No correlation between disc scale height and jet power in GRMHD simulations

ABSTRACT Whether tidal disruption events circularize or accrete directly as highly eccentric discs is the subject of current research and appears to depend sensitively on the disc thermodynamics. One aspect of this problem that has not received much attention is that a highly eccentric disc must have a strong, non-hydrostatic variation of the disc scale height around each orbit. As a complement to numerical simulations carried out by other groups, we investigate the dynamical structure of TDE discs using the non-linear theory of eccentric accretion discs. In particular, we study the variation of physical quantities around each elliptical orbit, taking into account the dynamical vertical structure, as well as viscous dissipation and radiative cooling. The solutions include a structure similar to the nozzle-like structure seen in simulations. We find evidence for the existence of the thermal instability in highly eccentric discs dominated by radiation pressure. For thermally stable solutions many of our models indicate a failure of the α-prescription for turbulent stresses. We discuss the consequences of our results for the structure of eccentric TDE discs.

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Modelling the atmosphere of lava planet K2-141b: implications for low- and high-resolution spectroscopy

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/staa2487 ◽

2020 ◽

Vol 499 (4) ◽

pp. 4605-4612

Author(s):

T Giang Nguyen ◽

Nicolas B Cowan ◽

Agnibha Banerjee ◽

John E Moores

Keyword(s):

Steady State ◽

Ocean Circulation ◽

Scale Height ◽

High Resolution Spectroscopy ◽

Return Flow ◽

High Dispersion ◽

Magma Ocean ◽

Steady State Flow ◽

Wide Range ◽

Very High

ABSTRACT Transit searches have uncovered Earth-size planets orbiting so close to their host star that their surface should be molten, so-called lava planets. We present idealized simulations of the atmosphere of lava planet K2-141b and calculate the return flow of material via circulation in the magma ocean. We then compare how pure Na, SiO, or SiO2 atmospheres would impact future observations. The more volatile Na atmosphere is thickest followed by SiO and SiO2, as expected. Despite its low vapour pressure, we find that a SiO2 atmosphere is easier to observe via transit spectroscopy due to its greater scale height near the day–night terminator and the planetary radial velocity and acceleration are very high, facilitating high dispersion spectroscopy. The special geometry that arises from very small orbits allows for a wide range of limb observations for K2-141b. After determining the magma ocean depth, we infer that the ocean circulation required for SiO steady-state flow is only 10−4 m s−1, while the equivalent return flow for Na is several orders of magnitude greater. This suggests that a steady-state Na atmosphere cannot be sustained and that the surface will evolve over time.

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Molecular scale height in spiral galaxies

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/sty3493 ◽

2018 ◽

Vol 484 (1) ◽

pp. 81-92 ◽

Cited By ~ 2

Author(s):

Narendra Nath Patra

Keyword(s):

Spiral Galaxies ◽

Scale Height ◽

Molecular Scale

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An origin of the variations of astronomical refraction

Symposium - International Astronomical Union ◽

10.1017/s0074180900065840 ◽

1979 ◽

Vol 89 ◽

pp. 27-33

Author(s):

Haruo Yasuda ◽

Rikinosuke Fukaya

Keyword(s):

Surface Layer ◽

Correction Term ◽

Empirical Relation ◽

Scale Height ◽

Atmospheric Density ◽

Analytical Expression ◽

Temperature And Pressure ◽

Astronomical Refraction

There exists an empirical relation between the anomalous refraction and the atmospheric density in the surface layer. From the relations the variations of scale height for each night can be determined by the temperature and pressure in the surface layer. A correction term to the refraction table is derived in an analytical expression.

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Approximate Schumann resonance parameters for a two-scale-height ionosphere

Journal of Atmospheric and Terrestrial Physics ◽

10.1016/0021-9169(90)90113-2 ◽

1990 ◽

Vol 52 (1) ◽

pp. 35-46 ◽

Cited By ~ 85

Author(s):

D.D. Sentman

Keyword(s):

Scale Height ◽

Schumann Resonance ◽

Resonance Parameters

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Resolving the Disk-Halo Degeneracy using Planetary Nebulae

Proceedings of the International Astronomical Union ◽

10.1017/s1743921317001144 ◽

2016 ◽

Vol 12 (S323) ◽

pp. 284-287

Author(s):

S. Aniyan ◽

K. C. Freeman ◽

M. Arnaboldi ◽

O. Gerhard ◽

L. Coccato ◽

...

Keyword(s):

Vertical Velocity ◽

Velocity Dispersion ◽

Mass Density ◽

Planetary Nebulae ◽

Disk Surface ◽

Scale Height ◽

Dark Halo ◽

Surface Mass ◽

Star Forming ◽

Light Spectra

AbstractThe decomposition of the 21 cm rotation curve of galaxies into contribution from the disk and dark halo depends on the adopted mass to light ratio (M/L) of the disk. Given the vertical velocity dispersion (σz) of stars in the disk and its scale height (hz), the disk surface density and hence the M/L can be estimated. Earlier works have used this technique to conclude that galaxy disks are submaximal. Here we address an important conceptual problem: star-forming spirals have an old (kinematically hot) disk population and a young cold disk population. Both of these populations contribute to the integrated light spectra from which σz is measured. The measured scale height hz is for the old disk population. In the Jeans equation, σz and hz must pertain to the same population. We have developed techniques to extract the velocity dispersion of the old disk from integrated light spectra and from samples of planetary nebulae. We present the analysis of the disk kinematics of the galaxy NGC 628 using IFU data in the inner regions and planetary nebulae as tracers in the outer regions of the disk. We demonstrate that using the scale height of the old thin disk with the vertical velocity dispersion of the same population, traced by PNe, results in a maximal disk for NGC 628. Our analysis concludes that previous studies underestimate the disk surface mass density by ~ 2, sufficient to make a maximal disk for NGC 628 appear like a submaximal disk.

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