Timekeeping with electron spin states in diamond | Zendy

J. S. Hodges | Zendy; Norman Y. Yao | Zendy; Dougal Maclaurin | Zendy; Chaitanya Rastogi | Zendy; Mikhail D. Lukin | Zendy; Dirk Englund | Zendy

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Timekeeping with electron spin states in diamond

Author(s) -

J. S. Hodges,

Norman Y. Yao,

Dougal Maclaurin,

Chaitanya Rastogi,

Mikhail D. Lukin,

Dirk Englund

Publication year - 2013

Publication title -

physical review a

Language(s) - English

Resource type - Journals

eISSN - 1094-1622

pISSN - 1050-2947

DOI - 10.1103/physreva.87.032118

Subject(s) - diamond , physics , spins , dephasing , spin (aerodynamics) , electron , atomic physics , allan variance , condensed matter physics , atomic units , quantum mechanics , standard deviation , materials science , thermodynamics , statistics , mathematics , composite material

Frequency standards based on atomic states, such as Rb or Cs vapors, or single trapped ions, are the most precise measures of time. Here we introduce a complementary device based on spins in a solid-state system - the nitrogen-vacancy defect in single crystal diamond. We show that this system has comparable stability to portable atomic standards and is readily incorporable as a chip-scale device. Using a pulsed spin-echo technique, we anticipate an Allan deviation of {\sigma}_y =1E-12 ({\tau})^(-1/2) with current photoluminescence detection methods and posit exceeding 1E-14 with improved diamond material processing and nanophotonic engineering.

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