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Main Author: Iwazaki, Aiichi
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.16746
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author Iwazaki, Aiichi
author_facet Iwazaki, Aiichi
contents A dark matter axion with mass $m_a$ induces an oscillating electric field in a cylindrical sample placed under a magnetic field $B_0$ parallel to the cylinder axis. When the cylinder is made of a highly electrically conductive material, the induced oscillating current flows only at the surface. In contrast, if the cylinder is composed of a material with small conductivity, e.g. $σ= 10^{-3}\text{eV}$, the electric current flows inside the bulk of the cylinder. Within the QCD axion model, the current $I$ is estimated as $I(σ=10^{-3}\text{eV})\simeq 2.8\times 10^{-14}\text{A}g_γ\big(R/6\text{cm}\big)^2 \big(σ/10^{-3}\text{eV}\big)\big(B_0/15\text{T}\big)\big(10/ε\big)\big(ρ_a/0.3\rm GeVcm^{-3}\big)^{1/2}$ for $m_a=10^{-4}$eV, with radius $R$, permittivity $ε= 10$ of the cylinder and axion energy density $ρ_a$, where $g_γ$ is model dependent parameter; $g_γ(\text{KSVZ}) = -0.96$ and $g_γ(\text{DFSZ}) = 0.37$. Because the current is proportional to $R^2$, using large sample with $R=80$cm, we have large signal-noise ratio ( $>1$ ) even in temperature $T=4$K, $I(σ=10^{-3}\text{eV})/I_n({σ=10^{-3}\text{eV})}\times \sqrt{δωδt_{ob}/2π} \simeq 1.1g_γ(4\text{K}/T)^{1/2}(L/100\text{cm})^{1/2}(R/80\text{cm}) (B_0/7\mbox{T})(ρ_a/0.3\rm GeVcm^{-3})^{1/2} (δt_{ob}/10^3\,\text{s})^{1/2}$ for $m_a=10^{-4}\text{eV}$ with $ε=10$ and $σ=εm_a$, where thermal noise is $I_n=\sqrt{2Tδω/πR_c}$ with $δω=10^{-6}m_a$ and resistance $R_c=L/(σπR^2)$ of the cylinder with length $L$. Although a superconducting solenoid sufficiently large to accommodate such a sample is required, the detection of dark matter axions in our proposal may be feasible in the mass range $m_a =10^{-4}\text{-}10^{-3}\text{eV}$.
format Preprint
id arxiv_https___arxiv_org_abs_2510_16746
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle A Way of Axion Detection with Mass $10^{-4} \text{-}10^{-3}$eV Using Cylindrical Sample with Low Electric Conductivity
Iwazaki, Aiichi
High Energy Physics - Phenomenology
High Energy Physics - Experiment
A dark matter axion with mass $m_a$ induces an oscillating electric field in a cylindrical sample placed under a magnetic field $B_0$ parallel to the cylinder axis. When the cylinder is made of a highly electrically conductive material, the induced oscillating current flows only at the surface. In contrast, if the cylinder is composed of a material with small conductivity, e.g. $σ= 10^{-3}\text{eV}$, the electric current flows inside the bulk of the cylinder. Within the QCD axion model, the current $I$ is estimated as $I(σ=10^{-3}\text{eV})\simeq 2.8\times 10^{-14}\text{A}g_γ\big(R/6\text{cm}\big)^2 \big(σ/10^{-3}\text{eV}\big)\big(B_0/15\text{T}\big)\big(10/ε\big)\big(ρ_a/0.3\rm GeVcm^{-3}\big)^{1/2}$ for $m_a=10^{-4}$eV, with radius $R$, permittivity $ε= 10$ of the cylinder and axion energy density $ρ_a$, where $g_γ$ is model dependent parameter; $g_γ(\text{KSVZ}) = -0.96$ and $g_γ(\text{DFSZ}) = 0.37$. Because the current is proportional to $R^2$, using large sample with $R=80$cm, we have large signal-noise ratio ( $>1$ ) even in temperature $T=4$K, $I(σ=10^{-3}\text{eV})/I_n({σ=10^{-3}\text{eV})}\times \sqrt{δωδt_{ob}/2π} \simeq 1.1g_γ(4\text{K}/T)^{1/2}(L/100\text{cm})^{1/2}(R/80\text{cm}) (B_0/7\mbox{T})(ρ_a/0.3\rm GeVcm^{-3})^{1/2} (δt_{ob}/10^3\,\text{s})^{1/2}$ for $m_a=10^{-4}\text{eV}$ with $ε=10$ and $σ=εm_a$, where thermal noise is $I_n=\sqrt{2Tδω/πR_c}$ with $δω=10^{-6}m_a$ and resistance $R_c=L/(σπR^2)$ of the cylinder with length $L$. Although a superconducting solenoid sufficiently large to accommodate such a sample is required, the detection of dark matter axions in our proposal may be feasible in the mass range $m_a =10^{-4}\text{-}10^{-3}\text{eV}$.
title A Way of Axion Detection with Mass $10^{-4} \text{-}10^{-3}$eV Using Cylindrical Sample with Low Electric Conductivity
topic High Energy Physics - Phenomenology
High Energy Physics - Experiment
url https://arxiv.org/abs/2510.16746