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Transcript 
Resonantly-Enhanced Photon
Regeneration
Guido Mueller, Pierre Sikivie, and D.B. Tanner
University of Florida
Karl van Bibber
Naval Postgraduate School, LLNL
• Shining light through walls
• Resonant enhancement
• Design requirements
• Strawperson design
• Sensitivity
Durham – Jul2009
Axion 2010, Gainesville, FL, Jan 15-17
• Goals;
– highlight recent experimental and
theoretical work in all areas of axion
physics
– have a low-key celebration of Pierre
Sikivie's sixtieth birthday.
• Friday January 15 and Saturday
January 16
– The main days for presentations,
• Sunday January 17
– Discussions and perhaps some
special activities.
Durham – Jul2009
Shining light through the wall
rate
γ
x
Durham – Jul2009
γ
a
ur
B0
x
ur
B0
∝
1
fa 4
BFT, BMV, GammeV limits. LIPPS, OSQAR similar
Durham – Jul2009
An application of the effect has been proposed
The existing experiments have all reached sensitivities
within about a factor of 3-4 of each other, with limits on
gaγγ in the range of 3 x 10-7 to 1 x10-6
Durham – Jul2009
Resonantly-Enhanced Photon Regeneration
Photon
Detectors
Laser
IO
Magnet
Magnet
Matched Fabry-Perots
Basic concept – use Fabry-Perot optical cavities in production and regeneration magnet.
P Resonant (γ → a → γ ) =
2
π
Simple
′
F
F
⋅
P
(γ → a → γ )
2
where F, F ’ are the finesses of the cavities
Hoogeveen and Ziegenhagen (1991); Sikivie, DT, and van Bibber (2007), Mueller et al (2009)
Durham – Jul2009
Karl van Bibber’s “EE” argument
The gain on the production
side is simple:
• The number of forward
passes the light makes in the
magnet is larger by a factor of
F/π
• Or, the cavity gain in power is
F/π
• The axion flux is larger by a
factor of F/π
Durham – Jul2009
Karl van Bibber’s “EE” argument
• On the regeneration side, 1 pass
through the magnet produces:
P1 = E12
• In the cavity, the light approaching a
mirror is
Pc = Ec2
• After 1 round trip this partial ray has
intensity
Prt = R2*Ec2
• This adds in phase to the regenerated
wave E1 (add amplitudes!)
Ec = R*Ec + E1
(1-R)*Ec = E1
Ec = E1/T
Pc = P1/T2
• This light is transmitted through the
mirror to the detector
Pdet = P1/T ~ F*P1/π
Durham – Jul2009
Take R + T = 1 for both mirrors
Requirements
• Laser must be “locked” to production cavity.
• Regeneration cavity must be locked to resonance of
production cavity without filling it with light at the laser
wavelength.
• Cavities must be aligned on mirror image modes (as if
inner mirrors and wall were not present).
• Need sensitive readout of weak emission from
regeneration cavity.
Detectors
Laser
IO
Magnet
Magnet
Matched Fabry-Perots
Durham – Jul2009
Strawman design
Magnets: 12 Tevatron dipoles
• 6 on each side of the wall
• 5 T field
• 6 m length each
• 48 mm diameter
• B0*Lmag = 180 T-m
Cavity: curved-flat FP
• 45 m length; FSR = c/2Lcav ~ 3.3 MHz
• Mirror radii: 114 m (outer) and -4500 m
(inner); g = 0.59
• Gaussian beam radii (field): 5.5 mm
(outer); 4.3 mm (inner)
• 1 ppm clip at 30 mm diameter
• Finesse = 3.1 x 105 ; T = 10 ppm;
A = 1 ppm/mirror
• Stored power ~ 1 MW
Durham – Jul2009
LIGO-style laser
• Diode pumped Nd:YAG MOPA
• 6-8 Watt.
• 1064 nm (282 THz).
• Stabilized by reference cavity.
• Pre-mode cleaner for spatial mode.
• TEM00 single-frequency VCO.
Durham – Jul2009
Length control
Photon
Detectors
Laser
IO
Magnet
Magnet
Matched Fabry-Perots
IO provides mode-matching of laser to cavity (telescope)
Modulation for “locking the cavity.”
Durham – Jul2009
RF Pockels cell modulators
Durham – Jul2009
Locking the cavities
Ec
ESB
ωm
• Pound-Drever-Hall locking
• Resonant regeneration experiment is complex:
• 2 length degrees of freedom + alignment
• Absolute position must be held to ~10-13 m
Durham – Jul2009
Offset lock the regeneration cavity
• Use low power, 100 mW,
Laser 2
• Offset locked to Laser 1
• Offset frequency Ω set
by the frequency of Osc. 2
• Ω = integer * FSR of the
cavities
• Regeneration cavity is
PDH locked to Laser 2
Durham – Jul2009
Readout scheme
• The axion field converts in the regeneration cavity to a
signal field ES at Laser 1 frequency ω0.
• Mix this with laser 2 (the LO) at a photodiode; the signal
is proportional to the intensity
• Write this in terms of the number of photons in each field
Durham – Jul2009
Readout scheme II
• Noise is shot noise:
• Phase is arbitrary and unknown, so add I and Q in
quadrature
• Shot-noise limited SNR is
i.e, one photon at an SNR of 1.
Durham – Jul2009
Other issues
• Can avoid zeros of sinc function in conversion rate by
alternating field directions.
• To go beyond L ~ 90 m would require first removing
sagitta and then using larger diameter magnets. Km
scales => 200 mm diameters.
• For high power in production cavity, thermal
management/thermal lenses become important.
• Avoid stray light.
• Must run in UHV.
• Dust elimination is critical; scatter from 100 particles of
10 µ diameter already dominates the loss budget.
• Need vibration-free mirror suspensions. Possibly
suspended.
• Include quantum efficiency, photodetector dark
current.
Durham – Jul2009
Sensitivity:
10–4
gaγγ (GeV–1)
10–6
Photon regeneration
10–8
10–10
10–12
10–14
CAST & HBS
Resonantly-enhanced
photon regeneration
Axion models
10–4
Durham – Jul2009
ma(eV)
10–3
The Resonant Regeneration Collaboration
FNAL:
Aaron Chou (Wilson Fellow, co-spokesperson GammeV),
William Wester (co-spokesperson GammeV),
Jason Steffen (Brinson Fellow)
Peter Mazur,
Ray Tomlin,
Al Baumbaugh
Naval Postgraduate School and Lawrence Livermore National Lab:
Karl van Bibber (Chief Scientist, co-spokesperson ADMX)
Univ. of Florida:
David Tanner (ADMX, LIGO)
Guido Muller (LIGO, Chair of LISA Interferometer working group)
Pierre Sikivie (ADMX, axion physics)
Univ. of Michigan:
Dick Gustafson (LIGO)
Durham – Jul2009
Collaborations need names…
Durham – Jul2009
Conclusions
• Resonant approach improves sensitivity to gaγγ by a
factor of 300 or so.
• It can reach 2 x 10-11 GeV-1 in 90 days of live time.
• All the technology for such an experiment exists.
– TeV magnets.
– Laser, cavity, instrument control, and readout adopt technology
proven in LIGO and LISA.
Durham – Jul2009
Axion 2010, Gainesville, FL, Jan 15-17
• Goals;
– highlight recent experimental and
theoretical work in all areas of axion
physics
– have a low-key celebration of Pierre
Sikivie's sixtieth birthday.
• Friday January 15 and Saturday
January 16
– The main days for presentations,
• Sunday January 17
– Discussions and perhaps some
special activities.
Durham – Jul2009
THE END
Durham – Jul2009
Cavity parameters
• Gaussian beams
• Strawman parameters
• Items governing finesse
• Items governing length
Durham – Jul2009
References
Durham – Jul2009
Cavity mode
Durham – Jul2009
Intensities
Durham – Jul2009
Cavities
Durham – Jul2009
Stability
Durham – Jul2009
Cavity parameters (10 W in; 0.8 / 8 ppm loss)
Durham – Jul2009
PDH 1
Durham – Jul2009
PDH 2
Durham – Jul2009
Cavity with F = 1500
Durham – Jul2009
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