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Cosmic Rays High Energy Astrophysics [email protected] http:// www.mssl.ucl.ac.uk/

Cosmic Rays High Energy Astrophysics

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Astrophysical significance of CR Where does CR radiation come from? What produces it and how? What can it tell is about conditions along the flight path? ‘Primary’ CR radiation can only be detected above the Earth’s atmosphere.

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Page 1: Cosmic Rays High Energy Astrophysics

Cosmic Rays

High Energy [email protected]

http://www.mssl.ucl.ac.uk/

Page 2: Cosmic Rays High Energy Astrophysics

Cosmic RadiationIncludes -• Particles (2% electrons, 98% protons and

atomic nuclei)• Photons

• Large energies ( )-ray photons produced in collisions of high

energy particles

eVEeV 209 1010

Page 3: Cosmic Rays High Energy Astrophysics

Astrophysical significance of CR

• Where does CR radiation come from?• What produces it and how?• What can it tell is about conditions along

the flight path?

• ‘Primary’ CR radiation can only be detected above the Earth’s atmosphere.

Page 4: Cosmic Rays High Energy Astrophysics

Primary and Secondary CR

• Earth’s and Sun’s magnetic field deflect primary cosmic rays (esp low energies).

• Only secondary particles reach the ground - and they can spread over a wide area (approx 1 sq km). ‘Extensive air showers’ can contain up to particles. Which is good because high-E particles are rare!

1010

Page 5: Cosmic Rays High Energy Astrophysics

Detecting Cosmic Rays

• Geiger counters• Scintillation counters• Cerenkov detectors• Spark chambers

• Large arrays are constructed on the ground to detect extensive air showers.

Page 6: Cosmic Rays High Energy Astrophysics

Cosmic rays (cont.)

Chemical compositionEnergy spectra

IsotropyOrigin

Page 7: Cosmic Rays High Energy Astrophysics

Chemical composition

Groups of nuclei Z CR UniverseProtons (H) 1 700 3000 (He) 2 50 300Light (Li, Be, B) 3-5 1 0.00001* Medium (C,N,O,F) 6-9 3 3Heavy (Ne->Ca) 10-19 0.7 1V. Heavy >20 0.3 0.06

Page 8: Cosmic Rays High Energy Astrophysics

Light element abundance

Overabundance of Li, Be and B due to spallation. Medium and heavy nuclei fragment in nuclear collisions and remains are almost always Li, Be or B.

Quantitative analysis is complicated… requires collision X-sections for various processes … and relative abundances seem to change with energy.

Page 9: Cosmic Rays High Energy Astrophysics

Cosmic Ray lifetime in GalaxyCR cannot travel through however

- all high-m particles break up.Assuming :

in disc.

2/50 mkg

yrsst

kgm

mn

tcmkg

p

614

27

36

2

10310

1067.1

10

../50

Page 10: Cosmic Rays High Energy Astrophysics

Escape from the Milky Way

Lifetime could be 10 or 100x larger in theGalactic halo where the density is lower.

Note - galactic disk ~1kpc, =>3000 years for particles to escape at ~c.

- BUT the magnetic field would trap them however.

Page 11: Cosmic Rays High Energy Astrophysics

Energy spectra of particles

L :

M:

H’:

53 Z96 Z

10Z

Log(eV per nucleon)

6 9 12

-6

-12

-18

P

ML

H’

Log Particle flux

m s ster eV-2 -1 -1 -1

NB : this is differential spectrum N(E). Sometimes integral spectrum N(>E).

Page 12: Cosmic Rays High Energy Astrophysics

Integral spectrum of primary CRmkEEN )(

5.1)( EEN5.2 E

5.1 E

Integral spectrum:

12 14 16 18 20 Log E (eV)

Log N(>E)m-2 s-1 ster-1

0-4-8

-12-16

N(>E) is number of particles with energy > E.

??

Page 13: Cosmic Rays High Energy Astrophysics

Cosmic Ray Isotropy

Anisotropies are often quoted in terms of the parameter :

where and are the minimum and maximum intensities measured in all directions.

%100minmax

minmax

IIII

maxI minI

Page 14: Cosmic Rays High Energy Astrophysics

Isotropy (cont.)

• So far, experimental results indicate only small amounts of anisotropy at low energies, with increasing with E.

• Below E~ eV, solar modulation hides the original directions.

• The direction of maximum excess is close to that of the Local Supercluster of Galaxies.

1010

Page 15: Cosmic Rays High Energy Astrophysics

Isotropy Table

Log Energy (in eV) (%)

12 ~0.05 14 ~0.1 16 ~0.6 18 ~2 19-20 ~20+

Page 16: Cosmic Rays High Energy Astrophysics

Isotropy and magnetic fields

At low energies, magnetic fields smear original directions of particles,

eg. eV protons in interstellar magnetic field of Tesla:

and (r=radius of curvature)

14101110

evBr

vm

2)( cv ~

Page 17: Cosmic Rays High Energy Astrophysics

Direction of low-E Cosmic Rays

= 1pc, << distance to Crab Nebulam

m

eBcE

eBcmcr

16

81119

1914

2

10310310106.1

106.110

r=radius of curvature

Page 18: Cosmic Rays High Energy Astrophysics

Thus ‘information’ about the original direction would be totally lost.

At higher energies, particles should retain more of their original direction (r increases with E), but their (number) fluxes are lower so no discrete source has been observed yet.

At eV, r=1Mpc: these particles cannot be confined to the Galaxy, hence they may be extragalactic.

2010

Page 19: Cosmic Rays High Energy Astrophysics

The Origin of Cosmic Rays• GalacticOrdinary stars (produce ~10 J/s)Magnetic stars (produce up to 10 J/s)Supernovae (produce ~3x10 J/s)Novae (produce ~3x10 J/s)

• Extragalactic

28

32

32

32

Page 20: Cosmic Rays High Energy Astrophysics

Origin of Galactic Cosmic Rays

• Energy output required: assume Galaxy is sphere radius 30kpc, = m, => volume = m

• Energy density CR ~ 10 J m (10 eV m ) Thus total energy of CR in Galaxy ~ 10 J.

• Age of Galaxy ~10 years, ~ 3x10 sec hence av. CR production rate ~ 3x10 J s Particles shortlived, => continuous acceltn.

2110 6310 3

-13 -3 6 -350

10 17

32 -1

Page 21: Cosmic Rays High Energy Astrophysics

Cosmic Rays from stars

• Ordinary stars Too low!!! Our Sun emits CR during flares but these have low-E (up to 10 -10 ); rate only ~10 J/s, total 10 J/s (10 stars in Galaxy)

• Magnetic stars Optimistic!!! Mag field about a million times higher than the Sun so output a million times higher, but only 1% magnetic (and low-E); ~10 J/s

10 11

17 1128

32

Page 22: Cosmic Rays High Energy Astrophysics

Supernovae

• Supernovae - a likely source Synchrotron radiation observed from SN so we know high energy particles are involved. Total particle energy estimated at ~10 J per SN (taking B from synchrotron formula and arguing that U ~U ).

• Taking 1 SN every 100 years, => 3x10 J/s. (also, SN produce heavies)32

B part

42

Page 23: Cosmic Rays High Energy Astrophysics

And from Novae

• Novae also promising… Assuming ~10 J per nova and a rate of about 100 per year, we obtain a CR production rate of 3x10 J/s.32

38

Page 24: Cosmic Rays High Energy Astrophysics

Extragalactic Cosmic Rays

10 eV protons (r~1Mpc) cannot be contained in Galaxy long enough to remove original direction, => travel in straight lines from outside Galaxy.

What conditions/geometry required to produce energy density of cosmic rays observed at these energies?

20

Page 25: Cosmic Rays High Energy Astrophysics

• ‘Limited’ extragalactic region, r=300Mpc estimate 1000 radio galaxies in that region, emitting 10 -10 J in their lifetime, 10 yrs.

• Volume of region, V~10 m

53 55 6

75

Page 26: Cosmic Rays High Energy Astrophysics

• Total energy release over life of Universe = 10 x 10 x 10 J ~ 10 J (1000 radio gals)

• Energy density ~ 10 J m ...the order of the energy density required IF the value measured at Earth is universal

• Quasars are another possible source of CR

4 3 55 62

-13 -3

- the radio galaxies must be replaced10,000 times

Page 27: Cosmic Rays High Energy Astrophysics

Electron sources of Cosmic Rays

• Electron mass small compared to protons and heavies, => lose energy more rapidly.

• Lifetimes are short, => electron sources are Galactic.

• Observed energy density ~ 4x10 eV m (total for cosmic rays ~ 10 eV m )

-33

6 -3

Page 28: Cosmic Rays High Energy Astrophysics

Pulsars as cosmic ray sources

• Assuming Crab pulsar-like sources… can Galactic pulsars source CR electrons? Need to calculate how many electrons produced by the Crab nebula.

• Observed synchrotron X-rays from SNR, ~10 Hz = 4 x 10 E B Hz assume B = 10 Tesla => E = 5 x 10 J = 3 x 10 eV

m18 36 2

SNR-8

e- -6 13

Page 29: Cosmic Rays High Energy Astrophysics

Power radiated per electron

• P = 2.4 x 10 E B J/s = 2.4 x 10 x 2.5 x 10 x 10 J/s = 6 x 10 J/s

• Observed flux = 1.6 x 10 J m sec keV • Distance = 1kpc = 3 x 10 m• Total luminosity, L = 1.6 x 10 x 4d J/s =

1.6 x 10 x 10 x 10 J/s = 1.6 x 10 J/s

12 2 2

12 -11 -16

-15

-10 -2 -1 -1

19

-10

-10

2

2 38

30

e-

Page 30: Cosmic Rays High Energy Astrophysics

• Number of electrons = luminosity/power = 1.6 x 10 / 6 x 10 = 2.6 x 10

• Synchrotron lifetime, =5 x 10 B E s = 30 years Thus in 900yrs since SN explosion, must be 30 replenishments of electrons and these must be produced by the pulsar.

• Total no. electrons = 2.6 x 10 x 30 ~ 8 x 10 each with E = 5 x 10 J

30 -15 44

-13 -2 -1syn

44

45

e- -6

Page 31: Cosmic Rays High Energy Astrophysics

• Total energy is thus 4 x 10 J Assume 1 SN every 100 years for 10 years => total energy due to pulsars : 4 x 10 x 10 J = 4 x 10 J in a volume of ~10 m (ie. the Galaxy)

• => energy density of electrons produced by pulsars : =4 x 10 J m = 4 x 10 J m = 4 x 10 / 1.6 x 10 eV m = 2.5 x 10 eV m

40

10

40 8 48

63

48-63

-3

-3-15

-15 -19 -3

4 -3