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Transcript of FORMATION AND EVOLUTION OF PLANETARY SYSTEMS: PROBING INITIAL CONDITIONS AND OUTCOMES WITH E-ELT...
![Page 1: FORMATION AND EVOLUTION OF PLANETARY SYSTEMS: PROBING INITIAL CONDITIONS AND OUTCOMES WITH E-ELT Michael R. Meyer Institute for Astronomy Department of.](https://reader035.fdocuments.in/reader035/viewer/2022081514/56649e015503460f94aea585/html5/thumbnails/1.jpg)
FORMATION AND EVOLUTION OF PLANETARY SYSTEMS:PROBING INITIAL CONDITIONS AND OUTCOMES WITH E-ELT
Michael R. Meyer
Institute for Astronomy
Department of Physics
(and many, many, others)
HARMONI Early Science, Oxford, 2 July, 2015
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What we need to explain…
Pepe, Ehrenreich, & Meyer, 2014, Nature, V513, 358
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Collapsing Cores & Specific Angular Momentum
Williams & Cieza (2011) ARAA; see also Belloche (2013)
Time
M(accr)
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Structure of Protostellar Disks
From M. Meyer, Physics World, November, 2009 Based on Dullemond et al. (2001) with artwork from R. Hurt (NASA)
1 AU 100 AU
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JWST/ELT Complementary Capabilities
Physical Resolution: 15 pc 50 pc 150 pc 450 pc JWST 1.65 m 1 AU 3 AU 10 AU 30 AU 10 m 7 AU 20 AU 60 AU 180 AU ELT 1.65 m .2 AU .5 AU 1.5 AU 5 AU 10 m 1 AU 3 AU 10 AU 30 AU
Spectral Resolution : R = 100 (molecular features) JWST R = 1000 (atomic features) JWST R = 10,000 (30 km/sec) ELT R = 100,000 (3 km/sec) ELT
Field of View: 2’ (star clusters within 1 kpc) JWST 1.5” (circumstellar disk at 150 pc) ELT
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METIS Instrument Baseline
Imaging at 3 – 19 μm. with low/medium resolution slit spectroscopy as well as coronagraphy for high contrast imaging.
High resolution (R ~ 100,000) IFU spectroscopy at 3 – 5 μm, including extended instantaneous wavelength coverage.
Work at the diffraction limit with single conjugate (SC) and eventually assisted by a laser tomography adaptive optics (LTAO) system.
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Instrument Concept
Common Fore-Optics
AO Wavefront Sensor
Imager
IFU Spectrograph
Warm Calibration Unit
as well as Q!
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LM band
N band
(SC)AO Performance
D=39m, V=6 guide star, 100 Hz closed loop
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Probing Planet-Forming Disks from 1-1000 m
Follette et al. (2015), van der Marel et al. (2013); METIS/MICADO/ALMA Science
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Inner CO Gas vs. Outer Dust Continuum:
Pinella et al. (2015); Pontoppidan et al. (2008); METIS/HARMONI Science
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(Multiple) Planet Forming Disks: HD 100546
L-band Scattered Light Spectro-astrometry with CRIRES
Avenhaus et al. (2014) Brittain et al. (2014)
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(Multiple) Planet Forming Disks: HD 100546
Not yet detected in K-band (Quanz et al. 2013; 2015b)
and there are other examples…
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Direct Detection (and Characterization) of Circumplanetary Disks
Quanz et al. (2015b); METIS/HARMONI/MICADO Science
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Direct Detection of Thermal Emission for Planets of Known Mass with E-ELT: Calibrating the Models
RV+Gaia follow-up requires imaging photometry and IFU spectroscopy!Quanz et al. (2015a); METIS/MICADO/HARMONI Science
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Phenomenological Planet Populations:
RV Data
CA
GI
Benz et al. (2014); Galvagni & Mayer (2014); Forgan & Rice (2013)
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Direct (Non-) Detections of Gas Giant Planets
Few massive planets at large orbital radii.
[>3 Mjup @ > 50 AU]
dN/da ~ a
Lafrenerie et al. (2007);
Nielssen & Close (2009);
Heinze et al. (2010);
Chauvin et al. (2010);
Delorme et al. (2011);
Vigan et al. (2012); Reggiani et al. (submitted); SPHERE+ERIS
NACO-LP: Chauvin et al. (2014)
Not good for GI
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DIRECT IMAGING: DISRUPTING PLANET FORMATION THEORY WITH THE E-ELT
a.Start with a fit to RV distributions (Cumming et al. 2008) with brown dwarf companions (Reggiani et al. submitted)
b.Evidence for dependence of Co, planet frequency over range of mass and orbital radius, on stellar mass (Johnson et al. 2010; Clanton et al. 2014).
c.Initial conditions (and theory) suggest dependence on ratio of planet mass to star mass.
d.RV/micro-lensing/Imaging consistent with log-normal surface density peaking at 10 AU (Meyer et al. in prep).
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METISThe Survey:75 G stars< 50 pc< 300 Myr
HARMONIFollow-upRequired!
10 20 30 40 50 Separation (AU)
10 20 30 40 50 Separation (AU)
Log
(Ju
pit
er M
ass)
-
0.5
0.0
0.
5
1
.0
1.5
Log
(Ju
pit
er M
ass)
-
0.5
0.0
0.
5
1
.0
1.5
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High Resolution Spectra of Brown Dwarfs and Planets:METIS/HARMONI Characterization Science
Brown dwarf doppler imaging with CRIRES Wind speeds on planets with CRIRES Crossfield et al. (2014) Snellen et al. (2014)
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Star Clusters, Disks, & Planets: E-ELT Opportunities
SYNERGIES
=> Building on legacy of VLT: E-ELT, JWST, and ALMA.
=> METIS and first-light instruments HARMONI & MICADO.
STAR CLUSTERS => Resolved IMFs within 10 Mpc.
DISKS
=> E-ELT will resolve planet-forming disks (gas and dust) inside 10 AU.
=> Spectro-astrometry: of what are forming planets in disks made?
=> E-ELT will detect planets in formation (and circumplanetary disks).
PLANETS
=> Direct detection of planets with known mass (constrain models).
=> Collide planet formation theory with planet populations vs. stellar mass.
=> Characterize gas giant planets, including phase maps, and weather!
=> Possible to image (and characterize) a handful of super-earths.
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BACKUP SLIDES
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MMT-AO 6.5m PSF Simulated Trapezium Observations R(Sky Noise) = 1 Rc = 0.2 pc from Close et al. 2003. using Hillenbrand & Carpenter (2000). Hcomp(at Rc) < 24 mag
R(sky noise) = 2.5 Rc = 0.5 pc R(Sky Noise) = 4 Rc = 0.8 pc R(Sky Noise) > 20 Rc = 4-5 pc Hcomp(at Rc) < 17.8 mag. Hcomp(at Rc) < 15.3 mags. Core Radius not resolved.
25 kpc 50 kpc 0.5 Mpc
5 kpcPSF 0.5 kpc
Resolved Stellar Pops: HARMONI/MICADO @ Confusion Limit
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Primordial Disk Evolution: A Scenario…
Williams & Cieza ARAA (2011); Effects of Photoevaporation? Ercolano et al. (2015)
Few AU
Volatiles(Ciesla et al; Banzatti et al.)
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Typical Disk ParametersParameter Median ~1σ Range
Log(M(disk)/M(star))[all ~1 Myr] [detected disks only]
-3.0 dex-2.3 dex
±1.3 dex±0.5 dex
Disk lifetime 2-3 Myr 1-6 Myr
Temperature power law [T(r)~r-q]
0.6 0.4-0.7
Taken from (or interpolated/extrapolated from):
Muzerolle et al. (2003), Andrews & Williams (2007), Hernandez et al. (2008), Isella et al. (2009)
Parameter Median ~1σ Range
R(inner) 0.1 AU ~0.08-0.4 AU
R(outer) 200 AU ~90-480 AU
Surface density power [Σ(r) ~ r-p] [Hayashi min. mass nebula][steady state viscous α disk]
0.61.51.0
0.2-1.0(predicted)(predicted)
Surface density norm. Σo (5AU)
14 g cm-2 ±1 dex
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Circumplanetary Disk Detection with ALMA (mm grains)
From Pineda et al. Cycle 3 Proposal (submitted)
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CA Phenomenology: Planet Masses and Orbits
Solid growth time: tp ~ Rp rp / [ d x d]
with d ~ M*/a and d~ sqrt(M*/a3)
tp ~ a5/2/ [M*3/2] cf. gas disk lifetime td ~ 1/M*
Given aouter, there is a timescale td ~ 1/M* giving Rp.
aouter ~ [td M*3/2]2/5 ~ M*
1/5
Very hard to form critical mass core beyond 10s of AU (all stars).
If Mp set by disk accretion: Mp ~ [dMacc/dt ] td ~ M*2 x (1/M*) ~ M*
Planet Mass linearly related to star mass.
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GI Phenomenology: Planet Masses and Orbits
Toomre Parameter: Q ~ cs(a) / G(a)
with d ~ M*/a, d~ sqrt(M*/a3), and cs ~ sqrt(T) ~ (M*/a)1/4
Q ~ 1/ [M*1/4 a3/4]
Depends “weakly” on stellar mass, more strongly on radius. For typical disk parameters, should operate > 50 AU.
Typical fragment mass would be ~ cs4/(a) ~ 5 Mjupiter.
Massive planets, beyond 50 AU, independent of stellar mass.
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Companions to Stars: Brown Dwarfs and Planets
Reggiani et al. (2011; 2013; 2015); Sahlman et al. (2011)
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Meyer, Reggiani, & Quanz (in preparation)
Co ~ M*
Mp/M*
Planet Populations versus Stellar Mass:
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Can ELTs Directly Image Super-Earths?
Hinz et al. (2010), Quanz et al. (2015) and the METIS Science Team