An integrated circuit for generating distributable and unconditional entanglement at microwave frequencies

Hsiang-Sheng Ku; Francois Mallet; William F. Kindel; Konrad W. Lehnert; Kent D. Irwin; Gene C. Hilton; Leila R. Vale; Emanuel Knill; Scott C. Glancy

An integrated circuit for generating distributable and unconditional entanglement at microwave frequencies

ORAL

Abstract

Entanglement, the unique feature of quantum mechanics, is the central resource of quantum information. In the strategy of continuous-variables quantum information processing, unconditional and distributable entanglement can be obtained by combining two squeezed states on a balanced beam splitter. Our group has recently demonstrated the generation of squeezed microwave states using a Josephson Parametric Amplifier [1] and implemented on-chip balanced beam splitters [2]. This talk will present a device that combines all these components on a single chip. The design requirements for such an ``on-chip entangler'' of the electromagnetic field modes will be discussed. \\[4pt] [1] M. A. Castellanos-Beltran et al, Nature Physics, 4, 929 (2008). \\[0pt] [2] Hsiang-Sheng Ku et al, arXiv:1010.3232v1

March 22, 2011, 11:51 AM – March 22, 2011, 12:03 PM

Authors

Hsiang-Sheng Ku
- JILA
- University of Colorado at Boulder
Francois Mallet
- JILA
William F. Kindel
- University of Colorado at Boulder
Konrad W. Lehnert
- JILA and NIST
Kent D. Irwin
- NIST
- National Institute of Standards and Technology
Gene C. Hilton
- NIST
- National Institute of Standards and Technology
Leila R. Vale
- NIST
- National Institute of Standards and Technology
Emanuel Knill
- NIST
Scott C. Glancy
- NIST