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REPORT ON 1994 SNOWMASS WORKSHOP - BOUNDARY LAYER CAMPAIGN 
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                    WP 3: CURRENT SYSTEMS AND MAPPING
            co-chairs:  Eigil Friis-Christensen and Nancy Crooker

For the 1994 Snowmass Workshop, WG 3 expanded their ongoing studies 
of traveling convection vortices (TCVs) in three ways:  a) by including 
other transient ionospheric signatures of magnetopause processes, such 
as poleward moving magnetic disturbances and auroral forms, and any 
relationships between them, b) by choosing specific events for 
coordinated studies with complementary data from multiple sources, 
especially multiple magnetometer chains, with special attention to 
active periods for space weather studies, and c) by incorporating at the 
outset efforts to model the background polar cap size, boundary 
location, and convection pattern specific to the solar wind conditions 
for each event.  To help implement the expanded program, Hermann Luehr 
agreed to serve as coordinator of the event studies.  His comprehensive 
tutorial lecture to the entire workshop audience set the tone for the 
global approach in the working group sessions.

All four sessions included both observational and theoretical 
presentations and discussion.  Below we summarize first the modeling 
results and then the observational results.

MODELS

Five models were discussed:  1) the Schulz, Lyons et al. model, 2) 
the Toffoletto-Hill model, 3) the IZMIRAN Electrodynamic Model (IZMEM), 
4) the Fedder-Lyon MHD model, and 5) the Lysak pressure-pulse model.  
Models 1 and 2 are sophisticated versions of superposed field models 
that map the solar wind electric field from the magnetopause to the 
ionosphere.  Model 3 gives empirical convection patterns parameterized 
by the IMF.  Model 4 is a computer simulation of the solar wind 
interaction with Earth's dipole.  Model 5 addresses the formation of 
TCVs in a dipole geometry.

To implement (c) above, output from Models 1-3 was solicited in 
advance for the four events with available solar wind data.  Determining 
background solar wind conditions from the data plots for input to the 
models became a challenging task in view of the large amplitude of the 
fluctuations present in most of the parameters for these events.  The 
task raised serious questions about the validity of the concept of a 
"background convection pattern", since in the models the pattern depends 
primarily upon the y and z components of the IMF, the averages of which 
were much smaller than the fluctuation amplitudes and, hence, highly 
uncertain.

Given these questionable solar wind parameters, Models 1-3 produced 
similar background convection patterns of the standard two-cell type.  
Margaret Chen described Model 1 and presented its results.  Model 1 has 
recently been successful in matching certain aspects of polar cap 
boundary position with observations, such as the interhemispherical 
difference in cusp latitude as a function of dipole tilt angle.  As 
predictions for the events, however, neither Model 1 nor Model 2 can as 
yet specify absolute polar cap boundary location, shape and size based 
on solar wind parameters alone.  An additional problem was identified in 
Model 1:  The convection pattern becomes unrealistic on the nightside 
owing to convergence of the equipotentials at a null point.  Several 
ways to solve this problem were discussed, and Larry Lyons and Margaret 
Chen agreed to look into them.  Model 2 results were given by Tom Hill 
and Ching Deng.  They have already solved the null point convergence 
problem by adding the equivalent of an expansion fan to the tail.  
Adding the low-latitude region of return flow to complete the convection 
cell pattern was discussed as a next step for improving their ability to 
compare with observations.  The difference in polar cap shape predicted 
by Models 1 and 2 was briefly mentioned (also in WG 2).  Compared to 
observations from space, Model 2 produces an elongated shape that 
becomes more pronounced as the IMF turns northward, consistent with only 
the darkest regions of the polar cap being open, while Model 1 produces 
a round polar cap, consistent with shape of the auroral border.  The 
Model 3 results were forwarded by Volodya Papitashvili, who could not 
attend the meeting.  They showed the average empirical patterns for the 
event IMF orientations and seasons, including the low-latitude return 
flow.  These patterns are readily available by electronic mail.

Presentations on Models 4 and 5 addressed transient phenomena 
directly.  Joel Fedder demonstrated Model 4's impressive ability to 
reproduce the pattern of auroral brightening observed by the Viking 
spacecraft in response to a solar wind pressure pulse accompanied by a 
change in IMF orientation.  The only drawback is that at present the 
simulations can be matched to data only if the transient occurs after a 
lengthy of period of northward IMF, which matches the model's baseline 
setting.  John Lyon used Model 4 to show the pronounced effects on the 
polar cap geometry and convection pattern in response to a major shock 
wave accompanied by a change in IMF and solar wind flow directions.  Bob 
Lysak presented the most recent results from his increasingly 
sophisticated numerical modeling scheme for calculating field-aligned 
currents generated at the polar cap boundary by solar wind pressure 
pulses.  His total current strength of 60 kA compares reasonably well with 
the values of 100-300 kA obtained from observations by Hermann Luehr.

Although the workshop stimulated interactions between modelers and 
observationalists within their own groups, in general the anticipated 
cross-interactions did not occur.  In the case of Models 1-3, the 
observationalists are not yet ready to consider their signatures in 
relation to the global convection pattern, and Models 1 and 2 are not 
yet ready to match several aspects of observed patterns.  The workshop 
did serve to stimulate progress in these directions.  In the case of 
Model 4, the baseline problem must be solved before comparisons with 
event data can be made.  Model 5 will be used for quantitative 
comparison with TCV currents.

OBSERVATIONS

The aim of WG 3 was to select event categories/phenomena covering:
a)  Poleward Moving Auroral Forms, PMAFs
b)  Progressing Polar Convection Disturbances, PPCDs
c)  Convection Reversal Boundaries, CRBs
d)  Traveling Convection Vortices, TCVs, divided into isolated events 
    during relatively quiet conditions and events during disturbed 
    conditions.

For the TCVs, which had been discussed at the earlier GEM workshops, 
this workshop provided the possibility of using a more extensive data 
set than previously because of the recent establishment of the MACCS 
magnetometer array in Canada and the possibility of incorporating 
Svalbard data.  Some specific questions about TCVs addressed at the 
workshop are:

1.  What is the spatial distribution of TCVs?  What does a given TCV 
look like at different longitudes?  Does it change its form during 
motion?

2.  Are the motions inferred from different locations consistent with a 
model of a (primarily) tailward moving system of vortices?

3.  Is a TCV seen at one location also a TCV seen from a different 
location?

4.  Are there any systematic relationships between TCVs and optical 
features?  Or absorption events?

5.  Which models are most relevant for the TCV:  pressure pulse, K-H 
instability, field-line resonance?

6.  How do vortices form?  Do they form around noon?

The selection of events was very restricted because the MACCS data 
were not fully available before the summer of 1993, and the Svalbard 
data had only been processed for the "dark" period, fall of 1993 and 
winter 1993/1994.  In addition to these constraints, the general 
geomagnetic activity during these intervals was not very favorable 
regarding, for instance, the occurrence of PPCDs.  The chosen events are 
briefly described below.

a)  PMAFs

12 Jan 1994:  A large PMAF was associated with large magnetic 
signatures and possibly with a simultaneously forming TCV at 0820 UT.

14 Jan 1994:  A "broad" oval disappeared and a "new" oval appeared 
to the South (and coming from the noon sector) associated with a 
westward current.

b)  PPCDs

27 Oct 1994:  Only one "decent" and not even remarkable event was 
detected during a thorough search through the Oct 1993 to Jan 1994 
interval.  The event was atypical because normally the PPCDs are 
associated with IMF By variations during a nearly constant negative Bz. 
For this event the IMF showed large Bz variations, positive and 
negative, simultaneous with the By variations.

29 March 1992:  This event was included as a supplement, even though 
the MACCS data are not available this early.

c)  CRBs

4 Aug 1991:  This event can be traced from the East Greenland data 
to the West Coast by means of the MAGIC (Greenland Ice Cap) stations.

d)  TCVs - isolated events

14 Oct 1993, around 1300 UT:  Near local noon in Greenland a twin 
vortex moved westward (tailward) on the West Coast and eastward (also 
tailward) on the East Coast. This is consistent with the westward motion 
observed at MACCS and the eastward motion at Svalbard, fitting the form 
of a classic TCV.

18 Dec 1993, one around 1350 UT and another around 1510 UT:  For 
these events all Greenland stations showed an  eastward motion while 
MACCS data indicated westward motion. No motion could be firmly 
identified in the Svalbard data. For the second event clear absorption 
was associated with the leading FAC.

    TCVs - disturbed conditions

11 Oct 1993 1600-1625 UT:  MACCS showed eastward (sunward) motion in 
the prenoon sector (unusual). Greenland data showed eastward (tailward) 
motion, but a very distorted pattern.

25 Oct 1993 around 1400 UT:  Greenland data showed eastward motion 
while MACCS data showed westward motion.

25 Oct 1993 at 1635 UT:  MACCS data showed eastward motion while the 
Greenland data indicate that this event is probably not a TCV because it 
is seen nearly simultaneously at all stations.

The following principal investigators were tentatively selected to 
examine the events from their perspective and discuss with the event 
coordinator, Hermann Luehr, the possibility of preparing a paper based 
on combined data sets.

Event Date		Principal investigator (possible co-authors)

Jan 12, 1992		Fasel
Jan 12, 1994		Jacobsen, Moretto, Friis-Christensen
Jan 14, 1994		Jacobsen
Oct 27, 1993		Limited interest in pursuing this event
Mar 29, 1992		Clauer, Rosenberg
Aug 04, 1991		Rosenberg, Clauer
Oct 14, 1993, 1300	Moretto, Friis-Christensen, Luehr
Dec 18, 1993, 1350	Moretto, Friis-Christensen, Luehr, Rosenberg
	      1510	Rosenberg,
Oct 11, 1993, 1600	Zesta, Engebrettson, Hughes
Oct 25, 1993, 1400	Luehr, Zesta, Engebrettson, Hughes 
Oct 25, 1993, 1635	Pinnock