Principles of Global Modeling

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Presentation transcript:

Principles of Global Modeling Paul Song Department of Physics, and Center for Atmospheric Research, University of Massachusetts Lowell Introduction Principles Example: Northward IMF Conclusions

Why is Modeling Needed in Space Physics? “Modeling” is a method to link key physical processes in distant regions according to physical laws: observations and predictions. Its objective is to provide qualitative physical understanding. It is in the form of cartoon-type sketches Computer simulations: field line tracing, streamline tracing, more quantitative. Simulation is a useful tool for modeling Can “modeling” be replaced by computer simulations? Computer simulations: sensitive to boundary conditions and initial conditions, as well as numerical methods about which simulationalists care most. Field line tracing near reconnection sites: large uncertainty. Stream line tracing: large uncertainty in regions of large velocity shears. Can simulation results and their interpretations be trusted unconditionally?

Chapman & Ferraro [1931] A new theory to explain magnetic storm Solar agent moves under the influence of the earth’s magnetic field Current associated with ion gyromotion reduces the field on the ground

Dungey [1961] Axford [1963]

Principles of MHD Modeling Perpendicular velocity: Frozen-condition is applicable everywhere except in reconnection regions and ionospheres In regions of ideal MHD: (steady state, E =- V x B) E parallel to B is 0=> Field line is equipotential => different field lines have different potentials Potential mapping: (VxB)L = constant Field lines cannot intersect (or infinite E field). At reconnection site B=0 E parallel to V is 0 => Streamline is equipotential => different streamlines have different potentials Streamlines cannot intersect (or infinite E field). At reconnection site V=0 Points on a field line move at their flow speeds to form the next field line. Must follow a given field line through a cycle For the whole system, magnetic in-flux = magnetic out-flux

Southward IMF Vasyliunas [1981]

The Magnetosphere Magnetopause Reconnection Direct evidence of quasi-steady reconnection at the magnetopause. ISEE 2 spacecraft was moving from the magnetosphere to the magnetosheath. The magnetic field in magnetosheath had BZ<0 and By>0 As the spacecraft passed through the LLBL and the boundary there were large dawnward flows and antisunward flows The spacecraft made several incursions into the LLBL which gradually increased in length.

The Magnetotail Magnetopause Reconnection Field lines at the magnetopause for Bz<0 and By>0 (top). Magnetic tension will move the plasma along the direction given by the heavy arrows. ISEE 2 was post noon so in the LLBL and magnetosheath the flow should be northward, dawnward and antisunward as observed. Reconnection at the magnetopause can also be “patchy” and localized in space. The left figure shows a localized reconnection event called a flux transfer event on the magnetopause.

Connection Takes Place not on Stagnation Field Line Russell, 1971

Principles of MHD Modeling, cont. Magnetospheric driving force Field line motion: pressure gradients, curvature force, and ionospheric coupling; no ExB drift!!! Flow along the field: pressure gradient Field line stretching/shortening: (caused by velocity shear) Field line length is proportional to B/ Slow mode: most efficient (convert pressure from parallel to B to perpendicular to B) Acceleration/deceleration: (perpendicular to B) Fast mode: most efficient for high  plasma Alfvén mode: most efficient for low  plasma or highly distorted field lines Field line bending: Alfvén mode: most efficient (no stretching/shortening needed)

Field Bending and Draping/stretching

Principles of MHD Modeling: Special cases Reconnection region Bending of dipole field: dipole field is curved but curl-free Field line pulling out of the ionosphere Steady state Magnetosphere-ionosphere coupling

Magnetic Reconnection Separatrix is not a slow shock The outflow region can be described by ideal MHD. Field-aligned potential drop is negligibly small. In steady state, E field in -Y-direction are same in all regions The outflow speed is Alfven speed Z X

Reconnection: Separatrices and slow shocks Separatrix Slow shock

Principles of MHD Modeling: Special case, cont. Reconnection region Bending of dipole field: dipole field is curved but curl-free Field line pulling out of the ionosphere Steady state Magnetosphere-ionosphere coupling

Bending A Dipole Field and Pulling It up Dipole field is current-free Motion at the foot of B field line produces a kink in the field line with a pair of currents The JxB force reacts to the initial foot motion (the motion needs to be sustained) If the foot motion is sustained, the JxB force makes the kink propagates upward The whole field is settled in a new L-value (current free again) The field line becomes longer: pulled out from the ionosphere (with high density plasma) The ionosphere rises (not due to ExB drift) Bending the field from the magnetosphere is a reverse process

Global Consequence of A Poleward Motion Antisunward motion of open field line in the open-closed boundary creates a high pressure region in the open field region (compressional wave), and a low pressure region in the closed field region (rarefaction wave) Continuity requirement produces convection cells through fast mode waves in the ionosphere and motion in closed field regions. Poleward motion of the feet of the flux tube propagates to equator and produces upward motion in the equator. No mapping E-field and no penetration E-field

Principles of MHD Modeling: Special cases, cont. Reconnection region Bending of dipole field: dipole field is curved but curl-free Field line pulling out of the ionosphere Steady State Magnetosphere-Ionosphere coupling

Steady State M-I Coupling coupled via field-aligned current, closed with Pedersen current Ohm’s law gives the electric field and Hall current electric drift gives the ion motion ionospheric JxB force is consistent with the ionosphere convection direction

Northward IMF [Dungey, 1964]

Topology for NBZ (Cowley, 1981)

Topology and Ionospheric Convection for NBZ with Dipole Tilt; [Crooker, 1992]

Ionospheric Convection and Field Perturbations for NBZ [Potemra et al

Ionospheric Observations for NBZ Field-aligned current Precipitation particles [Ijima and Potemra, 1978] [Newell and Meng, 1994]