Your search keyword '"van Roestel J"' showing total 65 results

51. Phase-resolved spectroscopy of Gaia14aae: line emission from near the white dwarf surface

Author

Green, M J, primary, Marsh, T R, additional, Steeghs, D, additional, Breedt, E, additional, Kupfer, T, additional, Rodríguez-Gil, P, additional, van Roestel, J, additional, Ashley, R P, additional, Wang, L, additional, Cukanovaite, E, additional, and Outmani, S, additional

Published

2019

52. High-speed photometry of Gaia14aae: an eclipsing AM CVn that challenges formation models

Author

Green, M J, primary, Marsh, T R, additional, Steeghs, D T H, additional, Kupfer, T, additional, Ashley, R P, additional, Bloemen, S, additional, Breedt, E, additional, Campbell, H C, additional, Chakpor, A, additional, Copperwheat, C M, additional, Dhillon, V S, additional, Hallinan, G, additional, Hardy, L K, additional, Hermes, J J, additional, Kerry, P, additional, Littlefair, S P, additional, Milburn, J, additional, Parsons, S G, additional, Prasert, N, additional, van Roestel, J, additional, Sahman, D I, additional, and Singh, N, additional

Published

2018

53. Discovery of 36 eclipsing EL CVn binaries found by the Palomar Transient Factory

Author

van Roestel, J, primary, Kupfer, T, additional, Ruiz-Carmona, R, additional, Groot, P J, additional, Prince, T A, additional, Burdge, K, additional, Laher, R, additional, Shupe, D L, additional, and Bellm, E, additional

Published

2018

54. The OmegaWhite Survey for short-period variable stars – IV. Discovery of the warm DQ white dwarf OW J175358.85−310728.9

Author

Macfarlane, S. A., primary, Woudt, P. A., additional, Dufour, P., additional, Ramsay, G., additional, Groot, P. J., additional, Toma, R., additional, Warner, B., additional, Paterson, K., additional, Kupfer, T., additional, van Roestel, J., additional, Berdnikov, L., additional, Dagne, T., additional, and Hardy, F., additional

Published

2017

55. PTF1 J085713+331843, a new post-common-envelope binary in the orbital period gap of cataclysmic variables

Author

van Roestel, J., primary, Groot, P. J., additional, Levitan, D., additional, Prince, T. A., additional, Bloemen, S., additional, Marsh, T. R., additional, Dhillon, V. S., additional, Shupe, D., additional, and Laher, R., additional

Published

2017

56. A radio-pulsing white dwarf binary star

Author

Marsh, T. R., primary, Gänsicke, B. T., additional, Hümmerich, S., additional, Hambsch, F.-J., additional, Bernhard, K., additional, Lloyd, C., additional, Breedt, E., additional, Stanway, E. R., additional, Steeghs, D. T., additional, Parsons, S. G., additional, Toloza, O., additional, Schreiber, M. R., additional, Jonker, P. G., additional, van Roestel, J., additional, Kupfer, T., additional, Pala, A. F., additional, Dhillon, V. S., additional, Hardy, L. K., additional, Littlefair, S. P., additional, Aungwerojwit, A., additional, Arjyotha, S., additional, Koester, D., additional, Bochinski, J. J., additional, Haswell, C. A., additional, Frank, P., additional, and Wheatley, P. J., additional

Published

2016

57. The OmegaWhite Survey for short-period variable stars – IV. Discovery of the warm DQ white dwarf OWJ175358.85–310728.9.

Author

Macfarlane, S. A., Woudt, P. A., Dufour, P., Ramsay, G., Groot, P. J., Toma, R., Warner, B., Paterson, K., Kupfer, T., van Roestel, J., Berdnikov, L., Dagne, T., and Hardy, F.

Subjects

VARIABLE stars, STELLAR evolution, WHITE dwarf stars, N stars, STELLAR magnetic fields, STELLAR rotation

Abstract

We present the discovery and follow-up observations of the second known variable warm DQ white dwarf OWJ175358.85–310728.9 (OWJ1753–3107). OWJ1753–3107 is the brightest of any of the currently known warm or hot DQ and was discovered in the OmegaWhite Survey as exhibiting optical variations on a period of 35.5452 (2) min, with no evidence for other periods in its light curves. This period has remained constant over the last 2 yr and a single-period sinusoidal model provides a good fit for all follow-up light curves. The spectrum consists of a very blue continuum with strong absorption lines of neutral and ionized carbon, a broad He ı λ4471 line and possibly weaker hydrogen lines. The C ı lines are Zeeman split, and indicate the presence of a strong magnetic field. Using spectral Paschen–Back model descriptions, we determine that OWJ1753–3107 exhibits the following physical parameters: Teff = 15 430 K, log (g) = 9.0, log (N(C)/N(He)) = -1.2 and the mean magnetic field strength is Bz = 2.1 MG. This relatively low temperature and carbon abundance (compared to the expected properties of hot DQs) is similar to that seen in the other warm DQ SDSS J1036+6522. Although OW J1753–3107 appears to be a twin of SDSS J1036+6522, it exhibits a modulation on a period slightly longer than the dominant period in SDSS J1036+6522 and has a higher carbon abundance. The source of variations is uncertain, but they are believed to originate from the rotation of the magnetic white dwarf. [ABSTRACT FROM AUTHOR]

Published

2017

58. Normering regionale wateroverlast in stedelijk gebied; inventarisatie problemen en aanbevelingen bij implementatie werknormen

Author

van der Knaap, W.G.M., Oosterhof, E., van Roestel, J., and van der Wielen, H.

Subjects

waterlogging, normen, stedelijke gebieden, MGS, sewerage, riolering, Land Use Planning, urban areas, waterverzadiging, standards, Landgebruiksplanning, netherlands, nederland

Abstract

Het toetsen van het watersysteem aan een norm voor wateroverlast moet zichtbaar maken waar burgers en goederen nog een te geringe bescherming ondervinden. Uit een inventariserend afstudeeronderzoek blijkt dat deze toetsing in het landelijke gebied in volle gang is. De toetsing van het water in de bebouwde kom aan de norm van eens per 100 jaar laat echter nog te wensen over. Dit is te verklaren uit de complexiteit van water en riolering in bebouwd gebied, de vele vrijheidsgraden die het toetsingsproces kent, het gebrek aan adequate informatie en de complexiteit in de verantwoordelijkheidsstructuur in het stedelijke waterbeheer. Meer sturing aan het toetsingsproces en aan de erop volgende bepaling van de definitieve beheersnorm lijkt wenselijk

Published

2004

59. The second data release of the INT Photometric Hα Survey of the Northern Galactic Plane (IPHAS DR2)

Author

Barentsen, Geert, primary, Farnhill, H. J., additional, Drew, J. E., additional, González-Solares, E. A., additional, Greimel, R., additional, Irwin, M. J., additional, Miszalski, B., additional, Ruhland, C., additional, Groot, P., additional, Mampaso, A., additional, Sale, S. E., additional, Henden, A. A., additional, Aungwerojwit, A., additional, Barlow, M. J., additional, Carter, P. J., additional, Corradi, R. L. M., additional, Drake, J. J., additional, Eislöffel, J., additional, Fabregat, J., additional, Gänsicke, B. T., additional, Gentile Fusillo, N. P., additional, Greiss, S., additional, Hales, A. S., additional, Hodgkin, S., additional, Huckvale, L., additional, Irwin, J., additional, King, R., additional, Knigge, C., additional, Kupfer, T., additional, Lagadec, E., additional, Lennon, D. J., additional, Lewis, J. R., additional, Mohr-Smith, M., additional, Morris, R. A. H., additional, Naylor, T., additional, Parker, Q. A., additional, Phillipps, S., additional, Pyrzas, S., additional, Raddi, R., additional, Roelofs, G. H. A., additional, Rodríguez-Gil, P., additional, Sabin, L., additional, Scaringi, S., additional, Steeghs, D., additional, Suso, J., additional, Tata, R., additional, Unruh, Y. C., additional, van Roestel, J., additional, Viironen, K., additional, Vink, J. S., additional, Walton, N. A., additional, Wright, N. J., additional, and Zijlstra, A. A., additional

Published

2014

60. A radio-pulsing white dwarf binary star

Author

Marsh, T. R., Gänsicke, B. T., Hümmerich, S., Hambsch, F.-J., Bernhard, K., Lloyd, C., Breedt, E., Stanway, E. R., Steeghs, D. T., Parsons, S. G., Toloza, O., Schreiber, M. R., Jonker, P. G., van Roestel, J., Kupfer, T., Pala, A. F., Dhillon, V. S., Hardy, L. K., Littlefair, S. P., Aungwerojwit, A., Arjyotha, S., Koester, D., Bochinski, J. J., Haswell, C. A., Frank, P., Wheatley, P. J., Marsh, T. R., Gänsicke, B. T., Hümmerich, S., Hambsch, F.-J., Bernhard, K., Lloyd, C., Breedt, E., Stanway, E. R., Steeghs, D. T., Parsons, S. G., Toloza, O., Schreiber, M. R., Jonker, P. G., van Roestel, J., Kupfer, T., Pala, A. F., Dhillon, V. S., Hardy, L. K., Littlefair, S. P., Aungwerojwit, A., Arjyotha, S., Koester, D., Bochinski, J. J., Haswell, C. A., Frank, P., and Wheatley, P. J.

Abstract

White dwarfs are compact stars, similar in size to Earth but ~200,000 times more massive. Isolated white dwarfs emit most of their power from ultraviolet to near-infrared wavelengths, but when in close orbits with less dense stars, white dwarfs can strip material from their companions, and the resulting mass transfer can generate atomic line and X-ray emission, as well as near- and mid-infrared radiation if the white dwarf is magnetic. However, even in binaries, white dwarfs are rarely detected at far-infrared or radio frequencies. Here we report the discovery of a white dwarf / cool star binary that emits from X-ray to radio wavelengths. The star, AR Scorpii (henceforth AR Sco), was classified in the early 1970s as a delta-Scuti star, a common variety of periodic variable star. Our observations reveal instead a 3.56 hr period close binary, pulsing in brightness on a period of 1.97 min. The pulses are so intense that AR Sco's optical flux can increase by a factor of four within 30 s, and they are detectable at radio frequencies, the first such detection for any white dwarf system. They reflect the spin of a magnetic white dwarf which we find to be slowing down on a 10^7 yr timescale. The spin-down power is an order of magnitude larger than that seen in electromagnetic radiation, which, together with an absence of obvious signs of accretion, suggests that AR Sco is primarily spin-powered. Although the pulsations are driven by the white dwarf's spin, they originate in large part from the cool star. AR Sco's broad-band spectrum is characteristic of synchrotron radiation, requiring relativistic electrons. These must either originate from near the white dwarf or be generated in situ at the M star through direct interaction with the white dwarf's magnetosphere.

61. A radio-pulsing white dwarf binary star

Author

Marsh, T. R., Gänsicke, B. T., Hümmerich, S., Hambsch, F.-J., Bernhard, K., Lloyd, C., Breedt, E., Stanway, E. R., Steeghs, D. T., Parsons, S. G., Toloza, O., Schreiber, M. R., Jonker, P. G., van Roestel, J., Kupfer, T., Pala, A. F., Dhillon, V. S., Hardy, L. K., Littlefair, S. P., Aungwerojwit, A., Arjyotha, S., Koester, D., Bochinski, J. J., Haswell, C. A., Frank, P., Wheatley, P. J., Marsh, T. R., Gänsicke, B. T., Hümmerich, S., Hambsch, F.-J., Bernhard, K., Lloyd, C., Breedt, E., Stanway, E. R., Steeghs, D. T., Parsons, S. G., Toloza, O., Schreiber, M. R., Jonker, P. G., van Roestel, J., Kupfer, T., Pala, A. F., Dhillon, V. S., Hardy, L. K., Littlefair, S. P., Aungwerojwit, A., Arjyotha, S., Koester, D., Bochinski, J. J., Haswell, C. A., Frank, P., and Wheatley, P. J.

Abstract

White dwarfs are compact stars, similar in size to Earth but ~200,000 times more massive. Isolated white dwarfs emit most of their power from ultraviolet to near-infrared wavelengths, but when in close orbits with less dense stars, white dwarfs can strip material from their companions, and the resulting mass transfer can generate atomic line and X-ray emission, as well as near- and mid-infrared radiation if the white dwarf is magnetic. However, even in binaries, white dwarfs are rarely detected at far-infrared or radio frequencies. Here we report the discovery of a white dwarf / cool star binary that emits from X-ray to radio wavelengths. The star, AR Scorpii (henceforth AR Sco), was classified in the early 1970s as a delta-Scuti star, a common variety of periodic variable star. Our observations reveal instead a 3.56 hr period close binary, pulsing in brightness on a period of 1.97 min. The pulses are so intense that AR Sco's optical flux can increase by a factor of four within 30 s, and they are detectable at radio frequencies, the first such detection for any white dwarf system. They reflect the spin of a magnetic white dwarf which we find to be slowing down on a 10^7 yr timescale. The spin-down power is an order of magnitude larger than that seen in electromagnetic radiation, which, together with an absence of obvious signs of accretion, suggests that AR Sco is primarily spin-powered. Although the pulsations are driven by the white dwarf's spin, they originate in large part from the cool star. AR Sco's broad-band spectrum is characteristic of synchrotron radiation, requiring relativistic electrons. These must either originate from near the white dwarf or be generated in situ at the M star through direct interaction with the white dwarf's magnetosphere.

62. The Final Season Reimagined: 30 Tidal Disruption Events from the ZTF-I Survey

Author

Erica Hammerstein, Sjoert van Velzen, Suvi Gezari, S. Bradley Cenko, Yuhan Yao, Charlotte Ward, Sara Frederick, Natalia Villanueva, Jean J. Somalwar, Matthew J. Graham, Shrinivas R. Kulkarni, Daniel Stern, Igor Andreoni, Eric C. Bellm, Richard Dekany, Suhail Dhawan, Andrew J. Drake, Christoffer Fremling, Pradip Gatkine, Steven L. Groom, Anna Y. Q. Ho, Mansi M. Kasliwal, Viraj Karambelkar, Erik C. Kool, Frank J. Masci, Michael S. Medford, Daniel A. Perley, Josiah Purdum, Jan van Roestel, Yashvi Sharma, Jesper Sollerman, Kirsty Taggart, Lin Yan, Hammerstein, E [0000-0002-5698-8703], van Velzen, S [0000-0002-3859-8074], Gezari, S [0000-0003-3703-5154], Cenko, SB [0000-0003-1673-970X], Yao, Y [0000-0001-6747-8509], Ward, C [0000-0002-4557-6682], Frederick, S [0000-0001-9676-730X], Villanueva, N [0000-0001-6917-4656], Somalwar, JJ [0000-0001-8426-5732], Graham, MJ [0000-0002-3168-0139], Kulkarni, SR [0000-0001-5390-8563], Stern, D [0000-0003-2686-9241], Andreoni, I [0000-0002-8977-1498], Bellm, EC [0000-0001-8018-5348], Dekany, R [0000-0002-5884-7867], Dhawan, S [0000-0002-2376-6979], Drake, AJ [0000-0003-0228-6594], Fremling, C [0000-0002-4223-103X], Gatkine, P [0000-0002-1955-2230], Groom, SL [0000-0001-5668-3507], Ho, AYQ [0000-0002-9017-3567], Kasliwal, MM [0000-0002-5619-4938], Karambelkar, V [0000-0003-2758-159X], Kool, EC [0000-0002-7252-3877], Masci, FJ [0000-0002-8532-9395], Medford, MS [0000-0002-7226-0659], Perley, DA [0000-0001-8472-1996], Purdum, J [0000-0003-1227-3738], van Roestel, J [0000-0002-2626-2872], Sharma, Y [0000-0003-4531-1745], Sollerman, J [0000-0003-1546-6615], Taggart, K [0000-0002-5748-4558], Yan, L [0000-0003-1710-9339], and Apollo - University of Cambridge Repository

Subjects

High Energy Astrophysical Phenomena (astro-ph.HE), Space and Planetary Science, 5101 Astronomical Sciences, Astrophysics::High Energy Astrophysical Phenomena, FOS: Physical sciences, Astronomy and Astrophysics, Astrophysics::Cosmology and Extragalactic Astrophysics, Astrophysics - High Energy Astrophysical Phenomena, 51 Physical Sciences, High-Energy Phenomena and Fundamental Physics, Astrophysics::Galaxy Astrophysics

Abstract

Tidal disruption events (TDEs) offer a unique way to study dormant black holes. While the number of observed TDEs has grown thanks to the emergence of wide-field surveys in the past few decades, questions regarding the nature of the observed optical, UV, and X-ray emission remain. We present a uniformly selected sample of 30 spectroscopically classified TDEs from the Zwicky Transient Facility Phase I survey operations with follow-up \textit{Swift} UV and X-ray observations. Through our investigation into correlations between light curve properties, we recover a shallow positive correlation between the peak bolometric luminosity and decay timescales. We introduce a new spectroscopic class of TDE, TDE-featureless, which are characterized by featureless optical spectra. The new TDE-featureless class shows larger peak bolometric luminosities, peak blackbody temperatures, and peak blackbody radii. We examine the differences between the X-ray bright and X-ray faint populations of TDEs in this sample, finding that X-ray bright TDEs show higher peak blackbody luminosities than the X-ray faint sub-sample. This sample of optically selected TDEs is the largest sample of TDEs from a single survey yet, and the systematic discovery, classification, and follow-up of this sample allows for robust characterization of TDE properties, an important stepping stone looking forward toward the Rubin era., Comment: 44 pages, 22 figures, 9 tables, accepted to ApJ

Published

2023

63. A rotating white dwarf shows different compositions on its opposite faces.

Author

Caiazzo I, Burdge KB, Tremblay PE, Fuller J, Ferrario L, Gänsicke BT, Hermes JJ, Heyl J, Kawka A, Kulkarni SR, Marsh TR, Mróz P, Prince TA, Richer HB, Rodriguez AC, van Roestel J, Vanderbosch ZP, Vennes S, Wickramasinghe D, Dhillon VS, Littlefair SP, Munday J, Pelisoli I, Perley D, Bellm EC, Breedt E, Brown AJ, Dekany R, Drake A, Dyer MJ, Graham MJ, Green MJ, Laher RR, Kerry P, Parsons SG, Riddle RL, Rusholme B, and Sahman DI

Abstract

White dwarfs, the extremely dense remnants left behind by most stars after their death, are characterized by a mass comparable to that of the Sun compressed into the size of an Earth-like planet. In the resulting strong gravity, heavy elements sink towards the centre and the upper layer of the atmosphere contains only the lightest element present, usually hydrogen or helium 1,2 . Several mechanisms compete with gravitational settling to change a white dwarf's surface composition as it cools 3 , and the fraction of white dwarfs with helium atmospheres is known to increase by a factor of about 2.5 below a temperature of about 30,000 kelvin 4-8 ; therefore, some white dwarfs that appear to have hydrogen-dominated atmospheres above 30,000 kelvin are bound to transition to be helium-dominated as they cool below it. Here we report observations of ZTF J203349.8+322901.1, a transitioning white dwarf with two faces: one side of its atmosphere is dominated by hydrogen and the other one by helium. This peculiar nature is probably caused by the presence of a small magnetic field, which creates an inhomogeneity in temperature, pressure or mixing strength over the surface 9-11 . ZTF J203349.8+322901.1 might be the most extreme member of a class of magnetic, transitioning white dwarfs-together with GD 323 (ref. 12 ), a white dwarf that shows similar but much more subtle variations. This class of white dwarfs could help shed light on the physical mechanisms behind the spectral evolution of white dwarfs., (© 2023. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2023

64. Publisher Correction: A very luminous jet from the disruption of a star by a massive black hole.

Author

Andreoni I, Coughlin MW, Perley DA, Yao Y, Lu W, Cenko SB, Kumar H, Anand S, Ho AYQ, Kasliwal MM, de Ugarte Postigo A, Sagués-Carracedo A, Schulze S, Kann DA, Kulkarni SR, Sollerman J, Tanvir N, Rest A, Izzo L, Somalwar JJ, Kaplan DL, Ahumada T, Anupama GC, Auchettl K, Barway S, Bellm EC, Bhalerao V, Bloom JS, Bremer M, Bulla M, Burns E, Campana S, Chandra P, Charalampopoulos P, Cooke J, D'Elia V, Das KK, Dobie D, Fernández JFA, Freeburn J, Fremling C, Gezari S, Goode S, Graham MJ, Hammerstein E, Karambelkar VR, Kilpatrick CD, Kool EC, Krips M, Laher RR, Leloudas G, Levan A, Lundquist MJ, Mahabal AA, Medford MS, Miller MC, Möller A, Mooley KP, Nayana AJ, Nir G, Pang PTH, Paraskeva E, Perley RA, Petitpas G, Pursiainen M, Ravi V, Ridden-Harper R, Riddle R, Rigault M, Rodriguez AC, Rusholme B, Sharma Y, Smith IA, Stein RD, Thöne C, Tohuvavohu A, Valdes F, van Roestel J, Vergani SD, Wang Q, and Zhang J

Published

2023

65. A very luminous jet from the disruption of a star by a massive black hole.

Author

Andreoni I, Coughlin MW, Perley DA, Yao Y, Lu W, Cenko SB, Kumar H, Anand S, Ho AYQ, Kasliwal MM, de Ugarte Postigo A, Sagués-Carracedo A, Schulze S, Kann DA, Kulkarni SR, Sollerman J, Tanvir N, Rest A, Izzo L, Somalwar JJ, Kaplan DL, Ahumada T, Anupama GC, Auchettl K, Barway S, Bellm EC, Bhalerao V, Bloom JS, Bremer M, Bulla M, Burns E, Campana S, Chandra P, Charalampopoulos P, Cooke J, D'Elia V, Das KK, Dobie D, Fernández JFA, Freeburn J, Fremling C, Gezari S, Goode S, Graham MJ, Hammerstein E, Karambelkar VR, Kilpatrick CD, Kool EC, Krips M, Laher RR, Leloudas G, Levan A, Lundquist MJ, Mahabal AA, Medford MS, Miller MC, Möller A, Mooley KP, Nayana AJ, Nir G, Pang PTH, Paraskeva E, Perley RA, Petitpas G, Pursiainen M, Ravi V, Ridden-Harper R, Riddle R, Rigault M, Rodriguez AC, Rusholme B, Sharma Y, Smith IA, Stein RD, Thöne C, Tohuvavohu A, Valdes F, van Roestel J, Vergani SD, Wang Q, and Zhang J

Abstract

Tidal disruption events (TDEs) are bursts of electromagnetic energy that are released when supermassive black holes at the centres of galaxies violently disrupt a star that passes too close 1 . TDEs provide a window through which to study accretion onto supermassive black holes; in some rare cases, this accretion leads to launching of a relativistic jet 2-9 , but the necessary conditions are not fully understood. The best-studied jetted TDE so far is Swift J1644+57, which was discovered in γ-rays, but was too obscured by dust to be seen at optical wavelengths. Here we report the optical detection of AT2022cmc, a rapidly fading source at cosmological distance (redshift z = 1.19325) the unique light curve of which transitioned into a luminous plateau within days. Observations of a bright counterpart at other wavelengths, including X-ray, submillimetre and radio, supports the interpretation of AT2022cmc as a jetted TDE containing a synchrotron 'afterglow', probably launched by a supermassive black hole with spin greater than approximately 0.3. Using four years of Zwicky Transient Facility 10 survey data, we calculate a rate of [Formula: see text] per gigapascals cubed per year for on-axis jetted TDEs on the basis of the luminous, fast-fading red component, thus providing a measurement complementary to the rates derived from X-ray and radio observations 11 . Correcting for the beaming angle effects, this rate confirms that approximately 1 per cent of TDEs have relativistic jets. Optical surveys can use AT2022cmc as a prototype to unveil a population of jetted TDEs., (© 2022. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2022