A Way of Axion Detection with Mass 10-4 -10-3eV Using Cylindrical Sample with Low Electric Conductivity

Abstract

A dark matter axion with mass ma induces an oscillating electric field in a cylindrical sample placed under a magnetic field B0 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= 10-3eV, the electric current flows inside the bulk of the cylinder. Within the QCD axion model, the current I is estimated as I(σ=10-3eV) 2.8× 10-14Agγ(R/6cm)2 (σ/10-3eV)(B0/15T)(10/ε)(ρa/0.3 GeVcm-3)1/2 for ma=10-4eV, with radius R, permittivity ε= 10 of the cylinder and axion energy density ρa, where gγ is model dependent parameter; gγ(KSVZ) = -0.96 and gγ(DFSZ) = 0.37. Because the current is proportional to R2, using large sample with R=80cm, we have large signal-noise ratio ( >1 ) even in temperature T=4K, I(σ=10-3eV)/In(σ=10-3eV)× δωδtob/2π 1.1gγ(4K/T)1/2(L/100cm)1/2(R/80cm) (B0/7T)(ρa/0.3 GeVcm-3)1/2 (δtob/103\,s)1/2 for ma=10-4eV with ε=10 and σ=εma, where thermal noise is In=2Tδω/πRc with δω=10-6ma and resistance Rc=L/(σπR2) 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 ma =10-4-10-3eV.