HD 187474, also known as HR 7552 and V3961 Sagittarii, is a star about 315
light years from the Earth, in the constellation
Sagittarius.[3] It is a 5th
magnitude star, so it will be faintly visible to the
naked eye of an observer far from
city lights. It is a variable star, whose brightness varies slightly from
magnitude 5.28 to 5.34.[4] HD 187474 is classified as an
Alpha2 Canum Venaticorum variable star, but it has a rotation period of 2345 days - more than an order of magnitude longer than is typical for that class.[6][9] HD 187474 is an
Ap star.[10]
In 1958,
Horace Babcock announced that HD 187474 has a magnetic field, the strength of which he estimated to be 1867
gauss. He found the star to be remarkable, because it was the only
A-type star he had found that seemed to have a magnetic field which did not vary in time.[11] However this perceived consistency turned out to be the result of Babcock's observations covering only a small portion of the star's unexpectedly long variability period.[12]
HD 187474 is a single-lined
spectroscopic binary. This was discovered by Sylvia Burd at
Palomar Observatory, and the result was communicated to S. Leeman by Babcock. Leeman published the finding in 1964, along with
orbital elements derived by Burd. The initial estimate of the orbital period was 700 days.[12]
The variability of HD 187474 was apparently discovered by Babcock sometime prior to 1976, the year when it was given the
variable star designation V3961 Sagittarii,[13] but the result was never published by him.[14][15]
Several groups have tried to determine the strength and geometry of HD 187474's magnetic field. In 1987 Pierre Didelon derived a surface field strength of 5.0±0.4 kilogauss, from observations of
Zeeman splitting of
spectral lines.[16] In the year 2000, John Landstreet and Gautier Mathys found that the variation of the measured magnetic field as the star rotated was far from
sinusoidal. They obtained an acceptable fit to the data with a model of the field which contained colinear
dipole,
quadrupole and
octupole terms.[17] Two years later, Stefano Bagnulo et al. modeled the field as a dipole inclined 80° with respect to the rotation axis plus a nonlinear quadrupole term.[18] The next year, V. R. Khalack et al. modeled the field as a set of virtual
magnetic charges, with the constraint that the total magnetic charge must be zero.[5] In 2005, Yu. V. Glagolevskij modeled the field as a dipole displaced from the star's center, and inclined relative to the rotation axis by 24°.[6]
^Kukarkin, B. V.; Kholopov, P. N.; Fedorovich, V. P.; Kireyeva, N. N.; Kukarkina, N. P.; Medvedeva, G. I.; Perova, N. B. (March 1977).
"62nd Name-List of Variable Stars"(PDF). Information Bulletin on Variable Stars. 1248: 1.
Bibcode:
1977IBVS.1248....1K. Retrieved 18 March 2023.