Cosmic Rays in the earth s atmosphere. Ilya Usoskin Sodankylä Geophysical Observatory ReSoLVE Center of Excellence, University of Oulu, Finland

1 Cosmic Rays in the earth s atmosphere Ilya Usoskin Sodankylä Geophysical Observatory ReSoLVE Center of Excellence, University of Oulu, Finland

Outline 2 Atmosphere Cosmic-ray induced atmospheric cascade Ground-based measurements of cosmic rays Atmospheric effects of cosmic rays

Atmosphere 3

Atmosphere layers 4 XR absorbtion UVI absorbtion Gas law+ Heat from below

Pressure profile 5

Composition 6 Gas % (volume) Nitrogen N 2 78.084 Oxygen O 2 20.946 Argon Ar 0.9340 Carbon dioxide CO 2 0.0397 Neon Ne 0.001818 Helium He 0.000524 Methane CH 4 0.000179

Large scale air transport 7

8 Atmospheric cascade What happens to CR in the atmosphere

Atmospheric cascade 9 Primary CR particle π π p N p n γ γ μ n N n e - e + e μ N p electromagnetic mesonic nucleonic

A cascade simulation 10

Cosmic ray measurements 11

CR detector = particle detector 12 A particle detector: transfer of (part of) the particle s energy inside the detector into some other form to be easily recorded/detected. The transformation may depend on the type and energy of the particles and the detector s type and design. de/dx Secondary/cascades measurements Magnetic deflections Transition radiation Cherenkov radiation Radio emission Aims to measure: Integral flux energy spectrum Individual particles:» Energy» Mass» Arrival direction

What can be observed 13 Elastic scattering of CR particle from nuclei of the detector. Emission of Cherenkov radiation by a particle moving faster than light in matter. Emission of transition radiation produced when a charged particle passes through a boundary of two media with different dielectric properties. Nuclear reactions (inelastic scattering by the strong force) between the CR particle and the detector nuclei. Bremsstrahlung caused by the CR particle in the detector material. This is negligibly small for CR protons or heavier CR particles.

14 On the ground Atmosphere itself is a part of the CR detector.

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How can it we observe? 16

EAS experiments 17 10 11-10 13 ev» Air showers are absorbed high in the atmosphere: very high altitude needed» Air shower are small : small spacing needed» High fluxes: small areas sufficient At 10 14-10 16 ev» Shower maximum still high in the atmosphere: moderate mountain altitude needed» Moderate detector spacing needed (<100 m)» Rather low fluxes: moderately large areas needed (0.1 km2) At 10 17-10 18 ev» Shower maximum deeper in atmosphere: sea level enough» Low fluxes: areas 1 km 2 needed (detector spacing 150 m) Above 10 18 ev» Extremely low fluxes: huge area needed ( 1000 km 2 )» Giant showers: spacing 1000 m adequate

Galactic cosmic rays: spectrum and fluxes 18 (1 particle per cm 2 -second)

First detector 19 Measure of the CRII

Ionization chamber 20

Geiger counter 21

Cloud chamber 22 Expansion cloud chamber. Cloud chambers were combined with magnetic fields to deflect particles (charge studies): (Skobeltzyn 1927)

Photoemulsion 23

Scintillators 24 The energy loss de/dx is converted into visible light colelcted by a photomultiplier. Scintillators can be inorganic (i.e., iodide, fluoride: NaI CsI BaF2...; liquid noble gases, Ar, Xe...), or organic (hydrocarbon compounds), liquid, or plastic

NM 25 Reflector (Paraphine or polyethilene) absorbes slow neutrons but transparent for higher energy n and p. Producer (lead) multiplies neutrons (~10 slow per one fast). Moderator (paraphin or polyethilen) thermalizes neutrons. Proportional Counter (3 kv) (n + 10 B α+ 7 Li)

NM network 26

Cherenkov light 27 The opening angle alpha is a function of the density of the air and, thus, of the height of emission : cosθ=1/βn MAGIC, the "Major Atmospheric Gamma Imaging Cherenkov

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Cosmic-ray induced ionization 29

History Theodor Wulf 30 300 m Theodor Wuld Wuld (German priest) studied ionization by an electroscope (a charge collector). 1909 : amount of radiation on the top of Eiffel tower is half of that at the ground (in a cave) radiation from ground

CR discovery by CRII 31 1912: Victor Hess (Nobel Prize 1936) launched an electrometer aboard a balloon to the altitude of 5 km. The ionization rate first decreased till 700 m but then increased with altitude space origin for ionization. It was easy to show that the ionizing radiation was not of solar origin.

Domenico Pacini 32 Domenico Pacini Pacini (Assistant at the "Regio Ufficio Centrale di Meteorologia e di Geodinamica ), 1912: ionization 3 m below water is 20% lower than at surface "a sizable cause of ionization exists in the atmosphere originating from penetrating radiation"

Atmospheric cascade 33 Primary CR particle π π p N p n γ γ μ n N n e - e + e μ N p electromagnetic mesonic nucleonic

Cosmic rays induced ionization: details 34 10 6 10 5 A) p, 200 MeV 10 6 B) p, 10 GeV 10 7 C) p, 100 GeV Y [sr cm 2 g -1 ] 10 4 10 3 10 2 10 1 SUM EM MUON HADR 10 5 10 4 10 6 10 5 10 0 0 200 400 600 800 1000 Atm. depth [g cm -2 ] 10 3 0 200 400 600 800 1000 Atm. depth [g cm -2 ] 10 4 0 200 400 600 800 1000 Atm. depth [g cm -2 ] OuluCRAC:CRII model

Comparison with measurements 35 10 Q [cm -3 sec -1 atm -1 ]100 Measurements (Readings, Aug 2005) Model (P C =2.5 GV φ=650 MV) 100 1000 P [hpa]

CRII: altitude vs. latitude 36 Atm. depth (g/cm 2 ) 200 400 600 800 1000 90 75 60 45 Geom. latitude (deg) 0 2 4 6 8 10 12 14 30 Geom. cutoff (GV) 15 0 25 20 15 10 5 4 3 2 1 Altitude (km) 0 10 20 30 40 CRII (cm -3 sec -1 )

Spatial distribution of CRII (cm -3 sec -1 ) at 12 km 37 10 17 24 90 60 30 CRII, 200 g/cm2 31 0 38-30 45-60 -90-180 -120-60 0 60 120 180

SEP effect (20-01 01-2005): anisotropy effect 38 Simulations by the ATMOCOSMIC model (Courtesy L. Desorgher and the U. Bern group)

Ionization of the atmosphere 39

40 Atmosphere is not plasma Fractional ionization rate ~10-18 sec -1 Degree of ionzation ~10-16 Can we neglect is?

41 What happens with the atmosphere in the presence of cosmic rays?

Sun Earth relation 42 Direct influence Solar irradiance, variations ~0.1% over a solar cycle Indirect influence IMF G C R S C R

CLOUD+SKY experiment 43 Duplissi et al. (2010), Enghoff et al. (2011) A 10-fold increase of ionization (typical changes 25%) 2-fold formation rate, BUT A 10-fold increase in SO2 (typical) 1000-fold formation rate change. Temperature, humidity also affect

Jan.2005: stratospheric aerosols 44 Angstrom exponent calculated from SAGE III aerosol extinction as a function of altitude and time in the Northern Polar region (latitude 66 73). Temperature in the same region at 14 km heights

Effect of SEP on polar strato. aerosols 45 SEP event GLE % NH effect NH temp SH effect SH temp 2005-Jan-20 5400 YES (strong) Cold YES (weak) Warm 1989-Sep 400 YES (weak) Cold NO Warm 2000-Jul-14 60 NO Warm -- -- 2001-Apr-15 240 NO Warm NO Warm 2003-Oct 50 NO Warm NO Cold The direct effect is weak (Mironova & Usoskin, 2008, 2012, 2013)

Climate model simulation (GCR ON-OFF) OFF) 46 Calisto, Usoskin, Rozanov, Thomas, 2011

GEC and clouds 47

Summary 48 Atmosphere is important for cosmic rays at Earth. Cosmic rays initiate a complicated cascade (shower) in the atmosphere. Cosmic rays form the main source of atmospheric ionization and related physical-chemical changes in the low-mid atmosphere. The direct effect of CR on the atmosphere is very weak. Indirect is unknown.

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