The Geometry of the H I of Several Members of the M81Group: The H I Is Fractal

David J. Westpfahl; Paul H. Coleman; Jordan Alexander; Thomas Tongue

doi:10.1086/300717

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The Geometry of the H I of Several Members of the M81 Group: The H I Is Fractal

David J. Westpfahl¹, Paul H. Coleman^1,2, Jordan Alexander^1,3, and Thomas Tongue^1,4

© 1999. The American Astronomical Society. All rights reserved. Printed in U.S.A.
The Astronomical Journal, Volume 117, Number 2 Citation David J. Westpfahl et al 1999 AJ 117 868 DOI 10.1086/300717

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Author affiliations

¹ Astrophysics Research Center, Physics Department, New Mexico Institute of Mining and Technology, Socorro, NM 87801

² Current address: University of Puerto Rico, Department of Physics, P.O. Box 23343, Rio Piedras, PR 00931-3343

³ Current address: Department of Physics, University of Oslo, P.O. Box 1048 Blindern, N-0316 Oslo, Norway

⁴ Current Address: Imagiware, Inc., 6441 Enterprise Lane, Suite 115, Madison, WI 53705

Dates

Received 1997 October 28
Accepted 1998 November 4

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Abstract

We use the box-counting method on single H I contours and the perimeter-area method on families of contours to show that the projected H I distributions of seven members of the M81 group are fractal. All seven have fractal dimensions that cover a small range, 1.5 ≥ D ≥ 1.2. This is nearly the same dimension as that of CO clouds in the Milky Way and suggests that the ISM may have a fractal dimension that stays within a limited range at all scales. Reliable determination of fractal dimension requires that observations be made with high angular and frequency resolution. If theorems of projection of opaque fractals apply to H I, then the dimension of the deprojected H I distributions may be 1.5 ≥ D ≥ 1.2 as well. Fractal structures have much more surface area than smooth structures, allowing heating, cooling, and material exchange to proceed much more rapidly.

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