16,081 research outputs found
Slabs in the lower mantle and their modulation of plume formation
Numerical mantle convection models indicate that subducting slabs can reach the core-mantle boundary (CMB) for a wide range of assumed material properties and plate tectonic histories. An increase in lower mantle viscosity, a phase transition at 660 km depth, depth-dependent thermal expansivity, and depth-dependent thermal diffusivity do not preclude model slabs from reaching the CMB. We find that ancient slabs could be associated with lateral temperature anomalies ~500°C cooler than ambient mantle. Plausible increases of thermal conductivity with depth will not cause slabs to diffuse away. Regional spherical models with actual plate evolutionary models show that slabs are unlikely to be continuous from the upper mantle to the CMB, even for radially simple mantle structures. The observation from tomography showing only a few continuous slab-like features from the surface to the CMB may be a result of complex plate kinematics, not mantle layering. There are important consequences of deeply penetrating slabs. Our models show that plumes preferentially develop on the edge of slabs. In areas on the CMB free of slabs, plume formation and eruption are expected to be frequent while the basal thermal boundary layer would be thin. However, in areas beneath slabs, the basal thermal boundary layer would be thicker and plume formation infrequent. Beneath slabs, a substantial amount of hot mantle can be trapped over long periods of time, leading to “mega-plume” formation. We predict that patches of low seismic velocity may be found beneath large-scale high seismic velocity structures at the core-mantle boundary. We find that the location, buoyancy, and geochemistry of mega-plumes will differ from those plumes forming at the edge of slabs. Various geophysical and geochemical implications of this finding are discussed
The gravitational time delay in the field of a slowly moving body with arbitrary multipoles
We calculate the time delay of light in the gravitational field of a slowly
moving body with arbitrary multipoles (mass and spin multipole moments) by the
Time-Transfer-Function (TTF) formalism. The parameters we use, first introduced
by Kopeikin for a gravitational source at rest, make the integration of the TTF
very elegant and simple. Results completely coincide with expressions from the
literature. The results for a moving body (with constant velocity) with
complete multipole-structure are new, according to our knowledge.Comment: 9 pages, no figure
News, liquidity dynamics and intraday jumps: evidence from the HUF/EUR market
We study intraday jumps on a pure limit order FX market by linking them to news announcements and liquidity shocks. First, we show that jumps are frequent and contribute greatly to the return volatility. Nearly half of the jumps can be linked with scheduled and unscheduled news announcements. Furthermore, we show that jumps are information based, whether they are linked with news announcements or not. Prior to jumps, liquidity does not deviate from its normal level, nor do liquidity shocks offer any predictive power for jump occurrence. Jumps emerge not as a result of unusually low liquidity but rather as a result of an unusually high demand for immediacy concentrated on one side of the book. During and after the jump, a dynamic order placement process emerges: some participants endogenously become liquidity providers and absorb the increased demand for immediacy. We detect an interesting asymmetry and find the liquidity providers to be more reluctant to add liquidity when confronted with a news announcement around the jump. Further evidence shows that participants submit more limit orders relative to market orders after a jump. Consequently, the informational role of order flow becomes less pronounced in the thick order book after the jump
Advanced relativistic VLBI model for geodesy
Our present relativistic part of the geodetic VLBI model for Earthbound
antennas is a consensus model which is considered as a standard for processing
high-precision VLBI observations. It was created as a compromise between a
variety of relativistic VLBI models proposed by different authors as documented
in the IERS Conventions 2010. The accuracy of the consensus model is in the
picosecond range for the group delay but this is not sufficient for current
geodetic pur- poses. This paper provides a fully documented derivation of a new
relativistic model having an accuracy substantially higher than one picosecond
and based upon a well accepted formalism of relativistic celestial mechanics,
astrometry and geodesy. Our new model fully confirms the consensus model at the
picosecond level and in several respects goes to a great extent beyond it. More
specifically, terms related to the acceleration of the geocenter are considered
and kept in the model, the gravitational time-delay due to a massive body
(planet, Sun, etc.) with arbitrary mass and spin-multipole moments is derived
taking into account the motion of the body, and a new formalism for the
time-delay problem of radio sources located at finite distance from VLBI
stations is presented. Thus, the paper presents a substantially elaborated
theoretical justification of the consensus model and its significant extension
that allows researchers to make concrete estimates of the magnitude of residual
terms of this model for any conceivable configuration of the source of light,
massive bodies, and VLBI stations. The largest terms in the relativistic time
delay which can affect the current VLBI observations are from the quadrupole
and the angular momentum of the gravitating bodies that are known from the
literature. These terms should be included in the new geodetic VLBI model for
improving its consistency.Comment: 37 pages, 4 figure
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