This book provides a modern introduction to the study of star formation, at a level suitable for graduate students or advanced undergraduates in astrophysics. The first third of the book provides a review of the observational phenomenology and then the basic physical processes that are important for star formation. The remainder then discusses the major observational results and theoretical models for star formation on scales from galactic down to planetary. The book includes recommendations for complementary reading from the research literature, as well as five problem sets with solutions.
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--> Contents:
Introduction and Phenomenology:
Observing the Cold Interstellar Medium
Observing Young Stars
Physical Processes:
Chemistry and Thermodynamics
Gas Flows and Turbulence
Magnetic Fields and Magnetized Turbulence
Gravitational Instability and Collapse
Stellar Feedback
Star Formation Processes and Problems:
Giant Molecular Clouds
The Star Formation Rate at Galactic Scales: Observations
The Star Formation Rate at Galactic Scales: Theory
Stellar Clustering
The Initial Mass Function: Observations
The Initial Mass Function: Theory
Protostellar Disks and Outflows: Observations
Protostellar Disks and Outflows: Theory
Protostar Formation
Protostellar Evolution
Massive Star Formation
The First Stars
Late-Stage Stars and Disks
The Transition to Planet Formation
--> --> Readership: Undergraduate and graduate students as well as researchers interested in astrophysics. -->
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•Dobbs, C. L., et al. 2014, in “Protostars and Planets VI”, ed. H. Beuther et al., pp. 3–26.
Suggested literature:
•Colombo, D., et al. 2014, ApJ, 784, 3.
We now begin our top–down study of star formation, from large to small scales. This chapter focuses on observations of the bulk properties of giant molecular clouds (GMCs), primarily in the Milky Way and in nearby galaxies where we can resolve individual GMCs. The advantage of looking at the Milky Way is of course higher resolution. The advantage of looking at other galaxies is that, unlike in the Milky Way, we can get an unbiased view of all the GMCs, with much smaller distance uncertainties and many fewer confusion problems. This allows us to make statistical inferences that are often impossible to check with confidence locally. This study will be a preparation for the next two chapters, which discuss the correlation of molecular clouds with star formation and the problem of the star formation rate.
8.1Molecular Cloud Masses
8.1.1Mass Measurement
The most basic quantity we can measure for a molecular cloud is its mass. However, this also turns out to be one of the trickiest quantities to measure. The most commonly used method for inferring masses is based on molecular line emission, because lines are bright and easy to see even in external galaxies. The three most commonly-used species on the galactic scale are 12CO, 13CO, and, more recently, HCN.
Optically Thin Lines: Conceptually, 13CO is the simplest, because its lines are generally optically thin. For emitting molecules in local thermodynamic equilibrium (LTE) at temperature T, it is easy to show from the radiative transfer equation that the intensity emitted by a cloud of optical depth τν at frequency ν is simply
where Bν(T) is the Planck function evaluated at frequency ν and temperature T.
Although we will not derive this equation here1, it behaves exactly as one would expect intuitively. In the limit of a very optically thick cloud, τν ≫ 1, the exponential factor becomes zero, and the intensity simply approaches the Planck function, which is the intensity emitted by a black body. In the limit of a very optically thin cloud, τν ≪ 1, the exponential factor just becomes 1 − τν, so the intensity approaches that of a black body multiplied by the (small) optical depth. Thus, the intensity is simply proportional to the optical depth, which is proportional to the number of atoms along the line of sight.
These equations allow the following simple method of deducing the column density from an observation of the 13CO and 12CO J = 1 → 0 lines (or any similar pair of J lines) from a molecular cloud. If we assume that the 12CO line is optically thick, as is almost always the case, then we can approximate 1 − e−τν ≈ 1 at line center, so Iν ≈ Bν (T). If we measure Iν, we can therefore immediately deduce the temperature T. We then assume that the 13CO molecules are at the same temperature, so that Bν(T) is the same for 12CO and 13CO except for the slight shift in frequency. Then if we measure Iν for the center of the 13CO line, we can solve the equation
for τν, the optical depth of the 13CO line. If N13CO is the column density of 13CO atoms, then for gas in LTE the column densities of atoms in the level 0 and 1 states are
where Z is the partition function, which is a known function of T, and T1 = 5.3 K is the temperature corresponding to the first excited state.
The opacity to line absorption at frequency ν is
where B01 and B10 are the Einstein coefficients for spontaneous absorption and stimulated emission, defined by
The quantity ϕ(ν) is the line shape function (see Chapter 1). The corresponding optical depth at line center is
Since we know tν from the line intensity, we can measure ϕ(ν) just by measuring the shape of the line, and N0 and N1 depend only on
and the (known) temperature, we can solve for
. In practice, we generally do this in a slightly more sophisticated way, by fitting the optical depth and line shape as a function of frequency simultaneously, but the idea is the same. We can then convert to an H2 column density by assuming a ratio of 12CO to H2, and of 13CO to 12CO.
This method also has some significant drawbacks that are worth mentioning. The need to assume ratios of 13CO to 12CO and 12CO to H2 are obvious ones. The former is particularly tricky, because there is strong observational evidence that the 13C to 12C ratio varies with galactocentric radius. We also need to assume that the 12CO and 13CO molecules are at the same temperature, which may not be true because the 12CO emission comes mostly from the cloud surface and the 13CO comes from the entire cloud. Since the cloud surface is usually warmer than its deep interior, this will tend to make us overestimate the excitation temperature of the 13CO molecules, and thus underestimate the true column density. This problem can be even worse because the lower abundance of 13CO means that it cannot self-shield against dissociation by interstellar UV light as effectively at 12CO. As a result, it may simply not be present in the outer parts of clouds at all, leading us to miss their mass and underestimate the true column density.
Another serious worry is the assumption that the 13CO molecules are in LTE. As shown in Problem Set 1, the 12CO J = 1 state has a critical density of a few thousand cm−3, which is somewhat above the mean density in a GMC even when we take into account the effects of turbulence driving mass to high density. The critical density for the 13CO J = 1 state is similar. For the 12CO J = 1 state, the effective critical density is lowered by optical depth effects, which thermalize the low-lying states. Since 13CO is optically thin, however, there is no corresponding thermalization for it, so in reality the excitation of the gas tends to be sub-LTE. The result is that the emission is less than we would expect based on an LTE assumption, and so we tend to underestimate the true 13CO column density, and thus the mass, using this method.
A final point to mention about this method is that, since the 13CO line is optically thin, it is simply not as bright as an optically thick line would be. Consequently, this method is generally only used within the Galaxy, not for external galaxies.
Optically Thick Lines: Optically thick lines are nice and bright, so we can see them in distant galaxies. The challenge for an optically thick line is how to infer a mass, given that we are really only seeing the surface of a cloud. Our standard approach here is to define an “X factor”: a scaling between the observed frequency-integrated intensity along a given line of sight and the column density of gas along that line of sight. For example, if we see a frequency-integrated CO J = 1 → 0 intensity ICO along a given line of sight, we define XCO = N/ICO, where N is the t...
