Abstract
We show that some Emden–Fowler (EF) equations encountered in astrophysics and cosmology belong to two EF integrable classes of the type d 2 z /d χ 2 = Aχ − λ −2 z n for λ =( n −1)/2 (class 1), and λ = n +1 (class 2). We find their corresponding invariants which reduce them to first-order nonlinear ordinary differential equations. Using particular solutions of such EF equations, the two classes are set in the autonomous nonlinear oscillator the form d 2 ν /d t 2 + a d ν /d t + b ( ν − ν n )=0 , where the coefficients a , b depend only on λ , n . For both classes, we write closed-form solutions in parametric form. The illustrative examples from astrophysics and general relativity correspond to two n = 2 cases from class 1 and 2, and one n = 5 case from class 1, all of them yielding Weierstrass elliptic solutions. It is also noticed that when n = 2, the EF equations can be studied using the Painlevé reduction method, since they are a particular case of equations of the type d 2 z /d χ 2 = F ( χ ) z 2 , where F ( χ ) is the Kustaanheimo-Qvist function.
Original language | American English |
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Journal | Zeitschrift für Naturforschung A |
DOIs | |
State | Published - Feb 4 2018 |
Disciplines
- Physical Sciences and Mathematics