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Coronal holes, 146 MHz emissions and geomagnetic storms
Chinese Astronomy
4 (1980) 194-201
Pergamon Press. Printed in Great Britain 0146-6364/80/0601-0194-$07.50/0
Acta Astr. Sinica 2~ (1979) 191-198
CORONAL HOLES,
Zhao
1 4 6 MHz EMISSIONS AND GEOMAGNETIC STOP,MS
Department of Geophysics, Beijing University Beijing Astronomical Observatory
Xue-pu
Liu X u - z h a o
Received 1978 April 14
ABSTRACT. Our a n a l y s i s o f t h e r e l a t i o n s h i p storms lends s u p p o r t to the idea t h a t with large areas.
For £wo t y p i c a l
inversely
correlated
The t i m e l a g b e t w e e n t h e o n s e t o f t h e
f a n beam i n t e r f e r o m e t e r In g e n e r a l ,
o f o u r Miyun S t a t i o n
at the
t h e s e r e c o r d s show a r e g u l a r
i m p l y i n g a d i m i n i s h e d e m i s s i o n from t h e c o r o n a l h o l e s and t h a t
holes follow the solar rotation. of the "central
strip
The p o s s i b i l i t y
the
R e s u l t s from a " s u p e r p o s e d d i a g r a m a n a l y s i s "
flux" demonstrate these effects
even more c l e a r l y .
o f u s i n g r a d i o and s u n s p o t d a t a t o d e t e r m i n e t h e C~4P o f
coronal holes is investigated high-velocity
i.
equatorial
with the area of the latter.
Records o f t h e 164 ~ z
recurrent
M-regions are coronal holes
meridian passage of the coronal hole is
times of coronal h o l e s are examined. variation,
the so-called
coronal h o l e s examined, t h e i r
e x t e n s i o n s a r e f o u n d t o be 25 - 50 ° . geomagnetic storm:and the central
between coronal h o l e s a n d geomagnetic
and an a t t e m p t i s made t o e v a l u a t e t h e s p e e d o f t h e
s o l a r s t r e a m and t h e s i z e o f t h e c o r o n a l h o l e from d a t a on
geomagnetic storms.
INTRODUCTION
It is generally believed that recurrent
g e o m a g n e t i c s t o r m s (RGS) a r e c a u s e d by h i g h - v e l o c i t y
s t r e a m s i n t h e s o l a r wind and t h e s e s t r e a m s o r i g i n a t e M - r e g i o n s on t h e s o l a r s u r f a c e .
i n what B a r t e l s h y p o t h e s i z e d a s t h e
But d e c a d e s o f o b s e r v a t i o n s h a v e f a i l e d
H - r e g i o n s , and t h e q u e s t i o n o f t h e o r i g i n
o f t h e RGS had r e m a i n e d o p e n .
we h a v e n o t b e e n a b l e t o make good p r e d i c t i o n s
o f t h e RGS, e s p e c i a l l y
to i d e n t i f y
the
As a r e s u l t ,
of their
times of
b e g i n n i n g and e n d i n g . R e c e n t l y , N o t l e and o t h e r s X-ray c o r o n a l h o l e s t h e CH and RGS.
[1] showed t h a t
the high-velocity
(CH), and S h e e l e y and o t h e r s
streams originate
in soft
[2] showed a g e n e r a l c o r r e s p o n d e n c e b e t w e e n
T h u s , t h e q u e s t i o n o f t h e M - r e g i o n s p u r s u e d f o r o v e r 40 y e a r s c a n be
s a i d to have been s o l v e d . However, f o r t h e p u r p o s e o f p r e d i c t i n g c o n n e c t i o n b e t w e e e n them and t h e CH; a l s o , CH n e e d s t o be e x a m i n e d .
RGS, we m u s t i n v e s t i g a t e
more d e e p l y t h e
the procedure for regular
ground o b s e r v a t i o n s o f
On t h e o t h e r h a n d , t h e s e s t u d i e s may i n t u r n l e a d t o b e t t e r
Coronal Holes
195
u n d e r s t a n d i n g o f t h e p a s t r e c o r d s o f g e o m a g n e t i c and s o l a r o b s e r v a t i o n s , to identify
t h e CH i n t h e p a s t and f i n d t h e i r
significance
in the study of solar activity.
2.
law o f v a r i a t i o n .
e n a b l i n g us p e r h a p s
These a r e o b v i o u s l y o f g r e a t
CORONAL HOLES AND GEOMAGNETIC DISTURBANCES
Papers published so far [3] on the connection between CH and geomagnetic disturbances deal with average statistical properties of the global geomagnetic activity (as represented by the A
index or the C index) before and after the central meridian passage (CMP) of a CH. P P In this paper, on the other hand, we shall concentrate on some individual events. For the
geomagnetic disturbance besides using the geomagnetic index
~,Kv
we also used our Peking
i=l
data on geomagnetic storms and equatorial Dst storms, so as to make a more refined analysis and comparison possible. As regards CH, observations on various wavelengths have not been perfectly consistent, and there has been no unified method of characterizing their edges, with the result
that the
CMP times obtained by different people (even from the same data) are ofter very
different.
(See Fig. 4 in [4]). For definiteness, we have chosen two CH with long
observational runs, which were observed simultaneously in the white-light K-corona and soft X-ray ranges (2-32 A, 44-54 A) or at the ultraviolet line of 284 A, and for which the various CMP times given are in fair agreement with one another. Hansen and others [4], these two CH are known as #4 and #5.
In the designation of
#4 extends from the South pole
to the equator, while #5 (which is designated as CHI in [i]) extends from the North pole towards the equator.
Their CMP dates are:
# 4 : 1 9 7 3 Jan 24 Feb 20 Mar 18 Apt 14 May ii* Jun 8 # 5 : 1 9 7 3 May 31 Jun 27 Jul 25 Aug 21 Sep 16 Oct 14 * Neupert and Pizzo judged the date to be May 15; after considering the 27-day period, we preferred r'ay II (cf. Pig.l). i.
Coronal Holes #4, #S and GeomagneticL Storms
In Fig. I, we have marked the CMP dates of CH #4 and #5, and the times of beginning and end of geomagnetic storms observed at Peking, as well as the maximum value of the K-index during the storm.
The figure includes data on other coronal holes and geomagnetic storms
observed at Peking. CH #5 showed clear boundaries in the soft X-rays, hence it was possible to estimate its extension in the equatorial zone, and to determinefairly accurately its CMP dates. fine analysis can be made in this case of the connection
A
between CH and RGS, and the
results are given in TABLE i. From TABLE 1 and Pig. i, we can note the following: a.
One or two days after each CMP of CH #5, which has a large equatorial area, we
find the start of a geomagnetic storm, (GS). b.
The time lag between the onset of the GS and the CMP of the CH varies with the
area of the CH.
In general, the larger the area, the smaller is the time lag.
(The event
of Jul 25 is an exception, it may be due to the flare of Calss 2f occurring at the same
196
Coronal Holes
time). c.
Looking a t F i g . 1 a s a w h o l e , we f i n d t h a t n o t e v e r y CbW o f e v e r y CH i s a c c o m p a n i e d
by a GS, t h i s
is especially
t r u e f o r t h o s e CH w i t h s m a l l e q u a t o r i a l
6
1910
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F i g . 1. O b s e r v a t i o n s o f g e o m a g n e t i c s t o r m s a t P e k i n g , and o f c o r o n a l holes in the soft X-ray, far ultraviolet and w h i l e - l i g h t K - c o r o n a i n t h e p e r i o d 1973 J a n 1 - Nov 20. The open. h a l f - f i l l e d and f i l l e d t r i a n g l e s and t h e numbers above them mark t h e s l o w - s t a r t , s l o w - s u d d e n - s t a r t , and s u d d e n - s t a r t o f g e o m a g n e t i c s t o r m s o b s e r v e d a t P e k i n g , and t h e c o r r e s p o n d i n g UT. Symbol [[ marks t h e end o f a s t r o m and t h e number a b o v e , t h e UT. The number i n b r a c k e t s d u r i n g t h e p e r i o d o f a s t o r m i s t h e maximum o b s e r v e d v a l u e o f t h e K - i n d e x . The CEP d a t e s o b s e r v e d a t 284 A, i n t h e r a n g e 2-54 A, and i n t h e w h i t e - l i g h t K - c o r o n a a r e r e s p e c t i v e l y marked w i t h \ , / , and [. T h e s e d a t e s a r e t a k e n from [ 3 ] , [5] and [1]. The c u r v e d o u t l i n e s a r e b a s e d on K - c o r o n a o u t l i n e s .
Table 1 Coronal hole #5
Geomagnetic s t o r m at Peking
Time of CEP
~hy 31 1332 UT
Jun 27 2119 lIT
Jul 25 0254 UT
Aug 21 0050 UT
Sep 16 2323 liT
Oct 14 1337 UT
Area (1010km)
3.3
4.7
3.0
3.2
2.4
l.l
Time of onset
Jun 2 0300 UT
Jun 28 2100 UT
Jul 26 0300 UT
Aug 22 ii00 UT
Oct 16 0520 UT
37
24
24
34
40
5
6
6
5
6
Jun 2 0700 UT
J u n 28 2300 UT
J u l 26 0900 UT
Aug 23 0300 UT
Oct 16 0800 UT
Duration [hrs) g~x. K - i n d e x
Dst storm
Main p h a s e start Duration (hrs) Max. decrease
41
26
30
46
43
-26y
-31y
-28y
-38y
-29y
2.
C o r o n a l H o l e s #4, #5 and EK p In o r d e r t o s u p p r e s s o t h e r d i s t u r b a n c e s
and t o b r i n g o u t t h e e f f e c t s
we made t h e u s u a l " s u p e r p o s e d d i a g r a m " a n a l y s i s , same CH a r e l i n e d up a t t h e CMP and summed. t o #4, and F i g s .
2B and 2C r e f e r
t o 8, w h e r e a s i n 2C, i t t h e CMP. These f i g u r e s t h e CMP.
t o #5.
i n which t h e % - i n d e x
Our r e s u l t s
o f CH on g e o m a g n e t i s ~ pertaining
a r e shown i n F i g .
2.
to the
Fig.
2A r e f e r s
In F i g s . 2A and 2B, t h e s u m m a t i o n e x t e n d s from 1
e x t e n d s from 1 t o S, c o r r e s p o n d i n g t o t h e 3 - h o u r p e r i o d a r o u n d
show t h a t t h e v a l u e o f ZK r e a c h e s a maximum a b o u t t h r e e d a y s a f t e r P I f t h e maximum c o r r e s p o n d s t o t h e h i g h - v e l o c i t y s t r e a m from t h e c e n t r a l p a r t o f
C o r o n a l Holes
197
the CH, then the time lag between the onset of #4
the GS and the CMP will give us the equatorial width of the CH, which we found to be 25-50 ° . Again from the figure, we note that the maximum value of EK reached is 40 for #4, P and 28 for #5. Using the empirical relation
211
between the velocity of the solar wind and
-6
' 24
EK derived by Synder and others [7], P u = 8.4EK + 330 (km/sec) P we find the average wind velocities %4
= 646 km/sec
%5
= 565 km/sec.
0 i~
2
4
2
4
6
#5
Further, according to the empirical relation, concluded by Notle and others
' "2
-6
I
-4
i
-'2
'IK, -30
[i], between
6 C
#5
the equatorial area A of the CH and the stream velocity u, (1010km2),
-10
we find, for these two CH, the average areas --6
A#4 = 2.75 x I0 I0 km 2
--4
" Z2
'
o
Fig. 2 Superposed Diagrams of EK P
A#5 = 1.80 x I0 I0 km 2 If we use the arithmetical mean of the result
from TABLE i, then we find for CH #5, an equatorial area of about 3.0 × I0 I0 km 2.
THUS,
the values derived first tend to be somewhat low.
3.
CORONAL HOLES AND SOLAR EMISSION AT 146 ~ z
Lantos and Avignon [8] compared the solar section at 169 ~ z photographs of CH at 284 A [figs. 3A, 3B). shown in Fig. 3C. CH effect.
on 1973 Oct 8 with
Our observations at 146 MHz on the same day are
Both the Nan~ay and our Hiyun transit observations showed clearly the
The depressions in the radio records mean that radio emission is reduced inside
a CH. To ascertain whether it is possible to identify CH from radio records at 146 ~ z , analyzed our transit observation of #4 and #5 made with our 146 ~ z i.
we
fan beam interferometer.
Features in. the original transit records at 146 b~z before and after the CMP of CH #5*
The records made before and after the CMP of #5 on b~ay 31 1973 are shown in Fig. 4.
Here,
the solid line marks the actual observed curve at 146 MHz, and the dotted curve represents the normal flux of the solar corona when without any structure. dotted curve measures the decrease in emission.
The depression under the
The figures show that the depression
moved daily from left to right, passing the centre on ~ y
31.
This movement is in agreement
* After completing this paper, we saw the recent work by Drago and others observed results at 169 ]~{z and at 408 ~{z on May 31 and Jun 27.
[9] giving the
198
Holes
Coronal
1973 Hay 28
coronal h o l e emission at 169H.z
Nay 30
B
coronal}
2S4 kh;le
Jun 1
coronal hole 146Msz
Jun 2
emission a t
F i g . 3 Radio t r a n s i t o b s e r v a t i o n s during t h e ~,'Po f a coronal h o l e
(1973 Oct
F i g . 4 Radio o b s e r v a t i o n s a t 146 ~Nz on d a y s b e f o r e and a f t e r t h e CMP o f #5 on Fay 31
8)
w i t h t h e w e s t w a r d m o t i o n o f t h e CH f o l l o w i n g t h e S u n ' s r o t a t i o n . F i g , S shows t h e o r i g i n a l The c e n t r a l
portions
(dotted line). days b e f o r e ,
r e c o r d s on 4 s u c c e s s i v e C ~ d a y s b e t w e e n ~ y
of these records all
show d e p r e s s i o n s r e l a t i v e
The r e c o r d s a r o u n d t h e day o f t h e C~P f o l l o w t h i s the right
side of the record is higher than the left
the reverse is the case.
(cf.
e.g.,
Fig. 4).
d a y s o f o t h e r CH and n e v e r f o u n d a n y m e t e r It thus appears that
31 and Aug 21.
t o the normal s t a t e general pattern: side;
We e x a m i n e d many more t r a n s i t
wave b u r s t s
in the central
t h e p r e s e n c e o f a l a r g e CH w i l t a f f e c t
one o r two
one o r two d a y s a f t e r r e c o r d s on CMP
portion.
t h e f l u x a t 146 ~ z .
But a s
C o r o n a l Holes
p o i n t e d o u t b y Dulk and S h e r i d a n [10],
199
the
d e c r e a s e i n e m i s s i o n a s s o c i a t e d w i t h a CH i s o n l y 10 - 50%, and i t may e a s i l y be masked b y other factors,
h e n c e t h e r e h a s b e e n no o n e - t o
one c o r r e s p o n d e n c e b e t w e e n t h e CH o b s e r v e d i n the soft
X-ray or f a r u l t r a v i o l e t
and t h e
d e p r e s s i o n s i n t h e m e t e r wave e m i s s i o n . 2.
The C e n t r a l S t r i p
further
the effect
145 ~ z ,
Flux
To examine
o f CH on r a d i o e m i s s i o n a t
we made a s e p a r a t e a n a l y s i s w i t h
the measured flux in the central strip
at the time of transit
o f t h e Sun.
This strip
North-South
of the centre
has a width of 6',
for
Aug 21
this is t h e resolving power in the East-West direction of our array at Miyun [ii]. The result of a superposed diagram analysis is shown in Fig. 6. (6A for #4, 6B for #5).
We
note clear minima on the day of CMP here: the radio emission at 146 ~ z
Fig. S Radio transit observations at 146 M~z on 4 successive CMP days of #5
is indeed
reduced in a CH. Comparing F i g s . 6 and 2, we s e e t h a t t h e r e i s a good c o r r e s p o n d e n c e b e t w e e n t h e " 1 4 6
~z
coronal holes" and geomagnetic activity, namely, about 3 days after the appearance of
the depression in the central strip flux, the average ZK reaches a maximum, and, in the P main, the greater the radio depressions, the higher will be the ZK maximum. P
4.
DISCUSSION
The above a n a l y s i s
shows t h a t good c o r r e l a t i o n s
e m i s s i o n and r e c u r r e n t
geomagnetic storms.
predictions of the RGS, and to derive (i)
exist
among c o r o n a l h o l e s ,
These c o r r e l a t i o n s
m e t e r wave
c a n h e l p u s t o make
some properties at Ct~P from the usual observations.
From the point of view of RGS prediction, the key is the timely identification of
the CMP of a CH, especially the first passage.
Although, as shown in Section 3, for CH #4
and CH #S which were observable by several means, the effects of CH on the radio emission at 146 ~ z
are detectable and resolvable, we cannot, in general ascertain the time of CMP
from the fan beam interferometer observations with any confidence, because of the great variability of the solar flux in the meter waves and because of the great variety of factors that affect the radio observations.
Saemundsson
[12] believed that the M-regions appear
in locations where previous sunspots have existed.
This, if true, would be helpful in
ascertaining the CMP from ground observations, so we re-examined this possibility with the sunspot distributions observed by various Chinese observatories in the period 1972 Aug 5 1973 Nov 12.
We found the following result:
if, after the disappearance of a large sunspot,
no new spots of any great size have appeared in the same longitudes within the following
200
Coronal Holes
Central strip flux
#4
A
8.~
L i
I
i
I
-4
-6
~"
i
0
-2
i
i
!
2
i
i
4
6
Central strip flux #5
B
[8.50
7.
"7.00
/
i
I
-6
I
--4
i
i
--2
i
i
)
0
Fig. 6 Superposed d i a g r a m s o f t h e c e n t r a l 3 or 4 solar rotations, Thus, by a c a r e f u l
I
2
I
4 strip
I
I
6 f l u x a t 146 ~ z
then a coronal hole will often appear in that analysis
location.
of the morphological changes in the transit
a t 146 ~ t z , and t h e d e c r e a s e i n t h e c e n t r a l
strip
observations
f l u x , w h i l e making u s e o f t h e above
t i m e - l a g b e t w e e n t h e d e a t h o f s u n s p o t s and t h e b i r t h
of coronal holes,
we may p o s s i b l y
arrive at a fairly effective means of determining the time of the first CMP, that is, the beginning of a series of recurrent geomagnetic storms. (2)
Coronal holes are large-scale structures on the Sun's surface.
Their relationship
with solar active longitudes, the Hale boundaries etc. is not clear at present.
Therefore,
it will be of great interest if we can derive the CMP dates of coronal holes in the past from historical records and correlate these with other relevant quantities.
In doing this,
in addition to the sunspot and meter wave observations, data on geomagnetic activity are of great value also.
As demonstrated in Section 2, a knowledge of the beginning of a RGS
series is helpful in determining the appearance of a coronal hole and its longitude on the Sun, and a superposed diagram analysis can lead to the relative sizes of the coronal hole. Also, we should remember Allen's analysis of the ~*-regions [13]: then from the life-spans
Coronal Holes
of single coronal
geomagnetic
hole,
storms,
are
far
of a series,
occur,
Although the correlations relations
we s h o u l d b e a b l e t o e s t i m a t e
from the duration
t i m e o f y e a r when t h e s t o r m s
its
the
latitude
among c o r o n a l
from being
one-to-one.
life-span
holes,
m e t e r wave e m i s s i o n
clearer
understanding
of the physical
of the coronal
This is obviously
of the space between the Earth and the Sun.
streams,
the equatorial
state
a n d how t h e l a t t e r
width of the hole,
and from the
on t h e S u n .
effects
the high-velocity
201
Our n e x t
of coronal propagates
holes
a n d RGS a r e g o o d ,
due to the neglect task
is
therefore
o f how t h i s
state
to gain a fashions
i n s p a c e f r o m t h e Sun t o u s .
REFERENCES J. T. Notle et al., Coronal holes as sources of solar wind, Solar Phys., 46 (1976), 303. N. R. Sheoley Jr., et al., Coronal holes, Solar wind Streams, and recurrent geomagnetic disturbanees, 1973---1976, So/at Phys., 49 (1976), 271. [ 3 ] W. 1M. Net, pert and V. A. Pizzo, Solar Coronal holes as sources o! recurrent geomagnetie distmrbances, J. Geophys. Res., 79 (1974), 3701. [ 4 ] R. T. Hansen, et alq Longlivea coronal structures and recurrent geomagnetic patterns in 1974, planet. Space 8oi., 24 (1976), 381. [ 5 ] B. Bell and G. Noel, Intensity of the Fe XV emission line corona, the level of geomagnetic activity and the velocity of the Solar wind, J. Geophys. ties., 81 (1976), 4508. [ 6 ] J. T. Notle et aL, An atlas of coronal hole boundary positions May 28 to November 21, 1973, Solar Phys., 46 (1976), 291. [ 7 ] C. W'~ Snyder and Marcia Neugehauer, The Solar wind velocity and its eorrelation with eosmie ray variations and with solar and geomagnetic activity, J. Geophys. Res., 68 (1963), 6361. [ 8 ] P. Lantos and Y. Avignon, The metric quiet sun during two cycles of activity and the nature of coronal holes, Astro. As~ophys., 41 (1975), 137. [ 9 ] France C%iuderi Drago, et al., Structure of coronal holes from UV and radio observations, Solar Phys. 51 (1977), 143. [10] G. A. Dulk and K. V. Sheridan, The structure of the middle corona from observations at 80 and 160 MHz, Solar Phys., 36 (1974), 191.
[1] [2]
[ii] [12] [13]
the
of the
Liu Xu-zhao and He Xiang-tao, Acta Astronomica Sinica 15 (1974) 61-72. Saemundseon, Th., Statistics of geomagnetic storms and Solar activity, Men. Not. Roy. AsfrO~t. So~., 123 (1962), 299. C. ~V. Allen, M--reglons, Pla~tet. Space Sci., 12 (1964), 487.
4 (1980) 194-201
Pergamon Press. Printed in Great Britain 0146-6364/80/0601-0194-$07.50/0
Acta Astr. Sinica 2~ (1979) 191-198
CORONAL HOLES,
Zhao
1 4 6 MHz EMISSIONS AND GEOMAGNETIC STOP,MS
Department of Geophysics, Beijing University Beijing Astronomical Observatory
Xue-pu
Liu X u - z h a o
Received 1978 April 14
ABSTRACT. Our a n a l y s i s o f t h e r e l a t i o n s h i p storms lends s u p p o r t to the idea t h a t with large areas.
For £wo t y p i c a l
inversely
correlated
The t i m e l a g b e t w e e n t h e o n s e t o f t h e
f a n beam i n t e r f e r o m e t e r In g e n e r a l ,
o f o u r Miyun S t a t i o n
at the
t h e s e r e c o r d s show a r e g u l a r
i m p l y i n g a d i m i n i s h e d e m i s s i o n from t h e c o r o n a l h o l e s and t h a t
holes follow the solar rotation. of the "central
strip
The p o s s i b i l i t y
the
R e s u l t s from a " s u p e r p o s e d d i a g r a m a n a l y s i s "
flux" demonstrate these effects
even more c l e a r l y .
o f u s i n g r a d i o and s u n s p o t d a t a t o d e t e r m i n e t h e C~4P o f
coronal holes is investigated high-velocity
i.
equatorial
with the area of the latter.
Records o f t h e 164 ~ z
recurrent
M-regions are coronal holes
meridian passage of the coronal hole is
times of coronal h o l e s are examined. variation,
the so-called
coronal h o l e s examined, t h e i r
e x t e n s i o n s a r e f o u n d t o be 25 - 50 ° . geomagnetic storm:and the central
between coronal h o l e s a n d geomagnetic
and an a t t e m p t i s made t o e v a l u a t e t h e s p e e d o f t h e
s o l a r s t r e a m and t h e s i z e o f t h e c o r o n a l h o l e from d a t a on
geomagnetic storms.
INTRODUCTION
It is generally believed that recurrent
g e o m a g n e t i c s t o r m s (RGS) a r e c a u s e d by h i g h - v e l o c i t y
s t r e a m s i n t h e s o l a r wind and t h e s e s t r e a m s o r i g i n a t e M - r e g i o n s on t h e s o l a r s u r f a c e .
i n what B a r t e l s h y p o t h e s i z e d a s t h e
But d e c a d e s o f o b s e r v a t i o n s h a v e f a i l e d
H - r e g i o n s , and t h e q u e s t i o n o f t h e o r i g i n
o f t h e RGS had r e m a i n e d o p e n .
we h a v e n o t b e e n a b l e t o make good p r e d i c t i o n s
o f t h e RGS, e s p e c i a l l y
to i d e n t i f y
the
As a r e s u l t ,
of their
times of
b e g i n n i n g and e n d i n g . R e c e n t l y , N o t l e and o t h e r s X-ray c o r o n a l h o l e s t h e CH and RGS.
[1] showed t h a t
the high-velocity
(CH), and S h e e l e y and o t h e r s
streams originate
in soft
[2] showed a g e n e r a l c o r r e s p o n d e n c e b e t w e e n
T h u s , t h e q u e s t i o n o f t h e M - r e g i o n s p u r s u e d f o r o v e r 40 y e a r s c a n be
s a i d to have been s o l v e d . However, f o r t h e p u r p o s e o f p r e d i c t i n g c o n n e c t i o n b e t w e e e n them and t h e CH; a l s o , CH n e e d s t o be e x a m i n e d .
RGS, we m u s t i n v e s t i g a t e
more d e e p l y t h e
the procedure for regular
ground o b s e r v a t i o n s o f
On t h e o t h e r h a n d , t h e s e s t u d i e s may i n t u r n l e a d t o b e t t e r
Coronal Holes
195
u n d e r s t a n d i n g o f t h e p a s t r e c o r d s o f g e o m a g n e t i c and s o l a r o b s e r v a t i o n s , to identify
t h e CH i n t h e p a s t and f i n d t h e i r
significance
in the study of solar activity.
2.
law o f v a r i a t i o n .
e n a b l i n g us p e r h a p s
These a r e o b v i o u s l y o f g r e a t
CORONAL HOLES AND GEOMAGNETIC DISTURBANCES
Papers published so far [3] on the connection between CH and geomagnetic disturbances deal with average statistical properties of the global geomagnetic activity (as represented by the A
index or the C index) before and after the central meridian passage (CMP) of a CH. P P In this paper, on the other hand, we shall concentrate on some individual events. For the
geomagnetic disturbance besides using the geomagnetic index
~,Kv
we also used our Peking
i=l
data on geomagnetic storms and equatorial Dst storms, so as to make a more refined analysis and comparison possible. As regards CH, observations on various wavelengths have not been perfectly consistent, and there has been no unified method of characterizing their edges, with the result
that the
CMP times obtained by different people (even from the same data) are ofter very
different.
(See Fig. 4 in [4]). For definiteness, we have chosen two CH with long
observational runs, which were observed simultaneously in the white-light K-corona and soft X-ray ranges (2-32 A, 44-54 A) or at the ultraviolet line of 284 A, and for which the various CMP times given are in fair agreement with one another. Hansen and others [4], these two CH are known as #4 and #5.
In the designation of
#4 extends from the South pole
to the equator, while #5 (which is designated as CHI in [i]) extends from the North pole towards the equator.
Their CMP dates are:
# 4 : 1 9 7 3 Jan 24 Feb 20 Mar 18 Apt 14 May ii* Jun 8 # 5 : 1 9 7 3 May 31 Jun 27 Jul 25 Aug 21 Sep 16 Oct 14 * Neupert and Pizzo judged the date to be May 15; after considering the 27-day period, we preferred r'ay II (cf. Pig.l). i.
Coronal Holes #4, #S and GeomagneticL Storms
In Fig. I, we have marked the CMP dates of CH #4 and #5, and the times of beginning and end of geomagnetic storms observed at Peking, as well as the maximum value of the K-index during the storm.
The figure includes data on other coronal holes and geomagnetic storms
observed at Peking. CH #5 showed clear boundaries in the soft X-rays, hence it was possible to estimate its extension in the equatorial zone, and to determinefairly accurately its CMP dates. fine analysis can be made in this case of the connection
A
between CH and RGS, and the
results are given in TABLE i. From TABLE 1 and Pig. i, we can note the following: a.
One or two days after each CMP of CH #5, which has a large equatorial area, we
find the start of a geomagnetic storm, (GS). b.
The time lag between the onset of the GS and the CMP of the CH varies with the
area of the CH.
In general, the larger the area, the smaller is the time lag.
(The event
of Jul 25 is an exception, it may be due to the flare of Calss 2f occurring at the same
196
Coronal Holes
time). c.
Looking a t F i g . 1 a s a w h o l e , we f i n d t h a t n o t e v e r y CbW o f e v e r y CH i s a c c o m p a n i e d
by a GS, t h i s
is especially
t r u e f o r t h o s e CH w i t h s m a l l e q u a t o r i a l
6
1910
.~ ~
~
•
"zh
1909
:9
4
, , ( Z4 o I * " / . . ,~/ 1 o
_1
1911 1912 1913 1914 1915
16
21
.3]x \ z~:,i~,,,r \
1908
~
11
n\
1907
1,"./ / I
zi
2
17
~
,
2
1
6
,11
{ [~ffN
•
21
(61
,, 2 6 20
4
.17
/
. 171
26 27
,~ (5) ." L/A~,~ ° ~A,q
"'4
~
1,
areas.
t.
/ ~ A~%~61'-
..~1
"lO'.°/J
19
[
1916
t,r.,
1917
1918
/
/I
//I
~,~,sllllJA(6)"
3 & ( 5)1
14
- (7),
"(o,.,
I /
.'.(5)u
t
'I
/
F i g . 1. O b s e r v a t i o n s o f g e o m a g n e t i c s t o r m s a t P e k i n g , and o f c o r o n a l holes in the soft X-ray, far ultraviolet and w h i l e - l i g h t K - c o r o n a i n t h e p e r i o d 1973 J a n 1 - Nov 20. The open. h a l f - f i l l e d and f i l l e d t r i a n g l e s and t h e numbers above them mark t h e s l o w - s t a r t , s l o w - s u d d e n - s t a r t , and s u d d e n - s t a r t o f g e o m a g n e t i c s t o r m s o b s e r v e d a t P e k i n g , and t h e c o r r e s p o n d i n g UT. Symbol [[ marks t h e end o f a s t r o m and t h e number a b o v e , t h e UT. The number i n b r a c k e t s d u r i n g t h e p e r i o d o f a s t o r m i s t h e maximum o b s e r v e d v a l u e o f t h e K - i n d e x . The CEP d a t e s o b s e r v e d a t 284 A, i n t h e r a n g e 2-54 A, and i n t h e w h i t e - l i g h t K - c o r o n a a r e r e s p e c t i v e l y marked w i t h \ , / , and [. T h e s e d a t e s a r e t a k e n from [ 3 ] , [5] and [1]. The c u r v e d o u t l i n e s a r e b a s e d on K - c o r o n a o u t l i n e s .
Table 1 Coronal hole #5
Geomagnetic s t o r m at Peking
Time of CEP
~hy 31 1332 UT
Jun 27 2119 lIT
Jul 25 0254 UT
Aug 21 0050 UT
Sep 16 2323 liT
Oct 14 1337 UT
Area (1010km)
3.3
4.7
3.0
3.2
2.4
l.l
Time of onset
Jun 2 0300 UT
Jun 28 2100 UT
Jul 26 0300 UT
Aug 22 ii00 UT
Oct 16 0520 UT
37
24
24
34
40
5
6
6
5
6
Jun 2 0700 UT
J u n 28 2300 UT
J u l 26 0900 UT
Aug 23 0300 UT
Oct 16 0800 UT
Duration [hrs) g~x. K - i n d e x
Dst storm
Main p h a s e start Duration (hrs) Max. decrease
41
26
30
46
43
-26y
-31y
-28y
-38y
-29y
2.
C o r o n a l H o l e s #4, #5 and EK p In o r d e r t o s u p p r e s s o t h e r d i s t u r b a n c e s
and t o b r i n g o u t t h e e f f e c t s
we made t h e u s u a l " s u p e r p o s e d d i a g r a m " a n a l y s i s , same CH a r e l i n e d up a t t h e CMP and summed. t o #4, and F i g s .
2B and 2C r e f e r
t o 8, w h e r e a s i n 2C, i t t h e CMP. These f i g u r e s t h e CMP.
t o #5.
i n which t h e % - i n d e x
Our r e s u l t s
o f CH on g e o m a g n e t i s ~ pertaining
a r e shown i n F i g .
2.
to the
Fig.
2A r e f e r s
In F i g s . 2A and 2B, t h e s u m m a t i o n e x t e n d s from 1
e x t e n d s from 1 t o S, c o r r e s p o n d i n g t o t h e 3 - h o u r p e r i o d a r o u n d
show t h a t t h e v a l u e o f ZK r e a c h e s a maximum a b o u t t h r e e d a y s a f t e r P I f t h e maximum c o r r e s p o n d s t o t h e h i g h - v e l o c i t y s t r e a m from t h e c e n t r a l p a r t o f
C o r o n a l Holes
197
the CH, then the time lag between the onset of #4
the GS and the CMP will give us the equatorial width of the CH, which we found to be 25-50 ° . Again from the figure, we note that the maximum value of EK reached is 40 for #4, P and 28 for #5. Using the empirical relation
211
between the velocity of the solar wind and
-6
' 24
EK derived by Synder and others [7], P u = 8.4EK + 330 (km/sec) P we find the average wind velocities %4
= 646 km/sec
%5
= 565 km/sec.
0 i~
2
4
2
4
6
#5
Further, according to the empirical relation, concluded by Notle and others
' "2
-6
I
-4
i
-'2
'IK, -30
[i], between
6 C
#5
the equatorial area A of the CH and the stream velocity u, (1010km2),
-10
we find, for these two CH, the average areas --6
A#4 = 2.75 x I0 I0 km 2
--4
" Z2
'
o
Fig. 2 Superposed Diagrams of EK P
A#5 = 1.80 x I0 I0 km 2 If we use the arithmetical mean of the result
from TABLE i, then we find for CH #5, an equatorial area of about 3.0 × I0 I0 km 2.
THUS,
the values derived first tend to be somewhat low.
3.
CORONAL HOLES AND SOLAR EMISSION AT 146 ~ z
Lantos and Avignon [8] compared the solar section at 169 ~ z photographs of CH at 284 A [figs. 3A, 3B). shown in Fig. 3C. CH effect.
on 1973 Oct 8 with
Our observations at 146 MHz on the same day are
Both the Nan~ay and our Hiyun transit observations showed clearly the
The depressions in the radio records mean that radio emission is reduced inside
a CH. To ascertain whether it is possible to identify CH from radio records at 146 ~ z , analyzed our transit observation of #4 and #5 made with our 146 ~ z i.
we
fan beam interferometer.
Features in. the original transit records at 146 b~z before and after the CMP of CH #5*
The records made before and after the CMP of #5 on b~ay 31 1973 are shown in Fig. 4.
Here,
the solid line marks the actual observed curve at 146 MHz, and the dotted curve represents the normal flux of the solar corona when without any structure. dotted curve measures the decrease in emission.
The depression under the
The figures show that the depression
moved daily from left to right, passing the centre on ~ y
31.
This movement is in agreement
* After completing this paper, we saw the recent work by Drago and others observed results at 169 ]~{z and at 408 ~{z on May 31 and Jun 27.
[9] giving the
198
Holes
Coronal
1973 Hay 28
coronal h o l e emission at 169H.z
Nay 30
B
coronal}
2S4 kh;le
Jun 1
coronal hole 146Msz
Jun 2
emission a t
F i g . 3 Radio t r a n s i t o b s e r v a t i o n s during t h e ~,'Po f a coronal h o l e
(1973 Oct
F i g . 4 Radio o b s e r v a t i o n s a t 146 ~Nz on d a y s b e f o r e and a f t e r t h e CMP o f #5 on Fay 31
8)
w i t h t h e w e s t w a r d m o t i o n o f t h e CH f o l l o w i n g t h e S u n ' s r o t a t i o n . F i g , S shows t h e o r i g i n a l The c e n t r a l
portions
(dotted line). days b e f o r e ,
r e c o r d s on 4 s u c c e s s i v e C ~ d a y s b e t w e e n ~ y
of these records all
show d e p r e s s i o n s r e l a t i v e
The r e c o r d s a r o u n d t h e day o f t h e C~P f o l l o w t h i s the right
side of the record is higher than the left
the reverse is the case.
(cf.
e.g.,
Fig. 4).
d a y s o f o t h e r CH and n e v e r f o u n d a n y m e t e r It thus appears that
31 and Aug 21.
t o the normal s t a t e general pattern: side;
We e x a m i n e d many more t r a n s i t
wave b u r s t s
in the central
t h e p r e s e n c e o f a l a r g e CH w i l t a f f e c t
one o r two
one o r two d a y s a f t e r r e c o r d s on CMP
portion.
t h e f l u x a t 146 ~ z .
But a s
C o r o n a l Holes
p o i n t e d o u t b y Dulk and S h e r i d a n [10],
199
the
d e c r e a s e i n e m i s s i o n a s s o c i a t e d w i t h a CH i s o n l y 10 - 50%, and i t may e a s i l y be masked b y other factors,
h e n c e t h e r e h a s b e e n no o n e - t o
one c o r r e s p o n d e n c e b e t w e e n t h e CH o b s e r v e d i n the soft
X-ray or f a r u l t r a v i o l e t
and t h e
d e p r e s s i o n s i n t h e m e t e r wave e m i s s i o n . 2.
The C e n t r a l S t r i p
further
the effect
145 ~ z ,
Flux
To examine
o f CH on r a d i o e m i s s i o n a t
we made a s e p a r a t e a n a l y s i s w i t h
the measured flux in the central strip
at the time of transit
o f t h e Sun.
This strip
North-South
of the centre
has a width of 6',
for
Aug 21
this is t h e resolving power in the East-West direction of our array at Miyun [ii]. The result of a superposed diagram analysis is shown in Fig. 6. (6A for #4, 6B for #5).
We
note clear minima on the day of CMP here: the radio emission at 146 ~ z
Fig. S Radio transit observations at 146 M~z on 4 successive CMP days of #5
is indeed
reduced in a CH. Comparing F i g s . 6 and 2, we s e e t h a t t h e r e i s a good c o r r e s p o n d e n c e b e t w e e n t h e " 1 4 6
~z
coronal holes" and geomagnetic activity, namely, about 3 days after the appearance of
the depression in the central strip flux, the average ZK reaches a maximum, and, in the P main, the greater the radio depressions, the higher will be the ZK maximum. P
4.
DISCUSSION
The above a n a l y s i s
shows t h a t good c o r r e l a t i o n s
e m i s s i o n and r e c u r r e n t
geomagnetic storms.
predictions of the RGS, and to derive (i)
exist
among c o r o n a l h o l e s ,
These c o r r e l a t i o n s
m e t e r wave
c a n h e l p u s t o make
some properties at Ct~P from the usual observations.
From the point of view of RGS prediction, the key is the timely identification of
the CMP of a CH, especially the first passage.
Although, as shown in Section 3, for CH #4
and CH #S which were observable by several means, the effects of CH on the radio emission at 146 ~ z
are detectable and resolvable, we cannot, in general ascertain the time of CMP
from the fan beam interferometer observations with any confidence, because of the great variability of the solar flux in the meter waves and because of the great variety of factors that affect the radio observations.
Saemundsson
[12] believed that the M-regions appear
in locations where previous sunspots have existed.
This, if true, would be helpful in
ascertaining the CMP from ground observations, so we re-examined this possibility with the sunspot distributions observed by various Chinese observatories in the period 1972 Aug 5 1973 Nov 12.
We found the following result:
if, after the disappearance of a large sunspot,
no new spots of any great size have appeared in the same longitudes within the following
200
Coronal Holes
Central strip flux
#4
A
8.~
L i
I
i
I
-4
-6
~"
i
0
-2
i
i
!
2
i
i
4
6
Central strip flux #5
B
[8.50
7.
"7.00
/
i
I
-6
I
--4
i
i
--2
i
i
)
0
Fig. 6 Superposed d i a g r a m s o f t h e c e n t r a l 3 or 4 solar rotations, Thus, by a c a r e f u l
I
2
I
4 strip
I
I
6 f l u x a t 146 ~ z
then a coronal hole will often appear in that analysis
location.
of the morphological changes in the transit
a t 146 ~ t z , and t h e d e c r e a s e i n t h e c e n t r a l
strip
observations
f l u x , w h i l e making u s e o f t h e above
t i m e - l a g b e t w e e n t h e d e a t h o f s u n s p o t s and t h e b i r t h
of coronal holes,
we may p o s s i b l y
arrive at a fairly effective means of determining the time of the first CMP, that is, the beginning of a series of recurrent geomagnetic storms. (2)
Coronal holes are large-scale structures on the Sun's surface.
Their relationship
with solar active longitudes, the Hale boundaries etc. is not clear at present.
Therefore,
it will be of great interest if we can derive the CMP dates of coronal holes in the past from historical records and correlate these with other relevant quantities.
In doing this,
in addition to the sunspot and meter wave observations, data on geomagnetic activity are of great value also.
As demonstrated in Section 2, a knowledge of the beginning of a RGS
series is helpful in determining the appearance of a coronal hole and its longitude on the Sun, and a superposed diagram analysis can lead to the relative sizes of the coronal hole. Also, we should remember Allen's analysis of the ~*-regions [13]: then from the life-spans
Coronal Holes
of single coronal
geomagnetic
hole,
storms,
are
far
of a series,
occur,
Although the correlations relations
we s h o u l d b e a b l e t o e s t i m a t e
from the duration
t i m e o f y e a r when t h e s t o r m s
its
the
latitude
among c o r o n a l
from being
one-to-one.
life-span
holes,
m e t e r wave e m i s s i o n
clearer
understanding
of the physical
of the coronal
This is obviously
of the space between the Earth and the Sun.
streams,
the equatorial
state
a n d how t h e l a t t e r
width of the hole,
and from the
on t h e S u n .
effects
the high-velocity
201
Our n e x t
of coronal propagates
holes
a n d RGS a r e g o o d ,
due to the neglect task
is
therefore
o f how t h i s
state
to gain a fashions
i n s p a c e f r o m t h e Sun t o u s .
REFERENCES J. T. Notle et al., Coronal holes as sources of solar wind, Solar Phys., 46 (1976), 303. N. R. Sheoley Jr., et al., Coronal holes, Solar wind Streams, and recurrent geomagnetic disturbanees, 1973---1976, So/at Phys., 49 (1976), 271. [ 3 ] W. 1M. Net, pert and V. A. Pizzo, Solar Coronal holes as sources o! recurrent geomagnetie distmrbances, J. Geophys. Res., 79 (1974), 3701. [ 4 ] R. T. Hansen, et alq Longlivea coronal structures and recurrent geomagnetic patterns in 1974, planet. Space 8oi., 24 (1976), 381. [ 5 ] B. Bell and G. Noel, Intensity of the Fe XV emission line corona, the level of geomagnetic activity and the velocity of the Solar wind, J. Geophys. ties., 81 (1976), 4508. [ 6 ] J. T. Notle et aL, An atlas of coronal hole boundary positions May 28 to November 21, 1973, Solar Phys., 46 (1976), 291. [ 7 ] C. W'~ Snyder and Marcia Neugehauer, The Solar wind velocity and its eorrelation with eosmie ray variations and with solar and geomagnetic activity, J. Geophys. Res., 68 (1963), 6361. [ 8 ] P. Lantos and Y. Avignon, The metric quiet sun during two cycles of activity and the nature of coronal holes, Astro. As~ophys., 41 (1975), 137. [ 9 ] France C%iuderi Drago, et al., Structure of coronal holes from UV and radio observations, Solar Phys. 51 (1977), 143. [10] G. A. Dulk and K. V. Sheridan, The structure of the middle corona from observations at 80 and 160 MHz, Solar Phys., 36 (1974), 191.
[1] [2]
[ii] [12] [13]
the
of the
Liu Xu-zhao and He Xiang-tao, Acta Astronomica Sinica 15 (1974) 61-72. Saemundseon, Th., Statistics of geomagnetic storms and Solar activity, Men. Not. Roy. AsfrO~t. So~., 123 (1962), 299. C. ~V. Allen, M--reglons, Pla~tet. Space Sci., 12 (1964), 487.