Synchronous Rotation | ScienceGate

Helical timing belts have been developed in order to reduce the noise that occurs when conventional timing belts are driven. Helical timing belts are characterized by synchronous rotation. Although several studies have been performed to clarify the noise characteristics and belt life of helical timing belts, the transmission error of these belts remains unclear. In the present study, the transmission error having a period of one pitch of the pulley was investigated both theoretically and experimentally for helical timing belt drives. Experimental conditions were such that the transmission force acts on the helical timing belts under quasi-static conditions and the belt incurs belt climbing at the beginning of meshing and at the end of meshing. Experimental results obtained for the transmission error agreed closely with the computed results. The computed results revealed that helical timing belts can be analyzed as a set of very narrow belts for which the helix angle is zero. The transmission error was found to decrease when the helix angle or the belt width increase within a range defined such that the face advance is less than one belt pitch. In addition, there exists an appropriate installation tension that reduces the transmission error.

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Radial Velocity Variations in Cool Supergiants

International Astronomical Union Colloquium ◽

10.1017/s0252921100098900 ◽

1984 ◽

Vol 88 ◽

pp. 283-288

Author(s):

Hugh C. Harris

Keyword(s):

Radial Velocity ◽

Main Sequence ◽

Short Period ◽

Cool Stars ◽

Synchronous Rotation ◽

Red Supergiants ◽

Velocity Variations ◽

Orbital Periods ◽

Low Amplitude ◽

Good Agreement

AbstractA survey of F, G, and W supergiants has been carried out with the DAO radial velocity spectrometer, an efficient instrument for detecting low-amplitude velocity variations in cool stars. Observations of 78 stars over five seasons show generally good agreement with OORAVEL results for spectroscopie binaries. The majority of supergiants show low-amplitude variability, with amplitudes typically 1 to 2 km s−1. The width of the cross-correlation profile has been measured for 58 supergiants. It reveals 14 stars with unusually broad lines, indicative of rotation velocities of 15 to 35 km s−1. Several have short-period binary companions and may be in synchronous rotation. The other broad-lined stars are apparently single or with long orbital periods; they may be making their first transition from the main sequence to become red supergiants.

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Modeling climate diversity, tidal dynamics and the fate of volatiles on TRAPPIST-1 planets

Astronomy and Astrophysics ◽

10.1051/0004-6361/201731620 ◽

2018 ◽

Vol 612 ◽

pp. A86 ◽

Cited By ~ 62

Author(s):

Martin Turbet ◽

Emeline Bolmont ◽

Jeremy Leconte ◽

François Forget ◽

Franck Selsis ◽

...

Keyword(s):

Climate Model ◽

Global Climate ◽

Global Climate Model ◽

Planetary Science ◽

Water Ice ◽

Planetary Evolution ◽

Ice Surface ◽

Surface Condensation ◽

Synchronous Rotation ◽

Ice Shell

TRAPPIST-1 planets are invaluable for the study of comparative planetary science outside our solar system and possibly habitability. Both transit timing variations (TTV) of the planets and the compact, resonant architecture of the system suggest that TRAPPIST-1 planets could be endowed with various volatiles today. First, we derived from N-body simulations possible planetary evolution scenarios, and show that all the planets are likely in synchronous rotation. We then used a versatile 3D global climate model (GCM) to explore the possible climates of cool planets around cool stars, with a focus on the TRAPPIST-1 system. We investigated the conditions required for cool planets to prevent possible volatile species to be lost permanently by surface condensation, irreversible burying or photochemical destruction. We also explored the resilience of the same volatiles (when in condensed phase) to a runaway greenhouse process. We find that background atmospheres made of N2, CO, or O2are rather resistant to atmospheric collapse. However, even if TRAPPIST-1 planets were able to sustain a thick background atmosphere by surviving early X/EUV radiation and stellar wind atmospheric erosion, it is difficult for them to accumulate significant greenhouse gases like CO2, CH4, or NH3. CO2can easily condense on the permanent nightside, forming CO2ice glaciers that would flow toward the substellar region. A complete CO2ice surface cover is theoretically possible on TRAPPIST-1g and h only, but CO2ices should be gravitationally unstable and get buried beneath the water ice shell in geologically short timescales. Given TRAPPIST-1 planets large EUV irradiation (at least ~103 × Titan’s flux), CH4and NH3are photodissociated rapidly and are thus hard to accumulate in the atmosphere. Photochemical hazes could then sedimentate and form a surface layer of tholins that would progressively thicken over the age of the TRAPPIST-1 system. Regarding habitability, we confirm that few bars of CO2would suffice to warm the surface of TRAPPIST-1f and g above the melting point of water. We also show that TRAPPIST-1e is a remarkable candidate for surface habitability. If the planet is today synchronous and abundant in water, then it should very likely sustain surface liquid water at least in the substellar region, whatever the atmosphere considered.

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A Starspot Model for the RS CVn Stars

Symposium - International Astronomical Union ◽

10.1017/s0074180900065190 ◽

1980 ◽

Vol 88 ◽

pp. 389-396

Author(s):

Steven N. Shore ◽

Douglas S. Hall

Keyword(s):

Essential Feature ◽

Rotational Velocity ◽

Active Regions ◽

Dynamo Model ◽

Evolutionary Status ◽

Mass Star ◽

Solar Mass ◽

Orbital Parameters ◽

Rs Cvn Stars ◽

Synchronous Rotation

We employ a simplified dynamo model to describe the long term photometric spectroscopic behavior of the RS CVn stars. The essential feature of the model is that the stars are in nearly synchronous rotation, with the differential rotation slower and the rotational velocity higher than for a single evolved 1 to 2 solar mass star. The spot groups are formed by eruption of enhanced toroidal fields, which have areas at the photosphere of several tenths of the surface area; the sizes of these regions are shear limited. Estimates of the lifetimes of active regions and of flare energetics are presented. The RS CVn phenomenon is then related to both the evolutionary status and the orbital parameters of the binary system.

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Atmospheric Circulation of Hot Jupiters

Symposium - International Astronomical Union ◽

10.1017/s0074180900218032 ◽

2004 ◽

Vol 202 ◽

pp. 261-268 ◽

Cited By ~ 1

Author(s):

Tristan Guillot

Keyword(s):

Large Scale ◽

Circulation Model ◽

Giant Planets ◽

Large Temperature ◽

Strong Wind ◽

Temperature Variations ◽

Hot Jupiters ◽

Stellar Radiation ◽

Synchronous Rotation ◽

Night Side

About 40% of the extrasolar giant planets discovered so far have orbital distances smaller than 0.2 AU. These “hot Jupiters” are expected to be in synchronous rotation with their star. The ability to measure their radii prompts a careful reexamination of their structure. I show that their atmospheric structure is complex and that thermal balance cannot be achieved through radiation only but must involve heat advection by large-scale circulation. A circulation model inspired from Venus is proposed, involving a relatively strong zonal wind (with a period that can be as short as 1 day). It is shown that even this strong wind is incapable of efficiently redistributing heat from the day side to the night side. Temperature variations of 200 K or more are to be expected, even at pressures as large as 10 bar. As a consequence, clouds should be absent on the day side, allowing more efficient absorption of the stellar light. The global chemical composition of the atmosphere should also be greatly affected by the presence of large temperature variations. Finally, stellar tides may also be important in their ability to deposit heat at levels untouched by stellar radiation, thereby slowing further the cooling of the planets.

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Starspot Activity on Short-period RS CVn Stars

International Astronomical Union Colloquium ◽

10.1017/s0252921100079926 ◽

1991 ◽

Vol 130 ◽

pp. 370-372

Author(s):

Michael Zeilik

Keyword(s):

Binary Stars ◽

Binary Systems ◽

Magnetic Activity ◽

Close Binary ◽

Tidal Interactions ◽

Rs Cvn Stars ◽

Short Period ◽

Basic Physics ◽

Synchronous Rotation ◽

Orbital Periods

We have yet to understand the magnetic activity cycles of cool close binary systems of sunlike stars. Mutual tidal interactions, as well as magnetic ones, may result from a regime of dynamo models not yet tested, because these have been developed for single stars. To arrive at the basic physics, though, requires that we first examine the phenomenology of magnetic activity for binary systems. In particular, we would like to discover if such activity has a clearly-defined cycle, such as the sun exibits.Among the proxy indicators of magnetic activity are the Ca II H and K lines. Strassmeier et al. (1988) used the strength of these lines as the primary criterion for the inclusion of systems in The Catalog of Chromospherically Binary Stars. Of the RS CVn stars in the catalog, 12 have orbital periods of one day or shorter; 9 are eclipsing systems. As part of a decade-long program, we have focussed our observations and models on eight of the short-period group (Hall, 1976): XY UMa, UV Psc, SV Cam, RT And, CG Cyg, ER Vul, BH Vir, and WY Cnc. These close systems are tidally-locked in synchronous rotation and tidally-distorted into Roche lobe configurations.

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Cassini state of Galilean Moons: Influence of a subsurface ocean

10.5194/egusphere-egu2020-8210 ◽

2020 ◽

Author(s):

Alexis Coyette ◽

Rose-Marie Baland ◽

Anne Lemaitre ◽

Tim Van Hoolst

Keyword(s):

Rotation Axis ◽

Rigid Bodies ◽

Galilean Satellites ◽

Precession Rate ◽

Subsurface Ocean ◽

Galilean Moons ◽

Existence And Stability ◽

Synchronous Rotation ◽

Laplace Plane ◽

Cassini State

Large moons such as the Galilean satellites are thought to be in an equilibrium rotation state, called a Cassini state (Peale, 1969). This state is characterized by a synchronous rotation and a precession rate of the rotation axis that is equal to the precession rate of the normal to its orbit. It also implies that the spin axis, the normal to the orbit and the normal to the Laplace plane are coplanar with a (nearly) constant obliquity.For rigid bodies, up to 4 possible Cassini states exist, but not all of them are stable. It is generally assumed that the Galilean satellites are in Cassini State I for which the obliquity is close to zero (see e.g. Baland et al. 2012). However, it is also theoretically possible that these satellites occupy or occupied another Cassini state.We here investigate how the interior structure, and in particular the presence of a subsurface ocean, influences the existence and stability of the different possible Cassini states.References :Baland, R.M., Yseboodt, M. and Van Hoolst, T. (2012). Obliquity of the Galilean satellites: The influence of a global internal liquid layer. Icarus 220, 435-448.Peale, S. (1969). Generalized Cassini&#8217;s laws. Astron. J. 74 (3), 483-489.

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