Overview

Maclaurin Toroid (MPT77)

In a separate chapter, we focused on the pioneering work of 📚 F. W. Dyson (1893, Phil. Trans. Royal Soc. London. A., Vol. 184, pp. 43 - 95), 📚 F. W. Dyson (1893, Phil. Trans. Royal Soc. London. A., Vol. 184, pp. 1041 - 1106) and, more recently, 📚 C. -Y. Wong (1974, ApJ, Vol. 190, pp. 675 - 694), who determined the approximate equilibrium structure of axisymmetric, uniformly rotating, incompressible tori. We will refer to these uniformly rotating configurations as "Dyson-Wong tori."

Here, we summarize the work of 📚 P. S. Marcus, W. H. Press, & S. A. Teukolsky (1977, ApJ, Vol. 214, pp. 584 - 597) — hereafter, MPT77 — who constructed a sequence of toroidal-shaped, self-gravitating, incompressible configurations that are not uniformly rotating but, rather, have a distribution of angular momentum that is identical to the distribution found in a uniformly rotating, uniform-density sphere. As we have pointed out in our associated overview of "simple rotation curves", this chosen (cylindrical) radial distribution of specific angular momentum is given by the expression,

where, ${\displaystyle L}$ is the total angular momentum, ${\displaystyle M}$ is the total mass, the mass fraction,

and ${\displaystyle M_{\varpi }(\varpi )}$ is the mass enclosed within a cylinder of radius, ${\displaystyle \varpi }$. Such equilibrium models are often referred to as ${\displaystyle n^{\prime }=0}$ configurations, although MPT77 do not use this terminology. Following the lead of MPT77, we will refer to each of their equilibrium configurations as a "Maclaurin Toroid."

Maclaurin Spheroid Reminder

As has been demonstrated in our accompanying discussion of the Maclaurin spheroid sequence, the (square of the) normalized angular momentum that is associated with a spheroid of eccentricity, ${\displaystyle e\equiv (1-c^2/a^2{)}^{1/2}}$, is,

In that same discussion, we have demonstrated that the corresponding ratio of rotational to gravitational potential energy is given by the expression,

Figure 4 from this accompanying discussion shows how ${\displaystyle L_{*}}$ varies with ${\displaystyle \tau }$ along the Maclaurin Spheroid sequence. In an effort to conform to MPT77's presentation, our Figure 1 (immediately below) displays the same information as displayed in Figure 4 of this separate chapter, but the axes have been swapped and the maximum displayed value of ${\displaystyle L_{*}}$ has been extended from 1 to 1.5.

MPT77 also evaluate the normalized total energy, ${\displaystyle E_{\mathrm{t}\mathrm{o}\mathrm{t}}/|E_0|}$, of each of their constructed equilibrium configurations, where

and, according to the caption of their Figure 4, ${\displaystyle E_0}$ is "… the energy of a nonrotating sphere of equal mass and volume." Drawing from our separate discussion of the Maclaurin spheroid sequence, it would be reasonable to assume that the energy normalization adopted by MPT77 is the same as the normalization used by [T78], namely,

For models along the Maclaurin spheroid sequence, this normalization leads to expressions for the two key energy terms of the form,

in which case, in the limit of a nonrotating sphere,

But in Figure 4 of MPT77, the point along the Maclaurin spheroid sequence — the solid, black curve — that represents a nonrotating ${\displaystyle (L_{*}=0)}$ sphere has a normalized energy, ${\displaystyle (E_{\mathrm{t}\mathrm{o}\mathrm{t}}/E_0)=-1.}$ We conclude, therefore, that the normalization adopted by MPT77 is,

Our Figure 2 (immediately above) attempts to quantitatively replicate the behavior of the Maclaurin spheroid sequence that is shown in Figure 4 (p. 213) of MPT77; the ordinate depicts, on a base-10 logarithmic scale, how the total energy varies with the spheroid's angular momentum over the range, ${\displaystyle 0\le L_{*}\le 1.50}$. More specifically, for eccentricities over the range, ${\displaystyle 0\le e\le 0.99998967881}$, the corresponding value of the spheroid's normalized angular momentum is obtained from the above expression for ${\displaystyle L_{*}}$, and the normalized energy is given by the relation,

Constructed Maclaurin Toroid Models

📚 Marcus, Press, & Teukolsky (1977) did not create a tabulated description of the models that they constructed along their so-called "Maclaurin Toroid" sequence. Throughout their paper, however, they highlighted some properties of a selected group of equilibrium models. Column (2) of Table 1, immediately below, provides a list of the values of the normalized angular momentum, ${\displaystyle L_{*}}$, that corresponds to the Maclaurin Toroid models that have been explicitly referenced in their discussion.

Using a simple iterative technique, we have determined the value of ${\displaystyle e}$ that corresponds to each tabulated ${\displaystyle L_{*}}$ if we assume that the referenced model is a Maclaurin spheroid, not a toroid; the value that corresponds to each spheroid's eccentricity is listed in column (3) of the table. In turn, columns (4) and (5) list the values of ${\displaystyle \tau }$ and ${\displaystyle E_{\mathrm{t}\mathrm{o}\mathrm{t}}/E_0}$ that is associated with a Maclaurin spheroid that has the stated eccentricity. If — using the coordinate pair, ${\displaystyle (L_{*},\tau )}$ — we were to position any one of these models into our Figure 1, above, the model would fall on the solid black portion of the "Maclaurin spheroid sequence." Similarly, if — using the coordinate pair, ${\displaystyle (L_{*},E_{\mathrm{t}\mathrm{o}\mathrm{t}}/E_0)}$ — we were to position any one of these models into our Figure 2, above, the model would fall on the solid black portion of the "Maclaurin spheroid sequence."