next up previous


SOHO Joint Observing Plan 002

TEMPERATURE GRADIENT IN A CORONAL HOLE

A H Gabriel, F Bely-Dubau.
Participating scientists :
E. Antonucci, Turin
C David, IAS
J E Wiik, Obs Nice

Progress:

CDS ID: TGRAD
SUMER ID: 8.1.2.7 (Pop 34)

Objective: To determine the onset region of the solar wind by measuring the vertical temperature gradient in a polar coronal hole.

Scientific Justification: Our knowledge of coronal temperatures in open-field (coronal hole) regions is very limited. The intensity of spectroscopic emission is very small, perhaps between 20 and 100 times less than the closed field regions, due to the lower density by a factor of the order 5 or more. SKYLAB observations have shown that ions typical of temperatures around 1 K dominate, but clearly these temperatures are limited by sensitivity to the first density scale height in the corona. Important questions regarding the role of coronal holes in the acceleration of the solar wind demande better information on the variation with height of the coronal temperature.

Thermal models (eg Parker) of the solar wind acceleration require high temperatures at the base of the wind. To explain the observed wind velocity we need temperatures of the order 4 K. Such high temperatures are not excluded by the present observations if the maximum occurs at heights not yet observed in emission. However some recent models of the wind acceleration propose direct transfer of momentum from Alfven waves to the medium, without dissipation; that is without requiring high temperatures. In this case the 1 K observed could be the maximum, and the temperature could fall progressively at greater heights. Thus the determination of the temperature gradient between 1' and 5' above the limb becomes a critical measurement.

Method: To measure the temperature, we depend upon a temperature-dependent spectral line ratio. As the line-of sight is perpendicular to the principal temperature gradient, we can propose to use a very sensitive line ratio, and interpret the ratio in terms of a local isothermal plasma. We avoid using ionisation ratios or differential emission measure analyses, since these are based on the assumption of ionisation equilibrium, which might not be valid in low density solar wind conditions. However, we include a set of Iron ion lines for a DEM complementary analysis, which might give added information. Since the region scanned (0 to 5 arcmin) could cover a range of temperatures, we choose a lithium-like ion, which is generally present over a wide range. The most sensitive ratio, taking account of solar abundance is that of oxygen VI, 2s-2p / 2s-3d.

This ratio of lines at 1036 Å and 173 Å requires that one of the lines is observed by the SUMER instrument and the other by the CDS. There will clearly be some concern about the relative calibration at these two wavelengths, since they arise from different instruments, with perhaps inprecise fields of view. However we do not need absolute information for this ratio. It will be sufficient to see how the temperature increases or decreases above the limb, and to rely on the sun itself to provide the absolute temperature calibration at the base.

Pointing and Target Selection: In view of the low emission of this part of the corona, the only means to measure the temperature is by observations tangentially at the limb. Coronal holes can exist at the poles of the sun, particularly around solar minimum when SOHO will be launched. Holes will also exist from time to time at lower latitudes. However, such low latitude holes will in general have a much smaller extent in the line of sight. In view of their low emissivity, their brightness will normally be contaminated by non-hole regions in the line-of-sight in front of, and behind, the hole. For reliable observations we are thus limited to the polar holes, which will not suffer from this line-of-sight effect.

Since the SUMER and CDS slits are normally aligned N-S, it is necessary for this measurement to rotate (roll) the spacecraft by 90 degrees, in order to place the slits tangential to the limb at the poles. This manoevre has been discussed and approved by the SWT, on the basis of a maximum period of 16 hours in the rolled position every 2 months.

Operating Details: Measurements of 1032 Å and 1038 Å lines with SUMER present no problems as the lines are intense. For the 173 Å line from CDS however there is a problem of intensity. If we choose the 8" 240" slit (provided for the NI channel) with the grazing incidence channel, and align this parallel to the solar limb, then it is possible to propose a sequence of 80 stepped positions starting just inside the limb with 25 s exposures and finishing at 5 arcmins above the limb with 2500 s exposures. This sequence takes a total of 13 hours and gives 5% photon counting statistics per position. It is however necessary to re-orient the roll position of SOHO by 90 degrees to achieve this measurement.

CDS Programme :

PHASE 1

PHASE 2

PHASE 3

Product: Scan of all GIS spectrum from 16 arcsec within limb to 304 arcsec above limb, from a 240 arcsec wide swath.

SUMER Programme Item 1:


Interruption or flag mode: No interruption.

Slit 1 with 1*300 arcsec.

Initial pointing: = 0.00 arcsec

= 986.00 arcsec

SOHO roll angle: 90.0000 deg

Solar rotation: No compensation.

Binning (spectral) = 1

(spatial) = 1

Compression: 5. Quasilog_min_max (0.92 s)

Reference pixel 1: 500 on detector A

Flat-field correction: OFF

Ion(s) in band 1:

O VI .... 1031.91 Å

O VI .... 1037.61 Å

Spectral window(s) (pixel) 50

Image format: Format #8 (50*360, B1); 2 time(s)

Spectrohelio mode: Spectrohelio 1

Scan from South to North.

Integration time: 25.0000 s

Step size: 0.380000 arcsec or 1 units.

Step number: 52

Step mode: Normal steps

Repetition number: 1

Staggering: 1

Your selection requires

a telemetry rate: 11.5200 kbit/s

Bitrate: 10.0000 kbit/s

This item will run

for approximately: 22.3818 minutes

and will cover a solar area defined by

300 px time(s) 19.76 arcsec

Note that the memory monitoring and the run times are not very accurate. The run

times just give the total exposure times with a margin of 1%. More detailed information

can be provided by the SUMER Simulator.

All items up to now will run

for approximately 22.3818 minutes

SUMER Programme Item 2:


Interruption or flag mode: No interruption.

Slit 1 with 4*300 arcsec.

Initial pointing: = 0.00 arcsec

= 1148.00 arcsec

SOHO roll angle: 90.0000 deg

Solar rotation: No compensation.

Binning (spectral) = 1

(spatial) = 1

Compression: 5. Quasilog_min_max (0.92 s)

Reference pixel 1: 500 on detector A

Flat-field correction: OFF

Ion(s) in band 1:

O VI .... 1031.91 Å

O VI .... 1037.61 Å

Spectral window(s) (pixel) 50

Image format: Format #8 (50*360, B1); 2 time(s)

Spectrohelio mode: Spectrohelio 1

Scan from South to North.

Integration time (low): 25.1355 s

Integration time (high): 2903.23 s

Step size: 3.80000 arcsec or 10 units.

Step number: 80

Step mode: Normal steps

Repetition number: 1

Staggering: 1

Your selection requires

a telemetry rate from: 0.0991997 kbit/s

to: 11.4579 kbit/s

Bitrate: 10.0000 kbit/s

This item will run

for approximately: 840.971 minutes

and will cover a solar area defined by

300 px time(s) 304.000 arcsec

Note that the memory monitoring and the run times are not very accurate. The run

times just give the total exposure times with a margin of 1%. More detailed information

can be provided by the SUMER Simulator.

All items up to now will run

for approximately 863 353 minutes

EIT Programme:

Programme objectives :

(images required in all 4 channels)

UVCS Programme:

PURPOSE:
Measure velocity, density and temperature gradient above 1.5 R (at completion of UVCS calibration an initial heliodistance of 1.4 R might be chosen).

OBSERVATION:
consisting of 1 Mirror Scan up to 2.5 R, to map the kinetic temperature of protons, and 2 Sit and Stare observations for line profiles.
Total time 11.5 h.

a) MIRROR SCAN

b) SIT AND STARE

Observing Sequence JOP--2--CH :
Temperature in Coronal Holes
Mirror Scan

Sit and Stare

CORONAL HOLE
Mirror Scan
Predicted Counting Rate

Sit and Stare
N--Predicted Counting Rate

Note:
The counting rate can be multiplied by a factor of 8.6 which means an integration along the slit comparable to the spatial resolution of CDS. It can be multiplied by an additional factor of 2 in the case of the Sit and Stare observation being this observation repeated.

LASCO Programme

Objectives :

method: use planned synoptic programme, with the possibility of optimising the data rate from the polar region chosen.

MDI Programme:

To map the line-of sight magnetic field

Ground-based observations (optional):

Magnetic fields, 10830 Å and Ca K maps for coronal hole morphology.



next up previous




SOHO Archive
Tue Aug 6 15:24:47 EDT 1996