TY - JOUR
T1 - Magnetic fields and rotation in white dwarfs and neutron stars
AU - Ferrario, Lilia
AU - Wickramasinghe, D. T.
PY - 2005/1/11
Y1 - 2005/1/11
N2 - Recent spectropolarimetric observations of Ap and Bp stars with improved sensitivity have suggested that most Ap and Bp stars are magnetic with dipolar fields of at least a few hundred gauss. These new estimates suggest that the range of magnetic fluxes found for the majority of magnetic white dwarfs is similar to that of main-sequence Ap-Bp stars, thus strengthening the empirical evidence for an evolutionary link between magnetism on the main sequence and magnetism in white dwarfs. We draw parallels between the magnetic white dwarfs and the magnetic neutron stars and argue that the observed range of magnetic fields in isolated neutron stars (Bp∼ ∼ 10 11-1015 G) could also be explained if their mainly O-type progenitors have effective dipolar fields in the range of a few gauss to a few kilogauss, assuming approximate magnetic flux conservation with the upper limit being consistent with the recent measurement of a field of Bp ∼ 1100 G for θ Orion C. In the magnetic field-rotation diagram, the magnetic white dwarfs can be divided into three groups of different origin: a significant group of strongly magnetized slow rotators (Prot ∼ 50-100 yr) that have originated from single-star evolution, a group of strongly magnetized fast rotators (Prot ∼ 700 s), typified by EUVE J0317-853, that have originated from a merger, and a group of modest rotators (Prot ∼ hours-days) of mixed origin (single-star and CV-type binary evolution). We propose that the neutron stars may similarly divide into distinct classes at birth, and suggest that the magnetars may be the counterparts of the slowly rotating high-field magnetic white dwarfs.
AB - Recent spectropolarimetric observations of Ap and Bp stars with improved sensitivity have suggested that most Ap and Bp stars are magnetic with dipolar fields of at least a few hundred gauss. These new estimates suggest that the range of magnetic fluxes found for the majority of magnetic white dwarfs is similar to that of main-sequence Ap-Bp stars, thus strengthening the empirical evidence for an evolutionary link between magnetism on the main sequence and magnetism in white dwarfs. We draw parallels between the magnetic white dwarfs and the magnetic neutron stars and argue that the observed range of magnetic fields in isolated neutron stars (Bp∼ ∼ 10 11-1015 G) could also be explained if their mainly O-type progenitors have effective dipolar fields in the range of a few gauss to a few kilogauss, assuming approximate magnetic flux conservation with the upper limit being consistent with the recent measurement of a field of Bp ∼ 1100 G for θ Orion C. In the magnetic field-rotation diagram, the magnetic white dwarfs can be divided into three groups of different origin: a significant group of strongly magnetized slow rotators (Prot ∼ 50-100 yr) that have originated from single-star evolution, a group of strongly magnetized fast rotators (Prot ∼ 700 s), typified by EUVE J0317-853, that have originated from a merger, and a group of modest rotators (Prot ∼ hours-days) of mixed origin (single-star and CV-type binary evolution). We propose that the neutron stars may similarly divide into distinct classes at birth, and suggest that the magnetars may be the counterparts of the slowly rotating high-field magnetic white dwarfs.
KW - Stars: Magnetic fields
KW - Stars: Neutron
KW - White dwarfs
UR - http://www.scopus.com/inward/record.url?scp=11844282787&partnerID=8YFLogxK
U2 - 10.1111/j.1365-2966.2004.08474.x
DO - 10.1111/j.1365-2966.2004.08474.x
M3 - Article
SN - 0035-8711
VL - 356
SP - 615
EP - 620
JO - Monthly Notices of the Royal Astronomical Society
JF - Monthly Notices of the Royal Astronomical Society
IS - 2
ER -