Transcript CTI meeting
Optical cavity with high quality
factor Q
Photonic crystals course final
presentation
Karin Söderström
IMT
INSTITUT DE
MICROTECHNIQUE
NEUCHÂTEL
Outline
1) Optical cavities and their use (history)
2) Quality factor Q
3) Lots of cavities
4) Applications of Cavities with PHC
•
•
IMT
INSTITUT DE
MICROTECHNIQUE
NEUCHÂTEL
Quantum optic
Frequency selective devices
Karin Söderström
2
Optical cavities and their use
• The simplest optical cavity: A Fabry-Pérot resonator is
composed of two parallel mirrors
• Associated with an active medium this cavity realized with
one mirror with R<100% leads to one of the greatest
discovery of the century
Laser by Th. Maiman Nature 187, 493-494 (1960)
Macro-cavity
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INSTITUT DE
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Optical cavities and their use
• One of the first study on resonator lead to the theoretical
great result:
– By placing a two-level system in a resonator you can modify
(enhance or stop) the spontaneous emission of the two–level
system
E.M.Purcell Phys. Rev. 69 (1946) p. 681
• This information lead to many hope in different field:
– One photon source
P. Michler, A. Kiraz, C. Becher, W. V. Schoenfeld, P. M.
Petroff, Lidong Zhang, E. Hu, and A. Imamoglu (2000)
Science 290 (5500), 2282.
– Quantum entanglement of radiation and matter is possible
Thompson, R. J., Rempe, G. & Kimble, H. J. Phys.
Rev. Lett. 68, 1132–1135 (1992).
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Quality factor Q
Definition: Q=Pin the cavity /PLosses α lifetime photon in the cavity t
Q α 1/g where g is the linewidth
If R
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Karin Söderström
, Q
. The quality of the information
5
.
Lots of different cavities
Fabry-Pérot cavity made of
two Bragg mirrors
Cavity made by a defect in a photonic
crystal
Kerry J. Vahala, Nature, 424, 6950, 839, (2003)
IMT
INSTITUT DE
MICROTECHNIQUE
NEUCHÂTEL
Karin Söderström
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Outline
1) Optical cavities and their use (history)
2) Quality factor Q
3) Lots of cavities
4) Cavities with PHC
•
•
IMT
INSTITUT DE
MICROTECHNIQUE
NEUCHÂTEL
Quantum optic
Frequency selective devices
Karin Söderström
7
PHC Cavities Applications
• Quantum optics:
• Control of the radiative lifetime (Purcell Effect)
Miniature laser, LED, VCSEL, mW threshold
Painter,O. et al. Science 284,
1819–1821 (1999).
INSTITUT DE
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Karin Söderström
Control of the t in a micropillar
Solomon et al,Phys.Rev.lett., 86, 17, 3903, (2001).
Applications:
Data transport in optical fiber.
Easy writing and reading of CD,
DVD (small spot size)
IMT
Fp α Qmode/Vmode
8
t=1.3ns
t=280ps
PHC Cavities Applications
• Quantum optics:
– Strong coupling
(of great interest due to the mode volume)
single-atom cavity quantum electrodynamics in the strong coupling regime
Theoretically proven: Vuckovic et al, Phys. Rev. E, 65, 016608, (2001)
Experimentally shown: Yoshie et al, Nature 432, 200-203 (2004) for a QD
Applications:
Study of center of mass motion: Rempe, Applied physics. B, 60, 233 (1995)
Single photon source: B Deveaud-Pledran, et al - US Patent App. 11/394,518, (2006)
Beauty of physics BEC Theoretical: E Ostrovskaya, Y Kivshar, Optics Exp. vol12, (2004)
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PHC Cavities Applications
• Frequency devices (the mode volume is less important)
Akahane et al, Nature, 425, 6961, 944, (2003)
Applications:
Very small spectrometer,
Multiplexer, Demultiplexer, Filters,
Spectroscopy
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PHC Cavities Applications
• Frequency devices (Vmode is less important, here Q=400)
Applications: Very small spectrometer, Multiplexer, Demultiplexer
Noda et al, Nature, 407, 608, (2000)
Shinya et al, Optics Exp,14,
25, 12394, (2006)
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PHC Cavities Applications
• Frequency devices (the mode volume is less important)
Applications: Filters
Qth: 7*10^7
Kuramochi et al, Appl. Phys. Lett., 88,
041112, (2006)
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PHC Cavities Applications
• Frequency devices (the mode volume is less important)
Application: Spectroscopy tool
A photonic crystal sensor with a resolution
of better than Dn =0.002 with a Q factor of 400
The Caltech
Nanofabrication
Group
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In this case it is
not a bridge:
small amount of
sample only
needed
Karin Söderström
Chow et al, Optics letters, 29, 10, 1093, (2004)
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Conclusions
• The cavity is the basis to construct devices with photonic
crystals with different functionality modes
– Single photon source needed for quantum computation
• Lots of progresses can be made on Q (from theoretical
studies) but the limits of the fabrication process can be
reached before
• Lots of different applications in many fields
– Laser, spectrometer, multiplexer, filter, spectroscopy
IMT
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Karin Söderström
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Thanks for your attention
?Questions?
?Questions?
?Questions?
?Questions?
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NEUCHÂTEL
Karin Söderström
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