The Luminous Convolution Model as an alternative to dark matter in spiral galaxies

The Luminous Convolution Model (LCM) demonstrates that it is possible to predict the rotation curves of spiral galaxies directly from estimates of the luminous matter. We consider two frame-dependent effects on the light observed from other galaxies: relative velocity and relative curvature. With on...

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Veröffentlicht in:	arXiv.org 2014-07
Hauptverfasser:	Cisneros, S, Oblath, N S, maggio, J A, Ott, R A, Chester, D, Battaglia, D J, Ashley, A, Robinson, R, Rodriguez, A
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Sprache:	eng
Schlagworte:	Astronomical models Constraint modelling Convolution Curvature Curve fitting Dark matter Emitters Galactic rotation Milky Way Galaxy Spiral galaxies Stars & galaxies
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creator	Cisneros, S Oblath, N S maggio, J A Ott, R A Chester, D Battaglia, D J Ashley, A Robinson, R Rodriguez, A
description	The Luminous Convolution Model (LCM) demonstrates that it is possible to predict the rotation curves of spiral galaxies directly from estimates of the luminous matter. We consider two frame-dependent effects on the light observed from other galaxies: relative velocity and relative curvature. With one free parameter, we predict the rotation curves of twenty-three (23) galaxies represented in forty-two (42) data sets. Relative curvature effects rely upon knowledge of both the gravitational potential from luminous mass of the emitting galaxy and the receiving galaxy, and so each emitter galaxy is compared to four (4) different Milky Way luminous mass models. On average in this sample, the LCM is more successful than either dark matter or modified gravity models in fitting the observed rotation curve data. Implications of LCM constraints on populations synthesis modeling are discussed in this paper. This paper substantially expands the results in arXiv:1309.7370.
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We consider two frame-dependent effects on the light observed from other galaxies: relative velocity and relative curvature. With one free parameter, we predict the rotation curves of twenty-three (23) galaxies represented in forty-two (42) data sets. Relative curvature effects rely upon knowledge of both the gravitational potential from luminous mass of the emitting galaxy and the receiving galaxy, and so each emitter galaxy is compared to four (4) different Milky Way luminous mass models. On average in this sample, the LCM is more successful than either dark matter or modified gravity models in fitting the observed rotation curve data. Implications of LCM constraints on populations synthesis modeling are discussed in this paper. 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subjects	Astronomical models Constraint modelling Convolution Curvature Curve fitting Dark matter Emitters Galactic rotation Milky Way Galaxy Spiral galaxies Stars & galaxies
title	The Luminous Convolution Model as an alternative to dark matter in spiral galaxies
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