T h e hydrostatic equilibrium and its implications 
on the mechanical properties of planets 

P . B A L D I - M . CAPTJTO ( * ) 

R e c e i v e d on A p r i l 7th, 1974 

SUMMARY. — Under the hypothesis of hydrostatic equilibrium the 
planets of the solar system are represented on the plane (J"2, w2 a?/MG) 
(J 2 = second term of the g r a v i t a t i o n a l potential, w = rotation rate of the 
planet, a — equatorial radius, M — mass of the planet, G = g r a v i t a t i o n a l 
constant). Since the points representing the planets lie on a straight line 
it is possible t o obtain informations on the giration m o m e n t and the m o m e n t 
of inertia of Uranus and P l u t o . 

RIASSUNTO. — P a r t e n d o dall'ipotesi di equilibrio idrostatico, i pia-
neti del sistema solare sono rappresentati nel piano ( J 2 , iv-a?! MG), d o v e J2 
è il secondo termine dell'espressione del potenziale gravitazionale, w la ve-
locità di rotazione del pianeta, a il raggio equatoriale, M la massa del pia-
neta, G la costante g r a v i t a z i o n a l e . 

P o i c h é i punti che rappresentano i pianeti giacciono su una linea retta, 
è possibile avere informazioni sul m o m e n t o giratore e sul m o m e n t o di 
inerzia di Urano e P l u t o n e . 

1. - INTRODUCTION. 

I n v e s t i g a t i o n s so f a r c a r r i e d o u t o n t h e solar s y s t e m w o u l d s e e m 

t o i n d i c a t e a f a i r d e g r e e of r e g u l a r i t y i n t h e s y s t e m i t s e l f , a n d also 

t h e p r e s e n c e of s p e c i a l m e c h a n i s m s ( 5 ) : a m o n g t h e s e l e t us r e c a l l t h e 

r e g u l a r i t y of t h e o r b i t s of t h e p l a n e t s ( s l i g h t i n c l i n a t i o n , s l i g h t e c c e n -

t r i c i t y , a n t i c l o c k - w i s e m o t i o n , e t c . ) ; i n t h e l a w g o v e r n i n g t h e r e l a t i o n -

( * ) Istituto di Fisica e Istituto di Geofìsica, Università di B o l o g n a . 



230 P . B A L D I - M . C A P U T O 

ship of the semimajor axes of two contiguous planets (a n+i Wn — const., 
Titius-Bode law); the alignment of the representative points of the 
planets in the Gw/M,M plane (7). 

The study of the motion of artificial and natural satellites makes 
it possible to obtain the parameters linked to the internal and external 
structure of the planet such, for example, as the total mass M , the 
flattening at the poles e, Ji (the second term of gravitational poten-
tial), the moments of inertia. 

Considering the planets to be in hydrostatic equilibrium by 
means of the above-mentioned terms it is possible to arrive, as we 
shall later show, at a knowledge of the values of p (C/Mr2), and con-
sequently at the value of the moments of inertia of almost all the 
planets. 

2. - T H E HYDROSTATIC EQUILIBRIUM OF A PLANET. 

Let us consider a planet in hydrostatic equilibrium: approximat-
ing in the first order, the equations that link flattening and J2, m 
( = w2 r3/MG), p (= C/Mr2), are (*): 

m [1] 

225 p2 — 300 p + 84 + 16 
15 J2 

— 3 • = 0 

[2] 

where Eq. [1] holds even in the absence of hydrostatic equilibrium. 
Eliminating e it follows that: 

21 
• m 

[3] 

The obvious considerations follow from Eq. [3]; real p and p > 0 
which imply: 

or 
A < + 1 

J2 < 1.33 TO 

A > — 21/4 

J2 > —3/39 to 



T H E H Y D R O S T A T I C E Q U I L I B R I U M A N D I T S I M P L I C A T I O N S E T C . 2 3 7 

Rejecting the case where the moment of inertia with respect to 
an equatorial axis of the planet is greater than the moment of inertia 
with respect to the polar axis (J < 0), there will be a further limit-
ation for A which will have to be greater than —3; from this it fol-
lows that p will have to be greater by about 0.13, that is the possibility 
is excluded of an excessive concentration of mass at the centre. 

3. - H Y D R O S T A T I C EQUILIBRIUM I N THE SOLAR SYSTEM. 

For the purpose of investigating the planets in the solar system 
in the light of the considerations set out above, let us represent such 
planets in the m, Ji plane. W e note immediately that the points re-
presenting those planets whose fundamental parameters we know: 
mass, average radius, rotation period and J2, belong with good ap-
proximation to a straight line that we shall call a. 

In this approximation one can obtain interesting information 
regarding the values of the moments of inertia of Uranus and Pluto 
and the mass of Pluto. 

4. - M O M E N T S OF I N E R T I A OF URANUS A N D PLUTO. 

lsi hypothesis: Let us suppose that the straight line must pass 
through the origin (p = const.), as well as through the points of the 
plane m, Ji that represent the planets of which the mass, the radius, 
the angular rotation rate and the value of Ji (Fig. 1) are known. 

The value of "average" p is found to be about 0.229 for all planets 
(Ji/m = const., approximating in the first order, imply A = const.). 
The moments of inertia of Uranus is found to be: C = 1.31 • 1047. 
For Pluto, using the observed values of R = 3200 km (3), 
M = 6.59 • 1026 gr (8), we obtain the value (1) of Table I I . 

2nd hypothesis: A straight line is plotted bearing in mind the 
known precision of the parameters of the various planets without 
forcing it to pass through the origin (Pig. 2). 

For Uranus we obtain a value of Ji equal to 0.0089, a value of 
the dynamical flattening equal to 0.05, in good agreement with the 
geometrical value derived from visual observations (6), a value of p 
equal to 0.232, and a moment of inertia G = 1.33 • 1047 gr • cm2. 



• ¿ T A JkE-.JUJL I w ^ m*m.JL 



7 

m = w 2 r 3 / H G 

Fig. 1. - Representation of the planets in the plane m = w-a?IMG, <72; the linear regression 
approximating the points overall is made to pass through the origin. 





T H E H Y D R O S T A T I C E Q U I L I B R I U M A N D I T S I M P L I C A T I O N S E T C . 241 



230 
P . B A L D I - M . C A P U T O 

I O 2 6 , 0 2 7 , o 2 8 1 0 = 9 1 0 3 ° 

P i g . 4. - The density of the angular moment in relation to the mass. 

For Pluto, making use of the values so far known and very un-
certain of the mass and the radius, there would seem to be found a 
value of p greater than 0.4, which is unacceptable. 

I t must however be noted that the determination of the mass 
of Pluto is obtained from the study of the perturbations of Neptune, 
that is from the perturbations of a very small body on a very large 
one, and it is therefore extremely unreliable because a small error 
in the mass of Neptune causes a very large error in the mass of Pluto. 
A further difficulty arises from the fact that up to the present only 
a fraction of revolution of the outer planet has been observed. The 
best value of the mass obtained so far is 6.59-1026 gr (8) and taking 
the radius of 3200 km (3), one obtains an average density of 4.8 
gr/cm3, too high for an outer planet. Also we shall' consider the radius 
of Pluto 2700 km estimated from optical observation (4), although 



T H E H Y D R O S T A T I C E Q U I L I B R I U M A N D ITS I M P L I C A T I O N S E T C . 2 4 3 

this radius, with the observed value of the mass gives an excessively 
high value of the mean density. 

Considering now the average-mass density plane, one can observe 
that the planets take up positions along two lines: on one side we 
find terrestrial planets, on the other the outer planets (Fig. 3). 

Pluto, an outer planet, should therefore belong to the straight 
line of outer planets and have an average density of about 2 gr/cm3 

or less; accepting this hypothesis, there follows a diminution of the 
mass. 

If we want to use the straight line which does not pass tlirough 
the oiigin, a A'alue of p at most as large as 0.4, and to keep the values 
of the radius, we obtain a value of o at most 0.3 and for G the values 
indicated in lines (2) and (3) of Table I I . 

Using Q = 0.3, the same values of R and the straight line pas-
sing through the origin, we obtain the values of C given in lines 4 
and 5 of the same Table, while assuming Q = 2 we obtain G as in li-
nes (0) and (7). 

For a further check, we set out in Fig. 4 the values obtained by 
us of the "density of rotational angular momentum" (Cw/M) of Ura-
nus, on the straight line obtained by MacDonald (7) for planets whose 
moments of inertia are known with a fair degree of precision. The 
agreement of the data obtained here with those observed for other 
planets is satisfactory. 

Obviously in Table I I one finds that the values of the density 
of rotational angular momentum in lines (1), (4), (6) coincide as well 
as those of lines (5), (7); the difference of the two sets is due only on 
the different values of R because the density of rotational angular 
momentum GwjM can also be written pwR-. The values of Gw/M 
of line (1) is too far below the straight line of MacDonald; it would 
be difficult to explain the loss of the initial energy of the planet. The 
values of lines (2) and (3) are too far above and it would be difficult 
to explain the gain of energy. The only reasonable models of Pluto 
are those of lines (4), (5), (6) and (7). 

R E F E R E N C E S 

(*) CAPUTO, M., 19G7. - The gravity field of the Earth. Academic Press, N e w 
Y o r k . 

( 2 ) COOK, A . H . , 1972. - The dynamical properties and internal structures 
of the Earth, the Moon and the Planets, "L'roc. R . soc.", Lond., A328, 
3 0 1 . 



230 P. B A L D I - M. C A P U T O 

( 3 ) H A L L I D A Y , I . , H A R D I E , R . K . , F R A N Z , 0 . a n d P R I S E R , J . B . , I 9 6 0 . -

" P u b i . Astron. Soc. P a c i f i c . " , 78, 113. 

(>) HALLIDAY, I., 1969. - " P u b i . Astron. Soc. P a c i f i c . " 81, 285. 

(5) KAULA, W . A . , 1968. - An introduction to planetary physics. John Wiley 
Sons, Inc. 

(•) KOVALEVSKY, J., 1970. - Determination des masses des planètes el satel-
lites. In (ed. A . Dollfus), "Surfaces and interiors of planets and satel-
lites", 1-44, London, Academic Press. 

( ' ) MACDONALD, G. J. F., 1964. - Tidal friction. " R e v . Geopliys.", 2, 467-
541. 

( 8 ) S E I D E L M A N N , P . K . , K L E P C Z Y N S C K I , W . J . , D U N C O M B E , R . L . , 1 9 7 1 . -

Determination of the mass of Pluto. " A s t r o n . J . " , 76, 488.