R
Rainer Blatt
Researcher at University of Innsbruck
Publications - 434
Citations - 39148
Rainer Blatt is an academic researcher from University of Innsbruck. The author has contributed to research in topics: Ion & Qubit. The author has an hindex of 86, co-authored 419 publications receiving 33415 citations. Previous affiliations of Rainer Blatt include University of Colorado Boulder & National Institute of Standards and Technology.
Papers
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Proceedings ArticleDOI
Absolute frequency measurement of 40 Ca + in a Paul trap
M. Chwalla,J. Benhelm,Kihwan Kim,Gerhard Kirchmair,Thomas Monz,M. Riebe,Philipp Schindler,Alessandro S. Villar,Christian F. Roos,W. Haensel,Rainer Blatt,Michel Abgrall,Giorgio Santarelli,G.D. Rovera,Ph. Laurent +14 more
TL;DR: In this article, an absolute frequency measurement of a single 40Ca+ ion in a linear Paul trap at the 10-15 level was performed using a Cs-referenced frequency comb to measure the probe laser exciting the 4s2S1/2 to 3d2D5/2 quadrupole transition at 411 THz.
Proceedings Article
Towards quantum computation with trapped Ca+ ions
Ferdinand Schmidt-Kaler,C. Roos,H. Rohde,S. Gulde,A.B. Mundt,Dietrich Leibfried,Juergen Eschner,Rainer Blatt +7 more
TL;DR: In this article, a single Ca+ ion has been cooled in the spherical Paul trap to the ground state of vibration with up to 99.9% probability, and the measured several decoherence time is attributed to residual laser and magnetic field fluctuations.
Towards experimental classical verification of quantum computation
Roman Stricker,J. Carrasco,Martin Ringbauer,Lukas Postler,Michael Meth,Claire Edmunds,Philipp Schindler,Rainer Blatt,Peter Zoller,Barbara Kraus,Thomas Monz +10 more
TL;DR: In this article , Stricker, Carrasco, Ringbauer, Postler, and Schindler discuss the role of Quantum Optics and Quantum Information in Quantum Information.
Proceedings ArticleDOI
Quantum Information Processing and Quantum Simulations with Trapped Ions
TL;DR: In this article, the use of trapped ions for quantum information processing is reviewed, and quantum simulations employ well controlled quantum systems to make predictions on another quantum system under investigation, using trapped ions quantum relativistic effects and spin systems.