Generalized auto-balanced Ramsey spectroscopy of clock transitions

TL;DR

The paper introduces a generalized auto-balanced Ramsey spectroscopy (GABRS) method that effectively eliminates measurement-induced perturbations in atomic clock frequency measurements through a two-loop control scheme, enhancing precision and robustness.

Contribution

It presents a novel two-loop GABRS scheme that achieves perfect compensation of probe-induced shifts and is resilient to typical experimental errors, extending its applicability across various precision measurement fields.

Findings

GABRS achieves perfect light shift compensation.

The method is robust against relaxation and pulse fluctuation errors.

Universal anti-symmetric error signals are generated with specific secondary variables.

Abstract

When performing precision measurements, the quantity being measured is often perturbed by the measurement process itself. This includes precision frequency measurements for atomic clock applications carried out with Ramsey spectroscopy. With the aim of eliminating probe-induced perturbations, a method of generalized auto-balanced Ramsey spectroscopy (GABRS) is presented and rigorously substantiated. Here, the usual local oscillator frequency control loop is augmented with a second control loop derived from secondary Ramsey sequences interspersed with the primary sequences and with a different Ramsey period. This second loop feeds back to a secondary clock variable and ultimately compensates for the perturbation of the clock frequency caused by the measurements in the first loop. We show that such a two-loop scheme can lead to perfect compensation of measurement-induced light shifts and does not suffer from the effects of relaxation, time-dependent pulse fluctuations and phase-jump modulation errors that are typical of other hyper-Ramsey schemes. Several variants of GABRS are explored based on different secondary variables including added relative phase shifts between Ramsey pulses, external frequency-step compensation, and variable second-pulse duration. We demonstrate that a universal anti-symmetric error signal, and hence perfect compensation at finite modulation amplitude, is generated only if an additional frequency-step applied during both Ramsey pulses is used as the concomitant variable parameter. This universal technique can be applied to the fields of atomic clocks, high-resolution molecular spectroscopy, magnetically induced and two-photon probing schemes, Ramsey-type mass spectrometry, and to the field of precision measurements. Some variants of GABRS can also be applied for rf atomic clocks using CPT-based Ramsey spectroscopy of the two-photon dark resonance.