Fast Rotating Stars: Effect of the Aspect Angle on Line Profiles

Fast rotation is expected to flatten the star and to produce non uniform temperature and density distributions (i.e. gravitational darkening). While the flattening mostly increases the absolute flux level of the energy distribution, gravitational darkening makes an equator-on star apparently cooler than a star seen through the pole. Both effects (Collins et al. 1991) influence the colours and the location of the star in the HR diagram but also, in a more subtle way, its spectral line profiles. More particularly, in early B type stars, gravitational darkening tends to privilege at the poles the formation of the ions with the highest ionization potentials and directly affects line formation. Consequently, most spectral line shapes - and especially the weakest ones - become aspect angle dependent which in several cases may play a role in the fundamental parameter determination procedures or even in the determination of stellar chemical abundances.

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The impact theory of spectral line shapes: a paradigm shift

Canadian Journal of Physics ◽

10.1139/cjp-2012-0345 ◽

2013 ◽

Vol 91 (11) ◽

pp. 879-895 ◽

Cited By ~ 19

Author(s):

A.D. May ◽

W.-K. Liu ◽

F.R.W. McCourt ◽

R. Ciuryło ◽

J. Sanchez-Fortún Stoker ◽

...

Keyword(s):

Spectral Line ◽

Line Shape ◽

Paradigm Shift ◽

Wigner Distribution ◽

Kinetic Equations ◽

Line Profiles ◽

Line Shapes ◽

Experimental Line ◽

Impact Theory ◽

The Impact

An overview of the binary collision impact theory of spectral line shapes has been given to provide a unified statistical mechanical approach to line-shape theory, laser theory, nonlinear optics, and transport phenomena in dilute gases. The computation of spectral line profiles corresponding to those obtained from ultra-high-resolution spectral line-shape measurements requires numerical ab initio calculation of scattering amplitudes directly from the underlying dynamics of collisions between radiatively active molecules and their perturbers. The Wigner distribution function–density matrix is utilized to describe the kinetic theory of spectral line shapes and to discuss the various collisional processes that contribute to the kernel of kinetic equations. The influence of features of the potential energy surface on spectral parameters is also discussed, and the importance of comparing experimental line profiles directly with numerically computed line shapes obtained from reliable interaction potentials is emphasized. This contrasts sharply with the universal practice of comparing experimental line widths and shifts using some average or approximate theoretical scattering cross-sections and it contrasts sharply with fitting experimental profiles to some convenient analytical line-shape model; hence the phrase “a paradigm shift” in the title of this work.

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Numerical Simulation of Granular Convection: Effects on Photospheric Spectral Line Profiles

International Astronomical Union Colloquium ◽

10.1017/s0252921100075412 ◽

1980 ◽

Vol 51 ◽

pp. 213-224

Author(s):

Åke Nordlund

Keyword(s):

Spectral Line ◽

Line Strength ◽

Blue Shift ◽

Spectral Lines ◽

Line Profiles ◽

Pressure Broadening ◽

Solar Granulation ◽

Velocity Fluctuations ◽

Excitation Potential ◽

On Line

AbstractThe results of numerical simulations of the solar granulation are used to investigate the effects on photospheric apectral lines of the correlated velocity and temperature fluctuations of the convective granular motions. It is verified that the granular velocity field is the main cause for the observed broadening and strengthening of photospheric spectral lines relative to values expected from pure thermal and pressure broadening. These effects are normally referred to as being due to “macro-turbulence” and “micro-turbulence”, respectively. It is also shown that the correlated temperature and velocity fluctuations produce a “convective blue shift” in agreement with the observed blue shift of photospheric spectral lines. Reasons are given for the characteristic shapes of spectral line bisectors, and the dependence of these shapes on line strength, excitation potential, and center to limb distance are discussed.

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Stark-Zeeman Broadening of Spectral Line Shapes in Magnetized Plasmas

Atoms ◽

10.3390/atoms8040091 ◽

2020 ◽

Vol 8 (4) ◽

pp. 91

Author(s):

Kamel Ahmed Touati ◽

Keltoum Chenini ◽

Mohammed Tayeb Meftah

Keyword(s):

Magnetic Field ◽

Spectral Line ◽

Stark Effect ◽

Line Broadening ◽

Lyman Alpha ◽

Line Shapes ◽

Field Temperature ◽

Motional Stark Effect ◽

On Line ◽

The Magnetic Field

In this work, we studied the Lyman-alpha line in the presence of a magnetic field, such as the ones found at the edge of tokamaks. The emphasis is on the contribution of the motional Stark effect on line broadening, which may have comparable effects to the internal plasma microfields for the spectral line in question. The effect of the magnetic field, temperature, and the Maxwell distribution of the ion velocities and density on Lyman-alpha are studied.

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Broadening of the Neutral Helium 492 nm Line in a Corona Discharge: Code Comparisons and Data Fitting

10.20944/preprints201803.0037.v1 ◽

2018 ◽

Author(s):

Roshin Raj Sheeba ◽

Mohammed Koubiti ◽

Nelly Bonifaci ◽

Franck Gilleron ◽

Jean-Christophe Pain ◽

...

Keyword(s):

Emission Line ◽

Corona Discharge ◽

Line Shape ◽

Diagnostic Technique ◽

Parameter Determination ◽

Line Profiles ◽

Plasma Parameters ◽

Line Shapes ◽

Physical Effects

Passive plasma spectroscopy is a well-established non-intrusive diagnostic technique. Depending on the emitter and its environment which determine the dominant interactions and effects governing emission line shapes, passive spectroscopy allows the determination of electron densities, emitter and perturber temperatures as well as other quantities like abundances. However, using spectroscopy needs appropriate line shape codes retaining all the physical effects governing the emission line profiles. This requires for line shape code developers to continuously correct or improve them to increase their accuracy when applied for diagnostics. This is exactly the aim expected from code-code and code-data comparisons. In this context, the He I 492 nm emitted in a helium corona discharge at room temperature represents an ideal case since its profile results from several broadening mechanisms: Stark, Doppler, resonance and van der Waals. The importance of each broadening mechanism depends on the plasma parameters. Here the profiles of the He I 492 nm in a helium plasma computed by various codes are compared for a selected set of plasma parameters. In addition, preliminary results related to plasma parameter determination using experimental spectra from a helium corona discharge at low pressure 1- 2 bars, are presented.

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Analysis of High Resolution Stellar Line Profiles

International Astronomical Union Colloquium ◽

10.1017/s0252921100075230 ◽

1980 ◽

Vol 51 ◽

pp. 75-84

Author(s):

David F. Gray

Keyword(s):

High Resolution ◽

Spectral Line ◽

Spectral Resolution ◽

Signal To Noise Ratio ◽

Physical Phenomenon ◽

Velocity Fields ◽

Line Profiles ◽

Late Type ◽

Signal To Noise ◽

Line Shapes

High resolution implies that we obtain some information on spectral line shapes. In late-type stars, we need to measure velocities of a few km/sec to accomplish this. Increasing the spectral resolution and the signal to noise ratio allows us to progress step by step toward deeper physical understanding. The steps we take often lead to good debate and “stimulate” our lives. I am sometimes amused at the urgency we feel to press on to the next step. We rarely seem to pause and enjoy the completion of previous steps. Perhaps this is because we always see shortcomings in completed work. Quite typically one will “discover” the importance of some physical phenomenon (It makes little difference how many others already know about it.), and in his eyes everything done previously becomes wrong because this phenomenon was not included. We used to hear how Milne-Eddington or Schuster-Schwarzschild model atmospheres were inadequate -we had to use instead properly computed depth dependence. We used to hear how LTE models were no good - we had to use more detailed physics. Now we talk about line analyses being inadequate because it has not included velocity fields. The curious thing is that we believe that including our pet phenomenon gives the correct models. We ignore all those other phenomena as yet unseen! (Is this a mechanism for maintaining sanity?) I think it really amounts to a statement of what we are able to measure, compute, or understand.

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The gravitational microlens influence on X-ray spectral line generated by an AGN accretion disc

Serbian Astronomical Journal ◽

10.2298/saj0164053p ◽

2001 ◽

pp. 53-56 ◽

Cited By ~ 4

Author(s):

L.C. Popovic ◽

E.G. Mediavilla ◽

J.A. Munoz ◽

M.S. Dimitrijevic ◽

P. Jovanovic

Keyword(s):

Spectral Line ◽

Accretion Disc ◽

Compact Objects ◽

Host Galaxy ◽

Line Profiles ◽

Solar Mass ◽

X Ray ◽

Line Shapes ◽

Ring Radius ◽

Disc Model

The influence of gravitational microlensing on the X-ray spectral line profiles originated from a relativistic accretion disc has been studied. Using a disc model, we show that microlensing can induce noticeable changes in the line shapes when the Einstein ring radius associated with the microlens is of a size comparable to that of the accretion disc. Taking into account the relatively small size of the X-ray accretion disc, we found that compact objects (of about a Solar mass) which belong to the bulge of the host galaxy can produce significant changes in the X-ray line profile of AGN.

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Testing the Planet Hypothesis: A Search for Variability in the Spectral‐Line Shapes of 51 Pegasi

The Astrophysical Journal ◽

10.1086/303770 ◽

1997 ◽

Vol 478 (1) ◽

pp. 374-380 ◽

Cited By ~ 35

Author(s):

Artie P. Hatzes ◽

William D. Cochran ◽

Christopher M. Johns‐Krull

Keyword(s):

Spectral Line ◽

Line Shapes

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From the Vector to Scalar Perturbations Addition in the Stark Broadening Theory of Spectral Lines

Universe ◽

10.3390/universe7060176 ◽

2021 ◽

Vol 7 (6) ◽

pp. 176

Author(s):

Valery Astapenko ◽

Andrei Letunov ◽

Valery Lisitsa

Keyword(s):

Spectral Line ◽

Stark Effect ◽

Coulomb Field ◽

Spectral Lines ◽

Alternative Methods ◽

Scalar Perturbation ◽

Numerical Comparison ◽

Line Shapes ◽

Stark Effects ◽

The Impact

The effect of plasma Coulomb microfied dynamics on spectral line shapes is under consideration. The analytical solution of the problem is unachievable with famous Chandrasekhar–Von-Neumann results up to the present time. The alternative methods are connected with modeling of a real ion Coulomb field dynamics by approximate models. One of the most accurate theories of ions dynamics effect on line shapes in plasmas is the Frequency Fluctuation Model (FFM) tested by the comparison with plasma microfield numerical simulations. The goal of the present paper is to make a detailed comparison of the FFM results with analytical ones for the linear and quadratic Stark effects in different limiting cases. The main problem is connected with perturbation additions laws known to be vector for small particle velocities (static line shapes) and scalar for large velocities (the impact limit). The general solutions for line shapes known in the frame of scalar perturbation additions are used to test the FFM procedure. The difference between “scalar” and “vector” models is demonstrated both for linear and quadratic Stark effects. It is shown that correct transition from static to impact limits for linear Stark-effect needs in account of the dependence of electric field jumping frequency in FFM on the field strengths. However, the constant jumping frequency is quite satisfactory for description of the quadratic Stark-effect. The detailed numerical comparison for spectral line shapes in the frame of both scalar and vector perturbation additions with and without jumping frequency field dependence for the linear and quadratic Stark effects is presented.

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AGN evolution as seen in spectral lines: The case of narrow-line Seyfert 1s

Proceedings of the International Astronomical Union ◽

10.1017/s1743921320002653 ◽

2019 ◽

Vol 15 (S356) ◽

pp. 94-94

Author(s):

Marco Berton

Keyword(s):

Active Galactic Nuclei ◽

Galactic Nuclei ◽

Spectroscopic Studies ◽

Spectral Lines ◽

Narrow Line ◽

Line Profiles ◽

Line Shapes ◽

Fundamental Information ◽

Line Region ◽

Gaussian Samples

AbstractLine profiles can provide fundamental information on the physics of active galactic nuclei (AGN). In the case of narrow-line Seyfert 1 galaxies (NLS1s) this is of particular importance since past studies revealed how their permitted line profiles are well reproduced by a Lorentzian function instead of a Gaussian. This has been explained with different properties of the broad-line region (BLR), which may present more pronounced turbulent motions in NLS1s with respect to other AGN. We investigated the line profiles in a recent large NLS1 sample classified using SDSS, and we divided the sources into two subsamples according to their line shapes, Gaussian or Lorentzian. The line profiles seem to separate all the properties of NLS1s. Black hole mass, Eddington ratio, [OIII] luminosity, and Fe II strength are all very different in the Lorentzian and Gaussian samples, as well as their position on the quasar main sequence. We interpret this in terms of evolution within the class of NLS1s. The Lorentzian sources may be the youngest objects, while Gaussian profiles may be typically associated to more evolved objects. Further detailed spectroscopic studies are needed to fully confirm our hypothesis.

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Predicting the broad-lines polarization emitted by supermassive binary black holes

Astronomy and Astrophysics ◽

10.1051/0004-6361/201834443 ◽

2019 ◽

Vol 623 ◽

pp. A56 ◽

Cited By ~ 3

Author(s):

D. Savić ◽

F. Marin ◽

L. Č. Popović

Keyword(s):

Black Holes ◽

Emission Lines ◽

Polarization Angle ◽

Broad Line ◽

Line Profiles ◽

Binary Black Holes ◽

True Nature ◽

Line Shapes ◽

Highly Sensitive ◽

Balmer Lines

Context. Some Type-1 active galactic nuclei (AGN) show extremely asymmetric Balmer lines with the broad peak redshifted or blueshifted by thousands of km s−1. These AGN may be good candidates for supermassive binary black holes (SMBBHs). The complex line shapes can be due to the complex kinematics of the two broad line regions (BLRs). Therefore other methods should be applied to confirm the SMBBHs. One of them is spectropolarimetry. Aims. We rely on numerical modeling of the polarimetry of binary black holes systems, since polarimetry is highly sensitive to geometry, in order to find the specific influence of supermassive binary black hole (SMBBH) geometry and dynamics on polarized parameters across the broad line profiles. We apply our method to SMBBHs in which both components are assumed to be AGN with distances at the subparsec scale. Methods. We used a Monte Carlo radiative transfer code that simulates the geometry, dynamics, and emission pattern of a binary system where two black holes are getting increasingly close. Each gravitational well is accompanied by its own BLR and the whole system is surrounded by an accretion flow from the distant torus. We examined the emission line deformation and predicted the associated polarization that could be observed. Results. We modeled scattering-induced broad line polarization for various BLR geometries with complex kinematics. We find that the presence of SMBBHs can produce complex polarization angle profiles φ and strongly affect the polarized and unpolarized line profiles. Depending on the phase of the SMBBH, the resulting double-peaked emission lines either show red or blue peak dominance, or both the peaks can have the same intensity. In some cases, the whole line profile appears as a single Gaussian line, hiding the true nature of the source. Conclusions. Our results suggest that future observation with the high resolution spectropolarimetry of optical broad emission lines could play an important role in detecting subparsec SMBBHs.

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