Tisserand's parameter

Tisserand's parameter (or Tisserand's invariant) is a number calculated from several orbital elements (semi-major axis, orbital eccentricity and inclination) of a relatively small object and a larger "perturbing body". It is used to distinguish different kinds of orbits. The term is named after French astronomer Félix Tisserand who derived it, and applies to restricted three-body problems in which the three objects all differ greatly in mass.

Definition

For a small body with semi-major axis $a\,\!$ , orbital eccentricity $e\,\!$ , and orbital inclination $i\,\!$ , relative to the orbit of a perturbing larger body with semimajor axis $a_{P}$ , the parameter is defined as follows:^[1]^[2]

T_{P}\ ={\frac {a_{P}}{a}}+2\cos i{\sqrt {{\frac {a}{a_{P}}}(1-e^{2})}}

Tisserand invariant conservation

In the three-body problem, the quasi-conservation of Tisserand's invariant is derived as the limit of the Jacobi integral away from the main two bodies (usually the star and planet).^[1] Numerical simulations show that the Tisserand invariant is conserved in the three-body problem on Gigayear timescales.^[3]^[4]

Applications

The Tisserand parameter's conservation was originally used by Tisserand to determine whether or not an observed orbiting body is the same as one previously observed.

Orbit classification

T_J, Tisserand's parameter with respect to Jupiter as perturbing body, is frequently used to distinguish asteroids (typically $T_{J}>3$ ) from Jupiter-family comets (typically $2<T_{J}<3$ ).^[5]
The minor planet group of damocloids are defined by a Jupiter Tisserand's parameter of 2 or less ( $T J \leq 2$ ).^[6]
The quasi-conservation of Tisserand's parameter constrains the orbits attainable using gravity assist for outer Solar System exploration.
T_N, Tisserand's parameter with respect to Neptune, has been suggested to distinguish near-scattered (affected by Neptune) from extended-scattered trans-Neptunian objects (not affected by Neptune; e.g. 90377 Sedna).
Tisserand's parameter could be used to infer the presence of an intermediate-mass black hole at the center of the Milky Way using the motions of orbiting stars.^[7]

Related notions

The parameter is derived from one of the so-called Delaunay standard variables, used to study the perturbed Hamiltonian in a three-body system. Ignoring higher-order perturbation terms, the following value is conserved:

{\sqrt {a(1-e^{2})}}\cos i

Consequently, perturbations may lead to the resonance between the orbital inclination and eccentricity, known as Kozai resonance. Near-circular, highly inclined orbits can thus become very eccentric in exchange for lower inclination. For example, such a mechanism can produce sungrazing comets, because a large eccentricity with a constant semimajor axis results in a small perihelion.

References

^ ^a ^b Murray, Carl D.; Dermott, Stanley F. (2000). Solar System Dynamics. Cambridge University Press. ISBN 0-521-57597-4.
^ Bonsor, A.; Wyatt, M. C. (2012-03-11). "The scattering of small bodies in planetary systems: constraints on the possible orbits of cometary material: Scattering in planetary systems". Monthly Notices of the Royal Astronomical Society. 420 (4): 2990–3002. arXiv:1111.1858. doi:10.1111/j.1365-2966.2011.20156.x.
^ Namouni, F. (2021-11-26). "Inclination pathways of planet-crossing asteroids". Monthly Notices of the Royal Astronomical Society. 510 (1): 276–291. arXiv:2111.10777. doi:10.1093/mnras/stab3405.
^ Namouni, F. (2023-11-20). "Orbit injection of planet-crossing asteroids". Monthly Notices of the Royal Astronomical Society. 527 (3): 4889–4898. arXiv:2311.09946. doi:10.1093/mnras/stad3570.
^ "Dave Jewitt: Tisserand Parameter". www2.ess.ucla.edu. Retrieved 2018-03-27.
^ Jewitt, David C. (August 2013). "The Damocloids". UCLA – Department of Earth and Space Sciences. Retrieved 15 February 2017.
^ Merritt, David (2013). Dynamics and Evolution of Galactic Nuclei. Princeton, NJ: Princeton University Press. ISBN 9781400846122.

External links

David Jewitt's page on Tisserand's parameter
Tisserand criterion

[MD2000-1] Murray, Carl D.; Dermott, Stanley F. (2000). Solar System Dynamics. Cambridge University Press. ISBN 0-521-57597-4.

[2] Bonsor, A.; Wyatt, M. C. (2012-03-11). "The scattering of small bodies in planetary systems: constraints on the possible orbits of cometary material: Scattering in planetary systems". Monthly Notices of the Royal Astronomical Society. 420 (4): 2990–3002. arXiv:1111.1858. doi:10.1111/j.1365-2966.2011.20156.x.

[3] Namouni, F. (2021-11-26). "Inclination pathways of planet-crossing asteroids". Monthly Notices of the Royal Astronomical Society. 510 (1): 276–291. arXiv:2111.10777. doi:10.1093/mnras/stab3405.

[4] Namouni, F. (2023-11-20). "Orbit injection of planet-crossing asteroids". Monthly Notices of the Royal Astronomical Society. 527 (3): 4889–4898. arXiv:2311.09946. doi:10.1093/mnras/stad3570.

[5] "Dave Jewitt: Tisserand Parameter". www2.ess.ucla.edu. Retrieved 2018-03-27.

[Damocloids-Jewitt-6] Jewitt, David C. (August 2013). "The Damocloids". UCLA – Department of Earth and Space Sciences. Retrieved 15 February 2017.

[DEGN-7] Merritt, David (2013). Dynamics and Evolution of Galactic Nuclei. Princeton, NJ: Princeton University Press. ISBN 9781400846122.

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