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143 results on '"Christensen, Ulrich R."'

1. The Effects of a Stably Stratified Region with radially varying Electrical Conductivity on the Formation of Zonal Winds on Gas Planets

Author

Wulff, Paula N., Christensen, Ulrich R., Dietrich, Wieland, and Wicht, Johannes

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

The outer areas of Jupiter and Saturn have multiple zonal winds, reaching the high latitudes, that penetrate deep into the planets' interiors, as suggested by gravity measurements. These characteristics are replicable in numerical simulations by including both a shallow stably stratified layer, below a convecting envelope, and increasing electrical conductivity. A dipolar magnetic field, assumed to be generated by a dynamo below our model, is imposed. We find that the winds' depth into the stratified layer depends on the local product of the squared magnetic field strength and electrical conductivity. The key for the drop-off of the zonal winds is a meridional circulation which perturbs the density structure in the stable layer. In the stable region its dynamics is governed by a balance between Coriolis and electromagnetic forces. Our models suggest that a stable layer extending into weakly conducting regions could account for the observed deep zonal wind structures., Comment: Accepted by JGR - Planets

Published
2024

2. Saturn's Magnetic Field at Unprecedented Detail Achieved by Cassini's Close Encounters

Author

Cao, Hao, Dougherty, Michele K., Hunt, Gregory J., Bunce, Emma J., Christensen, Ulrich R., Khurana, Krishan K., and Kivelson, Margaret G.

Subjects
Astrophysics - Earth and Planetary Astrophysics, Physics - Fluid Dynamics
Abstract

The last 22.5 orbits of the Cassini mission brought the spacecraft to less than 3000 km from Saturn's 1-bar surface. These close encounters offered an unprecedented view of Saturn's magnetic field, including contributions from the internal dynamo, the ionosphere, and the magnetosphere. In this chapter, we highlight the new picture of Saturn's magnetic field from the Cassini mission including the persistent yet time-varying low-latitude field-aligned currents, Alfv\'en waves planet-ward of the D-ring, extreme axisymmetry, and high-degree magnetic moments. We then discuss the implications and new questions raised for Saturn's innermost magnetosphere, equatorial ionosphere, and interior. We conclude this chapter with an outlook for the future exploration of Saturn and other giant planets., Comment: Peer reviewed and accepted for publication as Chapter 5 of a multi-volume work edited by Kevin Baines, Michael Flasar, Norbert Krupp, and Thomas Stallard, entitled Cassini at Saturn: The Grand Finale, to be published by Cambridge University Press. 15 pages, 10 figures

Published
2023

3. Direct driving of simulated planetary jets by upscale energy transfer

Author

Böning, Vincent G. A., Wulff, Paula, Dietrich, Wieland, Wicht, Johannes, and Christensen, Ulrich R.

Subjects
Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Solar and Stellar Astrophysics, Nonlinear Sciences - Chaotic Dynamics, Physics - Fluid Dynamics, Physics - Geophysics
Abstract

The precise mechanism that forms jets and large-scale vortices on the giant planets is unknown. An inverse cascade has been suggested. Alternatively, energy may be directly injected by small-scale convection. Our aim is to clarify whether an inverse cascade feeds zonal jets and large-scale eddies in a system of rapidly rotating, deep, geostrophic spherical-shell convection. We analyze the nonlinear scale-to-scale transfer of kinetic energy in such simulations as a function of the azimuthal wave number, m. We find that the main driving of the jets is associated with upscale transfer directly from the small convective scales to the jets. This transfer is very nonlocal in spectral space, bypassing large-scale structures. The jet formation is thus not driven by an inverse cascade. Instead, it is due to a direct driving by Reynolds stresses from small-scale convective flows. Initial correlations are caused by the effect of uniform background rotation and shell geometry on the flows. While the jet growth suppresses convection, it increases the correlation of the convective flows, which further amplifies the jet growth until it is balanced by viscous dissipation. To a much smaller extent, energy is transferred upscale to large-scale vortices directly from the convective scales, mostly outside the tangent cylinder. There, large-scale vortices are not driven by an inverse cascade either. Inside the tangent cylinder, the transfer to large-scale vortices is weaker, but more local in spectral space, leaving open the possibility of an inverse cascade as a driver of large-scale vortices. In addition, large-scale vortices receive kinetic energy from the jets via forward transfer. We therefore suggest a jet instability as an alternative formation mechanism of largescale vortices. Finally, we find that the jet kinetic energy scales as $\ell^{-5}$, the same as for the zonostrophic regime., Comment: 15 pages, 14 figures, accepted for publication in A&A

Published
2022
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4. Linking Zonal Winds and Gravity II: explaining the equatorially antisymmetric gravity moments of Jupiter

Author

Dietrich, Wieland, Wulff, Paula, Wicht, Johannes, and Christensen, Ulrich R.

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

The recent gravity field measurements of Jupiter (Juno) and Saturn (Cassini) confirm the existence of deep zonal flows reaching to a depth of 5\% and 15\% of the respective radius. Relating the zonal wind induced density perturbations to the gravity moments has become a major tool to characterise the interior dynamics of gas giants. Previous studies differ with respect to the assumptions made on how the wind velocity relates to density anomalies, on the functional form of its decay with depth, and on the continuity of antisymmetric winds across the equatorial plane. Most of the suggested vertical structures exhibit a rather smooth radial decay of the zonal wind, which seems at odds with the observed secular variation of the magnetic field and the prevailing geostrophy of the zonal winds. Moreover, the results relied on an artificial equatorial regularisation or ignored the equatorial discontinuity altogether. We favour an alternative structure, where the equatorially antisymmetric zonal wind in an equatorial latitude belt between $\pm 21^\circ$ remains so shallow that it does not contribute to the gravity signal. The winds at higher latitudes suffice to convincingly explain the measured gravity moments. Our results indicate that the winds are geostrophic, i.e. constant along cylinders, in the outer $3000\,$ km and decay rapidly below. The preferred wind structure is 50\% deeper than previously thought, agrees with the measured gravity moment, is compliant with the magnetic constraints and the requirement of an adiabatic atmosphere and unbiased by the treatment of the equatorial discontinuity.

Published
2021
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5. Linking Zonal Winds and Gravity: The Relative Importance of Dynamic Self Gravity

Author

Wicht, Johannes, Dietrich, Wieland, Wulff, Paula, and Christensen, Ulrich R.

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

Recent precise measurements at Jupiter's and Saturn's gravity fields constrain the properties of the zonal flows in the outer envelopes of these planets. A simplified dynamic equation, sometimes called the thermal wind or thermo-gravitational wind equation, establishes a link between zonal flows and the related buoyancy perturbation, which in turn can be exploited to yield the dynamic gravity perturbation. Whether or not the action of the dynamic gravity perturbation needs to be explicitly included in this equation, an effect we call the Dynamic Self Gravity (DSG), has been a matter of intense debate. We show that, under reasonable assumptions, the equation can be solved (semi) analytically. This allows us to quantify the impact of the DSG on each gravity harmonic, practically independent of the zonal flow or the details of the planetary interior model. The impact decreases with growing spherical harmonic degree l. For degrees l=2 to about l=4, the DSG is a first order effect and should be taken into account in any attempt of inverting gravity measurements for zonal flow properties. For degrees of about l=5 to roughly l=10, the relative impact of DSG is about 10% and thus seems worthwhile to include, in particular since this comes at little extra costs with the method presented here. For yet higher degrees, is seems questionable whether gravity measurements or interior models will ever reach the required precision equivalent of the DSG impact of only a few percent of less., Comment: 28 pages, 6 figures

Published
2019
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6. Global-scale equatorial Rossby waves as an essential component of solar internal dynamics

Author

Löptien, Björn, Gizon, Laurent, Birch, Aaron C., Schou, Jesper, Proxauf, Bastian, Duvall Jr., Thomas L., Bogart, Richard S., and Christensen, Ulrich R.

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

The Sun's complex dynamics is controlled by buoyancy and rotation in the convection zone and by magnetic forces in the atmosphere and corona. While small-scale solar convection is well understood, the dynamics of large-scale flows in the solar convection zone is not explained by theory or simulations. Waves of vorticity due to the Coriolis force, known as Rossby waves, are expected to remove energy out of convection at the largest scales. Here we unambiguously detect and characterize retrograde-propagating vorticity waves in the shallow subsurface layers of the Sun at angular wavenumbers below fifteen, with the dispersion relation of textbook sectoral Rossby waves. The waves have lifetimes of several months, well-defined mode frequencies below 200 nHz in a co-rotating frame, and eigenfunctions of vorticity that peak at the equator. Rossby waves have nearly as much vorticity as the convection at the same scales, thus they are an essential component of solar dynamics. We find a transition from turbulence-like to wave-like dynamics around the Rhines scale of angular wavenumber of twenty; this might provide an explanation for the puzzling deficit of kinetic energy at the largest spatial scales., Comment: This is the submitted version of the paper published in Nature Astronomy. 23 pages, 8 figures, 1 table

Published
2018
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8. Approaching a realistic force balance in geodynamo simulations

Author

Yadav, Rakesh K., Gastine, Thomas, Christensen, Ulrich R., Wolk, Scott J., and Poppenhaeger, Katja

Subjects
Physics - Geophysics, Astrophysics - Earth and Planetary Astrophysics, Physics - Fluid Dynamics
Abstract

Earth sustains its magnetic field by a dynamo process driven by convection in the liquid outer core. Geodynamo simulations have been successful in reproducing many observed properties of the geomagnetic field. However, while theoretical considerations suggest that flow in the core is governed by a balance between Lorentz force, rotational force and buoyancy (called MAC balance for Magnetic, Archimedean, Coriolis) with only minute roles for viscous and inertial forces, dynamo simulations must employ viscosity values that are many orders of magnitude larger than in the core due to computational constraints. In typical geodynamo models viscous and inertial forces are not much smaller than the Coriolis force and the Lorentz force plays a sub-dominant role. This has led to conclusions that these simulations are viscously controlled and do not represent the physics of the geodynamo. Here we show by a direct analysis of the relevant forces that a MAC balance can be achieved when the viscosity is reduced to values close to the current practical limit. Lorentz force, buoyancy and the uncompensated (by pressure) part of the Coriolis force are of very similar strength, whereas viscous and inertia are smaller by a factor of at least 20 in the bulk of the fluid volume. Compared to non-magnetic convection at otherwise identical parameters, the dynamo flow is of larger scale, less invariant parallel to the rotation axis (less geostrophic) and convection transports twice as much heat, all of which is expected when the Lorentz force strongly influences the convection properties., Comment: Accepted for publication in the Proceedings of the National Academy of Sciences (PNAS)

Published
2016
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9. Magnetic cycles in a dynamo simulation of fully convective M-star Proxima Centauri

Author

Yadav, Rakesh K., Christensen, Ulrich R., Wolk, Scott J., and Poppenhaeger, Katja

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

The recent discovery of an Earth-like exoplanet around Proxima Centauri has shined a spot light on slowly rotating fully convective M-stars. When such stars rotate rapidly (period $\lesssim 20$ days), they are known to generate very high levels of activity that is powered by a magnetic field much stronger than the solar magnetic field. Recent theoretical efforts are beginning to understand the dynamo process that generates such strong magnetic fields. However, the observational and theoretical landscape remains relatively uncharted for fully convective M-stars that rotate slowly. Here we present an anelastic dynamo simulation designed to mimic some of the physical characteristics of Proxima Centauri, a representative case for slowly rotating fully convective M-stars. The rotating convection spontaneously generates differential rotation in the convection zone which drives coherent magnetic cycles where the axisymmetric magnetic field repeatedly changes polarity at all latitudes as time progress. The typical length of the `activity' cycle in the simulation is about nine years, in good agreement with the recently proposed activity cycle length of about seven years for Proxima Centauri. Comparing our results with earlier work, we hypothesis that the dynamo mechanism undergoes a fundamental change in nature as fully convective stars spin down with age., Comment: 8 pages, 4 figures, double column; Accepted in ApJ Letters

Published
2016
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10. Explaining the coexistence of large-scale and small-scale magnetic fields in fully convective stars

Author

Yadav, Rakesh K., Christensen, Ulrich R., Morin, Julien, Gastine, Thomas, Reiners, Ansgar, Poppenhaeger, Katja, and Wolk, Scott J.

Subjects
Astrophysics - Solar and Stellar Astrophysics, Physics - Fluid Dynamics, Physics - Plasma Physics
Abstract

Despite the lack of a shear-rich tachocline region low-mass fully convective stars are capable of generating strong magnetic fields, indicating that a dynamo mechanism fundamentally different from the solar dynamo is at work in these objects. We present a self-consistent three dimensional model of magnetic field generation in low-mass fully convective stars. The model utilizes the anelastic magnetohydrodynamic equations to simulate compressible convection in a rotating sphere. A distributed dynamo working in the model spontaneously produces a dipole-dominated surface magnetic field of the observed strength. The interaction of this field with the turbulent convection in outer layers shreds it, producing small-scale fields that carry most of the magnetic flux. The Zeeman-Doppler-Imaging technique applied to synthetic spectropolarimetric data based on our model recovers most of the large-scale field. Our model simultaneously reproduces the morphology and magnitude of the large-scale field as well as the magnitude of the small-scale field observed on low-mass fully convective stars., Comment: Double column format, 6 pages, 5 figures. To appear in ApJL

Published
2015
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11. Effect of shear and magnetic field on the heat-transfer efficiency of convection in rotating spherical shells

Author

Yadav, Rakesh K., Gastine, Thomas, Christensen, Ulrich R., Duarte, Lucia, and Reiners, Ansgar

Subjects
Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Solar and Stellar Astrophysics, Physics - Fluid Dynamics, Physics - Geophysics, Physics - Plasma Physics
Abstract

We study rotating thermal convection in spherical shells. We base our analysis on a set of about 450 direct numerical simulations of the (magneto)hydrodynamic equations under the Boussinesq approximation. The Ekman number ranges from $10^{-3}$ to $10^{-5}$. The supercriticality of the convection reaches about 1000 in some models. Four sets of simulations are considered: non-magnetic simulations and dynamo simulations with either free-slip or no-slip flow boundary conditions. The non-magnetic setup with free-slip boundaries generates the strongest zonal flows. Both non-magnetic simulations with no-slip flow boundary conditions and self-consistent dynamos with free-slip boundaries have drastically reduced zonal-flows. Suppression of shear leads to a substantial gain in heat-transfer efficiency, increasing by a factor of 3 in some cases. Such efficiency enhancement occurs as long as the convection is significantly influenced by rotation. At higher convective driving the heat-transfer efficiency tends towards that of the classical non-rotating Rayleigh-B\'enard system. Analysis of the latitudinal distribution of heat flow at the outer boundary reveals that the shear is most effective at suppressing heat-transfer in the equatorial regions. Furthermore, we explore the influence of the magnetic field on the {\em non-zonal} flow components of the convection. For this we compare the heat-transfer efficiency of no-slip non-magnetic cases with that of the no-slip dynamo simulations. We find that at $E=10^{-5}$ magnetic field significantly affects the convection and a maximum gain of about 30\% (as compared to the non-magnetic case) in heat-transfer efficiency is obtained for an Elsasser number of about 3. Our analysis motivates us to speculate that convection in the polar regions in dynamos at $E=10^{-5}$ is probably in a `magnetostrophic' regime., Comment: 15 pages, double column format, 10 figures. Substantial modifications in version 2. Data for shells with aspect ratio 0.35 ("Supple_data") can be found in the source. To appear in "Geophysical Journal International"

Published
2015
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12. Performance benchmarks for a next generation numerical dynamo model

Author

Matsui, Hiroaki, Heien, Eric, Aubert, Julien, Aurnou, Jonathan M, Avery, Margaret, Brown, Ben, Buffett, Bruce A, Busse, Friedrich, Christensen, Ulrich R, Davies, Christopher J, Featherstone, Nicholas, Gastine, Thomas, Glatzmaier, Gary A, Gubbins, David, Guermond, Jean‐Luc, Hayashi, Yoshi‐Yuki, Hollerbach, Rainer, Hwang, Lorraine J, Jackson, Andrew, Jones, Chris A, Jiang, Weiyuan, Kellogg, Louise H, Kuang, Weijia, Landeau, Maylis, Marti, Philippe, Olson, Peter, Ribeiro, Adolfo, Sasaki, Youhei, Schaeffer, Nathanaël, Simitev, Radostin D, Sheyko, Andrey, Silva, Luis, Stanley, Sabine, Takahashi, Futoshi, Takehiro, Shin‐ichi, Wicht, Johannes, and Willis, Ashley P

Subjects
geodynamo, magnetohydrodynamics, benchmark, high-performance computing, Physical Sciences, Earth Sciences, Geochemistry & Geophysics
Abstract

Numerical simulations of the geodynamo have successfully represented many observable characteristics of the geomagnetic field, yielding insight into the fundamental processes that generate magnetic fields in the Earth's core. Because of limited spatial resolution, however, the diffusivities in numerical dynamo models are much larger than those in the Earth's core, and consequently, questions remain about how realistic these models are. The typical strategy used to address this issue has been to continue to increase the resolution of these quasi-laminar models with increasing computational resources, thus pushing them toward more realistic parameter regimes. We assess which methods are most promising for the next generation of supercomputers, which will offer access to O(106) processor cores for large problems. Here we report performance and accuracy benchmarks from 15 dynamo codes that employ a range of numerical and parallelization methods. Computational performance is assessed on the basis of weak and strong scaling behavior up to 16,384 processor cores. Extrapolations of our weak-scaling results indicate that dynamo codes that employ two-dimensional or three-dimensional domain decompositions can perform efficiently on up to ∼106 processor cores, paving the way for more realistic simulations in the next model generation.

Published
2016

13. Formation of starspots in self-consistent global dynamo models: Polar spots on cool stars

Author

Yadav, Rakesh K., Gastine, Thomas, Christensen, Ulrich R., and Reiners, Ansgar

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

Observations of cool stars reveal dark spot-like features on their surfaces. Compared to sunspots, starspots can be bigger or cover a larger fraction of the stellar surface. While sunspots appear only at low latitudes, starspots are also found in polar regions, in particular on rapidly rotating stars. Sunspots are believed to result from the eruption of magnetic flux-tubes rising from the deep interior of the Sun. The strong magnetic field locally reduces convective heat transport to the solar surface. Such flux-tube models have also been invoked to explain starspot properties. However, these models use several simplifications and so far the generation of either sunspots or starspots has not been demonstrated in a self-consistent simulation of stellar magnetic convection. Here we show that direct numerical simulations of a distributed dynamo operating in a density-stratified rotating spherical shell can spontaneously generate cool spots. Convection in the interior of the model produces a large scale magnetic field which interacts with near surface granular convection leading to strong concentrations of magnetic flux and formation of starspots. Prerequisites for the formation of sizeable high-latitude spots in the model are sufficiently strong density stratification and rapid rotation. Our model presents an alternate mechanism for starspot formation by distributed dynamo action., Comment: 14 pages; Important additions in version 2; To appear in A&A

Published
2014
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14. Bridging planets and stars using scaling laws in anelastic spherical shell dynamos

Author

Yadav, Rakesh K., Gastine, Thomas, Christensen, Ulrich R., and Duarte, Lucia D. V.

Subjects
Astrophysics - Solar and Stellar Astrophysics, Astrophysics - Earth and Planetary Astrophysics
Abstract

Dynamos operating in the interiors of rapidly rotating planets and low-mass stars might belong to a similar category where rotation plays a vital role. We quantify this similarity using scaling laws. We analyse direct numerical simulations of Boussinesq and anelastic spherical shell dynamos. These dynamos represent simplified models which span from Earth-like planets to rapidly rotating low-mass stars. We find that magnetic field and velocity in these dynamos are related to the available buoyancy power via a simple power law which holds over wide variety of control parameters., Comment: 2 pages; Proceedings of IAUS 302: Magnetic fields throughout stellar evolution (August 2013, Biarritz, France)

Published
2013
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15. Consistent scaling laws in anelastic spherical shell dynamos

Author

Yadav, Rakesh K., Gastine, Thomas, Christensen, Ulrich R., and Duarte, Lúcia D. V.

Subjects
Astrophysics - Solar and Stellar Astrophysics, Astrophysics - Earth and Planetary Astrophysics
Abstract

Numerical dynamo models always employ parameter values that differ by orders of magnitude from the values expected in natural objects. However, such models have been successful in qualitatively reproducing properties of planetary and stellar dynamos. This qualitative agreement fuels the idea that both numerical models and astrophysical objects may operate in the same asymptotic regime of dynamics. This can be tested by exploring the scaling behavior of the models. For convection-driven incompressible spherical shell dynamos with constant material properties, scaling laws had been established previously that relate flow velocity and magnetic field strength to the available power. Here we analyze 273 direct numerical simulations using the anelastic approximation, involving also cases with radius-dependent magnetic, thermal and viscous diffusivities. These better represent conditions in gas giant planets and low-mass stars compared to Boussinesq models. Our study provides strong support for the hypothesis that both mean velocity and mean magnetic field strength scale as a function of power generated by buoyancy forces in the same way for a wide range of conditions., Comment: 9 pages, 4 figures, 1 table; data used in the paper can be found in "Dataset.txt" file available in the source; to appear in ApJ

Published
2013
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16. Scaling laws in spherical shell dynamos with free-slip boundaries

Author

Yadav, Rakesh K., Gastine, Thomas, and Christensen, Ulrich R.

Subjects
Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Solar and Stellar Astrophysics, Physics - Geophysics
Abstract

Numerical simulations of convection driven rotating spherical shell dynamos have often been performed with rigid boundary conditions, as is appropriate for the metallic cores of terrestrial planets. Free-slip boundaries are more appropriate for dynamos in other astrophysical objects, such as gas-giants or stars. Using a set of 57 direct numerical simulations, we investigate the effect of free-slip boundary conditions on the scaling properties of heat flow, flow velocity and magnetic field strength and compare it with earlier results for rigid boundaries. We find that the nature of the mechanical boundary condition has only a minor influence on the scaling laws. We also find that although dipolar and multipolar dynamos exhibit approximately the same scaling exponents, there is an offset in the scaling pre-factors for velocity and magnetic field strength. We argue that the offset can be attributed to the differences in the zonal flow contribution between dipolar and multipolar dynamos., Comment: 10 pages, 9 figures, 1 table. To appear in ICARUS

Published
2012
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17. A magnetic field evolution scenario for brown dwarfs and giant planets

Author

Reiners, Ansgar and Christensen, Ulrich R.

Subjects
Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Solar and Stellar Astrophysics
Abstract

Very little is known about magnetic fields of extrasolar planets and brown dwarfs. We use the energy flux scaling law presented by Christensen et al. (2009) to calculate the evolution of average magnetic fields in extrasolar planets and brown dwarfs under the assumption of fast rotation, which is probably the case for most of them. We find that massive brown dwarfs of about 70 M_Jup can have fields of a few kilo-Gauss during the first few hundred Million years. These fields can grow by a factor of two before they weaken after deuterium burning has stopped. Brown dwarfs with weak deuterium burning and extrasolar giant planets start with magnetic fields between ~100G and ~1kG at the age of a few Myr, depending on their mass. Their magnetic field weakens steadily until after 10Gyr it has shrunk by about a factor of 10. We use observed X-ray luminosities to estimate the age of the known extrasolar giant planets that are more massive than 0.3M_Jup and closer than 20pc. Taking into account the age estimate, and assuming sun-like wind-properties and radio emission processes similar to those at Jupiter, we calculate their radio flux and its frequency. The highest radio flux we predict comes out as 700mJy at a frequency around 150MHz for $\tau$Boob, but the flux is below 60mJy for the rest. Most planets are expected to emit radiation between a few Mhz and up to 100MHz, well above the ionospheric cutoff frequency., Comment: 7 pages, accepted by A&A

Published
2010
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18. Surprisingly Weak Magnetism on Young Accreting Brown Dwarfs

Author

Reiners, Ansgar, Basri, Gibor, and Christensen, Ulrich R.

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

We have measured the surface magnetic flux on four accreting young brown dwarfs and one non-accreting young very low-mass star utilizing high resolution spectra of absorption lines of the FeH molecule. A magnetic field of 1-2 kG had been proposed for one of the brown dwarfs, 2MASS J1207334$-$393254, because of its similarities to higher mass T Tauri stars as manifested in accretion and the presence of a jet. We do not find clear evidence for a kilo-Gauss field in any of our young brown dwarfs but do find a 2 kG field on the young VLM star. Our 3-$\sigma$ upper limit for the magnetic flux in 2MASS J1207334$-$393254 just reaches 1 kG. We estimate the magnetic field required for accretion in young brown dwarfs given the observed rotations, and find that fields of only a few hundred Gauss are sufficient for magnetospheric accretion. This predicted value is less than our observed upper limit. We conclude that magnetic fields in young brown dwarfs are a factor of five or more lower than in young stars of about one solar mass, and in older stars with spectral types similar to our young brown dwarfs. It is interesting that, during the first few million years, the fields scale down with mass in line with what is needed for magnetospheric accretion, yet no such scaling is observed at later ages within the same effective temperature range. This scaling is opposite to the trend in rotation, with shorter rotation periods for very young accreting brown dwarfs compared with accreting solar-mass objects (and very low Rossby numbers in all cases). We speculate that in young objects a deeper intrinsic connection may exist between magnetospheric accretion and magnetic field strength, or that magnetic field generation in brown dwarfs may be less efficient than in stars. Neither of these currently have an easy physical explanation., Comment: accepted by ApJ

Published
2009
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19. Convective heat transfer in planetary dynamo models

Author

King, Eric M, Soderlund, Krista M, Christensen, Ulrich R, Wicht, Johannes, and Aurnou, Jonathan M

Subjects
dynamo, fluid dynamics, heat transfer, convection, core, turbulence, Physical Sciences, Earth Sciences, Geochemistry & Geophysics
Abstract

The magnetic fields of planets and stars are generated by the motions of electrically conducting fluids within them. These fluid motions are thought to be driven by convective processes, as internal heat is transported outward. The efficiency with which heat is transferred by convection is integral in understanding dynamo processes. Several heat transfer scaling laws have been proposed, but the range of parameter space to which they apply has not been firmly established. Following the plane layer convection study by King et al. (2009), we explore a broad range of buoyancy forcing (Ra) and rotation strength (E-1) to show that heat transfer (Nu) in spherical dynamo simulations occurs in two distinct regimes. We argue that heat transfer scales as Nu ∼ Ra6/5 in the rapidly rotating regime and Nu ∼ Ra2/7 in the weakly rotating regime. The transition between these two regimes is controlled by the competition between the thermal and viscous boundary layers. Boundary layer scaling theory allows us to predict that the transition between the regimes occurs at a transitional Rayleigh number, Rat = E -7/4. Furthermore, boundary layer control of heat transfer is shown to relate to the interior temperature profiles of the models. In the weakly rotating regime, the interior fluid is nearly adiabatic. In the rapidly rotating regime, adverse mean temperature gradients abide, irrespective of the Reynolds number (Re). Extrapolating our results to Earth's core, we estimate that core convection resides in the rapidly rotating regime, with Ra ≈ 2 × 1024 (Ra/Rat ≈ 0.02), corresponding to a superadiabatic density variation of Δρ/ρ ≈ 10-7, which is significantly below the sensitivity of present seismic observations. Copyright 2010 by the American Geophysical Union.

Published
2010

25. Determination of the lunar body tide from global laser altimetry data

Author

Thor, Robin N., Kallenbach, Reinald, Christensen, Ulrich R., Gläser, Philipp, Stark, Alexander, Steinbrügge, Gregor, Oberst, Jürgen, Institute of Geodesy and Geoinformation Science, Technische Universität Berlin, Berlin, Germany, DLR Institute of Planetary Research, Berlin, Germany, Max Planck Institute for Solar System Research, Göttingen, Germany, and Department of Geophysics, Stanford University, Stanford, USA

Subjects
ddc:523, ddc:629, 010504 meteorology & atmospheric sciences, Lunar orbiter, Laser altimetry, LRO, Laser Altimeter, Lunar interior, Tides, 01 natural sciences, Geochemistry and Petrology, 0103 physical sciences, Altimeter, Computers in Earth Sciences, Moon, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Planetengeodäsie, Inversion (meteorology), Geodesy, Geophysics, ddc:520, Planetare Sensorsysteme, Love number, Geology, Lunar Orbiter Laser Altimeter
Abstract

We use global data from the Lunar Orbiter Laser Altimeter (LOLA) to retrieve the lunar tidal Love number h2 and find h2 = 0.0387 ± 0.0025. This result is in agreement with previous estimates from laser altimetry using crossover points of LOLA profiles. The Love numbers k2 and h2 are key constraints on planetary interior models. We further develop and apply a retrieval method based on a simultaneous inversion for the topography and the tidal signal benefiting from the large volume of LOLA data. By the application to the lunar tides, we also demonstrate the potential of the method for future altimetry experiments at other planetary bodies. The results of this study are very promising with respect to the determination of Mercury’s and Ganymede’s h2 from future altimeter measurements., DLR Space Administration, International Max Planck Research School on Solar System Science at the University of Göttingen, Deutsche Forschungsgemeinschaft http://dx.doi.org/10.13039/501100001659

Published
2020

26. Joint Inversion of Receiver Functions and Apparent Incidence Angles for Sparse Seismic Data

Author

Joshi, Rakshit, Knapmeyer-Endrun, Brigitte, Mosegaard, Klaus, Igel, Heiner, Christensen, Ulrich R., Joshi, Rakshit, Knapmeyer-Endrun, Brigitte, Mosegaard, Klaus, Igel, Heiner, and Christensen, Ulrich R.

Abstract

The estimation of crustal structure and thickness is essential in understanding the formation and evolution of terrestrial planets. Initial planetary missions with seismic instrumentation on board face the additional challenge of dealing with seismic activity levels that are only poorly constrained a priori. For example, the lack of plate tectonics on Mars leads to low seismicity, which could, in turn, hinder the application of many terrestrial data analysis techniques. Here we propose using a joint inversion of receiver functions and apparent incidence angles, which contain information on absolute S-wave velocities of the subsurface. Since receiver function inversions suffer from a velocity depth trade-off, we in addition exploit a simple relation that defines apparent S-wave velocity as a function of observed apparent P-wave incidence angles to constrain the parameter space. We then use the Neighborhood Algorithm for the inversion of a suitable joint objective function. The resulting ensemble of models is then used to derive uncertainty estimates for each model parameter. In preparation for the analysis of data from the InSight mission, we show the application of our proposed method on Mars synthetics and sparse terrestrial data sets from different geological settings using both single and multiple events. We use information-theoretic statistical tests as model selection criteria and discuss their relevance and implications in a seismological framework.

Published
2021

27. Detection, Analysis, and Removal of Glitches From InSight's Seismic Data From Mars

Author

Scholz, John‐Robert, primary, Widmer‐Schnidrig, Rudolf, additional, Davis, Paul, additional, Lognonné, Philippe, additional, Pinot, Baptiste, additional, Garcia, Raphaël F., additional, Hurst, Kenneth, additional, Pou, Laurent, additional, Nimmo, Francis, additional, Barkaoui, Salma, additional, de Raucourt, Sébastien, additional, Knapmeyer‐Endrun, Brigitte, additional, Knapmeyer, Martin, additional, Orhand‐Mainsant, Guénolé, additional, Compaire, Nicolas, additional, Cuvier, Arthur, additional, Beucler, Éric, additional, Bonnin, Mickaël, additional, Joshi, Rakshit, additional, Sainton, Grégory, additional, Stutzmann, Eléonore, additional, Schimmel, Martin, additional, Horleston, Anna, additional, Böse, Maren, additional, Ceylan, Savas, additional, Clinton, John, additional, van Driel, Martin, additional, Kawamura, Taichi, additional, Khan, Amir, additional, Stähler, Simon C., additional, Giardini, Domenico, additional, Charalambous, Constantinos, additional, Stott, Alexander E., additional, Pike, William T., additional, Christensen, Ulrich R., additional, and Banerdt, W. Bruce, additional

Published
2020
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30. Prospects for measuring Mercury’s tidal Love number h2 with the BepiColombo Laser Altimeter

Author

Thor, Robin N., Kallenbach, Reinald, Christensen, Ulrich R., Stark, A., Steinbrügge, G., Ruscio, A. Di, Cappuccio, P., Iess, L., Hussmann, H., and Oberst, Jürgen

Subjects
ddc:629, satellites, planets, ddc:520, planet surfaces, Mercury, 520 Astronomie und zugeordnete Wissenschaften, planet interiors, 629 Andere Fachrichtungen der Ingenieurwissenschaften
Abstract

Context. The Love number h2 describes the radial tidal displacements of Mercury’s surface and allows constraints to be set on the inner core size when combined with the potential Love number k2. Knowledge of Mercury’s inner core size is fundamental to gaining insights into the planet’s thermal evolution and dynamo working principle. The BepiColombo Laser Altimeter (BELA) is currently cruising to Mercury as part of the BepiColombo mission and once it is in orbit around Mercury, it will acquire precise measurements of the planet’s surface topography, potentially including variability that is due to tidal deformation. Aims. We use synthetic measurements acquired using BELA to assess how accurately Mercury’s tidal Love number h2 can be determined by laser altimetry. Methods. We generated realistic, synthetic BELA measurements, including instrument performance, orbit determination, as well as uncertainties in spacecraft attitude and Mercury’s libration. We then retrieved Mercury’s h2 and global topography from the synthetic data through a joint inversion. Results. Our results suggest that h2 can be determined with an absolute accuracy of ± 0.012, enabling a determination of Mercury’s inner core size to ± 150 km given the inner core is sufficiently large (>800 km). We also show that the uncertainty of h2 depends strongly on the assumed scaling behavior of the topography at small scales and on the periodic misalignment of the instrument.

Published
2020
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33. Detection, Analysis, and Removal of Glitches From InSight's Seismic Data From Mars

Author

Scholz, John-Robert, Widmer-Schnidrig, Rudolf, Davis, Paul, Lognonne, Philippe, Pinot, Baptiste, Garcia, Raphael F., Hurst, Kenneth, Pou, Laurent, Nimmo, Francis, Barkaoui, Salma, De Raucourt, Sebastien, Knapmeyer-Endrun, Brigitte, Knapmeyer, Martin, Orhand-Mainsant, Guenole, Compaire, Nicolas, Cuvier, Arthur, Beucler, Eric, Bonnin, Mickael, Joshi, Rakshit, Sainton, Gregory, Stutzmann, Eleonore, Schimmel, Martin, Horleston, Anna, Bose, Maren, Ceylan, Savas, Clinton, John, Van Driel, Martin, Kawamura, Taichi, Khan, Amir, Stahler, Simon C., Giardini, Domenico, Charalambous, Constantinos, Stott, Alexander E., Pike, William T., Christensen, Ulrich R., Banerdt, W. Bruce, Scholz, John-Robert, Widmer-Schnidrig, Rudolf, Davis, Paul, Lognonne, Philippe, Pinot, Baptiste, Garcia, Raphael F., Hurst, Kenneth, Pou, Laurent, Nimmo, Francis, Barkaoui, Salma, De Raucourt, Sebastien, Knapmeyer-Endrun, Brigitte, Knapmeyer, Martin, Orhand-Mainsant, Guenole, Compaire, Nicolas, Cuvier, Arthur, Beucler, Eric, Bonnin, Mickael, Joshi, Rakshit, Sainton, Gregory, Stutzmann, Eleonore, Schimmel, Martin, Horleston, Anna, Bose, Maren, Ceylan, Savas, Clinton, John, Van Driel, Martin, Kawamura, Taichi, Khan, Amir, Stahler, Simon C., Giardini, Domenico, Charalambous, Constantinos, Stott, Alexander E., Pike, William T., Christensen, Ulrich R., and Banerdt, W. Bruce

Abstract

The instrument package SEIS (Seismic Experiment for Internal Structure) with the three very broadband and three short-period seismic sensors is installed on the surface on Mars as part of NASA's InSight Discovery mission. When compared to terrestrial installations, SEIS is deployed in a very harsh wind and temperature environment that leads to inevitable degradation of the quality of the recorded data. One ubiquitous artifact in the raw data is an abundance of transient one-sided pulses often accompanied by high-frequency spikes. These pulses, which we term glitches, can be modeled as the response of the instrument to a step in acceleration, while the spikes can be modeled as the response to a simultaneous step in displacement. We attribute the glitches primarily to SEIS-internal stress relaxations caused by the large temperature variations to which the instrument is exposed during a Martian day. Only a small fraction of glitches correspond to a motion of the SEIS package as a whole caused by minuscule tilts of either the instrument or the ground. In this study, we focus on the analysis of the glitch+spike phenomenon and present how these signals can be automatically detected and removed from SEIS's raw data. As glitches affect many standard seismological analysis methods such as receiver functions, spectral decomposition and source inversions, we anticipate that studies of the Martian seismicity as well as studies of Mars' internal structure should benefit from deglitched seismic data. Plain Language Summary The instrument package SEIS (Seismic Experiment for Internal Structure) with two fully equipped seismometers is installed on the surface of Mars as part of NASA's InSight Discovery mission. When compared to terrestrial installations, SEIS is more exposed to wind and daily temperature changes that leads to inevitable degradation of the quality of the recorded data. One consequence is the occurrence of a specific type of transient noise that we term glitch. Glitc

Published
2020

39. A sheet-metal geodynamo: a decade of modelling Earth's core on computers has led to the belief that we understand what produces Earth's magnetic field. More realistic simulations are now shaking that complacency

Author

Christensen, Ulrich R.

Subjects
Geodynamics -- Research -- Models, Earth -- Core, Magnetic fields -- Models -- Research, Environmental issues, Science and technology, Zoology and wildlife conservation, Models, Research, Properties
Abstract

Earth's magnetic field is often depicted as though a gigantic bar magnet resides inside our planet. In fact, the magnetic field is created by strong electrical currents generated by a [...]

Published
2008

40. The search for a subsurface ocean in Ganymede with Hubble Space Telescope observations of its auroral ovals

Author

Saur, Joachim, Duling, Stefan, Roth, Lorenz, Jia, Xianzhe, Strobel, Darrell F., Feldman, Paul D., Christensen, Ulrich R., Retherford, Kurt D., McGrath, Melissa A., Musacchio, Fabrizio, Wennmacher, Alexandre, Neubauer, Fritz M., Simon, Sven, Hartkorn, Oliver, Saur, Joachim, Duling, Stefan, Roth, Lorenz, Jia, Xianzhe, Strobel, Darrell F., Feldman, Paul D., Christensen, Ulrich R., Retherford, Kurt D., McGrath, Melissa A., Musacchio, Fabrizio, Wennmacher, Alexandre, Neubauer, Fritz M., Simon, Sven, and Hartkorn, Oliver

Abstract

We present a new approach to search for a subsurface ocean within Ganymede through observations and modeling of the dynamics of its auroral ovals. The locations of the auroral ovals oscillate due to Jupiter's time-varying magnetospheric field seen in the rest frame of Ganymede. If an electrically conductive ocean is present, the external time-varying magnetic field is reduced due to induction within the ocean and the oscillation amplitude of the ovals decreases. Hubble Space Telescope (HST) observations show that the locations of the ovals oscillate on average by 2.0 degrees 1.3 degrees. Our model calculations predict a significantly stronger oscillation by 5.8 degrees 1.3 degrees without ocean compared to 2.2 degrees 1.3 degrees if an ocean is present. Because the ocean and the no-ocean hypotheses cannot be separated by simple visual inspection of individual HST images, we apply a statistical analysis including a Monte Carlo test to also address the uncertainty caused by the patchiness of observed emissions. The observations require a minimum electrical conductivity of 0.09 S/m for an ocean assumed to be located between 150 km and 250 km depth or alternatively a maximum depth of the top of the ocean at 330 km. Our analysis implies that Ganymede's dynamo possesses an outstandingly low quadrupole-to-dipole moment ratio. The new technique applied here is suited to probe the interior of other planetary bodies by monitoring their auroral response to time-varying magnetic fields.

Published
2015

44. Approaching a realistic force balance in geodynamo simulations.

Author

Wolk, Scott J., Yadav, Rakesh K., Christensen, Ulrich R., Gastine, Thomas, and Poppenhaeger, Katja

Subjects
GEODYNAMICS, CORIOLIS force, LORENTZ force, MAGNETOHYDRODYNAMICS, TURBULENCE, CONVECTION (Astrophysics), MAGNETIC fields, PLANETARY science, MATHEMATICAL models
Abstract

Earth sustains its magnetic field by a dynamo process driven by convection in the liquid outer core. Geodynamo simulations have been successful in reproducing many observed properties of the geomagnetic field. However, although theoretical considerations suggest that flow in the core is governed by a balance between Lorentz force, rotational force, and buoyancy (called MAC balance for Magnetic, Archimedean, Coriolis) with only minute roles for viscous and inertial forces, dynamo simulations must use viscosity values that are many orders of magnitude larger than in the core, due to computational constraints. In typical geodynamo models, viscous and inertial forces are not much smaller than the Coriolis force, and the Lorentz force plays a subdominant role; this has led to conclusions that these simulations are viscously controlled and do not represent the physics of the geodynamo. Here we show, by a direct analysis of the relevant forces, that a MAC balance can be achieved when the viscosity is reduced to values close to the current practical limit. Lorentz force, buoyancy, and the uncompensated (by pressure) part of the Coriolis force are of very similar strength, whereas viscous and inertial forces are smaller by a factor of at least 20 in the bulk of the fluid volume. Compared with nonmagnetic convection at otherwise identical parameters, the dynamo flow is of larger scale and is less invariant parallel to the rotation axis (less geostrophic), and convection transports twice as much heat, all of which is expected when the Lorentz force strongly influences the convection properties. [ABSTRACT FROM AUTHOR]

Published
2016
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49. Formation of starspots in self-consistent global dynamo models: Polar spots on cool stars.

Author

Yadav, Rakesh K., Gastine, Thomas, Christensen, Ulrich R., and Reiners, Ansgar

Subjects
STARSPOTS, COOL stars (Astronomy), STELLAR dynamics, STELLAR magnetic fields, CONVECTION (Astrophysics), STELLAR rotation
Abstract

Context. Observations of cool stars reveal dark spot-like features on their surfaces. These starspots can be more extended than sunspots and cover a large area of the stellar surface. While sunspots appear only at low latitudes, starspots are also found in polar regions, in particular on rapidly rotating stars. Conventional flux-tube models have been invoked to explain starspot properties. However, these models use several simplifications, and so far, neither sunspots nor starspots have been generated in a self-consistent simulation of stellar magnetic convection. Aims. We aim to clarify the conditions necessary for the spontaneous formation of dark spots in numerical models of convectiondriven stellar dynamos. Methods. We simulated convection and magnetic field generation in rapidly rotating spherical shells assuming anelastic approximation. The high-resolution simulations were performed using a fully spectral magnetohydrodynamic code. Results. We demonstrate for the first time that a self-consistent distributed dynamo can spontaneously generate high-latitude dark spots. Dark spots are generated when a large-scale magnetic field, generated in the bulk of the convection zone, interacts with and locally quenches flow near the surface. Suffciently strong density stratification and rapid rotation are prerequisites for the formation of sizeable dark spots in the model. Conclusions. Our models present an alternative scenario for starspot formation by distributed dynamo action. Our results also lend strong support to the idea that dynamos in the interiors of rapidly rotating stars might be fundamentally dfferent from the solar one. [ABSTRACT FROM AUTHOR]

Published
2015
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