Maser Discoveries with the SKA Steve Goldman 12 April, 2016 Cavendish Laboratories.

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Presentation transcript:

Maser Discoveries with the SKA Steve Goldman 12 April, 2016 Cavendish Laboratories

AGB and RSG Masers SED fitting Mass loss The impact of the SKA

Asymptotic Giant Branch Stars Understanding the mass loss and dust contribution of AGB and RSG to the ISM

AGB lose 50-80% of mass Up to solar masses per year AGB stars may be the largest collective producers of dust in the universe

Regeneration of the universe

64 m

6 x 22 m dishes longest baseline 6 km

Wood et al. (1992) Marshall et al. (2004)

Wood et al. (1992) Marshall et al. (2004)

Metallicity and Luminosity Galactic: >2000 LMC: 8 SMC: 0 GCs: 0 Marshall et al. (2004)

Metallicity and Luminosity Galactic: >2000 LMC: 8 5 SMC: 0 GCs: 0 Marshall et al. (2004)

Awarded 92 hours Four new OH masers Doubled the number of reliable Vexp

0 masers

Metallicity and Luminosity Galactic: >2000 LMC: 12 SMC: 0 GCs: 0 Goldman et al. (in prep)

Metallicity and Luminosity Galactic: >2000 LMC: 12 SMC: 0 GCs: 0 ν exp ∝ ψ 1/2 L 1/4 Goldman et al. (in prep)

Metallicity and Luminosity Galactic: >2000 LMC: 12 SMC: 0 GCs: 0 ν exp = 0.13 ψ 1/2 L 0.4 ν exp ∝ ψ 1/2 L 1/4 Goldman et al. (in prep)

Metallicity and Luminosity Galactic: >2000 LMC: 12 SMC: 0 GCs: 0 ν exp ∝ ψ 1/2 L 1/4 Scaled to galactic samples Goldman et al. (in prep) ν exp = 0.13 ψ 1/2 L 0.4

Spectral Energy Distribution (SED) Fitting

Goldman et al. (in prep)

Photometry from: 2MASS, DENIS, MSX, AKARI, IRAS, Spitzer Spitzer phot and Spitzer (IRS) spectra Best fit DUSTY spectra: dotted line Blue within 95% confidence Goldman et al. (in prep)

Luminosity Expected expansion velocity Mass loss rate Goldman et al. (in prep) Photometry from: 2MASS, DENIS, MSX, AKARI, IRAS, Spitzer Spitzer phot and Spitzer (IRS) spectra Best fit DUSTY spectra: dotted line Blue within 95% confidence

Luminosity Expected expansion velocity Mass loss rate OH Expected gas-to- dust Goldman et al. (in prep) Photometry from: 2MASS, DENIS, MSX, AKARI, IRAS, Spitzer Spitzer phot and Spitzer (IRS) spectra Best fit DUSTY spectra: dotted line Blue within 95% confidence

Luminosity Expected expansion velocity Mass loss rate OH Expected gas-to- dust Goldman et al. (in prep) Photometry from: 2MASS, DENIS, MSX, AKARI, IRAS, Spitzer Spitzer phot and Spitzer (IRS) spectra Best fit DUSTY spectra: dotted line Blue within 95% confidence

LMC 380< R gd,expected < 540R gd,median ≈

LMC DUSTY output from OH maser 380< R gd,expected < 540R gd,median ≈

380< R gd,expected < 540R gd,median ≈ LMC from OH maser DUSTY output

380< R gd,expected < 540R gd,median ≈ LMC from OH maser DUSTY output

380< R gd,expected < 540R gd,median ≈ 405 LMC from OH maser DUSTY output

380< R gd,expected < 540R gd,median ≈ 405 LMC from OH maser DUSTY output

380< R gd,expected < 540R gd,median ≈ 405 LMC from OH maser DUSTY output

IRAS ? faster bi-polar outflows 17 km/s Predicted 4.8 km/s

Goldman et al. (in prep)

Mass loss Reimers 1975 Schroder & Cuntz 2005 Baud & Habing 1983 Zijlstra et al van Loon 2005

Goldman et al. (in prep)

< 1 km/s spectral resolution long baselines/high angular resolution zoom bands (1420, 1612, 1665, 1667, 1720, 2100 MHz)

The LMC RSG: IRAS

Conclusions Discovered 4 new circumstellar OH masers Increased the number of reliable wind speeds from 5  12 Developed a method of deriving gas-to-dust ratios (needs testing) Continue to see a strong dependence on both metallicity and luminosity of expansion velocity See a strong correlation between luminosity and mass loss Gas-to-dust ratio has shown to have little effect on the mass loss of AGB and RSGs This suggests that mass loss is (nearly) independent of metallicity between a half and twice solar

ν exp ∝ ψ 1/2 L 1/4

S. Höfner