The concept of gravitational focusing describes how the gravitational attraction between two particles increases the probability that they will collide. Without gravitational force, the likelihood of a collision would depend on the cross-sectional area of the two particles. However, the presence of gravity can cause particles that would have otherwise missed each other to be drawn together, effectively increasing the size of their cross-sectional area.[1]
Assuming two bodies having spherical symmetry, a collision will occur if the minimum separation between the two centres is less than the sum of the two radii. Because of the conservation of angular momentum, we have the following relationship between the relative speed when the separation equals this sum, and the relative speed when the objects are very far apart :
where is the minimum separation that would occur if the two bodies were not attracted one to the other. This means that a collision will occur not only when but when
and the cross-sectional area is increased by the square of the ratio, so the probability of collision is increased by a factor of However, by the conservation of energy we have
where is the escape velocity. This gives the increase in probability of a collision as a factor of [1] When neither body can be treated as having a negligible mass, the escape velocity is given by:
When the second body is of negligible size and mass, we have:
where is the average density of the large body.
The eccentricity of the hyperbolic trajectory is below or above depending on whether there is or isn't a collision, respectively. When there is no collision, the trajectories turn by in the centre-of-mass fame of reference.
Function
editGravitational focusing applies to extended objects like the Moon, planets and the Sun, whose interior density distributions are well known.[2] Gravitational focusing is responsible for the power-law mass function of star clusters.[3] Gravitational focusing plays a significant role in the formation of planets, as it shortens the time required for them to form and promotes the growth of larger particles.[1]
Dark matter
editGravitational focusing typically only has a small impact on the relaxed halo dark matter component, with effects typically remaining at around the 5% level. However, the impact of gravitational focusing on dark matter substructures could potentially be much greater.[4]
References
edit- ^ a b c Barnes, Rory (2011), "Gravitational Focusing", in Gargaud, Muriel; Amils, Ricardo; Quintanilla, José Cernicharo; Cleaves, Henderson James (Jim) (eds.), Encyclopedia of Astrobiology, Berlin, Heidelberg: Springer, p. 692, doi:10.1007/978-3-642-11274-4_670, ISBN 978-3-642-11274-4, retrieved 2023-01-01
- ^ Sofue, Yoshiaki (June 2020). "Gravitational Focusing of Low-Velocity Dark Matter on the Earth's Surface". Galaxies. 8 (2): 42. arXiv:2005.08252. doi:10.3390/galaxies8020042. ISSN 2075-4434.
- ^ Kuznetsova, Aleksandra; Hartmann, Lee; Burkert, Andreas (2017-02-21). "Gravitational Focusing and the Star Cluster Initial Mass Function". The Astrophysical Journal. 836 (2): 190. arXiv:1702.00279. doi:10.3847/1538-4357/aa5d51. ISSN 1538-4357. S2CID 119484707.
- ^ Kim, Hyungjin; Lenoci, Alessandro (2022-03-31). "Gravitational focusing of wave dark matter". Physical Review D. 105 (6): 063032. arXiv:2112.05718. doi:10.1103/PhysRevD.105.063032. S2CID 245117706.