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Critical Collapse of a Massive Scalar Field in Newtonian Gravity - Numerical Investigations of the Schodinger-Poisson System Inwood, Andrew
Abstract
Critical collapse in General Relativity (GR) has been studied extensively, both numerically and analytically, for a wide variety of matter models including massive and massless scalar fields coupled to gravity, as well as a variety of gas models. Comparatively less work has been done towards the investigation of critical collapse in Newtonian gravity, although some progress has been made using an isothermal gas model. In this paper we numerically investigate critical collapse of a massive scalar field in spherical symmetry, coupled to gravity in the Newtonian limit. The evolution of such a field is described by the Schrodinger-Poisson (SP) system. A Crank-Nicolson finite-differencing approximation is coded using the Rapid Numerical Prototyping Language (RNPL), and the updates are coded in FORTRAN. The SP system is investigated using Gaussian initial data, centred at the origin. By varying the amplitude of the Gaussian data, no evidence for critical behaviour is found, and so the SP system is modified through the gravitational coupling in an attempt to induce critical behaviour. This modification is realized by making the exponent in the Poisson equation variable. Type I critical behaviour is found using the Gaussian initial data centred at the origin for an exponent epsilon = 3. By performing a bisection search the critical value of the amplitude, A, is found to 15 digits of precision. The critical solution is found to be periodic in time, characteristic of Type I phenomena, with a period of T = 0.02. By surveying the 1-dimensional parameter space of A, the Lyapunov exponent associated with the growing mode in Type I phenomena is found to 3 significant digits to be lambda = 163.
Item Metadata
| Title |
Critical Collapse of a Massive Scalar Field in Newtonian Gravity - Numerical Investigations of the Schodinger-Poisson System
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| Creator | |
| Date Issued |
2009-05-11
|
| Description |
Critical collapse in General Relativity (GR) has been studied extensively, both numerically and
analytically, for a wide variety of matter models including massive and massless scalar fields
coupled to gravity, as well as a variety of gas models. Comparatively less work has been done
towards the investigation of critical collapse in Newtonian gravity, although some progress has
been made using an isothermal gas model. In this paper we numerically investigate critical
collapse of a massive scalar field in spherical symmetry, coupled to gravity in the Newtonian
limit. The evolution of such a field is described by the Schrodinger-Poisson (SP) system.
A Crank-Nicolson finite-differencing approximation is coded using the Rapid Numerical Prototyping
Language (RNPL), and the updates are coded in FORTRAN. The SP system is investigated
using Gaussian initial data, centred at the origin. By varying the amplitude of the Gaussian
data, no evidence for critical behaviour is found, and so the SP system is modified through the
gravitational coupling in an attempt to induce critical behaviour. This modification is realized
by making the exponent in the Poisson equation variable.
Type I critical behaviour is found using the Gaussian initial data centred at the origin for an
exponent epsilon = 3. By performing a bisection search the critical value of the amplitude, A, is found
to 15 digits of precision. The critical solution is found to be periodic in time, characteristic of
Type I phenomena, with a period of T = 0.02. By surveying the 1-dimensional parameter space
of A, the Lyapunov exponent associated with the growing mode in Type I phenomena is found
to 3 significant digits to be lambda = 163.
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| Extent |
620927 bytes
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| Genre | |
| Type | |
| File Format |
application/pdf
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| Language |
eng
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| Series | |
| Date Available |
2009-05-11
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| Provider |
Vancouver : University of British Columbia Library
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| Rights |
Attribution-NonCommercial-NoDerivatives 4.0 International
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| DOI |
10.14288/1.0085959
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| URI | |
| Affiliation | |
| Campus | |
| Citation |
Inwood, Andrew. 2009. Critical Collapse of a Massive Scalar Field in Newtonian Gravity - Numerical Investigations of the Schodinger-Poisson System. Undergraduate Honours Thesis. Department of Physics and Astronomy. University of British Columbia.
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| Peer Review Status |
Unreviewed
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| Scholarly Level |
Undergraduate
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| Copyright Holder |
Inwood, Andrew
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| Rights URI | |
| Aggregated Source Repository |
DSpace
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Rights
Attribution-NonCommercial-NoDerivatives 4.0 International