Determining G with Laser Spectroscopy to 38 ppb
Abstract
A precision measurement is proposed to determine, in a couple hours of integration time, the axion Compton frequency using a modest power (3 mW) tunable external-cavity diode laser at 2458 nm as input to drive a free-space table-top Mach-Zehnder interferometer whose sensing arm passes the expanded beam-waist (3~ mm) light beam through a 1~ T strong, 40~ cm long dipole magnetic field created by a custom-built permanent-magnet assembly with a large but achievable (6~ mm) gap between poles. As the laser frequency is slowly modulated at 1 kHz through a 65 MHz wide window that is well within the 30 GHz fine-tuning range of the laser, a small but readily observable modulation appears in the dark-port optical power of the dark-fringe phase-locked interferometer due to photons converting into axions within the light beam as it passes through the magnetic field. Measuring the axion Compton frequency, A≈ 122~THz, where the dark-port power modulation peaks, to within the line-width of the laser, A=1~ MHz, then determines G to 38 ppb, a roughly 600-fold improvement, through a relation between A and G, involving h, c, and nucleon masses.
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