel 150 GHz KID imager paired with a 1.5 m crossed Dragone telescope

Jack Sayers, Peter Day, Daniel Cunnane, Byeong Ho Eom, Henry LeDuc, Roger O'Brient, Marcus Runyan, Sean Bryan, Samuel Gordon, Philip Mauskopf, Bradley Johnson, Heather McCarrick, Tanay Bhandarkar

Proceedings Volume 11453, 114531C (2020) https://doi.org/10.1117/12.2561647

KEYWORDS: Telescopes, Imaging systems, Aluminum, Sensors, Waveguides, Cameras, Inductance, Crystals, Silicon, Polarization

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Proceedings Article | 18 May 2020 Presentation + Paper

A millimeter-wave kinetic inductance detector camera for long-range imaging through optical obscurants

Jack Sayers, Peter Day, Daniel Cunnane, Byeong Ho Eom, Henry LeDuc, Roger O'Brient, Marcus Runyan, Sean Bryan, Samuel Gordon, Philip Mauskopf, Bradley Johnson, Heather McCarrick, Tanay Bhandarkar

Proceedings Volume 11411, 114110H (2020) https://doi.org/10.1117/12.2557428

KEYWORDS: Sensors, Signal attenuation, Quasiparticles, Imaging systems, Superconductors, Photons, Inductance, Resonators, Absorption

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Proceedings Article | 23 July 2014 Paper

Development of hot-electron THz bolometric mixers using MgB2 thin films

Daniel Cunnane, Jonathan Kawamura, Boris Karasik, Matthaeus Wolak, X. Xi

Proceedings Volume 9153, 91531Q (2014) https://doi.org/10.1117/12.2054607

KEYWORDS: Terahertz radiation, Silicon carbide, Superconductors, Antennas, Technetium, Gold, Thin films, Bridges, Silica, Resistance

Read Abstract +

Terahertz high-resolution spectroscopy of interstellar molecular clouds greatly relies on hot-electron superconducting bolometric (HEB) mixers. Current state-of-the-art receivers use mixer devices made from ultrathin (~ 3-5 nm) films of NbN with critical temperature ~ 9-11 K. Such mixers have been deployed on a number of groundbased, suborbital, and orbital platforms including the HIFI instrument on the Hershel Space Observatory. Despite its good sensitivity and well-established fabrication process, the NbN HEB mixer suffers from the narrow intermediate frequency (IF) bandwidth ~ 2-3 GHz and is limited to operation at liquid Helium temperature. As the heterodyne receivers are now trending towards “high THz” frequencies, the need in a larger IF bandwidth becomes more pressing since the same velocity resolution for a Doppler shifted line at 5 THz requires a 5-times greater IF bandwidth than at 1 THz. Our work is focusing on the realization of practical HEB mixers using ultrathin (10-20 nm) MgB₂ films. They are prepared using a Hybrid Physical-Chemical Vapor Deposition (HPCVD) process yielding ultrathin films with critical temperature ~ 37-39 K. The expectation is that the combination of small thickness, high acoustic phonon transparency at the interface with the substrate, and very short electron-phonon relaxation time may lead to IF bandwidth ~ 10 GHz or even higher. SiC continues to be the most favorable substrate for MgB₂ growth and as a result, a study has been conducted on the transparency of SiC at THz frequencies. FTIR measurements show that semi-insulating SiC substrates are at least as transparent as Si up to 2.5 THz. Currently films are passivated using a thin (10 nm) SiO2 layer which is deposited ex-situ via RF magnetron sputtering. Micron-sized spiral antenna-coupled HEB mixers have been fabricated using MgB2 films as thin as 10 nm. Fabrication was done using contact UV lithography and Ar Ion milling, with E-beam evaporated Au films deposited for the antenna. Measurements have been carried out on these devices in the DC, Microwave, and THz regimes. The devices are capable of mixing signals above 20 K indicating that operation may be possible using a cryogen-free cooling system. We will report the results of all measurements taken to indicate the local oscillator power requirements and the IF bandwidth of MgB₂ HEB mixers.

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