Unraveling the Origin of Overionized Plasma in the Galactic Supernova Remnant W49B

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Transcription:

Unraveling the Origin of Overionized Plasma in the Galactic Supernova Remnant W49B Sarah Pearson (University of Copenhagen) 3 January 2013 In collaboration with: Laura A. Lopez (MIT), Enrico Ramirez-Ruiz (UCSC), Daniel Castro (MIT), Hiroya Yamaguchi (CfA), Patrick Slane (CfA), Randall Smith (CfA)

Outline Introduction to supernova remnants and project How do supernova remnants (SNRs) get overionized? Methods for analysis of W49B Electron temperature, Te Ionization temperature, Tz Results from project

Supernovae The death of certain stars They come in two types: Core-collapse supernovae (Type Ib/Ic and Type II) M > 8 M_sun Thermonuclear explosions (Type Ia)

Supernovae The death of certain stars 10 44 J They come in two types: Core-collapse supernovae (Type Ib/Ic and Type II) M > 8 M_sun Thermonuclear explosions (Type Ia)

Supernova remnants (SNRs) Interaction of supernova ejecta with surrounding medium SNRs provide knowledge of redistribution of elements in Interstellar medium (ISM) & circumstellar medium (CSM) the Universe SNRs are extremely complex and diverse objects

Galactic SNR W49B Most luminous supernova remnant in x-rays Ejecta dominated ~ young remnant (1000 years) Complex morphology Shows overionization features Ions stripped of more electrons than expected Lopez et al. (2012)

We present...... first spatially-resolved analysis of plasma conditions in W49B Using a 220 ks observation from NASA s Chandra X-ray Observatory Pearson et al. (2013)

Ionization Supernova remnants are normally underionized: Disperse medium ~ low densities Only excitation/ionization through collisional excitation of ions with electrons Long timescale for electrons to collisionally ionize ions Ions are not stripped of as many electrons as we would expect

ktz VS kte Electron temperature, kt e: Actual kinetic energy of electrons and ions Kawasaki et al. (2005)

ktz VS kte Electron temperature, kt e: Actual kinetic energy of electrons and ions Ionization temperature, kt z: Kawasaki et al. (2005)

ktz VS kte Electron temperature, kt e: Actual kinetic energy of electrons and ions Ionization temperature, kt z: To what extent are the ions ionized, how many electrons are they stripped of? Kawasaki et al. (2005)

ktz VS kte Electron temperature, kt e: Actual kinetic energy of electrons and ions Ionization temperature, kt z: To what extent are the ions ionized, how many electrons are they stripped of? Collisional ionization equilibrium (CIE): Kawasaki et al. (2005)

ktz VS kte Electron temperature, kt e: Actual kinetic energy of electrons and ions Ionization temperature, kt z: To what extent are the ions ionized, how many electrons are they stripped of? Collisional ionization equilibrium (CIE): kt e = ktz Kawasaki et al. (2005)

ktz VS kte Electron temperature, kt e: Actual kinetic energy of electrons and ions Ionization temperature, kt z: To what extent are the ions ionized, how many electrons are they stripped of? Collisional ionization equilibrium (CIE): kt e = ktz Excitations balanced by de-excitations Kawasaki et al. (2005)

How to get overionized young supernova remnants Higher densities => shorter time to reach collisional ionization equilibrium (CIE) CIE followed by rapid cooling of electrons t recombination > tcooling => overionized plasma Kawasaki et al. (2005)

How to get overionized young supernova remnants Higher densities => shorter time to reach collisional ionization equilibrium (CIE) CIE followed by rapid cooling of electrons t recombination > tcooling => overionized plasma Kawasaki et al. (2005) kt e < ktz

Cooling mechanisms Cooling through adiabatic expansion Cooling through thermal conduction

Cooling mechanisms Cooling through adiabatic expansion Cooling through thermal conduction tcooling < trecombination

Cooling mechanisms Cooling through adiabatic expansion Cooling through thermal conduction tcooling < trecombination Examining the overionization features helps us determine, what physical mechanisms are important

Overionization in W49B Collision with molecular cloud in left part Thermal conduction Free expansion in right part Adiabatic expansion Lopez et al. (2012)

Overionization in W49B Collision with molecular cloud in left part Thermal conduction Free expansion in right part Adiabatic expansion Lopez et al. (2012)

Disposition Introduction to supernova remnants (SNRs), x-ray astronomy and project How do we get overionized SNRs? Methods for analysis of W49B Electron temperature Ionization temperature Results from project

Measuring electron Model spectra for 56 and 13 different regions XSPEC - modeling of plasma temperature East West 550 500 450 400 350 300 250 200 150 East West 2 1.8 1.6 1.4 1.2 1 0.8 0.6 kte (kev) 100 0.4 For each region the best fit electron temperature is notified East West 50 450 400 350 300 250 200 50 100 150 200 250 300 350 400 450 500 550 East West 0.2 0 2 1.8 1.6 1.4 1.2 1 0.8 kte (kev) 150 0.6 100 0.4 50 0.2 50 100 150 200 250 300 350 400 450 500 0

Measuring electron Model spectra for 56 and 13 different regions XSPEC - modeling of plasma temperature For each region the best fit electron temperature is notified kte (kev) Pearson et al. 2013

Measuring electron Model spectra for 56 and 13 different regions temperature XSPEC - modeling of plasma For each region the best fit electron temperature is notified Temperature gradient kte (kev) Pearson et al. 2013

Measuring Tz from line ratios Use parameters from plasma model Fit Gaussians to H-like and Helike lines of S, Ar and Ca Calculate the flux ratio Derive ionization temperature, ktz, from flux ratio Ozawa et al. 2009

Measuring Tz from line ratios Use parameters from plasma model Fit Gaussians to H-like and Helike lines of S, Ar and Ca Calculate the flux ratio Derive ionization temperature, ktz, from flux ratio Ozawa et al. 2009

Measuring Tz from line ratios Use parameters from plasma model Fit Gaussians to H-like and Helike lines of S, Ar and Ca Calculate the flux ratio Derive ionization temperature, ktz, from flux ratio Ozawa et al. 2009

Results ktz/kte Sulfur Argon Calcium ktz / kte Pearson et al. 2013

Results ktz/kte Overionization features more prominent in right part of remnant Sulfur Argon Calcium ktz / kte Pearson et al. 2013

Results ktz/kte Overionization features more prominent in right part of remnant Supports cooling from adiabatic expansion Sulfur Argon Calcium ktz / kte Pearson et al. 2013

Results ktz/kte Sulfur Argon Calcium ktz / kte Pearson et al. 2013

Results ktz/kte Overionization features more prominent in the heavier elements Sulfur Argon Calcium ktz / kte Pearson et al. 2013

Results ktz/kte Overionization features more prominent in the heavier elements Due to different radiative recombination timescales (RRC) for heavier elements Sulfur Argon Calcium ktz / kte Pearson et al. 2013

Results ktz/kte Overionization features more prominent in the heavier elements Due to different radiative recombination timescales (RRC) for heavier elements Timescales: RRCSulfur < RRCArgon < RRCCalcium Sulfur Argon Calcium ktz / kte Pearson et al. 2013

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