English

Kozai Lidov Cycles = Simple Pendulum

Solar and Stellar Astrophysics 2025-03-27 v1 Earth and Planetary Astrophysics Classical Physics

Abstract

The quadrupole Kozai mechanism, which describes the hierarchical three-body problem in the leading order, is shown to be equivalent to a simple pendulum where the change in the eccentricity squared equals the height of the pendulum from its lowest point: emax2e2=h=l(1cosθ)e_{\text{max}}^2-e^2=h=l\left(1-\cos{\theta}\right). In particular, this results in useful expressions for the KLC period, and the maximal and minimal eccentricities in terms of orbital constants. We derive the equivalence using the vector coordinates α=j+e,β=je\boldsymbol{\alpha}=\textbf{j}+\textbf{e}, \boldsymbol{\beta}=\textbf{j}-\textbf{e} for the inner Keplerian orbit, where j\textbf{j} is the normalized specific angular momentum, and e\textbf{e} is the eccentricity vector. The equations of motion for α\boldsymbol{\alpha} and β\boldsymbol{\beta} simplify to α˙=2αϕ×α\dot{\boldsymbol{\alpha}}=2\partial_{\boldsymbol{\alpha}} \phi \times \boldsymbol{\alpha} and β˙=2βϕ×β\dot{\boldsymbol{\beta}}=2\partial_{\boldsymbol{\beta}} \phi \times \boldsymbol{\beta}, where ϕ\phi is the normalized averaged interaction potential and are symmetric to replacing α\boldsymbol{\alpha} and β\boldsymbol{\beta} for the KLC quadratic potential. Their constraints simplify to α2=β2=1\boldsymbol{\alpha}^2=\boldsymbol{\beta}^2=1, and they are distributed uniformly and independently on the unit sphere for a uniform distribution in phase space (with a fixed energy).

Keywords

Cite

@article{arxiv.2503.19972,
  title  = {Kozai Lidov Cycles = Simple Pendulum},
  author = {Roi D. Basha and Ygal Y. Klein and Boaz Katz},
  journal= {arXiv preprint arXiv:2503.19972},
  year   = {2025}
}

Comments

4 Pages, 2 Figures

R2 v1 2026-06-28T22:34:18.487Z