Operation of kinetic-inductance travelling wave parametric amplifiers at millimetre wavelengths

Tan, B-K; Klimovich, N; Stephenson, R; Faramarzi, F; Day, P

doi:10.1088/1361-6668/ad20fd

Cited by 4 publications

(1 citation statement)

References 26 publications

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“…With the placement of = f 6.148 GHz pumps on the leading edges of the first and second stopbands, respectively, we show that the pump harmonics and their cross-terms would fall into the subsequent stopbands at higher frequencies. The |S 21 | spectrum presented here has been simulated using the realistic modelling technique described in [24], which has been shown to accurately predict the measured performance of KITWPAs when the surface resistance of the superconducting film is calibrated to be close to negligible compared to the BCS prediction [28] at cryogenic temperature. Figure 5 .…”

Section: Harmonics Suppressionmentioning

confidence: 99%

Non-degenerate-pump four-wave mixing kinetic inductance travelling-wave parametric amplifiers

Longden,

Tan

2024

Eng. Res. Express

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Kinetic inductance travelling-wave parametric amplifiers (KITWPAs) have been demonstrated to achieve high gain over broad bandwidths whilst achieving near quantum-limited noise performance, properties which are extremely important for many ultra-sensitive experiments. In early KITWPA designs, the requirement for phase-matching lead to the creation of a large zero-gain gap in the centre of the gain profile where the peak gain is, which also slightly narrows down the operational bandwidth of the device. This has been mitigated in more recent designs by introducing a DC bias to the KITWPA device, which allows the gap to be tuned away from the amplification band. However, the added DC biasing requires a more complicated experimental setup and potentially leads to unwanted heat leak in the cryogenic environment. Additionally, operation with a DC bias also become challenging at higher frequencies beyond the microwave regime. In this paper, we present the concept of a KITWPA operating in a non-degenerate-pump four-wave mixing (NP-4WM) regime, whereby the injection of two pump tones along with a weak signal results in a broad, flat gain profile that removes the zero-gain gap as well as eliminates the need for a DC bias and the complexities associated with it. We demonstrate how a NP-4WM KITWPA is feasible to achieve broadband amplification at a range of frequencies, first in the microwave range where most KITWPAs reported to-date have been successfully experimentally characterised. We then extend the designs to several millimetre (mm) bands to illustrate how we can use this technique to design a broadband front-end pre-amplifier that covers several Atacama Large Millimetre/sub-millimetre Array (ALMA) Bands.

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Section: Harmonics Suppressionmentioning

confidence: 99%

Non-degenerate-pump four-wave mixing kinetic inductance travelling-wave parametric amplifiers

Longden,

Tan

2024

Eng. Res. Express

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Automated characterisation and operational insights of superconducting travelling wave parametric amplifiers: unveiling novel behaviours and enhancing tunability

Wood,

Klimovich,

Tan

2024

J. Inst.

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Superconducting travelling wave parametric amplifiers (TWPAs) exhibit great promise across various applications, owing to their broadband nature, quantum-limited noise performance, and high-gain operation. Whilst their construction is relatively simple, particularly for thin-film-based TWPAs, challenges such as the requirement for an extremely long transmission line, current fabrication limitations, and their sensitivity to fabrication tolerances, mean that their optimal operating conditions often differ from those anticipated during the design stage. As a result, manual fine-tuning of numerous operational parameters becomes necessary to recover optimal performance; a process that is both labour-intensive and time-consuming. This paper introduces an automated methodology designed to significantly accelerate the characterisation of a TWPA by several orders of magnitude without requiring human intervention. Additionally, we have developed metrics to condense the multitude of measured frequency responses of the TWPA, obtained in data cube form, into an easily-understandable format for further scientific interpretation. To demonstrate the efficacy and speed of our methodology, we utilise an existing NbTiN (niobium titanium nitride) TWPA as an example. This showcases the capability of our approach to unveil both broad- and fine-scale behaviours of the device, highlighting the importance of an automated experimental setup for the in-depth investigation of TWPAs for future developments.

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Terahertz-mediated microwave-to-optical transduction

Sahbaz,

Eckstein,

Van Harlingen

et al. 2024

Phys. Rev. A

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Operation of kinetic-inductance travelling wave parametric amplifiers at millimetre wavelengths

Cited by 4 publications

References 26 publications

Non-degenerate-pump four-wave mixing kinetic inductance travelling-wave parametric amplifiers

Non-degenerate-pump four-wave mixing kinetic inductance travelling-wave parametric amplifiers

Automated characterisation and operational insights of superconducting travelling wave parametric amplifiers: unveiling novel behaviours and enhancing tunability

Terahertz-mediated microwave-to-optical transduction

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