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Paper detail

Precision spectroscopy by photon-recoil signal amplification

Precision spectroscopy of atomic and molecular ions offers a window to new physics, but is typically limited to species with a cycling transition for laser cooling and detection. Quantum logic spectroscopy has overcome this limitation for species with long-lived excited states. Here, we extend quantum logic spectroscopy to fast, dipole-allowed transitions and apply it to perform an absolute frequency measurement. We detect the absorption of photons by the spectroscopically investigated ion through the photon recoil imparted on a co-trapped ion of a different species, on which we can perform efficient quantum logic detection techniques. This amplifies the recoil signal from a few absorbed photons to thousands of fluorescence photons. We resolve the line center of a dipole-allowed transition in 40Ca+ to 1/300 of its observed linewidth, rendering this measurement one of the most accurate of a broad transition. The simplicity and versatility of this approach enables spectroscopy of many previously inaccessible species.

preprint2014arXivOpen access
Yong WanFlorian GebertJannes B. WübbenaNils ScharnhorstSana AmairiIan D. LerouxBörge HemmerlingNiels LörchKlemens HammererPiet O. Schmidt
physics.atom-phquant-ph
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Yong WanFlorian GebertJannes B. WübbenaNils ScharnhorstSana AmairiIan D. LerouxBörge HemmerlingNiels LörchKlemens HammererPiet O. Schmidt

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