Low Velocity Gravitational Capture by Long Cosmic Strings

TL;DR

This paper derives equations describing the gravitational interaction between a compact object and a long cosmic string at low velocities, calculating the impact parameter for capture and analyzing different string stiffness regimes.

Contribution

It introduces coupled differential equations for low-velocity gravitational interactions with cosmic strings and provides analytical formulas for the critical impact parameter in different regimes.

Findings

Derived coupled equations for gravitational interaction.

Calculated impact parameter for capture as a function of velocity.

Provided analytical approximations for different string stiffness regimes.

Abstract

Coupled ordinary differential equations are derived for the distant gravitational interaction of a compact object of mass M and charge Q with an initially straight, infinitely long, cosmic string of tension mu << 1/G = 1, when the relative velocities are very low compared to the speed of light c = 1. (An intermediate result of this derivation is that any localized force F(t) on the string that is confined to a single plane perpendicular to the initial string configuration gives the intersection of the string with this plane -- the point where the force is applied -- the velocity F(t)/(2 mu).) The coupled equations are then used to calculate the critical impact parameter b for marginal gravitational capture as a function of the incident velocity v. For v<<(1-Q^2/M^2)^(1/3) mu^(2/3), so that the string acts relatively stiffly, b = (pi/4)[12 mu^3 (1-Q^2/M^2)^4]^(1/5) M v^(-7/5) + O(M v^(-1/5)). For (1-Q^2/M^2)^(1/3) mu^(2/3) << v << 1 - Q^2/M^2$, so that the string acts essentially as a test string that stays nearly straight, b = [(pi/2)(1-Q^2/M^2)]^(1/2) M v^(-1/2) + O(M v^(-2)). Between these two limits the critical impact parameter is found numerically to fit a simple algebraic combination of these two formulas to better than 99.5% accuracy.