Sung Woo Youn scite author profile

The axion is a highly motivated elementary particle that could address two fundamental questions in physics—the strong charge-parity (CP) problem and the dark matter mystery. Experimental searches for this hypothetical particle started reaching theoretically interesting sensitivity levels, particularly in the micro–electron volt (gigahertz) region. They rely on microwave resonators in strong magnetic fields with signals read out by quantum noise limited amplifiers. Concurrently, there have been intensive experimental efforts to widen the search range by devising various techniques and to enhance sensitivities by implementing advanced technologies. These orthogonal approaches will enable us to explore most of the parameter space for axions and axion-like particles within the next decades, with the 1- to 25-gigahertz frequency range to be conquered well within the first decade. We review the experimental aspects of axion physics and discuss the past, present, and future of the direct search programs.

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Search for Dark Matter Axions with CAST-CAPP

Adair

Altenmüller

Anastassopoulos

et al. 2022

Nat Commun

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The CAST-CAPP axion haloscope, operating at CERN inside the CAST dipole magnet, has searched for axions in the 19.74 μeV to 22.47 μeV mass range. The detection concept follows the Sikivie haloscope principle, where Dark Matter axions convert into photons within a resonator immersed in a magnetic field. The CAST-CAPP resonator is an array of four individual rectangular cavities inserted in a strong dipole magnet, phase-matched to maximize the detection sensitivity. Here we report on the data acquired for 4124 h from 2019 to 2021. Each cavity is equipped with a fast frequency tuning mechanism of 10 MHz/ min between 4.774 GHz and 5.434 GHz. In the present work, we exclude axion-photon couplings for virialized galactic axions down to gaγγ = 8 × 10−14 GeV−1 at the 90% confidence level. The here implemented phase-matching technique also allows for future large-scale upgrades.

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Status of the 25 T, 100 mm Bore HTS Solenoid for an Axion Dark Matter Search Experiment

Gupta

Anerella

Cozzolino

et al. 2019

IEEE Trans. Appl. Supercond.

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Magnetoresistance in copper at high frequency and high magnetic fields

et al. 2017

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A: In halo dark matter axion search experiments, cylindrical microwave cavities are typically employed to detect signals from the axion-photon conversion. To enhance the conversion power and reduce the noise level, cavities are placed in strong solenoid magnetic fields at sufficiently low temperatures. Exploring high mass regions in cavity-based axion search experiments requires high frequency microwave cavities and thus understanding cavity properties at high frequencies in extreme conditions is deemed necessary. We present a study of the magnetoresistance of copper using a cavity with a resonant frequency of 12.9 GHz at the liquid helium temperature in magnetic fields up to 15 T utilizing a second generation high temperature superconducting magnet. The observations are interpreted to be consistent with the anomalous skin effect and size effect. This is the first measurement of magnetoresistance at a high frequency (> 10 GHz) in high magnetic fields (> 10 T). K: Dark Matter detectors (WIMPs, axions, etc.); Detector design and construction technologies and materials; Microwave radiometers A X P : 1705.04754

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Multiple-Cavity Detector for Axion Search

Youn

2018

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Sung Woo Youn

Axion dark matter: How to see it?

Search for Dark Matter Axions with CAST-CAPP

Status of the 25 T, 100 mm Bore HTS Solenoid for an Axion Dark Matter Search Experiment

Magnetoresistance in copper at high frequency and high magnetic fields

Multiple-Cavity Detector for Axion Search

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