Your search keyword '"Ud-Doula, A."' showing total 430 results

401. Understanding structure in line-driven stellar winds using ultraviolet spectropolarimetry in the time domain.

Author

Gayley, Kenneth G., Vink, Jorick S., ud-Doula, Asif, David-Uraz, Alexandre, Ignace, Richard, Prinja, Raman, St-Louis, Nicole, Ekström, Sylvia, Nazé, Yaël, Shenar, Tomer, Scowen, Paul A., Sudnik, Natallia, Owocki, Stan P., Sundqvist, Jon O., Driessen, Florian A., and Hennicker, Levin

Subjects

*STELLAR structure, *STELLAR winds, *POLARIMETRY, *SUPERGIANT stars, *ASTRONOMICAL observations, *TIME series analysis, *ULTRAVIOLET astronomy

Abstract

The most massive stars are thought to lose a significant fraction of their mass in a steady wind during the main-sequence and blue supergiant phases. This in turn sets the stage for their further evolution and eventual supernova, and preconditions the surrounding medium for all following events, with consequences for ISM energization, chemical enrichment, and dust formation. Understanding these processes requires accurate observational constraints on the mass-loss rates of the most luminous stars, which can also be used to test theories of stellar wind driving. In the past, mass-loss rates have been characterized via collisional emission processes such as optical H α and free-free radio emission, but these so-called "density squared" diagnostics require correction in the presence of widespread clumping. Recent observational and theoretical evidence points to the likelihood of a ubiquitously high level of such clumping in hot-star winds, but quantifying its effects requires a deeper understanding of the complex dynamics of radiatively driven winds and their stochastic instabilities. Furthermore, large-scale structures initiating in surface anisotropies and propagating throughout the wind can also affect wind driving and alter mass-loss diagnostics. Time series spectroscopy of high resonance-line opacity in the UV, capable of high resolution and high signal-to-noise, are required to better understand these complex dynamics, and more accurately determine mass-loss rates. The proposed Polstar mission (Scowen et al. 2022, this volume) provides the necessary resolution at the Sobolev (∼10 km s−1) or sound-speed (∼20 km s−1) scale, for over three dozen bright galactic massive stars with signal-to noise an order of magnitude above that of the celebrated MEGA campaign (Massa et al. 1995) of the International Ultraviolet Explorer (IUE), via continuous observations that track propagating structures through the winds in real time. Supporting geometric constraints are provided by the polarimetric capabilities present in all the datasets of such a mission. [ABSTRACT FROM AUTHOR]

Published

2022

402. The effects of surface fossil magnetic fields on massive star evolution: V. Models at low metallicity.

Author

Keszthelyi, Z, Puls, J, Chiaki, G, Nagakura, H, ud-Doula, A, Takiwaki, T, and Tominaga, N

Subjects

*STELLAR rotation, *SMALL magellanic cloud, *MAGNETIC flux density, *SUPERGIANT stars, *STELLAR winds, *STELLAR evolution, *STELLAR magnetic fields

Abstract

At metallicities lower than that of the Small Magellanic Cloud, it remains essentially unexplored how fossil magnetic fields, forming large-scale magnetospheres, could affect the evolution of massive stars, thereby impacting the fundamental building blocks of the early Universe. We extend our stellar evolution model grid with representative calculations of main-sequence, single-star models with initial masses of 20 and 60 M |$_\odot$|⁠ , including appropriate changes for low-metallicity environments (⁠|$Z = 10^{-3}$| – |$10^{-6}$|⁠). We scrutinize the magnetic, rotational, and chemical properties of the models. When lowering the metallicity, the rotational velocities can become higher and the tendency towards quasi-chemically homogeneous evolution increases. While magnetic fields aim to prevent the development of this evolutionary channel, the weakening stellar winds lead to less efficient magnetic braking in our models. Since the stellar radius is almost constant during a blueward evolution caused by efficient chemical mixing, the surface magnetic field strength remains unchanged in some models. We find core masses at the terminal-age main sequence between 22 and 52 M |$_\odot$| for initially 60 M |$_\odot$| models. This large difference is due to the vastly different chemical and rotational evolution. We conclude that in order to explain chemical species and, in particular, high nitrogen abundances in the early Universe, the adopted stellar models need to be under scrutiny. The assumptions regarding wind physics, chemical mixing, and magnetic fields will strongly impact the model predictions. [ABSTRACT FROM AUTHOR]

Published

2024

403. Flowering pattern, floral abscission and yield attributes in soybean influenced by GABA

Author

Mohammad Abdur Rahim, M.O Islam, and A.K.M. Azad-ud-doula Prodhan .

Subjects

Crop, Point of delivery, Abscission, Agronomy, Yield (wine), fungi, food and beverages, Abscissic Acid, Biology

Abstract

An experiment was carried out in the field laboratory of the Department of Crop Botany, Bangladesh Agricultural University, Mymensingh, to investigate the flowering pattern, floral and pod abscission under untreated and GABA (mixture of GA3 and Abscissic acid) treated soybean and their trends concern to yield. The variety of soybean PB-1 (Shohag) was used in the investigation. GABA at 0.5, 1.0 and 2.0 mg L-1 of water with a control (only water) were used for foliar spray. Flower and pod initiation started from 54 and 60 DAS in all plants irrespective to GABA treatment. Flower production trend showed a deltoid pattern where pod production was gradually increased and slowed down at 74 DAS but not in GABA treated plant. The 4th node produced the highest number of flowers, then decreased and got zigzag pattern in upper nodes. GABA treated plants produced more nodes per plant and followed lower trend in flower and pod abscission indicated the efficacy of higher yield. Keywords: Flowering pattern; Floral abscission; Yield; Soybean; GABA DOI: 10.3329/jbau.v8i1.6394J. Bangladesh Agril. Univ. 8(1): 29-33, 2010

Published

1970

404. Backbone Dipoles Generate Positive Potentials in all Proteins: Origins and Implications of the Effect

Author

Marilyn R. Gunner, Mohammad A. Saleh, Asif ud-Doula, Michael Wise, and Elizabeth Cross

Subjects

Models, Molecular, chemistry.chemical_classification, Proton, Chemistry, Static Electricity, Biophysics, Proteins, Peptide, Calorimetry, Hydrogen-Ion Concentration, Ligands, Amides, Protein Structure, Secondary, Folding (chemistry), Kinetics, Crystallography, Dipole, chemistry.chemical_compound, Yield (chemistry), Amide, Side chain, Organic chemistry, Amine gas treating, Amino Acids, Research Article

Abstract

Asymmetry in packing the peptide amide dipole results in larger positive than negative regions in proteins of all folding motifs. The average side chain potential in 305 proteins is 109 +/- 30 mV (2. 5 +/- 0.7 kcal/mol/e). Because the backbone has zero net charge, the non-zero potential is unexpected. The larger oxygen at the negative and smaller proton at the positive end of the amide dipole yield positive potentials because: 1) at allowed phi and psi angles residues come off the backbone into the positive end of their own amide dipole, avoiding the large oxygen; and 2) amide dipoles with their carbonyl oxygen surface exposed and amine proton buried make the protein interior more positive. Twice as many amides have their oxygens exposed than their amine protons. The distribution of acidic and basic residues shows the importance of the bias toward positive backbone potentials. Thirty percent of the Asp, Glu, Lys, and Arg are buried. Sixty percent of buried residues are acids, only 40% bases. The positive backbone potential stabilizes ionization of 20% of the acids by >3 pH units (-4.1 kcal/mol). Only 6.5% of the bases are equivalently stabilized by negative regions. The backbone stabilizes bound anions such as phosphates and rarely stabilizes bound cations.

405. X-ray emission line profile modeling of hot stars.

Author

Kramer, Roban H., Tonnesen, Stephanie K., Cohen, David H., Owocki, Stanley P., ud-Doula, Asif, and MacFarlane, Joseph J.

Subjects

X-ray spectroscopy, X-ray telescopes, SCIENTIFIC apparatus & instruments

Abstract

The launch of high-spectral-resolution x-ray telescopes (Chandra, XMM) has provided a host of new spectral line diagnostics for the astrophysics community. In this paper we discuss Doppler-broadened emission line profiles from highly supersonic outflows of massive stars. These outflows, or winds, are driven by radiation pressure and carry a tremendous amount of kinetic energy, which can be converted to x rays by shock-heating even a small fraction of the wind plasma. The unshocked, cold wind is a source of continuum opacity to the x rays generated in the shock-heated portion of the wind. Thus the emergent line profiles are affected by transport through a two-component, moving, optically thick medium. While complicated, the interactions among these physical effects can provide quantitative information about the spatial distribution and velocity of the x-ray-emitting and absorbing plasma in stellar winds. We present quantitative models of both a spherically symmetric wind and a wind with hot plasma confined in an equatorial disk by a dipole magnetic field. [ABSTRACT FROM AUTHOR]

Published

2003

406. X-ray emission from magnetic massive stars

Author

Naze, Y., Pétit, V., Rindbrand, M., David Cohen, Owocki, S., Ud-Doula, A., Wade, G., and Rauw, G.

407. The Hot and Energetic Universe: A White Paper presenting the science theme motivating the Athena+ mission

Author

Nandra, Kirpal, Barret, Didier, Barcons, Xavier, Fabian, Andy, Herder, Jan-Willem Den, Piro, Luigi, Watson, Mike, Adami, Christophe, Aird, James, Afonso, Jose Manuel, Alexander, Dave, Argiroffi, Costanza, Amati, Lorenzo, Arnaud, Monique, Atteia, Jean-Luc, Audard, Marc, Badenes, Carles, Ballet, Jean, Ballo, Lucia, Bamba, Aya, Bhardwaj, Anil, Battistelli, Elia Stefano, Becker, Werner, Becker, Michaël De, Behar, Ehud, Bianchi, Stefano, Biffi, Veronica, Bîrzan, Laura, Bocchino, Fabrizio, Bogdanov, Slavko, Boirin, Laurence, Boller, Thomas, Borgani, Stefano, Borm, Katharina, Bouché, Nicolas, Bourdin, Hervé, Bower, Richard, Braito, Valentina, Branchini, Enzo, Branduardi-Raymont, Graziella, Bregman, Joel, Brenneman, Laura, Brightman, Murray, Brüggen, Marcus, Buchner, Johannes, Bulbul, Esra, Brusa, Marcella, Bursa, Michal, Caccianiga, Alessandro, Cackett, Ed, Campana, Sergio, Cappelluti, Nico, Cappi, Massimo, Carrera, Francisco, Ceballos, Maite, Christensen, Finn, Chu, You-Hua, Churazov, Eugene, Clerc, Nicolas, Corbel, Stephane, Corral, Amalia, Comastri, Andrea, Costantini, Elisa, Croston, Judith, Dadina, Mauro, D'Ai, Antonino, Decourchelle, Anne, Ceca, Roberto Della, Dennerl, Konrad, Dolag, Klaus, Done, Chris, Dovciak, Michal, Drake, Jeremy, Eckert, Dominique, Edge, Alastair, Ettori, Stefano, Ezoe, Yuichiro, Feigelson, Eric, Fender, Rob, Feruglio, Chiara, Finoguenov, Alexis, Fiore, Fabrizio, Galeazzi, Massimiliano, Gallagher, Sarah, Gandhi, Poshak, Gaspari, Massimo, Gastaldello, Fabio, Georgakakis, Antonis, Georgantopoulos, Ioannis, Gilfanov, Marat, Gitti, Myriam, Gladstone, Randy, Goosmann, Rene, Gosset, Eric, Grosso, Nicolas, Guedel, Manuel, Guerrero, Martin, Haberl, Frank, Hardcastle, Martin, Heinz, Sebastian, Herrero, Almudena Alonso, Hervé, Anthony, Holmstrom, Mats, Iwasawa, Kazushi, Jonker, Peter, Kaastra, Jelle, Kara, Erin, Karas, Vladimir, Kastner, Joel, King, Andrew, Kosenko, Daria, Koutroumpa, Dimita, Kraft, Ralph, Kreykenbohm, Ingo, Lallement, Rosine, Lanzuisi, Giorgio, Lee, J, Lemoine-Goumard, Marianne, Lobban, Andrew, Lodato, Giuseppe, Lovisari, Lorenzo, Lotti, Simone, McCharthy, Ian, McNamara, Brian, Maggio, Antonio, Maiolino, Roberto, Marco, Barbara De, Martino, Domitilla De, Mateos, Silvia, Matt, Giorgio, Maughan, Ben, Mazzotta, Pasquale, Mendez, Mariano, Merloni, Andrea, Micela, Giuseppina, Miceli, Marco, Mignani, Robert, Miller, Jon, Miniutti, Giovanni, Molendi, Silvano, Montez, Rodolfo, Moretti, Alberto, Motch, Christian, Nazé, Yaël, Nevalainen, Jukka, Nicastro, Fabrizio, Nulsen, Paul, Ohashi, Takaya, O'Brien, Paul, Osborne, Julian, Oskinova, Lida, Pacaud, Florian, Paerels, Frederik, Page, Mat, Papadakis, Iossif, Pareschi, Giovanni, Petre, Robert, Petrucci, Pierre-Olivier, Piconcelli, Enrico, Pillitteri, Ignazio, Pinto, C, Plaa, Jelle De, Pointecouteau, Etienne, Ponman, Trevor, Ponti, Gabriele, Porquet, Delphine, Pounds, Ken, Pratt, Gabriel, Predehl, Peter, Proga, Daniel, Psaltis, Dimitrios, Rafferty, David, Ramos-Ceja, Miriam, Ranalli, Piero, Rasia, Elena, Rau, Arne, Rauw, Gregor, Rea, Nanda, Read, Andy, Reeves, James, Reiprich, Thomas, Renaud, Matthieu, Reynolds, Chris, Risaliti, Guido, Rodriguez, Jerome, Hidalgo, Paola Rodriguez, Roncarelli, Mauro, Rosario, David, Rossetti, Mariachiara, Rozanska, Agata, Rovilos, Emmanouil, Salvaterra, Ruben, Salvato, Mara, Salvo, Tiziana Di, Sanders, Jeremy, Sanz-Forcada, Jorge, Schawinski, Kevin, Schaye, Joop, Schwope, Axel, Sciortino, Salvatore, Severgnini, Paola, Shankar, Francesco, Sijacki, Debora, Sim, Stuart, Schmid, Christian, Smith, Randall, Steiner, Andrew, Stelzer, Beate, Stewart, Gordon, Strohmayer, Tod, Strüder, Lothar, Sun, Ming, Takei, Yoh, Tatischeff, V, Tiengo, Andreas, Tombesi, Francesco, Trinchieri, Ginevra, Tsuru, TG, Ud-Doula, Asif, Ursino, Eugenio, Valencic, Lynne, Vanzella, Eros, Vaughan, Simon, Vignali, Cristian, Vink, Jacco, Vito, Fabio, Volonteri, Marta, Wang, Daniel, Webb, Natalie, Willingale, Richard, Wilms, Joern, Wise, Michael, Worrall, Diana, Young, Andrew, Zampieri, Luca, Zand, Jean In't, Zane, Silvia, Zezas, Andreas, Zhang, Yuying, and Zhuravleva, Irina

Subjects

astro-ph.HE, astro-ph.SR, 13. Climate action, Astrophysics::High Energy Astrophysical Phenomena, astro-ph.EP, Astrophysics::Instrumentation and Methods for Astrophysics, astro-ph.CO, Astrophysics::Cosmology and Extragalactic Astrophysics, 7. Clean energy, astro-ph.IM

Abstract

This White Paper, submitted to the recent ESA call for science themes to define its future large missions, advocates the need for a transformational leap in our understanding of two key questions in astrophysics: 1) How does ordinary matter assemble into the large scale structures that we see today? 2) How do black holes grow and shape the Universe? Hot gas in clusters, groups and the intergalactic medium dominates the baryonic content of the local Universe. To understand the astrophysical processes responsible for the formation and assembly of these large structures, it is necessary to measure their physical properties and evolution. This requires spatially resolved X-ray spectroscopy with a factor 10 increase in both telescope throughput and spatial resolving power compared to currently planned facilities. Feedback from supermassive black holes is an essential ingredient in this process and in most galaxy evolution models, but it is not well understood. X-ray observations can uniquely reveal the mechanisms launching winds close to black holes and determine the coupling of the energy and matter flows on larger scales. Due to the effects of feedback, a complete understanding of galaxy evolution requires knowledge of the obscured growth of supermassive black holes through cosmic time, out to the redshifts where the first galaxies form. X-ray emission is the most reliable way to reveal accreting black holes, but deep survey speed must improve by a factor ~100 over current facilities to perform a full census into the early Universe. The Advanced Telescope for High Energy Astrophysics (Athena+) mission provides the necessary performance (e.g. angular resolution, spectral resolution, survey grasp) to address these questions and revolutionize our understanding of the Hot and Energetic Universe. These capabilities will also provide a powerful observatory to be used in all areas of astrophysics.

408. An X-ray Comparison of Centrifugal Magnetospheres in Five B-type Stars

Author

Fletcher, Corinne, Petit, Veronique, Yael Naze, Ud-Doula, Asif, Wade, Gregg, Shultz, Matt, and Held Cohen, David

409. The latest developments on Of?p stars

Author

Nazé, Yael, ud-Doula, Asif, Spano, Maxime, Rauw, Gregor, De Becker, Michael, Walborn, Nolan R., Nazé, Yael, ud-Doula, Asif, Spano, Maxime, Rauw, Gregor, De Becker, Michael, and Walborn, Nolan R.

Abstract

In recent years several in-depth investigations of the three prototypical Of?p stars were undertaken, revealing their peculiar properties. To clarify some of the remaining questions, we have continued our monitoring of the prototypical Of?p trio. HD 108 has now reached its quiescent, minimum-emission state, for the first time in 50-60yrs, while new echelle spectra of HD 148937 confirm the presence in several H and He lines of the 7d variations detected previously only in the Hα line. A new XMM observation of HD 191612 clearly shows that its X-ray emission is not modulated by the orbital period of 1542d, but the high-energy variations are rather compatible with the 538d period of the optical changes - it is thus not of colliding-wind origin but linked to the phenomena responsible for the spectral/photometric variations, though our current MHD simulations remain at odds with the observational properties

410. CHANDRA VIEW OF MAGNETICALLY CONFINED WIND IN HD 191612: THEORY VERSUS OBSERVATIONS.

Author

Yaël Nazé, Asif ud-Doula, and Svetozar A. Zhekov

Subjects

*MAGNETIC stars, *MAGNETARS, *EMISSION control, *SUPERGIANT stars, *MAGNETOHYDRODYNAMICS

Abstract

High-resolution spectra of the magnetic star HD 191612 were acquired using the Chandra X-ray Observatory at both maximum and minimum emission phases. We confirm the flux and hardness variations previously reported with XMM-Newton, demonstrating the high repeatability of the behavior of HD 191612 over a decade. The line profiles appear typical for magnetic massive stars: no significant line shift, relatively narrow lines for high-Z elements, and formation radius at about . Line ratios confirm the softening of the X-ray spectrum at the minimum emission phase. Shift or width variations appear of limited amplitude at most (slightly lower velocity and slightly increased broadening at minimum emission phase, but within 1–2σ of values at maximum). In addition, a fully self-consistent 3D magnetohydrodynamic simulation of the confined wind in HD 191612 was performed. The simulation results were directly fitted to the data, leading to a remarkable agreement overall between them. [ABSTRACT FROM AUTHOR]

Published

2016

411. ERRATUM: “X-RAY EMISSION FROM MAGNETIC MASSIVE STARS” (APJS, 215, 10).

Author

Yaël Nazé, Véronique Petit, Melanie Rinbrand, David Cohen, Stan Owocki, Asif ud-Doula, and Gregg A. Wade

Published

2016

412. Discovery of extraordinary X-ray emission from magnetospheric interaction in the unique binary stellar system ϵ Lupi.

Author

Das, B, Petit, V, Nazé, Y, Corcoran, M F, Cohen, D H, Biswas, A, Chandra, P, David-Uraz, A, Leutenegger, M A, Neiner, C, Pablo, H, Paunzen, E, Shultz, M E, ud-Doula, A, and Wade, G A

Subjects

*MAGNETIC reconnection, *X-ray binaries, *X-ray telescopes, *MAGNETIC fields, *STELLAR winds, *NEUTRON stars, *MAGNETIC properties, *STELLAR magnetic fields

Abstract

We report detailed X-ray observations of the unique binary system ϵ Lupi, the only known short-period binary consisting of two magnetic early-type stars. The components have comparably strong, but anti-aligned magnetic fields. The orbital and magnetic properties of the system imply that the magnetospheres overlap at all orbital phases, suggesting the possibility of variable inter-star magnetospheric interaction due to the non-negligible eccentricity of the orbit. To investigate this effect, we observed the X-ray emission from ϵ Lupi, both near and away from periastron passage, using the Neutron Star Interior Composition Explorer mission (NICER) X-ray Telescope. We find that the system produces excess X-ray emission at the periastron phase, suggesting the presence of variable inter-star magnetospheric interaction. We also discover that the enhancement at periastron is confined to a very narrow orbital phase range (⁠|$\approx 5~{{\ \rm per\ cent}}$| of the orbital period), but the X-ray properties close to periastron phase are similar to those observed away from periastron. From these observations, we infer that the underlying cause is magnetic reconnection heating the stellar wind plasma, rather than shocks produced by wind–wind collision. Finally, by comparing the behavior of ϵ Lupi with that observed for cooler magnetic binary systems, we propose that elevated X-ray flux at periastron phase is likely a general characteristic of interacting magnetospheres irrespective of the spectral types of the constituent stars. [ABSTRACT FROM AUTHOR]

Published

2023

413. Chandra HETGS Multiphase Spectroscopy of the Young Magnetic O Star θ1 Orionis C.

Author

Gagné, Marc, Oksala, Mary E., Cohen, David H., Tonnesen, Stephanie K., ud-Doula, Asif, Owocki, Stanley P., Townsend, Richard H. D., and MacFarlane, Joseph J.

Published

2005

414. Electron scattering emission in the light curves of stars with centrifugal magnetospheres.

Author

Berry, I D, Owocki, S P, Shultz, M E, and ud-Doula, A

Subjects

*ELECTRON scattering, *LIGHT curves, *ELECTRON emission, *LIGHT scattering, *MAGNETOSPHERE

Abstract

Strongly magnetic, rapidly rotating B-type stars with relatively weak winds form centrifugal magnetospheres (CMs), as the stellar wind becomes magnetically confined above the Kepler co-rotation radius. Approximating the magnetic field as a dipole tilted by an angle β with respect to the rotation axis, the CM plasma is concentrated in clouds at and above the Kepler radius along the intersection of the rotational and magnetic equatorial planes. Stellar rotation can bring such clouds in front of the stellar disc, leading to absorption of the order of 0.1 mag (⁠|$\sim 10 {{\ \rm per\ cent}}$| of continuum flux). However, some stars with prominent CMs, such as σ Ori E, show an emission bump in addition to absorption dips, which has been so far unexplained. We show that emission can occur from electron scattering towards the observer when CM clouds are projected off the stellar limb. Using the rigidly rotating magnetosphere model, modified with a centrifugal breakout density scaling, we present a model grid of photometric light curves spanning parameter space in observer inclination angle i , magnetic obliquity angle β, critical rotation fraction W , and optical depth at the Kepler radius τK. We show that τK of order unity can produce emission bumps of the magnitude ∼0.05 seen in σ Ori E. We discuss the implications for modelling the light curves of CM stars, as well as future work for applying the radiative transfer model developed here to 3D magnetohydrodynamic simulations of CMs. [ABSTRACT FROM AUTHOR]

Published

2022

415. Ultraviolet line profiles of slowly rotating massive star winds using the 'analytic dynamical magnetosphere' formalism.

Author

Erba, C, David-Uraz, A, Petit, V, Hennicker, L, Fletcher, C, Fullerton, A W, Nazé, Y, Sundqvist, J, and ud-Doula, A

Subjects

*SUPERGIANT stars, *MAGNETOSPHERE, *STELLAR winds, *MAGNETIC flux density, *STELLAR magnetic fields, *RADIATIVE transfer

Abstract

Recent large-scale spectropolarimetric surveys have established that a small but significant percentage of massive stars host stable, surface dipolar magnetic fields with strengths on the order of kG. These fields channel the dense, radiatively driven stellar wind into circumstellar magnetospheres, whose density and velocity structure can be probed using ultraviolet (UV) spectroscopy of wind-sensitive resonance lines. Coupled with appropriate magnetosphere models, UV spectroscopy provides a valuable way to investigate the wind–field interaction, and can yield quantitative estimates of the wind parameters of magnetic massive stars. We report a systematic investigation of the formation of UV resonance lines in slowly rotating magnetic massive stars with dynamical magnetospheres. We pair the analytic dynamical magnetosphere (ADM) formalism with a simplified radiative transfer technique to produce synthetic UV line profiles. Using a grid of models, we examine the effect of magnetosphere size, the line strength parameter, and the cooling parameter on the structure and modulation of the line profile. We find that magnetic massive stars uniquely exhibit redshifted absorption at most viewing angles and magnetosphere sizes, and that significant changes to the shape and variation of the line profile with varying line strengths can be explained by examining the individual wind components described in the ADM formalism. Finally, we show that the cooling parameter has a negligible effect on the line profiles. [ABSTRACT FROM AUTHOR]

Published

2021

416. Spin-down and reduced mass loss in early-type stars with large-scale magnetic fields.

Author

Keszthelyi, Z., de Koter, A., Götberg, Y., Meynet, G., Brands, S.A., Petit, V., Carrington, M., David-Uraz, A., Geen, S.T., Georgy, C., Hirschi, R., Puls, J., Ramalatswa, K.J., Shultz, M.E., and ud-Doula, A.

Subjects

*STELLAR magnetic fields, *STELLAR evolution, *SUPERGIANT stars, *STELLAR rotation, *STELLAR activity

Abstract

Magnetism can greatly impact the evolution of stars. In some stars with OBA spectral types there is direct evidence via the Zeeman effect for stable, large-scale magnetospheres, which lead to the spin-down of the stellar surface and reduced mass loss. So far, a comprehensive grid of stellar structure and evolution models accounting for these effects was lacking. For this reason, we computed and studied models with two magnetic braking and two chemical mixing schemes in three metallicity environments with the mesa software instrument. We find notable differences between the subgrids, which affects the model predictions and thus the detailed characterisation of stars. We are able to quantify the impact of magnetic fields in terms of preventing quasi-chemically homogeneous evolution and producing slowly-rotating, nitrogen-enriched ("Group 2") stars. Our model grid is fully open access and open source. [ABSTRACT FROM AUTHOR]

Published

2021

417. MOBSTER – IV. Detection of a new magnetic B-type star from follow-up spectropolarimetric observations of photometrically selected candidates★.

Author

David-Uraz, A, Shultz, M E, Petit, V, Bowman, D M, Erba, C, Fine, R A, Neiner, C, Pablo, H, Sikora, J, ud-Doula, A, and Wade, G A

Subjects

*STELLAR magnetic fields, *B stars, *MAGNETIC fields, *STELLAR rotation

Abstract

In this paper, we present results from the spectropolarimetric follow-up of photometrically selected candidate magnetic B stars from the MOBSTER (Magnetic OB[A] Stars with TESS : probing their Evolutionary and Rotational properties) project. Out of four observed targets, one (HD 38170) is found to host a detectable surface magnetic field, with a maximum longitudinal field measurement of 105 ± 14 G. This star is chemically peculiar and classified as an α2 CVn variable. Its detection validates the use of the Transiting Exoplanet Survey Satellite (TESS) to perform a photometric selection of magnetic candidates. Furthermore, upper limits on the strength of a putative dipolar magnetic field are derived for the remaining three stars, and we report the discovery of a previously unknown spectroscopic binary system, HD 25709. Finally, we use our non-detections as case studies to further inform the criteria to be used for the selection of a larger sample of stars to be followed up using high-resolution spectropolarimetry. [ABSTRACT FROM AUTHOR]

Published

2021

418. The magnetic early B-type stars – IV. Breakout or leakage? H α emission as a diagnostic of plasma transport in centrifugal magnetospheres.

Author

Shultz, M E, Owocki, S, Rivinius, Th, Wade, G A, Neiner, C, Alecian, E, Kochukhov, O, Bohlender, D, ud-Doula, A, Landstreet, J D, Sikora, J, David-Uraz, A, Petit, V, Cerrahoğlu, P, Fine, R, Henson, G, and Collaborations, MiMeS and BinaMIcS

Subjects

*EARLY stars, *MAGNETOSPHERE, *PLASMA confinement, *LEAKAGE, *CIRCUMSTELLAR matter, *MASS loss (Astrophysics)

Abstract

Rapidly rotating early-type stars with strong magnetic fields frequently show H α emission originating in centrifugal magnetospheres (CMs), circumstellar structures in which centrifugal support due to magnetically enforced corotation of the magnetically confined plasma enables it to accumulate to high densities. It is not currently known whether the CM plasma escapes via centrifugal breakout (CB), or by an unidentified leakage mechanism. We have conducted the first comprehensive examination of the H α emission properties of all stars currently known to display CM-pattern emission. We find that the onset of emission is dependent primarily on the area of the CM, which can be predicted simply by the value B K of the magnetic field at the Kepler corotation radius R K. Emission strength is strongly sensitive to both CM area and B K. Emission onset and strength are not dependent on effective temperature, luminosity, or mass-loss rate. These results all favour a CB scenario; however, the lack of intrinsic variability in any CM diagnostics indicates that CB must be an essentially continuous process, i.e. it effectively acts as a leakage mechanism. We also show that the emission profile shapes are approximately scale-invariant, i.e. they are broadly similar across a wide range of emission strengths and stellar parameters. While the radius of maximum emission correlates closely as expected to R K, it is always larger, contradicting models that predict that emission should peak at R K. [ABSTRACT FROM AUTHOR]

Published

2020

419. The effects of surface fossil magnetic fields on massive star evolution – II. Implementation of magnetic braking in mesa and implications for the evolution of surface rotation in OB stars.

Author

Keszthelyi, Z, Meynet, G, Shultz, M E, David-Uraz, A, ud-Doula, A, Townsend, R H D, Wade, G A, Georgy, C, Petit, V, and Owocki, S P

Subjects

*STELLAR rotation, *STELLAR evolution, *SUPERGIANT stars, *YIELD surfaces, *STELLAR magnetic fields, *ANGULAR momentum (Mechanics)

Abstract

The time evolution of angular momentum and surface rotation of massive stars are strongly influenced by fossil magnetic fields via magnetic braking. We present a new module containing a simple, comprehensive implementation of such a field at the surface of a massive star within the Modules for Experiments in Stellar Astrophysics (mesa) software instrument. We test two limiting scenarios for magnetic braking: distributing the angular momentum loss throughout the star in the first case, and restricting the angular momentum loss to a surface reservoir in the second case. We perform a systematic investigation of the rotational evolution using a grid of OB star models with surface magnetic fields (M ⋆ = 5–60 M⊙, Ω/Ωcrit = 0.2–1.0, B p = 1–20 kG). We then employ a representative grid of B-type star models (M ⋆ = 5, 10, 15 M⊙, Ω/Ωcrit = 0.2, 0.5, 0.8, B p = 1, 3, 10, 30 kG) to compare to the results of a recent self-consistent analysis of the sample of known magnetic B-type stars. We infer that magnetic massive stars arrive at the zero-age main sequence (ZAMS) with a range of rotation rates, rather than with one common value. In particular, some stars are required to have close-to-critical rotation at the ZAMS. However, magnetic braking yields surface rotation rates converging to a common low value, making it difficult to infer the initial rotation rates of evolved, slowly rotating stars. [ABSTRACT FROM AUTHOR]

Published

2020

420. The magnetic early B-type stars – III. A main-sequence magnetic, rotational, and magnetospheric biography.

Author

Shultz, M E, Wade, G A, Rivinius, Th, Alecian, E, Neiner, C, Petit, V, Owocki, S, ud-Doula, A, Kochukhov, O, Bohlender, D, Keszthelyi, Z, and Collaborations, the MiMeS and BinaMIcS

Subjects

*EARLY stars, *STELLAR winds, *MAGNETIC flux density, *MAGNETIC confinement, *MAGNETIC measurements, *STELLAR magnetic fields, *AGE of stars, *MAGNETIC flux

Abstract

Magnetic confinement of stellar winds leads to the formation of magnetospheres, which can be sculpted into centrifugal magnetospheres (CMs) by rotational support of the corotating plasma. The conditions required for the CMs of magnetic early B-type stars to yield detectable emission in H α – the principal diagnostic of these structures – are poorly constrained. A key reason is that no detailed study of the magnetic and rotational evolution of this population has yet been performed. Using newly determined rotational periods, modern magnetic measurements, and atmospheric parameters determined via spectroscopic modelling, we have derived fundamental parameters, dipolar oblique rotator models, and magnetospheric parameters for 56 early B-type stars. Comparison to magnetic A- and O-type stars shows that the range of surface magnetic field strength is essentially constant with stellar mass, but that the unsigned surface magnetic flux increases with mass. Both the surface magnetic dipole strength and the total magnetic flux decrease with stellar age, with the rate of flux decay apparently increasing with stellar mass. We find tentative evidence that multipolar magnetic fields may decay more rapidly than dipoles. Rotational periods increase with stellar age, as expected for a magnetic braking scenario. Without exception, all stars with H α emission originating in a CM are (1) rapid rotators, (2) strongly magnetic, and (3) young, with the latter property consistent with the observation that magnetic fields and rotation both decrease over time. [ABSTRACT FROM AUTHOR]

Published

2019

421. Extreme resonance line profile variations in the ultraviolet spectra of NGC 1624-2: probing the giant magnetosphere of the most strongly magnetized known O-type star.

Author

David-Uraz, A, Erba, C, Petit, V, Fullerton, A W, Martins, F, Walborn, N R, MacInnis, R, Barbá, R H, Cohen, D H, Maíz Apellániz, J, Nazé, Y, Owocki, S P, Sundqvist, J O, ud-Doula, A, and Wade, G A

Subjects

*RING Nebula, *ULTRAVIOLET spectra, *MAGNETIC stars, *GALACTIC redshift, *MAGNETOSPHERE

Abstract

In this paper, we present high-resolution HST/COS observations of the extreme magnetic O star NGC 1624-2. These represent the first ultraviolet spectra of this archetypal object. We examine the variability of its wind-sensitive resonance lines, comparing it to that of other known magnetic O stars. In particular, the observed variations in the profiles of the C   iv and Si   iv doublets between low state and high state are the largest observed in any magnetic O-type star, consistent with the expected properties of NGC 1624-2's magnetosphere. We also observe a redshifted absorption component in the low state, a feature not seen in most stars. We present preliminary modelling efforts based on the Analytic Dynamical Magnetosphere (ADM) formalism, demonstrating the necessity of using non-spherically symmetric models to determine wind/magnetospheric properties of magnetic O stars. [ABSTRACT FROM AUTHOR]

Published

2019

422. A JVLA survey of the high-frequency radio emission of the massive magnetic B- and O-type stars.

Author

Kurapati, Sushma, Chandra, Poonam, Wade, Gregg, Cohen, David H., David-Uraz, Alexandre, Gagne, Marc, Grunhut, Jason, Oksala, Mary E., Petit, Veronique, Shultz, Matt, Sundqvist, Jon, Townsend, Richard H. D., and ud-Doula, Asif

Subjects

*BINARY stars, *MASS loss (Astrophysics), *MAGNETIC stars, *STELLAR mass, *MAGNETOSPHERE

Abstract

We conducted a survey of seven magnetic O-type stars and eleven B-type stars with masses above 8M⊙ using the Very Large Array in the 1, 3 and 13 cm bands. The survey resulted in a detection of two O- and two B-type stars. While the detected O-type stars - HD 37742 and HD 47129 - are in binary systems, the detected B-type stars, HD 156424 and ALS 9522, are not known to be in binaries. All four stars were detected at 3 cm, whereas three were detected at 1 cm and only one star was detected at 13 cm. The detected B-type stars are significantly more radio luminous than the non-detected ones, which is not the case for O-type stars. The non-detections at 13 cm are interpreted as due to thermal free-free absorption. Mass-loss rates were estimated using 3 cm flux densities and were compared with theoretical mass-loss rates, which assume free-free emission. For HD 37742, the two values of the massloss rates were in good agreement, possibly suggesting that the radio emission for this star is mainly thermal. For the other three stars, the estimated mass-loss rates from radio observations were much higher than those expected from theory, suggesting either a possible contribution from non-thermal emission from the magnetic star or thermal or non-thermal emission due to interacting winds of the binary system, especially for HD 47129. All the detected stars are predicted to host centrifugal magnetospheres except HD 37742, which is likely to host a dynamical magnetosphere. This suggests that non-thermal radio emission is favoured in stars with centrifugal magnetospheres. [ABSTRACT FROM AUTHOR]

Published

2017

423. X-ray emission from the giant magnetosphere of the magnetic O-type star NGC 1624-2.

Author

Petit, V., Cohen, D. H., Wade, G. A., Nazé, Y., Owocki, S. P., Sundqvist, J. O., ud-Doula, A., Fullerton, A., Leutenegger, M., and Gagné, M.

Subjects

*X-ray astronomy, *MAGNETOSPHERE, *MAGNETIC fields, *PHOTON detectors, *LUMINOSITY

Abstract

We observed NGC 1624-2, the O-type star with the largest known magnetic field (Bp ~ 20kG), in X-rays with the Advanced CCD Imaging Spectrometer (ACIS-S) camera on-board the Chandra X-ray Observatory. Our two observations were obtained at the minimum and maximum of the periodic Hα emission cycle, corresponding to the rotational phases where the magnetic field is the closest to equator-on and pole-on, respectively. With these observations, we aim to characterize the star's magnetosphere via the X-ray emission produced by magnetically confined wind shocks. Our main findings are as follows. (i) The observed spectrum of NGC 1624-2 is hard, similar to the magnetic O-type star θ¹ Ori C, with only a few photons detected below 0.8 keV. The emergent X-ray flux is 30percent lower at the Hα minimum phase. (ii) Our modelling indicated that this seemingly hard spectrum is in fact a consequence of relatively soft intrinsic emission, similar to other magnetic Ofp stars, combined with a large amount of local absorption (~1-3× 1022 cm-2). This combination is necessary to reproduce both the prominent Mg and Si spectral features, and the lack of flux at low energies. NGC 1624-2 is intrinsically luminous in X-rays (logXLem~33.4) but 70-95percent of the X-ray emission produced by magnetically confined wind shocks is absorbed before it escapes the magnetosphere (logXLISMcor~32.5). (iii) The high X-ray luminosity, its variation with stellar rotation, and its large attenuation are all consistent with a large dynamical magnetosphere with magnetically confined wind shocks. [ABSTRACT FROM AUTHOR]

Published

2015

424. Detection of 610-MHz radio emission from hot magnetic stars.

Author

Chandra, P., Wade, G. A., Sundqvist, J. O., Oberoi, D., Grunhut, J. H., ud-Doula, A., Petit, V., Cohen, D. H., Oksala, M. E., and David-Uraz, A.

Subjects

*SOLAR radio emission, *MAGNETIC stars, *STAR formation, *TELESCOPES, *ASTRONOMICAL observations

Abstract

We have carried out a study of radio emission from a small sample of magnetic O- and Btype stars using the Giant Metrewave Radio Telescope, with the goal of investigating their magnetospheres at low frequencies. These are the lowest frequency radio measurements ever obtained of hot magnetic stars. The observations were taken at random rotational phases in the 1390 and the 610 MHz bands. Out of the eight stars, we detect five B-type stars in both the 1390 and the 610 MHz bands. The three O-type stars were observed only in the 1390 MHz band, and no detections were obtained. We explain this result as a consequence of free-free absorption by the free-flowing stellar wind exterior to the confined magnetosphere. We also study the variability of individual stars. One star - HD 133880 - exhibits remarkably strong and rapid variability of its low-frequency flux density. We discuss the possibility of this emission being coherent emission as reported for CU Vir by Trigilio et al. [ABSTRACT FROM AUTHOR]

Published

2015

425. A MULTIPHASE SUZAKU STUDY OF X-RAYS FROM {tau} Sco

Author

Ud-Doula, A [Department of Physics, Penn State Worthington Scranton, 120 Ridge View Dr, Dunmore, PA 18512 (United States)]

Published

2010

426. DISCOVERY OF ROTATIONAL BRAKING IN THE MAGNETIC HELIUM-STRONG STAR SIGMA ORIONIS E

Author

Ud-Doula, A [Penn State Worthington Scranton, 120 Ridge View Drive, Dunmore, PA 18512 (United States)]

Published

2010

427. UVMag: stellar formation, evolution, structure and environment with space UV and visible spectropolarimetry.

Author

Neiner, C., Baade, D., Fullerton, A., Gry, C., Hussain, G., Lèbre, A., Morin, J., Petit, P., Sundqvist, J., ud-Doula, A., Vidotto, A., and Wade, G.

Subjects

*ULTRAVIOLET astronomy, *STAR formation, *STELLAR evolution, *MAGNETOSPHERE, *ASTRONOMICAL observations

Abstract

Important insights into the formation, structure, evolution and environment of all types of stars can be obtained through the measurement of their winds and possible magnetospheres. However, this has hardly been done up to now mainly because of the lack of UV instrumentation available for long periods of time. To reach this aim, we have designed UVMag, an M-size space mission equipped with a high-resolution spectropolarimeter working in the UV and visible spectral range. The UV domain is crucial in stellar physics as it is very rich in atomic and molecular lines and contains most of the flux of hot stars. Moreover, covering the UV and visible spectral domains at the same time will allow us to study the star and its environment simultaneously. Adding polarimetric power to the spectrograph will multiply tenfold the capabilities of extracting information on stellar magnetospheres, winds, disks, and magnetic fields. Examples of science objectives that can be reached with UVMag are presented for pre-main sequence, main sequence and evolved stars. They will cast new light onto stellar physics by addressing many exciting and important questions. UVMag is currently undergoing a Research & Technology study and will be proposed at the forthcoming ESA call for M-size missions. This spectropolarimeter could also be installed on a large UV and visible observatory (e.g. NASA's LUVOIR project) within a suite of instruments. [ABSTRACT FROM AUTHOR]

Published

2014

428. Investigating the origin of cyclical wind variability in hot, massive stars – I. On the dipolar magnetic field hypothesis★.

Author

David-Uraz, A., Wade, G. A., Petit, V., ud-Doula, A., Sundqvist, J. O., Grunhut, J., Shultz, M., Neiner, C., Alecian, E., Henrichs, H. F., Bouret, J.-C., and Collaboration, MiMeS

Subjects

*SUPERGIANT stars, *MAGNETIC fields, *ASTROPHYSICAL spectropolarimetry, *MAGNETIC properties, *STELLAR oscillations, *BAYESIAN analysis

Abstract

OB stars exhibit various types of spectral variability associated with wind structures, including the apparently ubiquitous discrete absorption components (DACs). These are proposed to be caused by either magnetic fields or non-radial pulsations. In this paper, we evaluate the possible relation between large-scale, dipolar magnetic fields and the DAC phenomenon by investigating the magnetic properties of a sample of 13 OB stars exhibiting well-documented DAC behaviour. Using high-precision spectropolarimetric data acquired in part in the context of the Magnetism in Massive Stars project, we find no evidence for surface dipolar magnetic fields in any of these stars. Using Bayesian inference, we compute upper limits on the strengths of the fields and use these limits to assess two potential mechanisms by which the field may influence wind outflow: magnetic wind confinement and local photospheric brightness enhancements. Within the limits we derive, both mechanisms fail to provide a systematic process capable of producing DACs in all of the stars of our sample. Therefore, this implies that dipolar fields are highly unlikely to be responsible for these structures in all massive stars, meaning that some other mechanism must come into play. [ABSTRACT FROM PUBLISHER]

Published

2014

429. Modeling the magnetospheres of luminous stars: Interactions between supersonic radiation-driven winds and stellar magnetic fields

Author

Ud-Doula, Asif [Bartol Research Institute, University of Delaware, Newark, Delaware 19716 (United States)]

Published

2007

430. An investigation of the magnetic properties of the classical Be star ω Ori by the MiMeS Collaboration An investigation of the magnetic properties of the classical Be star ω Ori by the MiMeS Collaboration.

Author

Neiner, C., Grunhut, J. H., Petit, V., ud-Doula, A., Wade, G. A., Landstreet, J., de Batz, B., Cochard, F., Gutiérrez-Soto, J., and Huat, A.-L.

Subjects

*STELLAR magnetic fields, *BE stars, *ASTROPHYSICAL spectropolarimetry, *ASTRONOMICAL observations, *LEAST squares, *PLASMA gases

Abstract

ABSTRACT One hundred and twenty-five new high-precision spectropolarimetric observations have been obtained with ESPaDOnS (Eschelle Spectro-Polarimetric Device for the Observation of Stars) at the Canada-France-Hawaii Telescope and Narval at Télescope Bernard Lyot to investigate the magnetic properties of the classical Be star ω Ori. No Stokes V signatures are detected in our polarimetric data. Measurements of the longitudinal magnetic field, with a median error bar of 30 G, and direct modelling of the mean least-squares deconvolved Stokes V profiles yield no evidence for a dipole magnetic field with polar surface strength greater than ∼80 G. We are therefore unable to confirm the presence of the magnetic field previously reported by Neiner et al. However, our spectroscopic data reveal the presence of periodic emission variability in H and He lines analogous to that reported by Neiner et al., considered as evidence of magnetically confined circumstellar plasma clouds. We revisit this hypothesis in light of the new magnetic analysis. Calculation of the magnetospheric Kepler radius RK and confinement parameter η* indicates that a surface dipole magnetic field with a polar strength larger than 63 G is sufficient to form of a centrifugally supported magnetosphere around ω Ori. Our data are not sufficiently sensitive to detect fields of this magnitude; we are therefore unable to confirm or falsify the magnetic cloud hypothesis. Based on our results, we examine three possible scenarios that could potentially explain the behaviour of ω Ori: (1) that no significant magnetic field is (or was) present in ω Ori, and that the observed phenomena have their origin in another mechanism or mechanisms than corotating clouds. We are, however, unable to identify one; (2) that ω Ori hosts an intermittent magnetic field produced by dynamo processes; however, no such process has been found so far to work in massive stars and especially to produce a dipolar field; and (3) that ω Ori hosts a stable, organized (fossil) magnetic field that is responsible for the observed phenomena, but with a strength that is below our current detection threshold. Of these three scenarios, we consider the second one (dynamo process) as highly unlikely, whereas the other two should be falsifiable with intense monitoring. [ABSTRACT FROM AUTHOR]

Published

2012