Back
Fri, 02.12.2016 11:45

Atomic Hong-Ou-Mandel experiment

Presenter: Denis Boiron; Laboratoire Charles Fabry, Institut d'Optique Graduate School, France
Host: I. Fuentes Guridi
Where: Josef-Stefan HS, Boltzmanngasse 5, 3rd floor, 1090 Wien

I will present an atomic analogue of the 1987 experiment of Hong, Ou and Mandel: two photons impinging each on a different imput port of a beamsplitter always emerge in the same output port if they are indistinguishable. This is a simple yet very illustrative two-particle effect not explainable by classical means. In our experiment, starting with a Bose-Einstein condensate of metastable helium, we have produced pairs of atoms by a four-wave mixing process. These atoms are manipulated by laser beams in a Bragg diffraction configuration to mimic mirrors and beam-splitters. The coincidence measurement at the output port of the beam-splitter is performed with a single-atom 3D resolved detector. Varying the indistinguishability, we have observed a dip in the coincidence count whose visibility is only compatible with quantum theory, as in the 1987 experiment.

Back
Fri, 02.12.2016 11:45

Atomic Hong-Ou-Mandel experiment

Presenter: Denis Boiron; Laboratoire Charles Fabry, Institut d'Optique Graduate School, France
Host: I. Fuentes Guridi
Where: Josef-Stefan HS, Boltzmanngasse 5, 3rd floor, 1090 Wien

I will present an atomic analogue of the 1987 experiment of Hong, Ou and Mandel: two photons impinging each on a different imput port of a beamsplitter always emerge in the same output port if they are indistinguishable. This is a simple yet very illustrative two-particle effect not explainable by classical means. In our experiment, starting with a Bose-Einstein condensate of metastable helium, we have produced pairs of atoms by a four-wave mixing process. These atoms are manipulated by laser beams in a Bragg diffraction configuration to mimic mirrors and beam-splitters. The coincidence measurement at the output port of the beam-splitter is performed with a single-atom 3D resolved detector. Varying the indistinguishability, we have observed a dip in the coincidence count whose visibility is only compatible with quantum theory, as in the 1987 experiment.

Comments (0)

No comments found!
Register and Login to post comments

Comments (0)

No comments found!
Register and Login to post comments
Back
Fri, 02.12.2016 11:45

Atomic Hong-Ou-Mandel experiment

Presenter: Denis Boiron; Laboratoire Charles Fabry, Institut d'Optique Graduate School, France
Host: I. Fuentes Guridi
Where: Josef-Stefan HS, Boltzmanngasse 5, 3rd floor, 1090 Wien

I will present an atomic analogue of the 1987 experiment of Hong, Ou and Mandel: two photons impinging each on a different imput port of a beamsplitter always emerge in the same output port if they are indistinguishable. This is a simple yet very illustrative two-particle effect not explainable by classical means. In our experiment, starting with a Bose-Einstein condensate of metastable helium, we have produced pairs of atoms by a four-wave mixing process. These atoms are manipulated by laser beams in a Bragg diffraction configuration to mimic mirrors and beam-splitters. The coincidence measurement at the output port of the beam-splitter is performed with a single-atom 3D resolved detector. Varying the indistinguishability, we have observed a dip in the coincidence count whose visibility is only compatible with quantum theory, as in the 1987 experiment.

Back
Fri, 02.12.2016 11:45

Atomic Hong-Ou-Mandel experiment

Presenter: Denis Boiron; Laboratoire Charles Fabry, Institut d'Optique Graduate School, France
Host: I. Fuentes Guridi
Where: Josef-Stefan HS, Boltzmanngasse 5, 3rd floor, 1090 Wien

I will present an atomic analogue of the 1987 experiment of Hong, Ou and Mandel: two photons impinging each on a different imput port of a beamsplitter always emerge in the same output port if they are indistinguishable. This is a simple yet very illustrative two-particle effect not explainable by classical means. In our experiment, starting with a Bose-Einstein condensate of metastable helium, we have produced pairs of atoms by a four-wave mixing process. These atoms are manipulated by laser beams in a Bragg diffraction configuration to mimic mirrors and beam-splitters. The coincidence measurement at the output port of the beam-splitter is performed with a single-atom 3D resolved detector. Varying the indistinguishability, we have observed a dip in the coincidence count whose visibility is only compatible with quantum theory, as in the 1987 experiment.

Comments (0)

No comments found!
Register and Login to post comments

Comments (0)

No comments found!
Register and Login to post comments