Preparing pure photon number states of the radiation field

@article{Varcoe2000nature, abstract = {The quantum mechanical description of a radiation field is based on states that are characterized by the number of photons in a particular mode; the most basic quantum states are those with fixed photon number, usually referred to as number (or Fock) states. Although Fock states of vibrational motion can be observed readily in ion traps1, number states of the radiation field are very fragile and difficult to produce and maintain. Single photons in multi-mode fields have been generated using the technique of photon pairs2, 3. But in order to generate these states in a cavity, the mode in question must have minimal losses; moreover, additional sources of photon number fluctuations, such as the thermal field, must be eliminated. Here we observe the build-up of number states in a high-Q cavity, by investigating the interaction dynamics of a probe atom with the field. We employ a dynamical method of number state preparation that involves state reduction of highly excited atoms in a cavity, with a photon lifetime as high as 0.2 seconds. (This set-up is usually known as the one-atom maser or 'micromaser'.) Pure states containing up to two photons are measured unambiguously.}, author = {Varcoe, B. T. H. and Brattke, S. and Weidinger, M. and Walther, H. }, citeulike-article-id = {1141433}, doi = {10.1038/35001526}, journal = {Nature}, keywords = {fock, nature}, month = {February}, number = {6771}, pages = {743--746}, posted-at = {2007-03-16 17:56:05}, priority = {2}, title = {Preparing pure photon number states of the radiation field}, url = {http://dx.doi.org/10.1038/35001526}, volume = {403}, year = {2000} }

TY - JOUR ID - Varcoe2000nature L3 - citeulike-article-id:1141433 TI - Preparing pure photon number states of the radiation field JF - Nature VL - 403 IS - 6771 SP - 743 EP - 746 N2 - The quantum mechanical description of a radiation field is based on states that are characterized by the number of photons in a particular mode; the most basic quantum states are those with fixed photon number, usually referred to as number (or Fock) states. Although Fock states of vibrational motion can be observed readily in ion traps1, number states of the radiation field are very fragile and difficult to produce and maintain. Single photons in multi-mode fields have been generated using the technique of photon pairs2, 3. But in order to generate these states in a cavity, the mode in question must have minimal losses; moreover, additional sources of photon number fluctuations, such as the thermal field, must be eliminated. Here we observe the build-up of number states in a high-Q cavity, by investigating the interaction dynamics of a probe atom with the field. We employ a dynamical method of number state preparation that involves state reduction of highly excited atoms in a cavity, with a photon lifetime as high as 0.2 seconds. (This set-up is usually known as the one-atom maser or 'micromaser'.) Pure states containing up to two photons are measured unambiguously. KW - fock KW - nature AU - Varcoe, BTH AU - Brattke, S AU - Weidinger, M AU - Walther, H PY - 2000/02/17/ UR - http://dx.doi.org/10.1038/35001526 ER -