Since the discovery of the first isolated magnetic white dwarf(MWD) Grw + 7
0 degrees 8047 nearly 60 years ago, the number of stars belonging to this c
lass has grown steadily. There are now some 65 isolated white dwarfs classi
fied as magnetic, and a roughly equal number of MWDs are found in the close
interacting binaries known as the magnetic cataclysmic variables (MCVs). T
he isolated MWDs comprise similar to 5% of all WDs, while the MCVs comprise
similar to 25% of all CVs. The magnetic fields range from similar to 3 x 1
0(4)-10(9) G in the former group with a distribution peaking at 1.6 x 10(7)
G, and similar to 10(7)-3 x 10(8) G in the latter group. The space density
of isolated magnetic white dwarfs with fields in the range similar to 3 x
10(4)-10(9) G is estimated to be similar to 1.5 x 10(-4) pc(-3). The MCVs h
ave a space density that is about a hundred times smaller.
About 80% of the isolated MWDs have almost pure H atmospheres and show only
hydrogen lines in their spectra (the magnetic DAs), while the remainder sh
ow He I lines (the magnetic DBs) or molecular bands of C-2 and CH (magnetic
DQs) and have helium as the dominant atmospheric constituent, mirroring th
e situation in the nonmagnetic white dwarfs. The incidence of stars of mixe
d composition (H and He) appears to be higher among the MWDs.
There is growing evidence based on trigonometric parallaxes, space motions,
and spectroscopic analyses that the isolated MWDs tend as a class to have
a higher mass than the nonmagnetic white dwarfs. The mean mass for 16 MWDs
with well-constrained masses is greater than or similar to 0.95 M.. Magneti
c fields may therefore play a significant role in angular momentum and mass
loss in the post-main-sequence phases of single star evolution affecting t
he initial-final mass relationship, a view supported by recent work on clus
ter MWDs. The progenitors of the vast majority of the isolated MWDs are lik
ely to be the magnetic Ap and Bp stars. However, the discovery of two MWDs
with masses within a few percent of the Chandrasekhar limit, one of which i
s also rapidly rotating (P-spin = 12 minutes), has led to the proposal that
these may be the result of double-degenerate (DD) mergers. An intriguing p
ossibility is that magnetism, through its effect on the initial-final mass
relationship, may also favor the formation of more massive double degenerat
es in close binary evolution. The magnetic DDs may therefore be more likely
progenitors of Type Ia supernovae.
A subclass of the isolated MWDs appear to rotate slowly with no evidence of
spectral or polarimetric variability over periods of tens of years, while
others exhibit rapid rotation with coherent periods in the range of tens of
minutes to hours or days. There is a strong suggestion of a bimodal period
distribution. The "rapidly" rotating isolated MWDs may include as a subcla
ss stars which have been spun up during a DD merger or a previous phase of
mass transfer from a companion star.
Zeeman spectroscopy and polarimetry, and cyclotron spectroscopy, have vario
usly been used to estimate magnetic fields of the isolated MWDs and the MWD
s in MCVs and to place strong constraints on the field structure. The surfa
ce field distributions tend in general to be strongly nondipolar and to a f
irst approximation can be modeled by dipoles that are offset from the cente
r by similar to 10%-30% of the stellar radius along the dipole axis. Other
stars show extreme spectral variations with rotational phase which cannot b
e modeled by off-centered dipoles. More exotic field structures with spot-t
ype field enhancements appear to be necessary. These field structures are e
ven more intriguing and suggest that some of the basic assumptions inherent
in most calculations of field evolution, such as force-free fields and fre
e ohmic decay, may be oversimplistic.