1997PhDT.........2P

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Title:		Study of Star Formation Regions with Molecular Hydrogen Emission Lines
Authors:		Pak, Soojong
Affiliation:		THE UNIVERSITY OF TEXAS AT AUSTIN
Journal:		Thesis (PHD). THE UNIVERSITY OF TEXAS AT AUSTIN , Source DAI-B 59/01, p. 260, Jul 1998, 125 pages.
Publication Date:		00/1997
Category:		Physics: Astronomy and Astrophysics
Origin:		ADS
Keywords:		MAGELLANIC CLOUDS, PHOTOIONIZATION
Abstract Copyright:		(c) 1997: UMI Company
Comment:		Publication Number: AAT 9822682; Advisor: JAFFE, DANIEL T.
Bibliographic Code:		1997PhDT.........2P

Abstract

The goal of my dissertation is to understand the large-scale, near-infrared (near-IR) H₂ emission from the central kiloparsec (kpc) regions of galaxies, and to study the structure and physics of photon-dominated regions (or photodissociation regions, hereafter PDRs). In order to explore the near-IR H₂ lines, our group built the University of Texas near-IR Fabry-Perot Spectrometer optimized for observations of extended, low surface brightness sources. In this instrument project, I designed and built a programmable high voltage DC amplifier for the Fabry-Perot piezoelectric transducers, a temperature-controlled cooling box for the Fabry-Perot etalon, instrument control software, and data reduction software. With this instrument, we observed H₂ emission lines in the inner 400 pc of the Galaxy, the central ~1 kpc of NGC 253 and M82, and the star formation regions in the Magellanic Clouds. We also observed the Magellanic Clouds in the CO J=1/to0 line. We found that the H₂ emission is very extended in the central kpc of the galaxies and is mostly UV-excited. The ratios of the H₂ (1,0) S(1) luminosities to the far-IR continuum luminosities in the central kpc regions do not change from the Galactic center to starburst galaxies and to ultraluminous IR bright galaxies. Using the data from the Magellanic Clouds, we studied the microscopic structure of star forming clouds. We compiled data sets including our H₂ (1,0) S(1) and CO J=1/to0 results and published (C scII) and far-IR data from the Magellanic Clouds, and compared these observations with models we made using a PDR code and a radiative transfer code. Assuming the cloud is spherical, we derived the physical sizes of H₂, (C scII), and CO emission regions. The average cloud size appears to increase as the metallicity decreases. Our results agree with the theory of photoionization-regulated star formation in which the interplay between the ambipolar diffusion and ionization by far-UV photons determines the size of stable clouds.

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