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Main Authors: Elms, Abbigail, Bagnulo, Stefano, Tremblay, Pier-Emmanuel, Cunningham, Tim, Munday, James, Landstreet, John, El-Badry, Kareem, Caiazzo, Ilaria, Melis, Carl, Pinter, Viktoria, Weinberger, Alycia
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.12048
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author Elms, Abbigail
Bagnulo, Stefano
Tremblay, Pier-Emmanuel
Cunningham, Tim
Munday, James
Landstreet, John
El-Badry, Kareem
Caiazzo, Ilaria
Melis, Carl
Pinter, Viktoria
Weinberger, Alycia
author_facet Elms, Abbigail
Bagnulo, Stefano
Tremblay, Pier-Emmanuel
Cunningham, Tim
Munday, James
Landstreet, John
El-Badry, Kareem
Caiazzo, Ilaria
Melis, Carl
Pinter, Viktoria
Weinberger, Alycia
contents The small DAHe and DAe spectral classes comprise isolated, hydrogen-dominated atmosphere white dwarfs that exhibit variable photometric flux and Balmer line emission. These mysterious systems offer unique insight into the complex interplay between magnetic fields, stellar rotation and atmospheric activity in single white dwarfs. DAHe stars have detectable magnetic fields through Zeeman-split spectral lines, whereas DAe stars lack such splitting. We report the first discovery and characterisation of magnetism in the DAe white dwarf WDJ165335.21-100116.33 with new time-resolved spectropolarimetry from FORS2. We detect a weak but variable longitudinal magnetic field with values $\langle B_z \rangle > -9.2 \pm 2.4$ kG and $\langle B_z \rangle < -2.2 \pm 1.0$ kG. Independent ZTF and ATLAS photometry reveal a consistent period of P = 80.3070 $\pm$ 0.0007 h. Time-resolved optical spectroscopy obtained with six ground-based instruments demonstrates strong modulation in the strength of the H$α$ and H$β$ Balmer line emission with P = 80.2922 $\pm$ 0.0108 h. The photometric flux and Balmer emission strength vary in antiphase, with the strongest magnetic detections coinciding with phases of low photometric flux and strong line emission. These characteristics support the theory that a magnetically active, temperature-inverted spot/region is producing an optically thin chromospheric emission region. Comparison with other DAe and DAHe white dwarfs reveals all systems have a strikingly similar antiphase phenomenology, reinforcing the theory that they are subject to a unified physical mechanism. With the detection of a weak magnetic field, we reclassify WDJ165335.21-100116.33 as a low-field DAHe white dwarf.
format Preprint
id arxiv_https___arxiv_org_abs_2603_12048
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Detection of a weak magnetic field in the Balmer emission line white dwarf WDJ1653-1001
Elms, Abbigail
Bagnulo, Stefano
Tremblay, Pier-Emmanuel
Cunningham, Tim
Munday, James
Landstreet, John
El-Badry, Kareem
Caiazzo, Ilaria
Melis, Carl
Pinter, Viktoria
Weinberger, Alycia
Solar and Stellar Astrophysics
The small DAHe and DAe spectral classes comprise isolated, hydrogen-dominated atmosphere white dwarfs that exhibit variable photometric flux and Balmer line emission. These mysterious systems offer unique insight into the complex interplay between magnetic fields, stellar rotation and atmospheric activity in single white dwarfs. DAHe stars have detectable magnetic fields through Zeeman-split spectral lines, whereas DAe stars lack such splitting. We report the first discovery and characterisation of magnetism in the DAe white dwarf WDJ165335.21-100116.33 with new time-resolved spectropolarimetry from FORS2. We detect a weak but variable longitudinal magnetic field with values $\langle B_z \rangle > -9.2 \pm 2.4$ kG and $\langle B_z \rangle < -2.2 \pm 1.0$ kG. Independent ZTF and ATLAS photometry reveal a consistent period of P = 80.3070 $\pm$ 0.0007 h. Time-resolved optical spectroscopy obtained with six ground-based instruments demonstrates strong modulation in the strength of the H$α$ and H$β$ Balmer line emission with P = 80.2922 $\pm$ 0.0108 h. The photometric flux and Balmer emission strength vary in antiphase, with the strongest magnetic detections coinciding with phases of low photometric flux and strong line emission. These characteristics support the theory that a magnetically active, temperature-inverted spot/region is producing an optically thin chromospheric emission region. Comparison with other DAe and DAHe white dwarfs reveals all systems have a strikingly similar antiphase phenomenology, reinforcing the theory that they are subject to a unified physical mechanism. With the detection of a weak magnetic field, we reclassify WDJ165335.21-100116.33 as a low-field DAHe white dwarf.
title Detection of a weak magnetic field in the Balmer emission line white dwarf WDJ1653-1001
topic Solar and Stellar Astrophysics
url https://arxiv.org/abs/2603.12048