Noise reduction and hyperfine level coherence in spontaneous noise spectroscopy of atomic vapor

TL;DR

This paper presents a measurement system that reduces extraneous noise in spontaneous noise spectroscopy of atomic vapor, enabling detailed observation of hyperfine level coherence and photon-atom interactions.

Contribution

It introduces a novel noise reduction scheme and laser stabilization method for high-precision spectral measurements in atomic vapor spectroscopy.

Findings

Noise reduction allows shot noise to be minimized through averaging.

Laser stabilization achieves spectral width below 1 kHz.

System effectively observes hyperfine coherence via frequency-modulated spontaneous noise spectra.

Abstract

We develop a system for measurements of power spectra of transmitted light intensity fluctuations, in which the extraneous noise, including shot noise, is reduced. In essence, we just apply light, measure the power of the transmitted light and derive its power spectrum. We use this to observe the spontaneous noise spectra of photon atom interactions. Applying light with frequency modulation, we can also observe the spontaneous noise reflecting the coherence between the hyperfine levels in the excited state. There are two in novel components in the measurement system, the noise reduction scheme and the stabilization of the laser system. The noise reduction mechanism can be used to reduce the shot noise contribution to arbitrarily low levels through averaging, in principle. This is combined with differential detection to keep unwanted noise at low levels. The laser system is stabilized to obtain spectral width below 1\,kHz without high frequency ($\gtrsim10\,$MHz) noise. These methods are described systematically and the performance of the asurement system is examined through experimental results.