1 / 5

PI Total time #CoIs, team

Low-mass brown dwarf formation in the Magellanic Clouds: A population long gone into obscurity in our neighbourhood

amelie
Download Presentation

PI Total time #CoIs, team

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Low-mass brown dwarf formation in the Magellanic Clouds: A population long gone into obscurity in our neighbourhood The Magellanic Clouds are the only nearby place where low-metallicity, very low-mass brown dwarfs are accessible to observation. And the ELT will be the only telescope reaching the depth and resolution needed to reveal them. PI Total time #CoIs, team Fernando Comerón 2n (ELT 42m) Not many people

  2. Scientific rationale Our Galaxy may have produced huge numbers of low metallicity, very low mass (a few MJup) brown dwarfs in its infancy –but they have faded beyond detection long since then: 10 MJup at 5 Gyr  MK = 30.5, H-K=-7.2 However, we can watch them forming now in the LMC and SMC –if they form at all! At K=28, Mlim = 6 MJup (1 Myr); 15 MJup (10 Myr); reachable in 2h at S/N>5 with a 42m ELT (similar times and limits for J, H). A low-mass star forming cloud is only ~2’’across at the LMC distance LTAO can yield nearly diffraction-limited image cores of the whole cluster, reach very deep, and overcome confusion.

  3. Immediate objectives • Observe low-mass SFR in the LMC and SMC. • Identify the lowest-mass objects from their position in color-color-magnitude diagrams. • Spectroscopy of the brightest candidates is possible • Compare mass functions to galactic, solar metallicity counterparts (we will know much more about those thanks to VISTA) • Extrapolate numbers over the history of the Milky Way: how abundant are old, low-metallicity low-mass brown dwarfs? • What if none is found? Is there a minimum mass threshold that depends on metallicity?

  4. ELT Justification: milliarcsecond-level resolution is needed down to K ~ 28. Legacy Value: Complete stellar and substellar IMFs in a low metallicity environment will be obtained. Data Reduction: Not particularly challenging from this point of view –crowded field photometry?

More Related