RHO AQR (Rho Aquarii), with a nod toward THETA AQR (Theta
Aquarii). Within Aquarius (the Water
Bearer) what comes most to mind is his "Water Jar," from which he pours the streaming liquid
into the mouth of the Southern Fish, Piscis
Austrinus. We might also admire the two great supergiants off to the west,
Sadalmelik (Alpha Aquarii) and Sadalsuud (Beta). The numerous stars
to the south are less appreciated. Among them, some eight
degrees below the Water Jar, is a
pair a bit over three-fourths of a degree apart. The more
westerly and brighter of the two, fourth magnitude Theta
Aquarii, is an ordinary class G (G8 giant-subgiant) that serves as a
guide star to more interesting, though fainter, fifth magnitude
(5.37) Rho Aqr to the east, a class B (B8) "giant" (but see
below). Though proximate on the sky, they have nothing to do
with each other. At a distance of 882 light years (give or take
91), Rho is almost five times farther than Theta (187 l-y,
plus/minus under 3). The distance plus a well-defined
temperature of 4970 Kelvin (needed to allow for infrared radiation) yields a
modest luminosity for Theta Aqr of just 16.6 Suns, from which we find radius of 11.8
solar. Theory suggests that it's a helium-fusing giant of
perhaps two solar masses. Even though Theta is just over two
degrees north of the ecliptic, there seems to be
no observation of radius via lunar occultation, which tells how
ignored the star really is. But then there is Rho. It's an
underobserved "mercury-manganese" (HgMn) star, one with huge
overabundances of these chemical elements as well as enrichments
of rare earths such as europium, alongside depletions of some
others, exemplified by calcium. For relatively slow rotators,
the outer stellar layers are fairly peaceful and unstirred. As
a result, some elements are lofted upward by radiation pressure,
while others sink under the force of gravity. With a projected
equatorial spin-speed of 69 kilometers per second rotation
(which translates to a rotation period of at most 4.4 days), Rho
apparently qualifies. The HgMn stars are higher temperature
versions of class A metallic line stars like Sirius. The odd abundances make
classification problematic. With a temperature of 12,450 Kelvin
(needed for evaluation of ultraviolet light) and a 0.1 magnitude
correction for dimming by interstellar dust, Rho radiates
at a rate of 773 Suns, the radius 6.6 solar. Theory reveals
that the star is either a subgiant with a dead helium core or a
dwarf that is close to
becoming one with a mass of 4.3 to 4.5 Suns, its age some 112
million years. Slight Doppler
shifts in the spectrum suggest a
companion with a 220-day
period, which yields a separation for low companion-mass of 1.2
Astronomical Units. As different as they are now, the two stars
have similar fates. Both are destined to lose their outer
layers and die as
white dwarfs with respective masses of 0.63
and 0.82 times that of the Sun. Because of its higher mass, Rho
goes first, not that Theta gives a hoot.
Written by Jim Kaler 4/10/15. Return to STARS.