Turbulence and waves in Earth’s iron-rich liquid outer core are believed to be responsible for the generation of the geomagnetic field via dynamo action. When waves break upon the mantle they cause a shift in the rotation rate of Earth’s solid exterior and contribute to variations in the length-of-day on a ∼6-year timescale. Though the outer core cannot be probed by direct observation, such torsional waves are believed to propagate along Earth’s radial magnetic field, but as yet no self-consistent mechanism for their generation has been determined. Here we provide evidence of a realistic physical excitation mechanism for torsional waves observed in numerical simulations. We find that inefficient convection above and below the solid inner co...
This article commences by surveying the basic dynamics of Earth's core and their impact on various m...
The westward drift component of the secular variation is likely to be a signal of waves riding on a ...
Slow convective motions in the liquid iron core of the Earth give birth to its magnetic field. How d...
Turbulence and waves in Earth’s iron-rich liquid outer core are believed to be responsible for the g...
Oscillations in Earth's liquid core with periods of several decades are inferred from variations in ...
Evidence for torsional oscillations (TOs) operating within the Earth's fluid outer core has been fou...
Torsional waves are a principal feature of the dynamics of the fluid outer core where the Earth's ma...
International audienceThe magnetic field inside the Earth's fluid and electrically conducting outer ...
The predominant force balance in rapidly rotating planetary cores is between Coriolis, pressure, buo...
International audienceWe report a calculation of time-dependent quasi-geostrophic core flows for 194...
Torsional Alfvén waves are theoretically predicted to exist in Earth's outer core, have been inferre...
AbstractEvidence for torsional oscillations (TOs) operating within the Earth's fluid outer core has ...
Observations of the change in Earth's magnetic field—the secular variation—provide information about...
This thesis addresses the generation and dispersion of wave packets in Earth's outer core. The waves...
This thesis addresses the generation and propagation of waves in Earth's fluid outer core, with the ...
This article commences by surveying the basic dynamics of Earth's core and their impact on various m...
The westward drift component of the secular variation is likely to be a signal of waves riding on a ...
Slow convective motions in the liquid iron core of the Earth give birth to its magnetic field. How d...
Turbulence and waves in Earth’s iron-rich liquid outer core are believed to be responsible for the g...
Oscillations in Earth's liquid core with periods of several decades are inferred from variations in ...
Evidence for torsional oscillations (TOs) operating within the Earth's fluid outer core has been fou...
Torsional waves are a principal feature of the dynamics of the fluid outer core where the Earth's ma...
International audienceThe magnetic field inside the Earth's fluid and electrically conducting outer ...
The predominant force balance in rapidly rotating planetary cores is between Coriolis, pressure, buo...
International audienceWe report a calculation of time-dependent quasi-geostrophic core flows for 194...
Torsional Alfvén waves are theoretically predicted to exist in Earth's outer core, have been inferre...
AbstractEvidence for torsional oscillations (TOs) operating within the Earth's fluid outer core has ...
Observations of the change in Earth's magnetic field—the secular variation—provide information about...
This thesis addresses the generation and dispersion of wave packets in Earth's outer core. The waves...
This thesis addresses the generation and propagation of waves in Earth's fluid outer core, with the ...
This article commences by surveying the basic dynamics of Earth's core and their impact on various m...
The westward drift component of the secular variation is likely to be a signal of waves riding on a ...
Slow convective motions in the liquid iron core of the Earth give birth to its magnetic field. How d...