Plane-parallel Atmosphere Research Articles

Model atmospheres and X-ray spectra of bursting neutron stars

Model atmosphere equations are derived which correspond to plane-parallel nongray atmospheres of very hot neutron stars in hydrostatic and radiative equilibrium. The nonlinear transfer equation used implements an exact photon redistribution function which precisely traces even those scattering events having large photon-electron energy exchange. The numerical results thus obtained encompass tables of the surface fluxes for 20 model atmospheres whose T(eff) ranges from 6 to 30 million K. The spectra of high gravity models are virtually identical with the blackbody spectrum shifted toward higher energies, while models approaching the Eddington limit develop a large low-energy hump.

Analyses of Wolf-Rayet Spectra

Wolf-Rayet stars represent an important stage in the evolution of massive stars, but are only poorly understood so far. For a better knowledge one might determine their effective temperatures, luminosities and atmospheric compositions. But the emission-line dominated Wolf-Rayet spectra were not accessible to a quantitative analysis for a long time, because “standard” model calculations for static, plane-parallel stellar atmospheres are not adequate to that type of stars.

The X- Y-, and H-matrices for molecular scattering

A method is described to calculate theX-,Y-, andH-matrices for molecular scattering in a homogeneous plane-parallel atmosphere. This method is based on the method of discrete ordinates by Chandrasekhar. A sample of results in 7 decimals is given and the accuracy of the method presented is discussed.

Invariant imbedding and searchlight problem in turbid slab

In this paper, with the aid of invariant imbedding, we discuss the mathematical model of a searchlight on a target of turbid plane-parallel atmosphere, bounded below by a diffuse reflector. In the real physical situation, the faint background light illuminating the top is considered. However in this paper, for the sake of simplicity, the angular distribution of radiation emergent from the top with a point source is considered, by imbedding the problem within a family of parameters.

An initial-value method for determining the radiation field in a plane-parallel atmosphere. The vector case

Abstract An initial value method for determining the radiation field in a plane-parallel atmosphere is extended to include polarization. Using the first principle of invariance by Chandrasekhar we eliminate the intensity of the upward radiation from the equation of transfer thus formulating the Cauchy problem. The concomitant scattering matrix satisfies the well-known integro-differential equation and after having determined this matrix we may solve the equation of transfer itself. Next, the Chandrasekhar principle allows us to find the intensity of the upward radiation, thus completing the solution. The case with Rayleigh scattering is discussed in detail. The behaviour of neutral points in an atmosphere, where the albedo of single scattering depends exponentially on the optical depth, is studied.

Rayleigh-Cabannes scattering in planetary atmospheres II. Constant internal sources in nonconservative atmospheres

The vector equation of radiative transfer is solved for non-conservative homogeneous plane-parallel atmosphere using the method of discrete ordinates. The scattering processes in the atmosphere bounded by a Lambert bottom are described by the Rayleigh-Cabannes phase matrix. The primary radiation field is generated by constant internal sources. A package of FORTRAN subroutines is compiled to find the axial radiation field for such an atmosphere at arbitrary optical depth.

Rayleigh-Cabannes scattering in planetary atmospheres III. The Milne problem in conservative atmospheres

The discrete ordinale method by Chandrasekhar is used to solve the conservative Milne problem in a homogeneous plane-parallel atmosphere which scatters the radiation according to the Rayleigh-Cabannes law.

Magnetic Buoyancy with Viscosity and Ohmic Dissipation and Flux Tube Formation

In the framework of the magnetohydrodynamic equations with dissipative terms in the form of turbulent viscosity (Vt) the linear stage of the instability of a subphotospheric field with respect to magnetic buoyancy is considered. For an exponential in z, isothermal plane-parallel atmosphere with a constant Alfvenic velocity the perturbations of the form are described by differential equation with constant coefficients. The qualitative dependence of the growth rate of instability on transverse wave number is determined (see Figures 1 and 2) and characteristic scales of the magnetic tubes are evaluated at the linear stage of instability (Kuznetsov, 1987, 1988).

Fourier series expansion of the transfer equation in the atmosphere-ocean system

We consider radiative transfer in a plane-parallel atmosphere bounded by a rough ocean surface. The problem is solved by using a Fourier series decomposition of the radiation field. For the case of a Lambertian surface as a boundary condition, this decomposition is classically achieved by developing the scattering phase matrix in a series of Legendre functions. For the case of a rough ocean surface, we obtain the decomposition by developing both the Fresnel reflection matrix and the wave facet distribution function in Fourier series. This procedure allows us to derive the radiance field for the case of the ruffled ocean surface, with a computation time only a few percent larger than for the case of a Lambertian surface.

The effects of Compton scattering in X-ray spectra

view Abstract Citations (25) References (22) Co-Reads Similar Papers Volume Content Graphics Metrics Export Citation NASA/ADS Effects of Compton Scattering in X-Ray Spectra Madej, Jerzy Abstract The ways in which Compton scattering on free electrons influences the continuous spectrum and temperature structure of a hot stellar atmosphere, where most of its radiation is emitted in the 1-10 keV energy range, are discussed. The numerical results pertain to the continuum spectra of X-ray bursters. The formulation and development of the numerical code, which reproduces angle-averaged relativistic Compton scattering of thermal (unpolarized) X-rays in a plane-parallel atmosphere in hydrostatic and radiative equilibrium, are described. Publication: The Astrophysical Journal Pub Date: April 1989 DOI: 10.1086/167304 Bibcode: 1989ApJ...339..386M Keywords: Compton Effect; Free Electrons; Radiative Transfer; Relativistic Electron Beams; Stellar Atmospheres; X Ray Spectra; Electron Scattering; Neutron Stars; Space Radiation; RADIATION MECHANISMS; X-RAYS: SPECTRA full text sources ADS |

Thomson Scattering in Magnetic Fields

AbstractThe equation of transfer in Thomson scattering atmospheres with magnetic fields is solved using Monte Carlo methods. Two cases, a plane parallel atmosphere with a magnetic field perpendicular to the atmosphere, and a dipole star, are investigated. The wavelength dependence of polarization from a plane-parallel atmosphere is qualitatively similar to that observed in the magnetic white dwarf Grw+70°8247, and the field strength determined by the calculation, 3.2×l08 G, is quantitatively similar to that determined from the line spectrum. The dipole model does not resemble the data as well as the single plane-parallel atmosphere.

Polarization of resonance lines formed in extenned spherical atmospheres

The problem of polarization of the resonance lines formed in extended spherical atmospheres is studied in detail. In this paper, the atmosphere is assumed to be at rest. The basic problem of resonance line polarization in spherical atmospheres as compared to the conventionally used plane-parallel atmospheres, is studied in Nagendra (1988). Our main interest in this paper is to understand the behaviour of polarized radiation fields in extended model spherical atmospheres so that some constraints can be placed on the model parameters in the modelling work conected with observations of polarization across resonance lines. A comparison of polarized lines formed under three kinds of line-scattering mechanisms is also made. They are CS=coherent scatteirng, CRD=complete redistribution, and PRD=partial frequency redistribution which, in the increasing order of generality, provide a good approximation in the two-level atom approach, to the resonance line polarization. The dependence of polarization on the opacity laws, extendedness and on optical depth is studied in detail. The distribution of line intensity and polarization across the visible disk of an extended model stellar atmosphere is studied, in view of the possible disk-resolved observations in future, of the extended atmospheres of the stars.

Correcting gravity measurements for the effects of local air pressure

A simple exponential atmosphere is used to derive the gravitational changes caused by the direct attraction of the local air pressure. This approach yields a Green function which can be used with surface air pressure readings near and including the observation point to correct gravity measurements for the gravitational attraction of the atmosphere. This model predicts a lower local air pressure admittance than the standard value (−0.43 μGal/mbar) obtained assuming a plane parallel atmosphere. The curvature of the Earth and the scale height of the atmosphere reduce this admittance by about 7–8%.

Exact Rayleigh scattering calculations for use with the Nimbus-7 Coastal Zone Color Scanner

For improved analysis of Coastal Zone Color Scanner (CZCS) imagery, the radiance reflected from a planeparallel atmosphere and flat sea surface in the absence of aerosols (Rayleigh radiance) has been computed with an exact multiple scattering code, i.e., including polarization. The results indicate that the single scattering approximation normally used to compute this radiance can cause errors of up to 5% for small and moderate solar zenith angles. At large solar zenith angles, such as encountered in the analysis of high-latitude imagery, the errors can become much larger, e.g.,>10% in the blue band. The single scattering error also varies along individual scan lines. Comparison with multiple scattering computations using scalar transfer theory, i.e., ignoring polarization, show that scalar theory can yield errors of approximately the same magnitude as single scattering when compared with exact computations at small to moderate values of the solar zenith angle. The exact computations can be easily incorporated into CZCS processing algorithms, and, for application to future instruments with higher radiometric sensitivity, a scheme is developed with which the effect of variations in the surface pressure could be easily and accurately included in the exact computation of the Rayleigh radiance. Direct application of these computations to CZCS imagery indicates that accurate atmospheric corrections can be made with solar zenith angles at least as large as 65 degrees and probably up to at least 70 degrees with a more sensitive instrument. This suggests that the new Rayleigh radiance algorithm should produce more consistent pigment retrievals, particularly at high latitudes.

The relationship between the Eddington limit, the observed upper luminosity limit for massive stars, and the luminous blue variables

The observed upper luminosity limits in the Galaxy and the LMC are compared with the Eddington limit as estimated for plane-parallel LTE model atmospheres which include the full effects of metal line opacities in the ultraviolet. It is shown that the Humphreys-Davidson (HD) limit corresponds to the locus of extremely low effective gravities. This result suggests that stars approaching the HD limit will suffer high mass-loss rates because of the reduction of the effective gravity due to radiation pressure. These high mass-loss rates ultimtely lead to the core mass fraction reaching its critical value and the reversal of the stellar evolution tracks. It is shown that radiation pressure, as an agent for producing enhanced mass loss near the HD limit, can in a natural way explain the kink in the HD limit near T(eff) roughly 10,000 K and the upper luminosity limit for yellow and red supergiants. The high mass-loss rates of the luminous blue variables, their location in the HR diagram, and their evolutionary stage are also discussed.

Analytic solution of transfer problem linearized with respect to a small parameter in the problem of an almost gray atmosphere

The problem of radiative transfer in a semi-infinite plane-parallel atmosphere that is almost gray is considered. The transfer equation is solved in the second approximation obtained in accordance with the iterative scheme proposed by Chandrasekhar, the case of a gray atmosphere being taken as the first approximation. An exact solution of this equation for arbitrary profiles of the absorption coefficient that do not depend on the optical depth is found.

Nature of the stratospheric haze on Uranus: Evidence for condensed hydrocarbons

We have used a number of models to analyze Voyager images of Uranus obtained at several high phase angles to derive physical and chemical properties of particulate matter present in the planet's lower stratosphere. These models include a multiple‐scattering algorithm for plane parallel atmospheres, a spherical atmosphere code for performing limb inversions, a microphysical model of aerosol formation, growth, and sedimentation, and a photochemical model of methane photolysis. We obtain definitive evidence for the presence of aerosols at pressure levels ranging from a few millibars to about 100 mbar. There are two possible sets of particle properties that can fit radiances observed close to but somewhat interior to the limb at several phase angles in four visible wavelength bands. The low‐density solution is characterized by particles having a modal radius and number density equal to 0.13 ± 0.02 µm and 2 ± 1 particles/cm³, respectively, at a pressure level of 44 mbar. The alternative, high‐density solution is characterized by particles having a modal radius that is 0.6–0.7 times that of the low‐density solution at the reference level and a density that is 2 orders of magnitude larger. Since the high‐density solution implies a mass production rate for the stratospheric aerosols that is much larger than those that can plausibly be supplied by photochemically produced gases that condense, whereas the low‐density solution does not, we favor the low‐density solution. Inversion of narrow‐angle, high‐resolution images of the limb provides a definition of a variable that provides a measure of the amount of aerosol scattering at high phase angles. The vertical profile of this variable shows a decrease of several orders of magnitude from pressure levels of tens to a few millibars. This decrease is due chiefly to the particle size of the aerosols becoming small compared to a wavelength. Above the base of the stratosphere the aerosol optical depth is approximately 0.01 in the mid‐visible. A major source for the stratospheric aerosols is the condensation of ethane, acetylene, and diacetylene gas species at pressure levels of approximately 14, 2.5, and 0.1 mbar, respectively. These gases are produced at much higher altitudes by solar UV photolysis of methane and diffuse to the lower stratosphere, where they condense. In addition, diacetylene is also produced photochemically within its condensation region. Condensation of locally produced diacetylene may represent a significant fraction of the total hydrocarbon condensation. Such a local source of condensation may be required by the inversions to the limb profiles, which indicate that at least half of the ice condensation occurs at altitudes above the 5‐mbar level. The hypothesis that the stratospheric particles are made of hydrocarbon ices is supported by the approximate agreement between the total ice condensation rate predicted by the methane photochemical model and the aerosol mass production rate derived for the low‐density solution of the Voyager data. The aerosol mass production rate derived from the Voyager data is equal to 2–15 × 10−17 g/cm²/s. Additional but weaker support for this hypothesis is provided by the Voyager radio occultation temperature profiles. It is suggested that solar UV radiation promotes solid state chemistry within the lower order hydrocarbon ices, resulting in the production of polymers capable of absorbing at visible wavelengths. Thus this altered material could play a key role in the planet's heat budget. Ethane, acetylene, and diacetylene ices evaporate at approximately the 600‐, 900‐, and 3000‐mbar levels of the upper troposphere. The polymeric material is expected to evaporate at pressures in excess of the evaporation level for diacetylene.

Rotating Stellar Atmospheres (Review Paper)

AbstractThe effects of rapid rotation on the emergent energy distribution, line profiles, atmospheric motions and polarization are discussed. A simplified explanation of some of the effects is presented. Results of detailed radiation transfer calculations are briefly reviewed. The rotation can lead to circulation and turbulent motions in the photospheric layers which could affect the outflow from the Be stars. The rotation rates actually observed in the Be stars are sufficiently below the critical rate that many of the effects predicted by the plane parallel atmosphere calculations should be small. Nevertheless, the models are useful and necessary for estimating rotation speeds from lines that are widely separated in wavelength. The rapidly rotating photospheric models predict far too small an infrared excess, as well as too small an intrinsic polarization. The explanation of these observations requires that geometrically extended envelopes be considered. Theoretical models for the intrinsic polarization are critically discussed. It is stressed that polarization is a powerful diagnostic for determining the asymmetrical structure of the outer atmospheres of the Be stars.

The Neumann solution of the multiple scattering problem in a plane-parallel medium—IIc. The specific intensity in a semi-infinite space

Using a new formulation of the resolvent function [Rutily and Bergeat JQSRT 38, 61 (1987)], we solve the Milne integral equation for the mean intensity in a semi-infinite plane-parallel atmosphere. The specific intensity is then derived at any optical depth. By expanding the intensity in power series in the albedo, we derive the corresponding intensities of a n-times scattered radiation field propagating in a half-space ( n ⩾/ 1).

The properties of OB supergiants in the Large Magellanic Cloud. I - Energy distributions of 10 B supergiants

view Abstract Citations (20) References (59) Co-Reads Similar Papers Volume Content Graphics Metrics Export Citation NASA/ADS The Properties of OB Supergiants in the Large Magellanic Cloud. I. Energy Distributions of 10 B Supergiants Fitzpatrick, Edward L. Abstract It is demonstrated here that line-blanketed, LTE plane-parallel model atmosphere calculations provide excellent fits to the energy distributions from the ultraviolet through the visual ranges of B supergiants in the LMC. The models are computed using the atmosphere program of Kurucz (1979) but have been constructed with lower gravities than were contained in Kurucz's model grid. The models are also shown to fit the ultraviolet through near-infrared continua of several lightly reddened luminous Milky Way stars. Measurements of effective temperatures and gravities for 10 LMC B supergiants from model fits to the continua are used to obtain estimates of the radii, luminosities, and masses of the stars. For supergiants earlier than type B2, these parameters are reasonable when compared to the results of stellar evolution calculations. The results for the later B types, however, appear incompatible with evolution theory. Publication: The Astrophysical Journal Pub Date: January 1987 DOI: 10.1086/164905 Bibcode: 1987ApJ...312..596F Keywords: Magellanic Clouds; Spectral Energy Distribution; Stellar Evolution; Stellar Physics; Stellar Spectrophotometry; Supergiant Stars; Milky Way Galaxy; Stellar Atmospheres; Stellar Models; Ubv Spectra; Astrophysics; GALAXIES: MAGELLANIC CLOUDS; SPECTROPHOTOMETRY; STARS: ATMOSPHERES; STARS: EVOLUTION; STARS: SUPERGIANTS full text sources ADS | data products SIMBAD (11) NED (1) MAST (1) INES (1) Related Materials (1) Part 2: 1988ApJ...335..703F