Title: Visions of Antarcitc Astronomy Sydney 19.07.2003
1Precision CMB Polarization from Dome-C Paolo de
Bernardis for the B-modes collaboration
Looking for the signature of stochastic
gravitational waves background in the primordial
universe
Visions of Antarcitc Astronomy - Sydney 19.07.2003
2The Observable
Sub-atomic dimensions
- The inflation process in the early universe
boosts quantum fluctuations into fluctuations at
cosmological scales. - Generic preditions of this scenario are
- A flat geometry of the Universe
- Generation of scalar (density) fluctuations
- Adiabatic
- With a nearly scale invariant spectrum
- Generation of tensor fluctuations (gravitational
waves)
inflation
Cosmological dimensions
3The Observable
- The inflation process in the early universe
boosts quantum fluctuations into fluctuations at
cosmological scales. - Generic preditions of this scenario are
- A flat geometry of the Universe
- Generation of scalar (density) fluctuations
- Adiabatic
- With a nearly scale invariant spectrum
- Generation of tensor fluctuations (gravitational
waves)
OBSERVABLE CONSEQUENCES
Temperature fluctuations in the CMB, with a very
precise power spectrum
4The Observable
- The inflation process in the early universe
boosts quantum fluctuations into fluctuations at
cosmological scales. - Generic preditions of this scenario are
- A flat geometry of the Universe
- Generation of scalar (density) fluctuations
- Adiabatic
- With a nearly scale invariant spectrum
- Generation of tensor fluctuations (gravitational
waves)
OBSERVABLE CONSEQUENCES
Temperature fluctuations in the CMB, with a very
precise power spectrum
OBSERVED BY BOOMERanG, DASI, WMAP ..
5The Observable
- The inflation process in the early universe
boosts quantum fluctuations into fluctuations at
cosmological scales. - Generic preditions of this scenario are
- A flat geometry of the Universe
- Generation of scalar (density) fluctuations
- Adiabatic
- With a nearly scale invariant spectrum
- Generation of tensor fluctuations (gravitational
waves)
OBSERVABLE CONSEQUENCES
Temperature fluctuations in the CMB, with a very
precise power spectrum
Stochastic Background of gravitational waves
6The Observable
- The inflation process in the early universe
boosts quantum fluctuations into fluctuations at
cosmological scales. - Generic preditions of this scenario are
- A flat geometry of the Universe
- Generation of scalar (density) fluctuations
- Adiabatic
- With a nearly scale invariant spectrum
- Generation of tensor fluctuations (gravitational
waves)
OBSERVABLE CONSEQUENCES
Temperature fluctuations in the CMB, with a very
precise power spectrum
Curl-like polarization of the CMB (B-modes)
7E ?
T/S0.28
8rms B-modes polarization signal 2 orders of
magnitude smaller than rms T anisotropy !
E ?
T/S0.28
9The signal is extremely weak
- Nobody really knows how to detect this.
- Pathfinder experiments are needed
- Whatever smart, ambitious experiment we design to
detect the B-modes - It needs to be extremely sensitive
- It needs an extremely careful control of
systematic effects - It needs careful control of foregrounds
- It will need independent experiments with
orthogonal systematics.
10- Bolometric experiments feature higher
instantaneous sensitivity. - Ex. BICEP at south pole is a bolometer camera
with 100 bolometers at 100 and 150 GHz, with
resolution of the order of 1o, and with a
rotating analyzer for polarization detection. - We want to use bolometric detectors to have high
instantaneous sensitivity, but interferometric
techniques to have orthogonal systematics.
11- The collaboration
- UK (Cardiff University)
- (L. Piccirillo, W. Gear, P. Ade, P. Mauskopf, M.
Griffin, G. Pisano, B. Maffei, A. Orlando, C.
Calderon, S. Melhuish, ...) - UK (Cambridge University)
- (A. Lasenby, G. Yassin, M. Jones, S. Withington,
...) - France (IAS / College de France / Obs. de
Paris) - (J.L. Puget, J.M. Lamarre, Y. Giraud-Heraud, J.
Delabrouille, F. Pajot, ...) - Italy (University of Milan Bicocca)
- (G. Sironi, M. Gervasi, ...)
- Italy (University of Rome La Sapienza)
- (Silvia Masi, P. de Bernardis, G. Polenta ...)
12- Main aims
- Build a 256 horns bolometric interferometer
- High sensitivity map of large angular scales CMB
anisotropy polarization from Dome-C - Subtract the gravitational lensing contribution
- Obtain the power spectrum of the B-modes
Space
This is part of a long term plan.
Balloon
Antarctica (Dome-C)
13Adding interferometer using passive correlators
and direct detectors
phase shift
Complex visibility
horns
direct detector
beam combiner
phase shift
Complex visibility
complex correlator
horns
amplifiers
heterodyne bolometric amplifier/mixer (low
noise elem.) nothing digital/analog
correlator beam combiner (passive) diodes di
rect detectors (low noise elem.) Low freq. (GHz) high freq. ( 90 GHz)
Michelson and Fizeau, followed by COAST in
Cambridge, pioneered these ideas
14What signal we expect to see at the detector?
recovered with spatial or temporal chopping
15Recovered visibilities
Fourier Transform
Average
Image of the sky
Power spectrum
16Pupil plane interferometry (fringes are
temporally displayed)
Method of combining the two beams using
polarizers (or half-silvered mirrors) and then
focusing on a single pixel detector. Also called
Michelson interferometer.
Beam splitter has the property that the phase
difference between transmitted and reflected beam
is exactly 90 degrees. Thats why the /-
D1
Dz(t) variable delay
D2
17- In general we have N horns spaced with
baselines Bij - we can form n(n-1)/2 baselines each requiring a
correlator to recover the corresponding visibility
18- Each telescope/optical element has its own phase
switcher (for example Dz(t) in the Michelson) - Each phase switcher is modulated at a different
audio-frequency Fi bigger than 1/? of the direct
detector - Each detector receives radiation from all the
phase switchers - All the n(n-1)/2 beating frequencies Bij Fi-Fj
are within the electrical bandwidth of the
detectors - n(n-1)/2 phase sensitive detection provides phase
and quadrature signals corresponding to the
output of a n(n-1)/2 matrix of complex
correlators
phase switching frequencies
beating frequencies
det. bandpass
f
19Receiver Architecture (real instrument is 256
horns)
corrugated feed-horns
Ortho-Mode Transducers (OMT)
Rectangular wave-guide phase switchers
Wave-guide to strip-line transitions
Stokes-parameters extraction
one direct detector per line (contains all the
beating frequencies)
20Facts about bolometric interferometry
- A bolometric interferometer has same sensitivity
as an array of total power bolometers - clean modulation of input polarization
- can measure 4 Stokes parameters simultaneously
- Has different systematics and no aberrations
- chop phase instead of rotation of polarization
vector - Ground-based atmospheric fluctuations reduced by
a big factor (tens or hundreds M. Jones) - Little sensitivity to microphonics. The use of
pulse tube coolers coupled with ADR or 3He
fridges allows extended observations in remote
areas (like Dome-C)
21Sensitivity of Planck HFI
0.1K 1.6K 4K 60K detectors filters horns mir
ror
from A. Lange Detectors for future CMB
observations
22The ultimate sensitivity
from A. Lange Detectors for future CMB
observations
23- Ground based fsky0.2 NET150µK.s1/2 20,000
baselines, 200 horns, 1 year
24- Planck HFI- like fsky1 NET60µK.s1/2
25- Ultimate fsky1 NET16µK.s1/2
26shield
tent
electronics
Cryo detector
container
Alt-AZ mount
Roof of tower
Dome-C Tower
27Rotary valve assembly
Demonstrator Dome-C 2004
270K
Cryomec PT-405
- Atmospheric noise
- Planet
- No polarization
30K
2.5K
628 mm
ADR
Beam A
Beam B
0.1K
28cryogenic system
- Pulse tube refrigerator Cryomec PT-405 (0.5W _at_4K,
air cooled, 5kW) - Keeps the as there is power). Service every 20000 hours.
- Sub-K cooler 3He fridge (our design) or ADR
(Timbies design) depending on bolo needs. - Heat switches (Rome design)
- Control electronics (readout and regulation)
including cryo harness.
29Measurements on the water-cooled version of
PT405 installed in Rome La Sapienza
30Measurements on the water-cooled version of
PT405 installed in Rome La Sapienza
31Full Array Dome-C 2005