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Calibraci

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Laboratorio de Astrof sica Espacial y F sica Fundamental ... Galaxies Starburst galaxies, ULIRGs. Star formation measured by. SFR: Star Formation Rate (Mo/yr) ... – PowerPoint PPT presentation

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Title: Calibraci


1
Calibración de trazadores de formación estelar
mediante modelos de síntesis


LAEFF-INTA Laboratorio de Astrofísica Espacial y
Física Fundamental
  • Héctor Otí-Floranes, J. M. Mas-Hesse M. Cerviño
  • SEA, Santander, 11 de julio de 2008

2
STARBURSTS
  • Regions of intense stellar formation
  • Galaxies ?? Starburst galaxies, ULIRGs
  • Star formation measured by
  • SFR Star Formation Rate (Mo/yr)
  • SFS Star Formation Strength (Mo)
  • We are interested in the youngest population
  • ? Massive stars
  • Different SFR tracers
  • UV
  • H? ionized gas
  • FIR heated dust
  • Mechanical energy ? X-rays
  • OII?3727

3
GOALS
  • Using synthesis models, study the evolution of
    magnitudes
  • FIR
  • NLyc
  • UV
  • Mechanical Energy
  • Others
  • Obtain SFR SFS calibrations for each of them
  • Calibrate the tracers metallicity, age, etc.

4
POPULATION SYNTHESIS MODELS
  • Initial population with Initial Mass Function
  • IMF(M)?? M-2.35 (M2-120 Mo)
  • Evolution of stars
  • Isochrones evolution of intrinsic properties
    (Teff, LBOL, etc.)
  • Libraries isochrones data ? measurable
    magnitudes (luminsities, colours, etc.)
  • SFR two types of models
  • EB (extended models, SFR) constant star
    formation
  • IB (instantaneous bursts, SFS) no further
    formation (usual age 4-6 Myr)
  • SBS Star Formation Strenght initial mass of the
    burst
  • Unless stated Zo
  • Age lt 250 Myr
  • Models used
  • CMHK02 (Cerviño, Mas-Hesse Kunth)
  • SB99 (Leitherer et al.)

5
IMF CORRECTION
  • Compare our calibrations with those from
  • Kennicutt (1998)
  • Salim et al. (2007)
  • But they consider M0.1-100 Mo (us M2-120 Mo)
  • Two-fold correction
  • SFR(0.1-100) 3.4135 SFR(2-120)
  • We include more massive stars. With SB99
    calculate the ratio when steady state is attained
    (lt30 Myr)
  • L1500/L15001.04
  • FIR/FIR1.16
  • NLyc/NLyc1.16

6
UV EMISSION 1
  • Direct tracer of star formation
  • But severely affected by extinction
  • L1500, L2000 and L3500 (U-band)
  • EB evolution
  • steep increase 0.7 dex in 4-5 Myr
  • slower raise 0.3 dex in ??250 Myr
  • Metallicity delay in stellar evolution
  • EB VERY LOW dependence, lt10 Z0.008
  • Good agreement with Kennicutt within 12 after 30
    Myr useful for ages gt 20 Myr
  • Disagreement with Salim 30 with respect to
    Kennicutt
  • Intrinsic difference between models 15
  • Variety of SFHs of sources of sample 10
  • Z0.016 5
  • Z of sample ? Salim value was expected to be
    between predictions of models with Z0.008-0.020

7
UV EMISSION 2
  • Metallicity delay in stellar evolution
  • IB MEDIUM dependence, 15-25 higher Z0.008 for
    L1500 and L2000
  • IB STRONG dependence, 15-65 for L3500

8
FIR EMISSION 1
  • We assume thermal equilibrium of dust
  • ? All energy absorbed is reemitted
  • Parameters
  • Cardelli et al. (1989) extinction law (RV3.1)
  • 30 ionizing photons 100 Ly?
  • E(B-V) colour excess E(B-V)0.1-1
  • Similar behaviour to UV radiation

Saturation for E(B-V)gt0.5 ? E(B-V)1
9
FIR EMISSION 2
  • Metallicity delay in stellar evolution
  • IB MEDIUM dependence, 25 higher Z0.008
  • EB VERY LOW dependence, lt11 Z0.008
  • Kennicutt (1998) lies within 15 after 100 Myr

Kennicutt only appropiate for long-lived (?100
Myr) starbursts
10
IONIZING PHOTONS 1
  • Photons with??lt912 Ã… can ionize H atoms
  • ? Balmer lines (among others)
  • Assume a fraction 1-f0.3 is absorbed by dust
    before ionization
  • Metallicity delay in stellar evolution
  • IB HIGH dependence, 0.2-0.4 dex higher for
    Z0.008
  • EB MEDIUM dependence, 25 higher Z0.008

EB attains rapidly the steady state
11
IONIZING PHOTONS 2
When considering 1-f0.3 in Kennicutt
  • Kennicutt value without correction
  • 50 higher than models
  • After correction
  • Models expressions agree
  • for ages gt 8 Myr

12
MECHANICAL ENERGY
  • Winds from massive stars and SNe inject
    mechanical energy into the medium
  • LK energy injected per unit of time
  • Dominance
  • Early ages winds
  • When massive stars comence to die SNe
  • Metallicity
  • When Z? ? power of winds ?, number of WR stars ?
  • IB HIGH dependence, 60 discrepancies with
    Z0.008
  • EB EXTREMELY LOW dependence in the stationary
    state (gt40 Myr) when compared to Z0.008

13
EB CALIBRATION
Scaled to SFR1 Mo/yr
14
IB CALIBRATION
Scaled to SFS1 Mo
15
CONCLUSIONS
  • Robust calibrations of SFR and SFS based on
    several tracers have been obtained using
    shynthesis models
  • Appropriate calibrations should be used depending
    on the burst properties
  • Star formation regime EB or IB VERY IMPORTANT
  • Age VERY IMPORTANT, especially in IB models
  • Metallicity negligible in EB models for UV and
    FIR
  • E(B-V), etc.
  • Calibrations from literature agree with our
    models
  • Kennicutt (1998)
  • UV good agreement at all ages gt 30 Myr
  • FIR applies only at ages gt 100 Myr
  • NLyc/H? after correction for prior dust
    absorption, at ages gt 8 Myr
  • Salim et al. (2007)
  • UV it underestimates SFR
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