Jeremy Bloxham
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Jeremy Bloxhamearth-sciences Degrees
Earth Sciences
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Geophysics
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#147
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Earth Sciences
Jeremy Bloxham's Degrees
- Bachelors Physics University of Oxford
Why Is Jeremy Bloxham Influential?
(Suggest an Edit or Addition)According to Wikipedia, Jeremy Bloxham FRS is a British geophysicist, and Mallinckrodt Professor of Geophysics, at Harvard University. He was Dean of Science. Education He earned his Ph.D. from the University of Cambridge in 1986.
Jeremy Bloxham's Published Works
Number of citations in a given year to any of this author's works
Total number of citations to an author for the works they published in a given year. This highlights publication of the most important work(s) by the author
Published Works
- An Earth-like numerical dynamo model (1997) (414)
- The secular variation of Earth's magnetic field (1985) (347)
- Geomagnetic secular variation (1989) (343)
- Time‐dependent mapping of the magnetic field at the core‐mantle boundary (1992) (295)
- Fluid flow near the surface of Earth's outer core (1991) (271)
- A New Model of Jupiter's Magnetic Field From Juno's First Nine Orbits (2018) (221)
- Jupiter’s interior and deep atmosphere: The initial pole-to-pole passes with the Juno spacecraft (2017) (210)
- Thermal core– mantle interactions (1987) (207)
- The origin of geomagnetic jerks (2002) (182)
- Convective-region geometry as the cause of Uranus' and Neptune's unusual magnetic fields (2004) (181)
- Morphology of the geomagnetic field and implications for the geodynamo (1987) (179)
- Geomagnetic field analysis—III. Magnetic fields on the core—mantle boundary (1985) (175)
- Jupiter’s atmospheric jet streams extend thousands of kilometres deep (2018) (170)
- Numerical Modeling of Magnetohydrodynamic Convection in a Rapidly Rotating Spherical Shell (1999) (168)
- Torsional oscillations and the magnetic field within the Earth's core (1997) (130)
- Numerical dynamo models of Uranus' and Neptune's magnetic fields (2006) (126)
- Ørsted Initial Field Model (2000) (123)
- Thin shell dynamo models consistent with Mercury's weak observed magnetic field [rapid communication] (2005) (117)
- Geomagnetic field analysis-IV. Testing the frozen-flux hypothesis (1986) (94)
- Simple models of fluid flow at the core surface derived from geomagnetic field models (1989) (91)
- The expulsion of magnetic flux from the Earth's core (1986) (89)
- Sensitivity of the geomagnetic axial dipole to thermal core–mantle interactions (2000) (75)
- The magnetic fields of Uranus and Neptune: Methods and models (1996) (75)
- A complex dynamo inferred from the hemispheric dichotomy of Jupiter’s magnetic field (2018) (60)
- The steady part of the secular variation of the Earth's magnetic field (1992) (59)
- Convection and channel formation in solidifying Pb−Sn alloys (1997) (56)
- Simultaneous stochastic inversion for geomagnetic main field and secular variation: 2. 1820–1980 (1989) (54)
- The treatment of attitude errors in satellite geomagnetic data (1996) (54)
- Azimuthal flows in the Earth's core and changes in length of day at millennial timescales (2004) (53)
- Time‐Dependent Flow at the Core Surface and Conservation of Angular Momentum in The Coupled Core‐Mantle System (2013) (52)
- Inner core tilt and polar motion (2002) (51)
- The determination of fluid flow at the core surface from geomagnetic observations (1988) (51)
- Lateral temperature variations at the core-mantle boundary deduced from the magnetic field (1990) (48)
- Time‐independent and time‐dependent behaviour of high‐latitude flux bundles at the core‐mantle boundary (2002) (47)
- The effect of thermal core–mantle interactions on the palaeomagnetic secular variation (2000) (46)
- The dynamical regime of fluid flow at the core surface (1988) (44)
- Mapping the fluid flow and shear near the core surface using the radial and horizontal components of the magnetic field (1991) (41)
- Effects of sediment aggregate size on DRM intensity: a new theory (2001) (39)
- On the consequences of strong stable stratification at the top of Earth's outer core (1990) (36)
- Torque balance, Taylor’s constraint and torsional oscillations in a numerical model of the geodynamo (2003) (36)
- Simultaneous stochastic inversion for geomagnetic main field and secular variation: 1. A large‐scale inverse problem (1987) (34)
- Deformation of Earth's inner core by electromagnetic forces (2000) (32)
- Variations in the Earth's gravity field caused by torsional oscillations in the core (2004) (31)
- Models of the magnetic field at the core-mantle boundary for 1715, 1777, and 1842 (1986) (31)
- On the dynamics of topographical core-mantle coupling (1997) (31)
- Electromagnetic coupling and the toroidal magnetic field at the core-mantle boundary (1994) (29)
- Dynamics of Angular Momentum in the Earth's Core (1998) (29)
- The analysis of initial Juno magnetometer data using a sparse magnetic field representation (2017) (28)
- MoSST-DAS: The First Generation Geomagnetic Data Assimilation Framework (2008) (27)
- On the dynamical implications of models of Bs in the Earth’s core (1999) (26)
- Alleviation of the Backus Effect in geomagnetic field modelling (1995) (25)
- On the effect of boundary topography on flow in the Earth's core (1993) (25)
- Deep rotating convection generates the polar hexagon on Saturn (2020) (23)
- The evolution of the earth's magnetic field (1989) (23)
- Suppression of channel convection in solidifying Pb-Sn alloys via an applied magnetic field (1999) (23)
- Deep convection–driven vortex formation on Jupiter and Saturn (2020) (20)
- Energetics of numerical geodynamo models (2002) (19)
- A New Model of Jupiter's Magnetic Field at the Completion of Juno's Prime Mission (2021) (18)
- Axial drop motion in rotating fluids (1995) (17)
- The phase difference between length of day and atmospheric angular momentum at subannual frequencies and the possible role of core‐mantle coupling (1997) (15)
- Using reversed magnetic flux spots to determine a planet's inner core size (2007) (14)
- Plan for living on a restless planet sets NASA's solid Earth agenda (2003) (13)
- The Juno Mission (2017) (12)
- The motion of an inviscid drop in a bounded rotating fluid (1992) (12)
- Can Cassini magnetic field measurements be used to find the rotation period of Saturn's interior? (2010) (12)
- Global Magnetic Field (2013) (10)
- Illuminating Earth's interior through advanced computing (2004) (9)
- Microwave observations reveal the deep extent and structure of Jupiter’s atmospheric vortices (2021) (9)
- The construction of sparse models of Mars's crustal magnetic field (2017) (9)
- On the secular variation of Saturn’s magnetic field (2016) (7)
- The effect of thermal core-mantle interactions and the palaeosecular variation (2000) (7)
- The geomagnetic main field and the geodynamo (1991) (6)
- Dipole Decay, Secular Variation and Reversals (2003) (5)
- Contributions to Jupiter's Gravity Field From Dynamics in the Dynamo Region (2020) (5)
- Comment on “The topographic torque on a bounding surface of a rotating gravitating fluid and the excitation by core motions of decadal fluctuations in the Earth's rotation” (1995) (5)
- Numerical Dynamo Modeling: Comparison with the Earth's Magnetic Field (2013) (3)
- A One‐Dimensional Map of BS from Torsional Oscillations of the Earth's Core (2013) (3)
- Differential Rotation in Jupiter's Interior Revealed by Simultaneous Inversion for the Magnetic Field and Zonal Flux Velocity (2022) (3)
- Convection and channel formation in solidifying Pb-Sn alloys (1997) (1)
- Juno Magnetometer Observations in the Earth’s Magnetosphere (2013) (1)
- A Dynamo Simulation Generating Saturn‐Like Small Magnetic Dipole Tilts (2022) (1)
- Investigating Barotropic Zonal Flow in Jupiter's Deep Atmosphere Using Juno Gravitational Data (2021) (1)
- Geomagnetic reversals: Evidence for asymmetry and fluctuation (1986) (1)
- Time variation of Jupiter’s internal magnetic field consistent with zonal wind advection (2019) (1)
- Analysis and model-based optimization of a pectin extraction process-DTU Orbit (18/10/2019) (2018) (1)
- Application of Slepian Basis Functions to Magnetic Field Analysis of Saturn (2007) (1)
- Can Mercury's Weak Surface Magnetic Field be Generated by a Dynamo? (2003) (1)
- Contributions to Jupiter's gravity field from dynamics in the dynamo region and deep atmosphere (2019) (1)
- Jupiter's magnetic field morphology: Implications for the dynamo (2018) (1)
- Bloxham receives Macelwane Medal (1995) (1)
- No Evidence for Time Variation in Saturn’s Internal Magnetic Field (2021) (0)
- Book reviews (1991) (0)
- Inferring the depth of the atmospheric flows on Jupiter from the Juno gravity measurements (2017) (0)
- Unveiling the Interior of Jupiter with Juno (2017) (0)
- Spatial Resolutions of Numerical Dynamo Solutions: Implications for Model Error in Data Assimilation (2005) (0)
- Simulating vortices and jets in deep atmospheres of gas giant planets (2020) (0)
- Models of Jupiter's Interior that match Juno's Gravity Measurements (2017) (0)
- Publisher Correction: Time variation of Jupiter’s internal magnetic field consistent with zonal wind advection (2021) (0)
- Book reviews (1993) (0)
- Juno’s Magnetometer Investigation: Early Results (2017) (0)
- USING FUTURE OBSERVATIONS TO DETERMINE WHETHER THE SOURCE OF MERCURY'S MAGNETIC FIELD IS AN ACTIVE DYNAMO. S. Stanley (2005) (0)
- MoSST−DAS: TheFirstGenerationGeomagneticData Assimilation Framework (2008) (0)
- The depth and structure of the atmospheric flows on Jupiter: results from the Juno gravity measurements (2017) (0)
- The magnetic field at the core-mantle boundary. (1985) (0)
- First Results of the Juno Magnetometer Investigation in Jupiter's Magnetosphere (2016) (0)
- Variations in the Earth's Gravitational Potential Caused by Pressure Changes at the Core-Mantle Boundary (2002) (0)
- Implications of Initial Juno Magnetic Field Models for the Jovian Dynamo (2018) (0)
- Juno and Jupiter's Magnetic Field (2013) (0)
- Determining Core Properties From a Planet's Magnetic Field Morphology (2005) (0)
- Studies of synthetic observation data assimilation into geodynamo solutions: understanding the effects of Rayleigh number and changes in solution error due to data assimilation (2005) (0)
- Models of the Magnetic Field at the Core-Mantel Boundary for 1715, 1777, and 1842 in History of Geophysics. Reproduction d'articles parus dans Terrestrial Magnetism and Atmospheric Electricity EOS, Journal of Geophysical Research et Geophysical Research Letters de 1904 à 1988. (1990) (0)
- Juno’s Exploration of Jupiter’s Magnetic Field and Magnetosphere (2020) (0)
- Short-Period (3-5 Year) Signals in Magnetic Observatory Data: Internal or External (2005) (0)
- High-resolution Models of the Earth's Main Magnetic Field (2010) (0)
- A complex dynamo inferred from the hemispheric dichotomy of Jupiter’s magnetic field (2018) (0)
- Book review (1991) (0)
- Connecting Jupiter's atmosphere and magnetic field: Wind-driven advection of the Great Blue Spot (2019) (0)
- Jupiter's Magnetic Field and Magnetosphere at the Midpoint of Juno's Mapping Mission (2019) (0)
- Torsional Oscillations and The Geodynamo (2002) (0)
- Book review (1989) (0)
- A Global Simulation of the Dynamo, Zonal Jets, and Vortices on Saturn (2022) (0)
- Flux expulsion, secular variation and reversals (2001) (0)
- New Time-dependent Geomagnetic Field Model based on CHAMP and Oersted data (2009) (0)
- Connecting Jupiter's atmosphere and magnetic field (2019) (0)
- Numerical Dynamo Modelling and the Magnetic Fields of Uranus and Neptune (2002) (0)
- Book review (1988) (0)
- The Juno Magnetometer Investigation Provides the First Detailed Jovian Magnetic Field Model (2018) (0)
- Publisher Correction: Time variation of Jupiter’s internal magnetic field consistent with zonal wind advection (2021) (0)
- Jupiter and Saturn : Two Classes of Planetary Magnetic Field (2015) (0)
- Determining Dynamo Region Properties from Observations of a Planet's Magnetic Field (2006) (0)
- Core flow and length-of-day changes. (1991) (0)
- Forecasting changes in the Earth's magnetic field using core-surface flows and torsional oscillations (2010) (0)
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