Transcript radio Image

Science Capabilities - Summary
100 s
200  bursts per year
 prompt emission sampled to > 20 µs
AGN flares > 2 mn
 time profile + E/E 
acceleration
1 orbit
physics of jets and
 bursts delayed emission
all 3EG sources + 80 new in 2 days
 periodicity searches (pulsars & X-ray binaries)
1 day
3EG 
limit
 pulsar beam & emission vs. luminosity, age, B
104 sources in 1-yr survey
1 yr
catalog
0.01 
 AGN: logN-logS, duty cycle,
emission vs. type, redshift, aspect angle
0.001
 extragalactic background light ( + IR-opt)
LAT 1 yr
2.3 10-9
cm-2 s-1
 new  sources (µQSO,external galaxies,clusters)
Active Galactic Nuclei
- Cosmic Linear Accelerator •
Synchrotron and inverse Compton radaition emitted by ultra –relativistic flow of
electron-positron plasma along the axis of the distant rotating super-massive black
hole (Quasar: PKS 0637-752)
Active Galactic Nuclei: New Way to Study
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Measure the spectra above 100 MeV
from AGN (based on blazar logN-logS
extrapolations)
Explore low-energy spectrum where
many AGN have peak emission
Monitor variability and notify flares
Study of AGN evolution and history of
star-forming activity
Overlap with ground-based gamma-ray
observations
Study of time correlation
Btwn X-ray and -ray.
Active Galactic Nuclei: Time Variability
GLAST monitors all-sky continuously with high sensitivity, detects many AGN flare-ups before
anyone else, and records their entire history for the first time.
Active Galactic Nuclei: Spectrum
GLAST will detect ~3000 AGNs, reaching to z~4-5. Thus we will detect cosmological
evolution of AGNs and their role in the galaxy formation. Extragalactic IR-UV
background light (EBL) by star-forming activity absorbs high energy gammarays by  > e+e-. Thus GLAST will measure history of star-formation in z~1-5.
Accelerating Shock Fronts
- Cosmic Random Phase Synchrotron Super Nova Remnant 1006 seen by ASCA (X-ray band)
Image of synchrotron radiation by high energy (~200TeV) electrons in the
accelerating shock front in SN1006
Accelerating Shock Fronts
- Cosmic Random Phase Synchrotron Super Nova Remnant 1006 seen by Cangaroo (TeV gamma-ray)
Image of photons (CMB) scattered by high energy (~200TeV) electrons
in the accelerating shock front of SN1006.
Pulsars (Rotating Neutron Stars)
- Cosmic Betatron •
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Synchrotron emission (X-ray) by high energy electrons (~100GeV) from the neutron
star’s magnetosphere (Magnetic induction: Pulsed)
Synchrotron emission (X-ray) by high energy electrons (~100TeV) from the nebula
around the neutron star’s magnetosphere (Accelerating shock front: Unpulsed)
The bell-shaped synchrotron nebula around the Crab
pulsar (the small dot at the center of the opening of the
bell-shaped nebula). A string-like flow of electrons along
its rotation axis is also visible.
Pulsars: Radio-Quite Brothers (NS)
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Until recently, all pulsars have been discovered in Radio Band, with one exception of
Geminga.
In the past 5 years several pulsars have been discovered in X-ray. They are generally very
weak in Radio Band.
Many radio-quiet pulsars to be discovered
We now expect to find many radio-quiet pulsars. We can see throught the Galaxy with
gamma-rays but not with radio wave. So we will study distribution of pulsars (ie. NS’s) in
the Galaxy.
History of star-formation activity in our Galaxy.
Geminga’s pulse profile by EGRET
Radio-loud
GLAST
Radio-quiet
Gamma-ray Bursts
LAT:
– Capture > 25% of GRBs in LAT FOV (2 sr or more)
– Deadtime of < 100 msec per event
– Spectral resolution < 20%, especially at energies above 1 GeV
GBM:
– Monitor energy range: 10 keV - 20 MeV
– Monitor FOV of 8 sr (shall overlap
that of the LAT)
– Notify observers world-wide:
• Recognize bursts in realtime
• Determine burst positions to few degree
accuracy
• Transmit (within seconds) GRB
coordinates to the ground
• Re-point the main instrument to GRB
positions within 10 minutes
Gamma-Ray Bursts: Wide Energy Coverage
•Cover the classical gamma-ray band where most of the burst photons
are emitted by GLAST Gamma-ray Burst Monitor (GBM)
•Monitor all of the sky visible from Low-Earth Orbit ( 10keV-30MeV)
•Monitor 40% of the sky visible from LEO (20MeV-500GeV)
•Identify when and where to re-point the spacecraft to optimize
observations and notify other observers
Simulation:
Spectrum of an
intense GRB by
GLAST
10 keV
10 MeV
10 GeV
Gamma-Ray Bursts at > 20 MeV
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•
EGRET discovered high energy GRB
afterglow
– only one burst
– dead time limited observations
GLAST will observe many more high
energy afterglows
–
strong constraint to GRB models
Gamma-Ray Bursts at > 20 MeV
Spatial:
• Monitor > 2 sr of the sky at all times
• Localize sources to with > 100 photons to < 10 arcmin
Temporal:
• Perform broad band spectral studies and search for spectral structure
• Find correlation between 10 keV - 20 MeV and > 20 MeV photons
• Determine characteristics of > 20 MeV afterglow
Gamma-Ray Bursts: Correlation btwn X-ray and -ray
Standard wisdom about GRB is: the more energetic, the closer to the central energy source.
GLAST measures both in X-ray/soft -ray (GBM) and high energy -ray (LAT), arrowing to
study temporal correlation between them.
Cosmic Ray Interaction with Inster Stellar Matter (1)
Inner Galaxy (|l|<60o,|b|<10o)
by EGRET. Elect. Brems., Inv.
Compton, Isotr. Diff., and
N-N int. (pi-zero).
SNR IC443 by EGRET and
GLAST (simulation).
Elect. Brems., Inv. Compton,
and N-N int. (pi-zero).
Note that electron contri. dominates
in SNRs.
Cosmic-Ray Flux and Composition
in SNRs, GMCs, Galactic Plane/Bulge, Nearby galaxies, Nearby Clusters
 Separation of electron contribution (brems. and IC) and proton contribution (pi-0)
is important. Association of SNRs, history of the galaxy or the cluster
 Even in galactic level, the total energy of cosmic-ray is non-negligible. It can be very
important in cluster level.
Cosmic Ray Interaction with Inster Stellar Matter (2)
Gamma Cygni SNR: Pulsar, SNR, and cosmic-ray interaction with ISM
Measurement on cosmic-ray proton and electron fluxes
Radio image of
Molecular H line
(21cm)
EGRET image
GLAST image
(simulation)
Cosmic Ray Contents in Nearby Galaxies
GLAST will measure cosmic electron and proton fluxes for LMC, SMC and M31
Past SN rate, past history of galaxies, stability of galaxies
LMC by EGRET
LMC by GLAST
(simulation)
LMC in IR (IRAS)
Galactic Diffuse Emission: Galaxy Simulator Project
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Objectives
– Separate pi-zero and electron brems. contributions
– Determine total mass of nearby GMCs
C/H ratio
– Galactic electron distribution
SNR association?
– Galactic arm structure
What are between arms?
– Correlation with radio, X & hard-X observations
– Galactic magnetic field: strength and large scale structure
– Determine total amount of cold dark baryonic matter
Giant Molecular Clouds
in Cygns region
(galactic arm structure?)
Pi-zero flux measurement
by GLAST will determine
the total mass in the GMCs
and their C/H.
Schedule of the GLAST Mission
Calendar Years
2000
2001
SRR
PDR
NAR
2002
I-CDR
2003
M-CDR
2005
2004
Inst. Delivery
Launch
Implementation
Formulation
Build & Test
Engineering Models
Build & Test
Flight Units
2010
Ops.
Inst.
I&T
Inst.-S/C
I&T
Schedule
Reserve
Thank you for attention.
Please wait for launch in
2005