Photon-by-photon feedback control of a single-atom trajectory

• Published in: Nature (London) Vol. 462; no. 7275; pp. 898 - 901
• Main Authors: Rempe, G, Ourjoumtsev, A, Koch, M, Sames, C, Murr, K, Kubanek, A, Pinkse, P. W. H
• Format: Journal Article
• Language: English
• Published: London Nature Publishing Group UK 17.12.2009; Nature Publishing Group
• Subjects: Algorithms; Atoms & subatomic particles; Charged particles; Exact sciences and technology; Humanities and Social Sciences; Kinetic energy; letter; Light; Measurement; multidisciplinary; Photons; Physics; Properties; Quantum physics; Science; Science (multidisciplinary); The physics of elementary particles and fields; Germany; Quantum system; Dipoles; Feedback; Open systems; Single atom; Quantum noise; Trajectories; Quantum limit; Kinetic energy; Quantum fluctuation
• ISSN: 0028-0836; 1476-4687
• DOI: 10.1038/nature08563

Feedback is one of the most powerful techniques for the control of classical systems. An extension into the quantum domain is desirable as it could allow the production of non-trivial quantum states and protection against decoherence. The difficulties associated with quantum, as opposed to classical, feedback arise from the quantum measurement process-in particular the quantum projection noise and the limited measurement rate-as well as from quantum fluctuations perturbing the evolution in a driven open system. Here we demonstrate real-time feedback control of the motion of a single atom trapped in an optical cavity. Individual probe photons carrying information about the atomic position activate a dipole laser that steers the atom on timescales 70 times shorter than the atom's oscillation period in the trap. Depending on the specific implementation, the trapping time is increased by a factor of more than four owing to feedback cooling, which can remove almost all the kinetic energy of the atom in a quarter of an oscillation period. Our results show that the detected photon flux reflects the atomic motion, and thus mark a step towards the exploration of the quantum trajectory of a single atom at the standard quantum limit.