Your search keyword '"Day, Tom"' showing total 3 results

1. A Room-Temperature Solid-State Maser Amplifier

Author

Day, Tom, Isarov, Maya, Pappas, William J., Johnson, Brett C., Abe, Hiroshi, Ohshima, Takeshi, McCamey, Dane R., Laucht, Arne, and Pla, Jarryd J.

Subjects

Quantum Physics, Physics - Instrumentation and Detectors

Abstract

Masers once represented the state-of-the-art in low noise microwave amplification technology, but eventually became obsolete due to their need for cryogenic cooling. Masers based on solid-state spin systems perform most effectively as amplifiers, since they provide a large density of spins and can therefore operate at relatively high powers. Whilst solid-state masers oscillators have been demonstrated at room temperature, continuous-wave amplification in these systems has only ever been realized at cryogenic temperatures. Here we report on a continuous-wave solid-state maser amplifier operating at room temperature. We achieve this feat using a practical setup that includes an ensemble of nitrogen-vacancy center spins in a diamond crystal, a strong permanent magnet and simple laser diode. We describe important amplifier characteristics including gain, bandwidth, compression power and noise temperature and discuss the prospects of realizing a room-temperature near-quantum-noise-limited amplifier with this system. Finally, we show that in a different mode of operation the spins can be used to cool the system noise in an external circuit to cryogenic levels, all without the requirement for physical cooling.

Published

2024

2. Strong Microwave Squeezing Above 1 Tesla and 1 Kelvin

Author

Vaartjes, Arjen, Kringhøj, Anders, Vine, Wyatt, Day, Tom, Morello, Andrea, and Pla, Jarryd J.

Subjects

Quantum Physics, Physics - Applied Physics

Abstract

Squeezed states of light have been used extensively to increase the precision of measurements, from the detection of gravitational waves to the search for dark matter. In the optical domain, high levels of vacuum noise squeezing are possible due to the availability of low loss optical components and high-performance squeezers. At microwave frequencies, however, limitations of the squeezing devices and the high insertion loss of microwave components makes squeezing vacuum noise an exceptionally difficult task. Here we demonstrate a new record for the direct measurement of microwave squeezing. We use an ultra low loss setup and weakly-nonlinear kinetic inductance parametric amplifiers to squeeze microwave noise 7.8(2) dB below the vacuum level. The amplifiers exhibit a resilience to magnetic fields and permit the demonstration of record squeezing levels inside fields of up to 2 T. Finally, we exploit the high critical temperature of our amplifiers to squeeze a warm thermal environment, achieving vacuum level noise at a temperature of 1.8 K. These results enable experiments that combine squeezing with magnetic fields and permit quantum-limited microwave measurements at elevated temperatures, significantly reducing the complexity and cost of the cryogenic systems required for such experiments., Comment: Main text: 9 pages, 4 figures. Supplementary information: 21 pages, 17 figures

Published

2023

3. Opacity on NIF: Anchor 2 Iron (Level 2 Milestone 7118 Report)

Author

Perry, Ted, primary, Heeter, Robert, additional, Johns, Heather, additional, Dodd, Evan, additional, Krasheninnikova, Natalia, additional, Opachich, Kathy, additional, Fontes, Chris, additional, Wallace, Matt, additional, Dutra, Eric, additional, Durand, Alice, additional, Day, Tom, additional, and Urbatsch, Todd, additional

Published

2020