HIGH ENERGY ASTROPHYSICS - Lecture 7. PD Frank Rieger ITA & MPIK Heidelberg Wednesday

Similar documents
Radiation processes and mechanisms in astrophysics I. R Subrahmanyan Notes on ATA lectures at UWA, Perth 18 May 2009

Compton Scattering I. 1 Introduction

Applied Nuclear Physics (Fall 2006) Lecture 19 (11/22/06) Gamma Interactions: Compton Scattering

Special relativity and light RL 4.1, 4.9, 5.4, (6.7)

Thomson scattering: It is the scattering of electromagnetic radiation by a free non-relativistic charged particle.

Astrophysical Radiation Processes

Radiative Processes in Astrophysics

Compton Scattering. hω 1 = hω 0 / [ 1 + ( hω 0 /mc 2 )(1 cos θ) ]. (1) In terms of wavelength it s even easier: λ 1 λ 0 = λ c (1 cos θ) (2)

Compton Scattering II

Accelerator Physics NMI and Synchrotron Radiation. G. A. Krafft Old Dominion University Jefferson Lab Lecture 16

Part III. Interaction with Single Electrons - Plane Wave Orbits

X-ray Radiation, Absorption, and Scattering

Lecture 6 Scattering theory Partial Wave Analysis. SS2011: Introduction to Nuclear and Particle Physics, Part 2 2

Notes on x-ray scattering - M. Le Tacon, B. Keimer (06/2015)

Particle Physics. Michaelmas Term 2011 Prof Mark Thomson. Handout 5 : Electron-Proton Elastic Scattering. Electron-Proton Scattering

Radiative Processes in Astrophysics

QFT. Unit 11: Cross Sections and Decay Rates

Neutrinos, nonzero rest mass particles, and production of high energy photons Particle interactions

Lecture 3. Experimental Methods & Feynman Diagrams

Dipole Approxima7on Thomson ScaEering

no incoming fields c D r


Chapter 2 Radiation of an Accelerated Charge

We start with a reminder of a few basic concepts in probability. Let x be a discrete random variable with some probability function p(x).

Lecture: Scattering theory

Recap Lecture + Thomson Scattering. Thermal radiation Blackbody radiation Bremsstrahlung radiation

PHYS 5012 Radiation Physics and Dosimetry

1 Monday, November 21: Inverse Compton Scattering

DIFFERENTIAL CROSS SECTION FOR COMPTON SCATTERING. 1. introduction. 2. Differential cross section with respect to the square of momentum transfer

GAMMA-RAYS FROM MASSIVE BINARIES

Electrodynamics of Radiation Processes

High-Energy Astrophysics Lecture 6: Black holes in galaxies and the fundamentals of accretion. Overview

Accretion Disks. 1. Accretion Efficiency. 2. Eddington Luminosity. 3. Bondi-Hoyle Accretion. 4. Temperature profile and spectrum of accretion disk

Physics 214 Final Exam Solutions Winter 2017

Radiative processes in high energy astrophysical plasmas

Lecture 11: Polarized Light. Fundamentals of Polarized Light. Descriptions of Polarized Light. Scattering Polarization. Zeeman Effect.

FI 3103 Quantum Physics

PHAS3135 The Physics of Stars

Jackson, Classical Electrodynamics, Section 14.8 Thomson Scattering of Radiation

Photon Interactions in Matter

Interaction of particles with matter - 2. Silvia Masciocchi, GSI and University of Heidelberg SS2017, Heidelberg May 3, 2017

Outline. Chapter 6 The Basic Interactions between Photons and Charged Particles with Matter. Photon interactions. Photoelectric effect

Astro 305 Lecture Notes Wayne Hu

Chapter 11. Radiation. How accelerating charges and changing currents produce electromagnetic waves, how they radiate.

Lecture 3 (Part 1) Physics 4213/5213

4 Relativistic kinematics

1. Kinematics, cross-sections etc

Interaction of Particles and Matter

Radiative Processes in Astrophysics

The Compton Effect. Martha Buckley MIT Department of Physics, Cambridge, MA (Dated: November 26, 2002)

Scattering amplitudes and the Feynman rules

Can blazar flares be triggered by the VHE gamma-rays from the surrounding of a supermassive black hole?

Physics 504, Lecture 22 April 19, Frequency and Angular Distribution

The Larmor Formula (Chapters 18-19)

Lorentz Force. Acceleration of electrons due to the magnetic field gives rise to synchrotron radiation Lorentz force.

Lecture 9 - Applications of 4 vectors, and some examples

High-Energy Astrophysics

February 18, In the parallel RLC circuit shown, R = Ω, L = mh and C = µf. The source has V 0. = 20.0 V and f = Hz.

Fundamental Concepts of Particle Accelerators III : High-Energy Beam Dynamics (2) Koji TAKATA KEK. Accelerator Course, Sokendai. Second Term, JFY2012

Scattering of Electromagnetic Radiation. References:

Synchrotron Radiation: II. Spectrum

BOHR S THEORY AND PHYSICS OF ATOM CHAPTER

Classical electric dipole radiation

PHYS 5012 Radiation Physics and Dosimetry

Synchrotron Radiation II

Modern Physics for Scientists and Engineers International Edition, 4th Edition

EEE4101F / EEE4103F Radiation Interactions & Detection

Examples. Figure 1: The figure shows the geometry of the GPS system

Minimum Bias Events at ATLAS

Lecture 8 Notes, Electromagnetic Theory II Dr. Christopher S. Baird, faculty.uml.edu/cbaird University of Massachusetts Lowell

PHYS 5012 Radiation Physics and Dosimetry

Bremsstrahlung Radiation

Chapter 2 Bremsstrahlung and Black Body

PHY492: Nuclear & Particle Physics. Lecture 3 Homework 1 Nuclear Phenomenology

Bethe-Block. Stopping power of positive muons in copper vs βγ = p/mc. The slight dependence on M at highest energies through T max

Calculating cross-sections in Compton scattering processes

Atomic Physics. Chapter 6 X ray. Jinniu Hu 24/12/ /20/13

1 Monday, October 31: Relativistic Charged Particles

Scattering Processes. General Consideration. Kinematics of electron scattering Fermi Golden Rule Rutherford scattering cross section

(a) Write down the total Hamiltonian of this system, including the spin degree of freedom of the electron, but neglecting spin-orbit interactions.

Examples - Lecture 8. 1 GPS System

Relativistic Transformations

arxiv:astro-ph/ v1 7 Jul 1999

PHYS 3313 Section 001 Lecture #7

Observational Appearance of Black Hole Wind Effect of Electron Scattering

PHY-494: Applied Relativity Lecture 5 Relativistic Particle Kinematics

Strong-Field QED and High-Power Lasers

Lecture 6:Feynman diagrams and QED

Physics 111 Homework Solutions Week #9 - Thursday

Particle Physics Homework Assignment 3

Sources of radiation

University of Alberta

PHYS 390 Lecture 23 - Photon gas 23-1

Selected Topics in Physics a lecture course for 1st year students by W.B. von Schlippe Spring Semester 2007

Relativistic Effects. 1 Introduction

Inelastic scattering

Scattering. 1 Classical scattering of a charged particle (Rutherford Scattering)

[1+ m2 c 4 4EE γ. The equations of conservation of energy and momentum are. E + E γ p p γ

Benvenuti al Mera-TeV!

Particle Physics Homework Assignment 4

Transcription:

HIGH ENERGY ASTROPHYSICS - Lecture 7 PD Frank Rieger ITA & MPIK Heidelberg Wednesday 1

(Inverse) Compton Scattering 1 Overview Compton Scattering, polarised and unpolarised light Di erential cross-section d /d andtotalcross-section Compton kinematics f ( i, ) Thomson ( f ' i )andklein-nishinaregime Inverse Compton scattering Energy change in Inverse Compton scattering 2

2 Thomson Scattering of Polarized Radiation by an electron Consider radiation from a free electron in response to incident linearly polarised electromagnetic wave. Force on charge (neglecting magnetic force for v c): ~F = m e ~r = ee0 ~ sin! 0 t with ~ denoting E-field direction. With dipole moment ~ d := e~r: ~d = e2 E 0 m e ~ sin! 0 t ) ~ d = e2 E 0 m e! 2 0 ~ sin! 0 t electron 3

Power of radiating dipole (cf. Larmor s formula, lecture 4): dp d = q2 4 c 3 ~v 2 sin 2 = ~d 2 4 c 3 sin2 and by intergration over solid angle (Larmor s formula): P = 2q2 3c 3 ~v 2 = 2 ~ d 2 3c 3 Time-averaged power: Averaging ~ d 2 = e4 E0 2 m 2 e R T =! 2 0 0 sin 2! 0 tdt=1/2 gives: 1 T sin 2! 0 t over time t,with< sin 2! 0 t>= dp d = e4 E 2 0 8 m 2 ec 3 sin2 and P = e4 E 2 0 3m 2 ec 3 (Note: := angle between ~ d and ~n!) 4

Incident (time-averaged) radiation flux on electron: Di erential cross-section d With dp d = e4 E 2 0 sin2 8 m 2 ec 3 : < ~ S >= c 8 E2 0 for scattering into d, is defined as dp d :=< ~ S > d d = ce2 0 d 8 d d d polarized = e4 m 2 ec 4 sin2 =:r 2 0 sin 2 with classical electron radius r 0 := e2 m e c 2 =2.82 10 13 cm Visualization: d gives area presented by electron to a photon that is going to be scattered in direction d. 5

Total cross-section by integrating over solid angle, or immediately from P =< ~ S > ) = P/< ~ S > where P =(e 4 E 2 0)/(3m 2 ec 3 )=E 2 0r 2 0c/3 and< ~ S >= ce 2 0/(8 ), giving: with Thomson cross-section T : = 8 3 r2 0=: T Note: T =6.652 10 25 cm 2 1. T applies only to non-relativistic regime; for higher energies, Klein-Nishina cross-section KN must be used (see later) 2. Scattered radiation is linearly polarised in direction of incident polarisation vector, ~, anddirectionofscattering, ~n. 3. Single particle (time-averaged) Thomson power P = T < ~ S >= T c (E 2 0/8 ) = TcU rad with radiation energy density U rad = E 2 0/8 =time-averaged energy density in incident wave. 6

3 Thomson Scattering of Unpolarized Radiation Unpolarised radiation: can have E-field in any direction = independent superposition of two linearly polarized beams with perpendicular axes. To scatter non-polarised radiation propagating in direction k into direction n, need to average two scatterings through angle and /2:! d = 1 d ( ) + d ( /2) d unpol 2 d pol d pol = r2 0 2 (sin2 +1)= r2 0 2 (cos2 +1)= 3 T 16 (1 + cos2 ) where = 6 (k, n). Forward-backward symmetry (! + )! Total cross-section, integrated over, is again = T. 1 n 2 /2 k 7

4 Thomson Optical Depth =Probability for a photon to experience Thomson scattering while traversing region containing free electrons with density n e Z T := n e T ds For T 1 source optically-thin to Thomson scattering, for T 1 optically-thick. Example - Thomson scattering in black hole accretion flows: Ion density = electron density, in terms of dimensionless accretion rate ṁ := M/ M Edd,whereM Edd ' 2.2 (M BH /10 8 M ) M /yr ' 10 26 M BH,8 g/sec M 10 n(r) = =2.5 10 11 1 8 M rs 3/2 ṁ cm 3 4 r 2 m p v r r M BH assuming radial inflow velocity v r = (GM/r) 1/2 = c(r s /r) 1/2 / p 2(fraction <1offreeinfall);Schwarzschildradiusr s := 2GM/c 2. ) Thomson optical depth: T ' n e (r) T r ' 5 1 ṁ r s r 1/2 ) optically-thin for low accretion rates. 8

5 Kinematics of Compton Scattering Scattering of photon o an electron at rest; withmomentum4-vector(e/c,~p) notation: Initial and final four momentum of photon: Pi = h i c (1,~n i), P f = h f c (1,~n f) Initial and final four momenta of electron: Qi = m e (c, 0), Q f = f m e (c, ~v f ) scattered photon n i n f incident photon e - recoil Energy and momentum conservation: Pi + Q i = P f + Q f ) Q 2 f =( P i + Q i Pf ) 2 = P 2 i + Q 2 i + P 2 f +2 P i Qi 2 P i Pf 2 Q i Pf 9

With Q 2 = Q Q = 2 m e c 2 2 m e v 2 = m e c 2 and P 2 =0: ) P i P f = Q i ( P i Pf ) or: With ~n i ~n f =cos : h i h f c 2 (1 ~n i ~n f )=m e (h i h f ) h i f (1 cos ) =m e c 2 ( i f ) So that f = i 1+ h i m e c 2 (1 cos ) or in terms of wavelength with Compton wavelength = c/ : or f = i 1+ i m e c 2 (1 cos ) f i = h m e c (1 cos ) =: c (1 cos ) 0 c := h/m e c =2.426 10 10 cm. Note: f > i for all angles ( 6= 0),photonsalwayslosesenergy. 10

Fractional energy change: averaging over,withtaylorexpansionforh i m e c 2 (=Thomson regime): := h h i = f i i ' 1 i apple i 1 h i m e c2[1 cos ] i = h i m e c 2 [1 < cos >] = h i m e c 2 1 Compton scattering: Scattering of photon o an electron accompanied by energy transfer (decrease in photon energy). Thomson scattering: in regime h i m e c 2,transfersmall,scatteringalmost elastic ( i = h i = h f = f ), Thomson cross-section applies (initial and final wavelength quasi identical). Klein-Nishina scattering: in regime h i >m e c 2 transfer large, scattering deeply inelastic, needtousecross-sectionderivedfromqed. 11

6 Klein-Nishina Formula General formula for di erential cross-section derived by Klein & Nishina 1929 based on QED: d d = 3 2 f i 16 T + f sin 2 i f i with = h and f = i /(1 + i [1 cos ]) (kinematics). d /d measures mc 2 probability that photon gets scattered into angle. If i ' f (for i m e c 2 ) Thomson regime: d d! 3 16 T 1+[1 sin 2 ] = 3 16 T 1+cos 2 = d d T homson,unpolarized Note: Principal e ects is to reduce cross-section from classical value increases. T as energy Increased forward-scattering with increasing energy. At small energies, crosssection is forward-backward (, + ) symmetric. 12

d /d [m 2 /sr] Thomson limit: Wiki

7 Total Compton Cross-section Integration over solid angle gives total cross-section: = 2 =... = 3 4 where Z T 0 d sin d d apple 1+x 2x(1 + x) x 3 1+2x ln(1 + 2x) + 1 2x ln(1 + 2x) 1+3x (1 + 2x) 2 x h i m e c 2 Limits: (x) ' T (1 2x +...) for x 1 (Thomson) (x) ' 3 1 8 T ln 2x + 1 for x 1 (extreme KN) x 2 14

1 asymptotics! T! KN /! T 0.1 0.001 0.01 0.1 1 10 E/m e c 2 Figure 1: Total Compton cross-section as a function of normalized photon energy x = h i /m e c 2 along with asymptotics to high energies. 15

8 Inverse Compton Scattering If electron moves with velocity v (lab. frame K), energy can be transferred from electron to photon = Inverse Compton Scattering (ICS). In electron rest frame K 0,previousresultholds(writtenintermsofrest-frame variables = primed), e.g.: 0 0 apple i f = 1 1+ 0 i m e c 2 (1 cos 0 ) with 0 scattering angle in K 0, i 0, 0 f propagation directions: ' 0 i cos 0 =cos 0 i cos 0 f +sin 0 i sin 0 f cos( 0 i 0 i m e c 2(1 cos 0 ) polar angles between electron and photon 0 0 where i, f azimuthal angles of incident and scattered photon in electron rest frame [ERF], noting that cos 0 = ~n 0 f ~n 0 i and in spherical coordinates ~n 0 i = (cos i 0, sin 0 i cos 0 i, sin i 0 sin 0 i )withcos(a b) =cosa cos b +sinasin b etc. Last relation on rhs in energy eq. valid in Thomson regime. 0 f) 16

Photon energies s in K 0 and K are related by Doppler formula i = D 0 i $ 0 i = i (1 cos i ) (1) f = 0 f (1 cos f ) = 0 f (1+ cos 0 f) (2) where D =1/( [1 cos ]), = v/c, =1/ p 1 v 2 /c 2. Thomson regime for 0 i m ec 2,i.e., i m e c 2 / Limits: (1) for i =0(photonapproachesfrombehind): 0 i = i (1 )! i /[2 ]. (2) for i = (head-on collision): 0 i = i (1 + )! 2 i ) Maximum energy in Thomson regime (using equation (2) above): f,max =2 0 f =2 0 i =4 2 i. ) in Klein-Nishina regime: f,max < m e c 2 + i m e c 2 (energy conservation). 17

Alternatively, usingaberration formula (lecture 4): cos 0 i,f = cos i,f 1 cos i,f Isotropic distribution in lab. frame K: halfthephotonshave i between (headon) and /2. ) in electron rest frame K 0, cos 0 i = for i = /2. ) For relativistic electrons ( ' 1), most photons are close to head-on in ERF. In Thomson regime: for 0 i m ec 2, 0 i = 0 f f = 2 i (1 cos i )(1 + cos 0 f)= 2 i (1 cos i ) = 2 i (1 cos i ) (1 cos f ) (1 2 )= i (1 cos i ) (1 cos f ) with eqs. (1),(2) before: 1+ cos f 1 cos f For head-on scattering i = and f =0(photonsturnsaroundafterscattering), f,max i = (1 + ) (1 ) = 2 (1 + ) 2 ' 4 2. 18

Summary: Scattered photon energy in lab frame: f ' ( 2 i, i m e c 2 / Thomson regime m e c 2, i m e c 2 / Klein Nishina limit 19

Figure 2: 2 -energy boost in Thomson regime as a result of relativistic beaming. Top left: Electron moving with velocity v in lab frame, incoming photons are isotropically distributed. Top right: Incoming photons as seen in the rest frame of the electron. They are now highly anisotropic, electron sees them as nearly head-on, their typical energies are boosted by a factor. Bottom left: Photons after scattering in electron rest frame. They are approximately isotropic and have roughly the same energy (Thomson regime) they had before being scattered. Bottom right: Scattered photons as seen in the lab-frame. They are now again highly collimated, with their typical energies boosted by a further factor, so that in lab-frame the overall energy is boosted by a factor 2 [Credits: N. Kaiser].

2 Single Particle Power radiated in Inverse Compton Scattering Total power emitted by an electron exposed to some photon field n ph ( ): Thomson regime ( h i m e c 2, 0 = 0 f )-scattered power in e -rest frame K0 : de 0 Z = dt 0 T curad 0 = T c n 0 ph( 0 ) 0 f( 0, 0 ) d 0 with n 0 ph ( 0 )d 0 =numberdensityofincidentphotonswithenergyind 0. Recall 1: de 0 /dt 0 = de/dt = Lorentz invariant (lecture 4). Recall 2: Phase space distribution f(x, p) := dn d 3 ~xd 3 ~p = f 0 (x 0, p 0 )=invariant. Let n ph ( )d := f ph (x, p)d 3 p,usethatd 3 p transforms same as energy (lecture 4): ) n ph( )d = n0 ph ( 0 )d 0 0 =Lorentzinvariant. Thus, with Doppler shift 0 = (1 cos ) andthomson 0 f = 0 : U 0 rad := Z 0 n 0 ph( 0 )d 0 = Z 02n0 ph ( 0 )d 0 0 = Z 02n ph( )d = Z 2 2 (1 cos ) 2n ph( )d 3

Assuming isotropic incident radiation field, angle average gives Z 1 1 cos ) 2 1(1 2 d cos = 1 Z 1 2 cos + 2 1(1 2 cos 2 ) d cos = 1 2+ 2 2 3 so Urad 0 = 2 1+ 2 /3 U rad Angle-averaged Compton scattered power (lab. frame) [erg/s]: de dt = de0 = dt 0 T curad 0 = T c 2 2 1+ U rad 3 Energy lost by electron = IC power =scatteredpowerminus incoming power: de e dt = P IC = T c(urad 0 U rad )= T c 2 + 1 2 2 1 U rad = 4 3 3 with 2 1= 2 2. Notes: (1) Total P IC in Thomson regime is independent of input photon spectrum. (2) Number of photons scattered per unit time dn s /dt = T cu rad /(h i ) ) Average energy increase (Thomson regime) via P IC =<h f >dn s /dt: 2 2 2 T cu rad =1+ 3 2 P IC =<h f > T c U rad h i! = 4 3 2 2 T cu rad ) < f >= 4 3 2 2 i 4

Notes: If energy transfer in K 0 is not neglected (general KN case), Blumenthal and Gould (1970) showed that for incident isotropic photon distribution de e dt = P IC = 4 3 2 2 T cu rad apple 1 63 < 2 i > 10 m e c 2 < i > with < i >= R i n ph ( i )d i /( R n ph ( i )d i )etcaveragesoverincidentphoton spectrum (spectrum now matters). ) Energy can be given or taken from electron. For power-law electron number distribution N e ( )=C p between min apple apple max,totalthomson IC power [erg/s] for 1: Z dee P tot = dt ( ) N e( )d = 4 C 3 T 3 p 3 p U rad max min 3 p For thermal distribution of non-relativistic electrons (< 2 >=3kT/m e c 2, ' 1): 4kT P tot = c m e c 2 T N e U rad [erg s 1 ] 5

3 Inverse Compton Cooling Timescale Electron cooling timescale due to ICS for isotropic incident radiation field in Thomson regime: t cool = E e de e /dt = m ec 2 P IC ' 3 10 7 1 U rad [cgs] sec. Electron cooling timescale in general case: useknformulaabove. ) analytical approximation for isotropic electrons and photons: Moderski et al. (2005): Energy Loss Rate: with: where de e dt F KN := 1 U rad f KN (x) ' = 4 3 c T Z i,max i,min 2 U rad F KN f KN (x) i n ph ( i )d i 1 (1 + x) 1.5 for x := 4 i m e c 2 < 10 4 6

and U rad = R i,max i,min i n ph ( i )d i =totalenergydensityinincidentfield. ) in KN regime the cooling timescale increases as some function of! 1 0.1 log F KN (x) 0.01 0.001 0.0001 0.01 0.1 1 10 100 log x Figure 1: Compton weighting function F KN (x) formono-energeticphotonfield. Atlow(x 1) energies, Thomson regime applies (F KN ' 1). In KN regime (x 1), radiated power is much reduced due to reduction in cross-section. Note: In principle, energy losses in the KN regime are not continuous, but catastrophic (electron loses significant fraction of its energy in a single interaction), yet noted approximation still turns out to be useful for many cases. 7

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback