Micromotion minimisation by synchronous detection of parametrically excited motion
Abstract
Precise control of charged particles in radio-frequency (Paul) traps requires minimising excess micromotion induced by stray electric fields. We present a method to detect and compensate such fields through amplitude modulation of the radio-frequency trapping field. Modulation at frequencies close to the motional modes of the trapped particle excites coherent motion whose amplitude linearly depends on the stray field. In trapped-ion experiments, this motion can be detected by recording the arrival times of photons scattered during laser cooling. Only a single laser beam is required to resolve fields in multiple directions. In a demonstration using a 88Sr+ ion in a surface electrode trap, we achieve a sensitivity of 0.1\, V\, m-1\, /\, Hz and a minimal uncertainty of 0.015\, V\, m-1.
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