Gas modulation refractometry (GAMOR) - On its ability to eliminate the influence of drifts

TL;DR

GAMOR is a refractometry technique that effectively eliminates the influence of linear drifts such as cavity length changes and gas leaks, enabling highly accurate gas property measurements despite environmental fluctuations.

Contribution

This work demonstrates that GAMOR can withstand significant temperature and leakage variations without affecting measurement accuracy, highlighting its robustness over conventional methods.

Findings

GAMOR is immune to linear drifts from cavity length changes and leaks.

It can tolerate temperature fluctuations of 100 mK over 103 seconds.

Leakage rates filling the reference cavity over days do not impact accuracy.

Abstract

Gas modulation refractometry (GAMOR) is a technique based on a dual-Fabry-Perot (FP) cavity (DFPC) for assessment of gas refractivity, density, and pressure that can alleviate significant limitations of conventional refractometry systems, predominantly those related to drifts. Repeated assessments of the beat frequency when the measurement cavity is evacuated provide conditions under which the methodology is immune to the linear parts of the drifts in the system, both those from length changes of the cavities and those from gas leaks and outgassing. This implies that the technique is solely influenced by the non-linear parts of the drifts. This work provides a description of the principle behind the GAMOR methodology and explicates the background to its unique property. Based on simple models of the drifts of the temperature in the cavity spacer and the residual gas in the reference cavity, this work predicts that a GAMOR system, when used for assessment of refractivity, can sustain significant temperature drifts and leakage rates without being affected by noticeable errors or uncertainties. The cavity spacer can be exposed to temperature fluctuations of 100 mK over 103 s, and the reference cavity can have a leakage that fills it up with gas on a timescale of days, without providing errors or uncertainties in the assessment of refractivity that are 3 x 10^(-12), which, for N2, corresponds to 0.01 ppm (parts per million) of the value under atmospheric pressure conditions, and thereby 1 mPa. Since well-designed systems often have temperature fluctuations and leakage rates that are smaller than these, it is concluded that there will, in practice, not be any appreciable influence from cavity length drifts, gas leaks, and outgassing in the GAMOR methodology.