lecture 4 turbulence and magnetic fields in molecular...
TRANSCRIPT
![Page 1: Lecture 4 Turbulence and Magnetic Fields in Molecular Cloudsastro1.physics.utoledo.edu/~megeath/ph6820/lecture4_ph6820.pdf · J = 6 pc M J = 450 Msun (cloud size) For n(H 2) = 100](https://reader034.vdocument.in/reader034/viewer/2022052008/601cf968708ca92366160575/html5/thumbnails/1.jpg)
Lecture 4Turbulence and Magnetic
Fields in Molecular Clouds
Herschel Image of the Rosette Cloud
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Molecular Cloud PropertiesComposition: H2, He, dust (1% mass), CO (10-4 by number), and many other molecules with low abundances.
Sizes: 10-100 pc
Masses: 10 to 106 Msun. Most of the molecular gas mass in galaxies is found in the more massive clouds.
Average Density: 100 cm-3
Gas Temperature: 10-30 K
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Review: Properties of Molecular Clouds
3Heyer et al. 2009
Virial
BoundNote: alpha may be underestimated if clouds are centrally condensed
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The Stability of Clouds: Jeans Instability
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Are Clouds Stable to Fragmentation?For n(H2) = 40 cm-3 λJ = 6 pc MJ = 450 Msun (cloud size)
For n(H2) = 100 cm-3 λJ = 4. pc MJ = 350 Msun (cloud size)
For n(H2) = 1000 cm-3 λJ = 1.2 pc MJ = 100 Msun (clump size)
From clouds in the inner galaxy from Heyer et al. 2009
Cloud masses and lengths exceed Jeans length masses.
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Typical cloud efficiencies are a few percent for molecular clouds
From Evans et al. 2009
Star Formation Efficiency
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Typical cloud efficiencies are a few percent for molecular clouds
From Evans et al. 2009
Star Formation Efficiency
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Lifetimes of Nearby Clouds
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Converging Flows
H2
HI fl
ow (f
rom
bub
ble
as e
xam
ple)
Heitsch et al. In press
HI fl
ow (f
rom
bub
ble
as e
xam
ple)
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The Destruction of Molecular Clouds
M16
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What Drives the Colliding Flows?
11N44 Superbubble in LMC
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The Virial Theorem for Molecular Clouds
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Virial Theorem with External Pressure
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Comparing the internal and external pressure of molecular clouds
• A self gravitating gas with AV > 2 has an internal pressure of P/k > 2 x 104 cm-3 K.
• P/k = 100 cm-3 σ2 μ mH = 3 x 104 cm-3 K (σ = 1 km s-1)
• Typical external ISM gas pressure is P/k = 2 x 104 cm-3 K
• Molecular clouds with AV > 2 and n > 100 cm-3 are not pressure confined. 14
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Could a thermally supported cloud be stable?
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Could a thermally supported cloud be stable?
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Could a thermally supported cloud be stable?
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M = 104 MsunTK = 20 K (cs = 0.25 km s-1)=> Rcrit = 200 pc
But most clouds are much smaller. Also, considering only thermal motions α = |Ω/K| ~6 - thus not virialized
Furthermore Jeans criterion means that clouds are unstable to fragmentation
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Timescales• Star formation lifetime < 5 Myr
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t = length/σ
Star formation timescale comparable to cloud free-fall time and larger than crossing time.
Star formation time > cloud free-fall time. This suggest some sort of support.
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Could Magnetic Fields Support Clouds?
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Magnetic Fields in Galaxies
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Magnetic field Orientation in
the Orion Molecular
Cloud
Polarization of emission from grains at 850 microns. Polarization perpendicular to B
Matthews 2001 ApJ 562, 400.
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Could Magnetic Fields Support Clouds?
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Could Magnetic Fields Support Clouds?
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What is the mass to flux ratio?
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B can be measured by the Zeeman effect to OH or HI
N(H2) can be measured my molecular line or extinction measurements
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The data: are molecular clouds supercritical or subcritical?
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Diffuse ISMSub-Critical
Molecular Clouds: Critical
Critical
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The data: are molecular clouds supercritical or subcritical?
• Current consensus is that magnetic fields do not provide support against collapse.
• This makes some sense, if magnetic fields dominated, then the clouds would expand.
• However, there are significant uncertainties in the data.
• However, magnetic fields may be strong enough to play some role in cloud evolution, this is an area of intense research.
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Can Turbulence Stabilize Clouds?
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Kinematics and Morphology of Orion Cloud
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Turbulent Pressure
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Supersonic Motions in Clouds
Sound speed in molecular clouds
cs = (kT/μmH)1/2
cs = 0.25 km s-1 for T = 20 K
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Can Turbulence Stabilize Clouds?
• M = 104 Msunσ = 1km s-1
=> Rcrit = 12 pc• α = |Ω/K| ~1 (2 needed for virial)
• This looks good, but there could still Jeans fragmentation• Plus, turbulence may aid fragmentation (turbulent
fragmenation)
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Shock Waves
• Occur when two parcels of gas collide at supersonic velocities.
• Collision results in the compression of the gas. • In sub-sonic case, compression would result in
pressure (sound) waves.• Since motion is faster than speed of sound, a
dense layer of shock gas is produced.• If gas cools rapidly, then shock will dissipate
energy. 32
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Shock Waves
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Driven Turbulence
in a Periodic
Box
Frrom Paolo Padon’s website: http://cass246.ucsd.edu/~ppadoan/new_website/astrophysical.php
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Self-gravitating
turbulent gas with periodic
boundary condition
Density projection (column density?)
Paolo Padoan’s website: http://cass246.ucsd.edu/~ppadoan/new_website/astrophysical.php
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Cluster Formation in a Turbulent Cloud
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Can Turbulence Stabilize Clouds?
• The problem is that turbulence can decay rapidly.
• The decay timescale is a fraction of a crossing time.
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Kinetic Energy Decay
323 2563
ZEUShydro
weakMHD
SPHhydro
strongMHD
193703
ML,
Kle
ssen
, Bur
kert,
Sm
ith (1
998,
Phy
s. R
ev. L
ett.)
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Nakamujra & Li 2007
Outflow Driven TurbulenceSimulation of a cluster forming clump within cloud. Outflows from stars in cloud eject gas, gas falls back on clump and stirs the turbulence.
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Timescales• Star formation lifetime < 5 Myr
40
t = length/σ
Star formation timescale comparable to cloud free-fall time and larger than crossing time.
Star formation time > cloud free-fall time. This suggest some sort of support.
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What is the role of turbulence?
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• Decay of turbulence may happen, but perhaps decay on the order of a crossing time, which can be 10 Myr on the longest scale, is OK.
• Turbulence may delay collapse to more than one free fall time.
• Although turbulence may slow the collapse of the cloud, it will also enhance fragmentation and lead to the fragmentation of the gas into individual stars.
• Stars that are formed by turbulence can stir up gas (feedback), but will also destroy clouds
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Summary1. Molecular clouds are confined by gravity and not external
pressure.
2. Thermally supported clouds are unstable
3. Molecular fields are unlikely to stabilize cloud
4. Turbulence may support clouds on large scales, but cause fragmentation on much smaller scales.