The Magnetosphere and Plasmasphere

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The Magnetosphere and Plasmasphere

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Title: The Magnetosphere and Plasmasphere

1
The Magnetosphere and Plasmasphere

CSI 769
3rd section, Oct. Nov. 2005
J. Guillory

Lecture 7 (Oct.18)
Bow shock scattering Magnetosphere structure,
charged particle orbits
Advance reading Gombosi Ch.1 6 (and/or Parks
Ch. 4, 8 10), Tascione Ch.4, and Sci. Am. Apr.
1991 Collisionless Shock Waves
Lecture 8 (Oct. 25)
Dawn-dusk electric field gyrokinetic codes
magnetotail current sheet
Advance reading Gombosi Ch. 7 14, Parks Sec.
7.8 11.5), Tasc. Ch 5
Lecture 9 (Nov. 1)
MHD codes boundary conditions parallel
E-fields precipitation satellite diagnostics
Advance reading Gombosi Ch. 4 , Parks Sec. 7.7
In conjunction with the last topic
Joel Fedder (NRL) is scheduled for a Space
Sciences Seminar on his MHD magnetosphere code,
Wed. 10/26, 300 p.m., 206
Please attend.

3
Bow shock
4
Perpendicular shock
5
Oblique shock
6
waves particles in upstream foreshock
From Sagdeev Kennel, Sci. Am. Apr. 1991
7
Foreshock region
8
Current in shock layer
From G. K. Parks, Physics of Space Plasmas, AW
1991
9
Components of v along B and the shock surface,
for incident reflected particles
10
Repeated reflections from solitons near nonsteady
shock
From Sagdeev Kennel, Sci. Am. Apr. 1991
11
ISEE In-situ B-field measurements across bow shock
12
Collisionless shock structureHybrid code
simulation by M. Leroy et al, GRL 8, 1269 (1981)
C. S. Wu, D. Winske et al., Sp.Sci. Revws 37, 63
(1984)
13
Ion distributions near shock
14
Phase space in normal direction
Electric potential structure
15
Incoming particle scattering

Stochastic Injection of Energetic Particles from
Bow Shock and from Tailward reconnection region
Nonadiabatic because gyroradius B scale-length
locally
Particle orbit diffusion due to field
fluctuations
Some particles accelerated near bow shock and
magnetic reconnection regions

16
Magnetic field geometry
17
Model field topology for northward IMF
IMF dipole
18
Model field topology for southward IMF
From G. K. Parks, Physics of Space Plasmas, AW
1991
19
Field line motion with southward IMF (after J.
Dungey, 1961). North is DOWN in this fig.
From G. K. Parks, Physics of Space Plasmas, AW
1991
20
Detail of day-side reconnection field flows
21
Field near reconnection region(more on
reconnection later)
22
Inner magnetosphereEnergetic proton density
contours, showing South Atlantic anomaly
23
Mag. dipole offset from rotation axisand tilted
24
Van Allen Belts

Inner belt energetic protons
from cosmic ray albedo neutron decay (CRAND)
and from diffusion from elsewhere.
Outer belt somewhat energetic ions
from solar wind injection and
accelerated from ionosphere,
and diffusion from elsewhere.

25
Approx. avg. contours of spatial distribution of
trapped energetic protons electrons
(Van Allen, 1968)
26
NSSDC quiet-time static empirical model (AP-8)
of energetic proton flux density
J. D. Gaffey D. Belitza, J. Spacecraft
Rockets 31, 172 (1994)
27
NSSDC quiet-time static empirical model (AE-8)
of energetic electron flux density
J. D. Gaffey D. Belitza, J. Spacecraft
Rockets 31, 172 (1994)
28
Calculated energetic proton lifetimes (x ne) in
inner Van Allen belt under quiescent conditions
R. C. Wentworth, Pitch Angle Diffusion.. ,
Phys. Fluids 6, 431 (1963)
29
Satellite measurement of proton density vs L,
during quiet and CME-arrival conditions
OGO-5 measuremts
R. Chappell et al, JGR 75, 50 (1970)
30
Squeezing the magnetospherequasistatic pressure
balance estimate

Ram pressure of CME arrival IMF
rv2
vs
interior particlefield pressure
Increasing B produces inductive E fields and
currents

31
Energy transfer from CME to magnetosphere time
delay
From Tascione, after Baker et al, JGR 90, 1205
(1985)
32
Particle currents in the magnetosphere
33
Ring current reduces B at surface

After CME compression of day-side magnetosphere,
Bhoriz at RE decreases
1 hr after sudden-commencement rise, and
stays reduced for 1-3 days, gradually returning
to pre-storm values.
This is correlated with injection of 10-100keV
magnetotail particles into ring-current region.

34
Global magnetic change index (Tascione sec 4.7)

K integer, 0 9 3-hr average of DB, on
quasi-log scale, for each of several ground
locations
Kp average of Ks from 12 locations between 48
63 degrees latitude, averaged with local
seasonal variation filtered out

35
Dst index (Tascione p.51)

Hourly avg. (from 4 low-latitude ground stations)
of changes in horizontal component of B, with
seasonal variations subtracted out.
A measure of changes in ring-current intensity

36
AE (Auroral electrojet) index

Spread between max positive max negative
changes in horizontal component of B at several
auroral-latitude locations, 62.5 71.6 degree
latitudes
Global AE maximum of the positive changes in
horizontal component at any such location -
maximum of the negative changes in horizontal
component at any such location

37
Electric fields and more currents plasma flows

Plasma corotation-induced E field
E - (w x r) x B
BoRE (RE/r)2 (2sin l el cos l er)
approximately, for dipole B.
Inner part of earths magnetosphere corotates.
Added to dawn-dusk E field due to solar wind

38
Model E-fields in equatorial plane
39
Collisionless plasma flow (not currents) in E
perpendicular to B

vD/c E x B /B2 (cgs) , if (as usual) E (cgs)
ltlt B (G)

40
B-Field-aligned currents and fields

High-conductivity acceleration-limited currents
along B-lines
Downstreaming charges arrive die at dense
ionosphere, producing auroral glow.
Upstreaming charges from ionosphere populate
plasmasphere and magsphere.

41

From Tascione
42
Field-aligned ion beam distributions in plasma
sheet boundary layer from ISEE-1, 16 Feb
1980.(T.E. Eastman, R.J. DeCoster L.A. Frank,
in Cross-Scale Coupling in Space Plasmas
43
Velocities for steady-state polar wind with no
field-aligned current
S. B. Ganguli, H. B. Mitchell, P. Palmadesso,
NRL Memo Report 5673, 1985
44
Velocities (magnitude) 70 min after onset of a
current of -1 mA/m2 at 1500 km
S. B. Ganguli, H. B. Mitchell, P. Palmadesso,
NRL Memo Report 5673, 1985
45
Heating by these currents
S. B. Ganguli, H. B. Mitchell, P. Palmadesso,
NRL Memo Report 5673, 1985
46
Particle orbits in inner magnetosphere

Assumptions
DB/B is small over a gyroradius gyroperiod
Motion of the particles of interest is
collisionless (except if the hit the ionosphere,
where they die)

47
Charged particle orbits, static B(for B
quasistatic and gradB/ B ltlt rg-1 )

Fast gyration about field line
North-south bounce due to magnetic mirror force
Slow east-west drift due to inhomogeneous
magnetic field
ExB drifts due to electric fields

48
Gyration about B-line

rg gmv/qB (MKS units)
Wc qB/gm (MKS units) or qB/mc (cgs)
Sub-kHz to MHz angular frequencies (2pf)
Wc 1.76x107 B(G)/g for electrons
104 B(G) for protons

49
Scale of Proton Gyroradius Gyrofrequency

0.1 G rg(1 MeV) 10 km A (eperp/e)½
wci 1000 rad/s f ci 160/s
.01 G rg(1 MeV) 100 km A (eperp/e)½
wci 100 rad/s f ci 16/s
tN-S 1.3 s (L2) 50 gyroperiods

50
Adiabatic invariants

General form ?pdq
1. Magnetic moment invariant
gm pperp2/2mB (m qrg2/2c)
2. Bounce invariant J ?ppards
3. Longitudinal drift invariant (L shell)

51
North-South bounce motion

Determined by pitch-angle of fast velocity vector
at magnetic equator,
And by energy conservation.
If Eparallel 0, each particles parallel energy
is converted to perpendicular energy until it has
no more parallel momentum, then it reverses its
parallel motion.

52
Effective magnetic mirror force

When a very-small-size dipole moves along
magnetic field lines of an inhomogeneous field,
there is an effective force parallel to the
field line that has magnitude sign
Fparallel - m d B/ds
where s measures arclength along the magnetic
field. A dipole entering a region of stronger
magnetic field thus has a retarding force on it,
slowing its parallel motion.

One may ask How can this be? The magnetic force
on a charged particle, qvxB/c, is always
perpendicular to v and so can do no work on the
particle if B is constant in time.
In fact, the particle kinetic energy,
½ m vz 2 ½ m vy 2 , does not change only the
partition between vz and vy changes.
And this change of the direction of v is due to
the fact that the particle is not exactly at the
position of its guiding center, so the directions
of the field lines of B at the particle are not
quite the same on opposite sides of the
gyro-orbit, leading to a gyro-averaged vxB force
that has a parallel component.

The constancy of m (½ m vperp 2 ) /B during
collisionless nonrelativistic charged particle
motion along B, and
the constancy of ½ m vpar 2 ½ m vperp 2 KE,
mean that vpar can be expressed in terms of its
value at some reference point so by
½ m vpar 2 (½ m vpar 2)o - m(B - Bo),
i. e. the parallel motion is derivable from a
potential, mB.
(If there is also a static electric field
parallel to the magnetic field, the effective
potential for parallel motion of the dipoles
generalizes nicely to mB qf .)
When B has a minimum at some reference point so
along each magnetic field line encircled (or
enhelixed) by a particle, the collisionless
parallel motion will be that of a particle in an
effective potential well (remember, though, that
the magnetic potential depends on the constant m,
which is not the same for all particles !).

55
Half of Loss-cone(s) in magnetic-equator
velocity-space
Shown for no parallel electric field
56

Particle turns around where ( if) vpar 2 0,
where all the energy is converted to
perpendicular energy,
i. e. at B such that
(½ m vpar 2)o - m(B - Bo) - q(f - f o) 0.
This turning point equation, with the help of
magnetic moment constancy
(½ m vperp 2 ) /B (½ m vperp 2 ) o /B o ,
specifies the turning points as where
(½ m vpar 2)o - (½ m vperp 2 ) o (B/Bo - 1) -
q(f - f o) 0.

When there is negligible parallel electric field
this is simply
B /Bo 1 (vpar2 / vperp 2)o ,
so each trapped collisionless particle mirrors,
i.e. changes its sign of parallel velocity, at a
value of B/Bo that depends on its pitch angle at
the minimum of the magnetic field.
In the reference-plane velocity space vpar o,
vperp o, one can draw a boundary for any value
of B1, such that particles with v perp o above
the boundary will be trapped in the spatial
region where B lt B1 , and those with v perp o
below the boundary can progress to higher values
of B than B1 if nothing else stops them first.

58
Loss regions in midplane velocity space(s) when
there is a steady parallel E field toward the
ionosphere (positive potential on field line)
trapped
Lost to ionosphere in 1 bounce
Positive potential occurs so as to reduce
electron loss rate to the (increased) ion loss
rate.
59
Same thing in midplane energy space
60
Particle gyration bounce in inner magnetosphere
From T. Tascione, Intro to the Space Environment
61
(From G. K. Parks, Physics of Space Plasmas)
Energy conservation (with E0)
ao pitch angle at mag. Equator (l 0) Bo
field strength at mag. Equator
62
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63
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64
Charged particle longitudinal drift due to
magnetic field inhomogeneity
Cross-field drift of and particles under
force F
From Parks, Physics of Space Plasmas
65
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66
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67
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68
Longitude-drift periods (from Parks)
69
Drift Rate (in terms of energy, mag. Moment,
bounce invariant, bounce period, and L)

For static magnetic dipole, with E 0
ltdf/dtgt - (2cLRE e /em) (3/2 - J/4et)
with t ?ds/vy N-S bounce period,
and J m ?vy ds bounce action integral.
T. G. Northrop, in Radiation Trapped in the
Earths Magnetic Field, B. M. McCormac, ed.,
Reidel 1966

For nonstatic dipole B without shear
(but changes slow enough to preserve J and m)
ltdf/dtgt - (2c/et)?rdq (B/Bq )(2m(H - mB -
qF))½
(Bq /B)( ?/?L)(rB/Bq) ½ r ?B/?L
- ½ (2m(H - mB - qF))-½ 2m(H -qF)r ?lnB/?L rq
?F/?L
with F electric
potential
and f longitude
angle.
T. J. Birmingham, Guiding center drifts in
time-dependent meridional magnetic fields,
Phys. Fluids 11, 2749 (1968)

71
Ring Current from drifting, gyrating
particles(Parks sec. 7.7.4, with corrections)

(a) From guiding-center drifts
Jgc e (ni vdrift(i) - ne vdrift(e-) )
Sn(KE) e (KE/e) (1 cos2a) bxgradB
/B2
bxgradB/ B2 -3/rB if at l 0
so Jgc -3nltKEgti ltKEgte /rB (for
equatorial particles)
Igc ?JgcdV /2pr - 3Etot/(2pr2B)
(b) From pressure gradient of gyrating particles
JgradPperp xB grad (nltKEgti ltKEgte perp.)
IgradPperp ?rdrdl grad (nltKEgti ltKEgte
perp.)/B
Etot/2pr2B

so this (b) current reduces the average net ring
current magnetic field by about 1/3. The net
ring current then reduces the magnetic field at
the magnetic equator at 1 RE by
DB/B - (2/3) Etot/Emag ,
where Emag is the volume-integrated energy in
magnetic field.
See more general derivation in R. L. Carovillano
J. J. Maguire, in Physics of the Magnetosphere,
(Carovillano et al, eds), Reidel, 1968.
Ring current usually peaks at 4-5 RE (quiet) at
2-4 RE (storm)
Mean proton energy 85keV (90 are in 10 - 250
keV)
Quiet-time ring current density 10-8 A/m,
increased by factor of several during storms.
See Tascione sections 5.4.3, 5.9, 5.10

73
Typical energy spectrum of energetic protons
74
Power delivered by solar wind/ CME

Power Current x ?(-vxB)dl
Current varies as wc, i.e. as B
Power varies as B2v sin4(q/2)
where
q angle of IMF from northward
sin 0 for northward IMF
sin 1 for southward IMF
J. K. Alexander, L.F. Bargatze, J. L. Burch et
al.,
Coupling of the solar wind to the
magnetosphere
in
Solar Terrestrial Physics
D.M. Butler K. Papadopoulos, eds. NASA, 1984
Tascione, sections 3.7, 5.8, 5.10

75
Energy injection into ring current

Empirical approximate formula for ring-current
addition rate in terms of Dst and ring-current-
enhancement lifetime t
UR(J/hr) 4x1010(dDst/dt Dst/ t)
(Tascione sec.5.10)
See Akasofu Sp. Sci Rev, 28, p160, 1981 for a
related formula Dst 60(log
epsilon - 18)2 25
where epsilon B2v sin4(q/2)

76
Nov. 6, 2001 event

Southward B component 80 nT
Unusually sharp CME shock with speed gt1000km/s
Nearly perpendicular shock
L8 SEPs showed sharp rise in on shock arrival
L3 14-25 MeV protons arrived minutes before
shock
and were trapped when shock arrived
via front-side cusp entry
stayed trapped til Oct 03 storm detrapped them
3-20 MeV electrons enhanced at first, but
deep dropout of total gt1MeV electron flux at
L3-8,
with few-days recovery time

Mary Hudsons PIC particle follower, riding on
Fedder-Lyons-Mobarry MHD code,
followed particles from ACE input data
Cluster data (Morikis Kistler, UNH)
Cluster apogee 20 RE, perigee 4 RE, every 48
hrs
50 hr orbit, 2hrs in magnetosphere at 4RE
Sampex data 1-3 MeV electrons, 10-20 MeV
electrons

78
Stochastic Injection of Energetic Particlesfrom
Bow Shock andTailward reconnection region

Nonadiabatic because gyroradius B scale-length
locally
Timescale t varies as m5/4e-1/2
Flux density injected varies as density at low
densities
M. G. Rusbridge, Non-adiabatic effects in
charged-particle motion near a neutral line,
Plasma Physics 19, 1087 (1977) and
Non-adiabatic charged particle motion near a
magnetic field zero line, Plasma Physics 13, 977
(1971)
W. Peter N. Rostoker, Theory of plasma
injection into a magnetic field, Phys. Fluids
25, 730 (1982)
J. Chen P. J. Palmadesso, Chaos and nonlinear
dynamics of single-particle orbits in a
magnetotail-like magnetic field, JGR 91, 1499
(1986) errata 91, 9025 (1986)

79
Particle Diffusion

Dominated by field fluctuations in storm
conditions.
Lee/Sydora Gyrokinetic Code calculates for
Tokamaks.
Diffusion model
W. N. Spjeldvik, Consequences of the duration
of solar energetic particle-associated magnetic
storms on the intensity of geomagnetically
trapped protons, in Modeling Magnetospheric
Plasma, T.E. Moore J.H. Waite, eds. AGU 1988
J.M. Cornwall, Radial diffusion of ionized
helium and protons a probe for magnetospheric
dynamics JGR 77, 1756 (1972)
df/dt L2d/dL (DLLL-2df/dL) - Af Gm-1/2df/dm
A charge exchange factor, G Coulomb slowing
DLL(L, m) given in Cornwall (1972),
assumes power-law ( n-2) spectrum of
fluctuations in B and E.

80
Flow dynamics of charge-neutralized plasma fluid

?t UgradU (1/rmo)(Bgrad)B - grad(B2/2)
- (1/r) divP g
P pressure tensor pperp I (ppar -
pperp)bb
(div P )perp gradperp pperp - (ppar -
pperp)(bgrad)b
(div P )par (bgrad)ppar (ppar -
pperp)divb
div P gradp for isotropic pressure
?t Ugrad (pperp/rB) 0
?t Ugrad( pparB2/r3) 0
G.F. Chew, M.L. Goldberger, F.E. Low, Proc.
Roy. Soc (Lon.) A236, 112 (1956)
N.A. Krall A.W. Trivelpiece, Principles of
Plasma Physics, McGraw Hill 1973

81
Magnetosphere Simulation

Particle codes, incl. gyro-averaged particle
followers (e.g. Mary Hudsons at NASA R. M.
Winglee code at UW)
Fluid (MHD) codes
Fedder-Lyon-Mobarry code (NRL)
BATSRUS (U. Michigan)
Spicer code(s) Odin etc.
Modified MHD Winglee
Hybrid (particles and MHD) codes
Rice MSM code
Kazeminezhad 2D code

Models are available for community use
CCMC http//ccmc.gsfc.nasa.gov/
UCLA http//www-ggcm2.igpp.ucla.edu/
Source codes in public domain
GEDAS (Japan, T. Ogino) (Japan, T.)
http//gedas22.stelab.nagoya-u.ac.jp/simulatio
n/jst2k/hpf02.html
BATSRUS http//csem.engin.umich.edu/
NRL http//www.lcp.nrl.navy.mil/hpcc-ess/software
.html
FCTMHD3D (C.R. DeVore)
AMRMHD3D (P. MacNeice)
Zeus 3D MHD (Michael Norman) http//zeus.ncsa.uiu
c.edu8080/lca_intro_zeus3d.html
CFD Codes http//icemcfd.com/cfd/CFD_codes.html

83
Fedder-Lyon-Mobarry (FLM) Codedistorted
spherical coord. grid
84
MHD eqns as solved in FLM code
J. G. Lyon, Numerical methods used, Proc.
ISSS-7, 26-31 March 2005
85
FLM Code

Does not include particle acceleration (since
its an MHD code)
but does show overall energetics of CME coupling
for southward IMF,
and shows very weak coupling for northward IMF.
Coupling is by fast magnetosonic wave propagation
from magnetopause.
Shows Poynting vector energy flow from these
waves.

86
BATS-R-US Code (U. Mich.) Block-Adaptive-Tree
Solarwind Roe-Upwind Scheme)

Gombosi et al
3D MHD, Eulerian xyz grid (x toward sun)
Block-adaptive mesh refinement
Cell-centered finite volume method
Upwind-differencing Riemann solver
(Powell 1994)
Efficiently parallelized
High computation/communication ratio

Runs on Sun, SGI shared memory, Cray T3D T3E,
and IBM SP2
Simulation box typically 192 RE wide,
192 to -384 RE in x direction
Cell size typically .25 RE to 32 RE
Inner boundary at 3 RE (no mass flow across it)
coupled along assumed dipole B lines to finite
tensor conductivity, height-integrated ionosphere
layer at 1 RE M. L. Goodman, Ann. Geophys. 13,
843 (1995)
Dipole inner field separated off as in Tanaka,
JGR 100, 12057 (1995)

88
BATSRUS simulation of outermost closed B lines,
for Parker spiral IMF
89
Winglee modified MHD code

R.M. Winglee, Regional Particle simulations and
Global Two-fluid Modeling of Magnetospheric
Current Systems, in
J. L. Horowitz et al., Cross Scale Coupling in
Space Plasmas, QC 809.P5 C76, 1995
Uses a 2-fluid modified MHD set of equations
Gets the injection of currents plasma across
B-field lines

90
Rice MSM Code
91
Rice MSM Code

E. C. Roelof, B. H. Mauk, R. R. Meier, K. R.
Moore, R. A. Wolf, Simulation of EUV and ENA
magnetospheric images based on the Rice
Convection Model,
in Instrumentation for Magnetospheric Imagery
II, SPIE 1993.
(ENA energetic neutral atom)
Streamlined version of RCM MSM (magnetic
specification model), has non-self-consistent E
field from phenomenological convection patterns.

92
F. Kazeminezhad new code

2D hybrid
Triangular
finite-element
grid

93
MagnetoTail
94
Magnetic Reconnection
95
Modeling driven reconnection
96
2-D Compressible Resistive MHD Simulation
ofDriven Reconnection

S. -P. Jin W. -H. Ip, Phys. Fluids B3, 1927
(Aug. 1991)
Plasma beta at inflow boundary of simulation box
initially 0.1
Alfven Mach of inflow MA 0.15 (for -.5 lt z
lt.5), tapering to 0 at z gt1
High Lundquist Number 400 - 2500 (very low
resistivity)
Lundquist Number ratio of JxB force to
resistive mag. diffusion force
Initial Bz(x) profile half sine wave -w lt x lt w
(w lt1), 1 for x gt w
(odd function of x)
Initial state in pressure balance
Grid resolution in x Dx increases 13 every
step.
Grid concentrated in center near x 0.
Time in units of Alfven-wave x-crossing time.
Sim. 40 units.
Implicit integration scheme Y. Q. Hu, J. Comp.
Phys 84, 441 (1989)

97
B lines, v vectors, DT(), Dr()
Time ?
S-P. Jin W-H. Ip. 2D compressible MHD sim. ,
PhysFluids B 3, 1927 (1991)
98
PIC simulation of particle orbits near a magnetic
reconnection line

H-J. Deeg, J.E. Borovsky N. Duric, Phys Fluids
B 3, 2660 (1991)
Geometry and results shown in following slides

99
Region where magnetic insulation fails, i.e
where B is weak
H-J. Deeg, J.E. Borovsky N. Duric, Phys Fluids
B 3, 2660 (1991)
100
Geometry for PIC simulation of particle
acceleration near reconnection region
H-J. Deeg, J.E. Borovsky N. Duric, Phys Fluids
B 3, 2660 (1991)
101
Proton orbits in views 1 2
102
Proton orbit in views 2 3
103
Energy gain of protons entering near neutral point
H-J. Deeg, J.E. Borovsky N. Duric, Phys Fluids
B 3, 2660 (1991)
104
Final proton energy vs initial proton energy, for
protons initially incoming near neutral point
H-J. Deeg, J.E. Borovsky N. Duric, Phys Fluids
B 3, 2660 (1991)
105
Turbulence in B-line reconnectionMatthaeus
Lamkin, PhysFluids 29, 2513 (1986)
Contours of constant J
Magnetic field
Contours of constant vorticity
Fluid stream-lines
106
Disturbed magnetotail reconnection at current
sheet can launch plasmoids relax (as well as
accelerating particles forward backward)
E. W. Hones, Sci. Am. March 1986
107
Some references on field-line reconnection

Observations by Cluster satellite
A. Runov et al.,
Geophys. Res. Lett. 30, 1579 (2003)
Observations by WIND satellite
T. D. Phan et al.,
Nature 404, 848 (2000)
M. Oieroset, R. P. Lin et al., Nature
412, 414 (2001)
3D PIC simulation
P.L. Pritchett F. Coroniti, JGR 109, A
01220 (2004)
2D simulation with guide field normal to
plane P. L.
Pritchett (UCLA) Onset Saturation of
Guide-field Magnetic Reconnection, Phys. Plasmas
12, 062301 (June 2005)

108
More references on field-line reconnection

Particle acceleration orbits
H-J Deeg, J.E. Borovsky N. Duric (LANL),
Particle acceleration near X-type magnetic
neutral lines, Phys. Fluids B 3, 2660 (1991)
Electric field enhancements (EFE)
J. D. Scudder F. S. Mozer, Electron
demagnetization and collisionless magnetic
reconnection in bltlt1 plasmas, Phys. Plasmas 12,
092903 ( Sept. 2005)
Role of microinstabilities (anomalous
resistivity)
M. Ugai L. Zheng, Conditions for fast
reconnection mechanism in 3D Phys. Plasmas 12,
--- ( Sept. 2005)

109
Satellite sensors

Radiation Belt Mappers
GOES (ESA)
Cluster, Vortex
Doublestar
Polar
Image
Geotail (Japan)
ISEE1-3, IMP1-8 other former sats with elderly
data
Ionospheric satellites measuring energetic
particles DMSP, SAMPEX etc.
Upcoming NPOESS NPP

110
Living With A Star Research Network
Pole Sitter
Solar Dynamics Observatory
L1 Solar Sentinel
Ionospheric Mappers
L2
Radiation Belt Mappers
Distributed network of spacecraft providing
continuous observations Geospace Dynamics
Nework with constellations of smallsats in key
regions of geospace.
111
How to find satellite orbit info ( related data)

http//pwg.gsfc.nasa.gov/orbits
/menu_orbits.html
Orbits for Wind, ISTP, Cluster, Image, Polar

112
Radiation Belt Mappers
Understand origin and dynamics of the radiation
belts. Determine time space-dependent
evolution of penetrating radiation during
magnetic storms. First Element multiple
spacecraft in 3 petal equatorial orbits in-situ
measurements. Second Element Add higher
latitude coverage.
113
GOES description

GOES (Geostationary Operational Environmental
Satellites, NOAA/NESDIS)
2 spacecraft at 75deg W and 135deg W, one at
98deg W and/to 108deg W, moved with season.
35,600 km equatorial orbit, spin axis parallel to
earths spin axis. Telemetry to NOAA ERL,
Boulder.
measuring
solar X-rays,
B field at satellite,
high energy particles, via SEM (Space Environment
Monitor).
SEM has
(a) Total Energy Detector (TED)- intensity of
energetic particles 0.3-20 keV in 11 bands
(b)Medium-Energy Proton Electron Detector
(MEPED) - 30 keV-60MeV
(c) High-Energy Proton Alpha Detector (HEPAD) -
370 MeV- gt850 MeV.

114
Cluster Vortex
115
Cluster Doublestar (DSP)
116
Cluster data (Morikis Kistler, UNH)

Cluster (ESA NASA, 2000)
Cluster apogee 20 RE, perigee 4 RE, every 48 hrs
50 hr orbit, 2hrs in magnetosphere at 4RE

117
Some Cluster results

Cluster has now proven the existence of The
Kelvin-Helmholtz instability as an important
solar wind entry process.
These large-scale vortices could lead to
substantial entry of solar wind to populate the
Earth's magnetosphere. (Tai Phan, UCB SpSciLab.)

118
Polar orbit (http//pwg.gsfc.nasa.gov/orbits/aaar
eadme_polarpar.html
The POLAR orbital parameter plots show the radial
distance, eccentric dipole (ED) magnetic local
time (MLT), and eccentric dipole L-shell value.
The darker segments correspond to times when one
of the magnetic footpoints (traced down to 100 km
altitude using the T89, Kp3-,3,3, model) falls
in one of the following regions cusp, cleft, or
auroral oval.
119
Polar observation of an event

Images in visible light from the Polar
satellite's Visible Imaging System compares the
northern auroral regions on May 11, 1999, and a
more typical day on November 13, 1999. Credit
University of Iowa/NASA.

120

Polar, contd
May 11, 1999 event solar wind flux dropped a lot
produced an intense "polar rain" of electrons
over one of the polar caps of Earth.
Electrons flow unimpeded along the Sun's magnetic
field lines to Earth and precipitate directly
into the polar caps, inside the normal auroral
oval.
Such a polar rain event was observed for the
first time in May 1999 when Polar detected a
steady glow over the North Pole in X-ray images.
Jack Scudder, U. Iowa, PI for the
Hot Plasma Analyzer on NASA's Polar spacecraft.
Scudder and Don Fairfield of Goddard had
predicted the details

121

In parallel with the polar rain event, Earth's
magnetosphere swelled to five to six times its
normal size.
NASA's Wind, IMP-8, and Lunar Prospector
spacecraft, the Russian INTERBALL satellite and
the Japanese Geotail satellite observed the most
distant bow shock ever recorded by satellites.
SAMPEX spacecraft reveal that in the wake of this
event, Earth's outer electron radiation belts
dissipated and were severely depleted for several
months afterward.

122
Image Satellite ENA sensors
123
Image website (Southwest Research)

http//pluto.space.swri.edu/IMAGE/
HENA D. G. Mitchell and HENA team, the Johns
Hopkins University Applied Physics Laboratory
MENA C. J. Pollock and J.-M. Jahn, Southwest
Research Institute

124
HENA Images of ENA fluxes during the July 15-16
2000 Geomagnetic Storm
125
Geotail (Japanese space program)

Instruments
Solar wind, hot plasma, composition analyzers,
directional data on electrons/protons/helium
above 20keV, protons above 400keV, electrons
above 120kev, B field, etc.
http//www-istp.gsfc.nasa.gov/istp/geotail/geotail
_key_parameters.html

126
DMSP Satellites

Orbits circular, sun-synchronous, polar, 850km
alt.
98.7 deg inclination, period 101 min., revisit
time 6 hrs.
Global coverage _at_ 12hrs each satellite
Communications S-band, about 3 MBPS in 1995
maybe more capacity now.
Design life 3-5 yrs.
Block(group) 5D-2 (5 sats) launched 1991-98,
earlier ones presumably now down or inoperative
Block 5D-3 (5 more satellites, S16-20, built by
Martin Marietta) launched 1999-06 Block 6
beginning 04.

127
DMSP, contd.

Relevant sensors for space weather
SSI/ES Ionospheric Plasma Drift/Scintillation
Monitor 4 sensors monitoring ion electron
densities, temperatures, drift velocities of
ions, and plasma irregularities above the F
region.
SSI/ES-2, 3 are enhanced versions, flown since
94 and 99.
SSJ/4 Precipitating Electron/Proton Spectrometer
SSB/X X-ray detector array - x-rays from earths
atmosphere.
Upgraded version SSB/X-2 can also detect gamma
ray bursts.
SSM magnetometer measures B-field fluctuations
due to hi-latitude ionosphere currents.

128
Sampex (GSFC)

Solar Anomalous and Magnetospheric Particle
Explorer (Medium Earth Orbit).
First of NASA's Small Explorer (SMEX) missions.
Typical orbit 520 x 670 km, 82 deg inclination
Energy, composition and charge states of
(1) cosmic rays
(2) solar energetic particles
(3) magnetospheric electrons trapped by the
Earth's magnetic field).
http//www.astronautix.com/craft/sampex.htm
etc.
Sampex data 1-3 MeV electrons, 10-20 MeV
electrons
PET Proton-Electron Telescope energy spectra of
electrons from 0.5 to 30 MeV, and of H and He
from 20 to 200 MeV/nuc
http//www.srl.caltech.edu/sampex/

129
Upcoming NPP NPOESS

The NPP satellite is scheduled for launch in 2007
into a circular sun-synchronous polar orbit at a
nominal altitude of 824 kilometers and a 1030
a.m. descending node.
This orbit provides a 16-day repeat cycle (8-day
quasi-repeat), similar to that of the EOS
satellites.
Ref.The NPOESS Preparatory Project Architecture
and Prototype Studies (Aerospace Corp. website)
The National Polar-orbiting Operational
Environmental Satellite System (NPOESS)
represents a convergence of systems previously
operated by the Department of Defense and the
National Oceanic and Atmospheric Administration
(NOAA).
Scheduled for launch in 2009, it will support a
broad range of activities in global environmental
monitoring, meteorology, and climatology.

130
NASA CDAW at GMU, Mar. 2005

http//cdaw.gsfc.nasa.gov/geomag_cdaw
/register/wg2_participants.html
Names contact information of researchers in
magnetosphere dynamics data
http//solar.scs.gmu.edu/meetings/cdaw/data/
cdaw2/wg2_datatable.htm
Data files for selected events, from several
satellite instruments (click on data first
WG2 data table)

131
Magnetosphere Homework Assignment, 10/25/05

1. Look up typical magnetotail storm-period data
(Bfield strength, particle densities, particle
temperatures) from, e.g., IMP 8 data.
2. Use these data along with Fig. 5.6 of Tascione
to estimate the order of magnitude of
(a) tailward speed of ejected plasmoid (km/s)
(b) directed particle energy of tailward-ejected
plasmoid (J)
(c) kinetic power loss (mean particle energy loss
rate) during plasmoid ejection (W)
(d) magnetic energy stored in magnetotail (J)
3. Use ACE or WIND data to estimate the typical
order of magnitude of CME ram pressure rv2 (J/m3)
and of CME-enhanced power delivery to day-side
magnetopause (W), for southward Bz -80nT and
twice the typical Parker-spiral westward By. Is
this pressure much bigger than the magnetic field
pressure? Estimate the power (W) delivered into
the magnetopause by such a CME.
4. Tascione problem 5-4
5. Tascione problem 5-5
6. Tascione problem 5-12

132
CSI 769 Class Project, fall 2005Magnetosphere
portion

This part of the project focuses on the
energetics of the Halloween 03 CME-induced
changes in the magnetosphere, by doing five short
order-of-magnitude calculations based on
retrieved data.
1. From Wind or ACE data, estimate the peak CME
(particle magnetic) pressure increase on the
bow shock, and its rise rate during the Halloween
03 event.
2. From earthbound magnetometer data, e. g. Dst,
estimate
(a) the time delay of surface DB after the
bow-shock energy delivery, and
(b) the energy and power delivery to the
enhanced ring current during the storm.
(c) If the time delay is related to propagation
of a disturbance at near the Alfven speed, use
the magnitudes of B and estimated plasma
densities to compare the time delay to that of
the most direct delivery route.
(d) Is the ratio of estimated change in
ring-current energy (volume integral of DKE
D(B2/2mo)) to CME energy (magnetopause-intersectin
g volume integral of energy density in the CME on
bow-shock arrival) of order unity or ltlt1?
3. (a) Based on your estimates of magnetospheric
DB due to enhanced ring current and its risetime,
estimate the peak E fields (mV/m) induced, and
compare them to the corotation E field.
(b) Give an estimate of the peak E field on the
topside of the ionosphere, say at 500km altitude,
and the ExB drift speed E/B (km/s) at 60degrees
magnetic latitude.
4. Use geotail data during the storm to estimate
the peak change in magnetic energy storage in the
magnetotail volume, and its buildup rate.
Compare these numbers with the estimated
frontside energy arrival by the CME.
5. Use NOAA energetic-particle flux data etc. to
estimate the change in total energy in MeV (and
higher-energy) protons transported by the storm
to the auroral ionosphere, and compare this with
the other energies calculated above.
Part of the data is collected at
http//solar.scs.gmu.edu/meetings/cdaw/Data_maste
r_table.html

133
Some textbook errata

Tascione
Eq. 1.17 (not ) after first term
Eq. 1.33 B(vector)x gradient of scalar B
(magnitude of vector B), not of vector B.
Fig. 2.6 protons dont arrive with predominantly
45 degree Incidence, even though B
does. Water-sprinkler effect.
p. 35 U components theta phi here are
interchanged from the usual (i.e. Jackson).
p.38 Eq 3.28 factor of d is ignored in the final
proportionality and is treated as constant in
3.29, but reappears as Lo2 in 3.30.
p.44 Eq. 4.9 Z on left, not H.
Eq. 4.10 B on left, not H.
p. 59 Eq. 5.20 sign (not -) in numerator.

134
Some textbook errata, contd.

Parks
p. 56 Eq. 3.36 3.37 Confused notation. r and
lambda are component indices, not independent
variables.
p. 72 Eq. 3.73 Careful! The rotation axis is not
the magnetic axis. See Tascione Eqs 4.1 4.2.
p. 106, first line of sec. 4.55.6 current
density, not currents. Current is meaningful for
single charged particle
in motion (Iqv). Current density is not
p. 139 problem 18 dimensional error in formula.
p. 156, top two eqns either one or the other
(not both, unless gamma 1).
p. 249 Eq. 7.20 see eq. 7.57 when p is
anisotropic.
p.255 below eq. 7.39 outward out of paper
(as looking down from N pole), not radially
outward
from earth.
p. 259 after eq. 7.53 del parallel plus del
perp. (not -)
p.261 after eq. 7.65 B is not necessarily given,
just static.
p.264 after eq. 7.70 Br vanishes at the magnetic
equator (only).
p.265 eq. 7.74 sum over species! Epsilon is
the energy-density of all the drifting particles
(e i).
p.267 Eq. 7.82 delta BT/Bs on left side, not
delta BT.
p. 314, before sec. 8.2.2 Plasmas in steady
state do support free charges, but mainly at or
near their boundaries. Like a
pretty-good conductor, they move the net charge
to the surface.

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