Transcript Template
VU
October 4, 2006
The Nobel prize in Physics 2006
piet mulders
[email protected]
Physics
2006
• John C. Mather (1946)
NASA Goddard Space Flight
Center, Greenbelt, MD, USA
(PhD from Berkeley)
• George F. Smoot (1945)
University of California,
Berkeley, CA, USA
(PhD from MIT)
for …
For their discovery of the blackbody form and anisotropy of
the cosmic microwave background radiation
From www.nobel.se:
The Nobel Prize in Physics 2006 has been awarded to U.S.
physicists John Mather (NASA) and George Smoot (LBL) for their
discovery of the basic form of the cosmic microwave background
radiation as well as its small variations in different directions.
The very detailed observations that the laureates have carried
out from the COBE satellite have played a major role in the
development of modern cosmology into a precise science.
Measuring temperatures
in the universe
Looking at the color (maximum of light emission) or more general
to the form of the emission spectrum
Tmax ~
1
Energy ~ T
These emission shapes can also be created in a lab and were first
described by Max Planck (Nobel prize 1918)
4
History of the CMB
• Expanding universe (Friedmann 1922, Lemaitre 1927, Willem de
Sitter) and redshift (Edwin Hubble 1929)
• Richard Tolman (working with Hubble) showed in 1934 that cooling
blackbody radiation in an expanding universe retains its form
• Prediction of Cosmic Background Radiation (George Gamov 1948;
Ralph Alpher and Robert Herman 1950)
• Accidental observation of Cosmic Microwave Background (CMB) at
Bell Labs by Arno Penzias & Robert Wilson 1965 (Nobel prize 1978)
• Robert Dicke, Peebles, Roll and Dave Wilkinson 1965 realized
immediately that CMB had been found!
Origin of the CMB
13.7 billion years ago
BIG BANG
inflatie
and finally now …
History of COBE satellite
• Announcement of NASA of opportunities for small
space-based experiments in 1974
• COBE mission (delayed by 1986 shuttle accident)
is launched by rocket in 1989 (Mather)
• Measurement of shape of CMB shows a perfect
Planckian shape with T= 2.726 K (Smoot 1990)
FIRAS optical paths
FIRAS
The COBE satellite
Measurements of
fluctuations in the
CMB ~ 10-5 K
T = 2.728 K
DT = 3 mK
DT = 20 mK
DMR
Temperature maps of sky
T ,
2.7248K
2.7252K
COBE and WMAP
T = 2.728 K
DT ~ mK
• Uniform distribution
• A dipole effect
corresponding to the
motion of Earth with
respect to CMB rest frame
(about 600 km/s)
• Effect of our own galaxy
(choosen as the equator
of the projection)
• Quadrupole (Sachs/Wolfe)
• Absence of other mK
variations gives support
to inflation models and
dark matter
DT ~ 10 mK
Cosmology becoming a precision science
WMAP data
T ,
Angular momentum Spectrum
2.7248K
2.7252K
T , almYlm ,
l
Nbaryonen
N fotonen
10
(6.50.4
)
10
0.3
Future of CMB research
• COBE (1989-1993)
• WMAP (2001-present)
• Planck
Planck is part of the ESA Horizon 2000 Scientific Program. Its
scientific goal is to measure the CMB anisotropies at all angular
scales larges than 5-10’ over entire sky with a precision of 2x10-6
It is planned to launch Planck in the first quarter of 2007. After
launch, Planck will be directed to the second Lagrangian point of
the Earth-Sun System.
• Combine with other ‘messengers from
universe’
– Neutrinos (ANTARES, AMANDA, KM3NET)
– UHECR (Auger, LOFAR)
– Gravitational waves (VIRGO, LISA)
1.5 x 106 km
Summary
• An excellent decision of the Nobel committee
• COBE and follow-up mission WMAP have changed
our view of the universe
• Cosmology has become a precision science
• Dark matter is no longer exotic and in combination
with other experiments (astronomical and lab
experiments at LHC) within reach
• The history of the early universe
(with scenarios like inflation) come
within ‘experimental reach’
visible, gravitational
(blue) and X-ray (red)
picture of bullet cluster
dark energy
baryons
dark matter