The Interplanetary and Magnetospheric causes of Geomagnetically Induced Currents (GICs) \ 10 A in the Mäntsälä Finland Pipeline: 1999 through 2019

The interplanetary and magnetospheric phenomena time-coincident with intense geomagnetically induced current (GIC) > 10 A and > 30 A events during 21 years (1999 through 2019) at the Mäntsälä, Finland (57.9 magnetic latitude) gas pipeline have been studied. Although forward shocks and substorms are predominant causes of intense GICs, some newly discovered geoeffective interplanetary features are: solar wind plasma parcel (PP) impingements, possible interplanetary magnetic field (IMF) northward (Bn) and southward (Bs) turnings, and reverse shocks. The PPs are possibly the loop and filament portions of coronal mass ejections (CMEs). From a study of > 30 A GIC events, it is found that supersubstorm (SSS: SML < 2500 nT) and intense substorm ( 2500 nT < SML < 2000 nT) auroral electrojet intensifications are the most frequent (76%) cause of all of these GIC events. These events occur most often (76%) in superstorm (SYM-H 250 nT) main phases, but they can occur in other storm phases and lesser intensity storms as well. After substorms, PPs were the most frequent causes of Mäntsälä GIC > 30 A events. Forward shocks were the third most frequent cause of the > 30 A events. Shock-related GICs were observed to occur at all local times. The two “Halloween” superstorms of 29–30 and 30–31 October 2003 produced by far the greatest number of GICs in the interval of study (9 > 30 A GICs and 168 > 10 A GICs). In the first Halloween superstorm, a shock-triggered SSS (SML < 3548 nT) caused 33, 57, 51 and 52 A GICs. The 57 A GIC was the most intense event of the superstorm and of this study. It is possible that this SSS is a new form of substorm. Equally intense magnetic storms were also studied but their related GICs were far less numerous and less intense.


Introduction
Geomagnetically induced currents (GICs) are currents induced in the solid Earth or in conductors on the Earth's surface by sudden, intense currents flowing in space plasmas. Such a phenomenon was noted a century and a half ago when the deflection of telegraph magnetic needles of the Midland Railroad (England) was observed to be coincident with auroral sightings (Barlow, 1849). Currents were noted to flow even when the batteries were not connected. More recently Campbell (1980) observed electric currents flowing in the Alaska oil pipeline and deduced that the source was the auroral electrojet current (a midnight sector current flowing in the ionosphere at 100 km altitude with intensities of up to and possibly greater than 10 6 A). This paper was motivated by the extensive GIC data set existing for the natural gas pipeline near Mäntsälä, Finland (57.9°N geomagnetic latitude; 60.6°N geographic latitude, 25.2°E geographic longitude: Pirjola & Lehtinen, 1985;Pulkkinen et al., 2001;Viljanen et al., 2006). Viljanen et al. (2010) performed a nice 11-year study on this data set for GIC > 5 A events during magnetic storm intervals. The purpose of this present paper is to identify for the first time the interplanetary, magnetospheric and ionospheric phenomena time-coincident with intense Topical Issue -10 years of JSWSC > 10 A and > 30 A Mäntsälä GIC events over a 21-year interval, from 1 January 1999 to 31 December 2019. This paper is intended to be a top-level survey, to identify the possible relationship between Mäntsälä intense GIC events and interplanetary time-coincident features. We will also identify the Mäntsälä GIC relationships with magnetic storms and substorms (which are causes by interplanetary magnetic field (IMF) southward component Bs) to obtain information about the relationship between the intensity of the GICs and the intensities of the magnetospheric and ionospheric activity.
We caution the reader that Mäntsälä is located at subauroral (57.9°magnetic) latitudes, so the interplanetary and magnetospheric causes of GICs at auroral latitudes, mid-latitudes, and equatorial latitudes might be different. Similar studies on other data sets will be needed to determine the causes of GICs at these other regions of the Earth.
Why are we performing this study? All GIC events on Earth are believed to be ultimately related to interplanetary drivers. The dB/dt events that cause Mäntsälä GICs could also cause GICs in other subauroral systems. Of course, the GIC intensities for the other subauroral systems will be different (owing to different physical layouts, ground conductances, etc.), but statistically the physical interplanetary causes may be the same. A survey of this type has never been performed before. It will be shown that new, important potential causes of GICs at Mäntsälä will be discovered.
2 Databases, methods of analyses, and related background space plasma observations

GIC data
This study was undertaken using the current intensity measurements taken from the natural gas pipeline near Mäntsälä, Finland (57.9°N geomagnetic). See Pulkkinen et al. (2001) and Viljanen et al. (2010) for more details. Viljanen et al. (2010) have indicated that the Mäntsälä GIC measurement noise level is about 1 A. The measurements were taken at 10 s intervals and for this study, we examine only the largest events with intensities of 10 A (and also 30 A) current or greater. The study covers an interval of time from 1 January 1999 to 30 December 2019, almost two full solar cycles. Event intervals with GICs larger than 10 A (and 30 A) are recorded and are discussed in the Appendix. All of the GIC event data have interplanetary and geomagnetic activity data superposed, and are shown as figures in the Appendix. The GIC data are available from the Space and Earth Observation Centre of the Finnish Meteorological Institute (https://space.fmi.fi/gic/index.php). The solar wind and geomagnetic activity data are discussed separately, below. Figure 1 shows the Mäntsälä GIC data availability over the study interval as a function of solar activity cycle phase. The top panel is the solar F10.7 radiation intensity in solar flux units (sfu) as a function of year (bottom panel, horizontal axis), indicating the phase of the solar cycle. 1999 is in the ascending phase of solar cycle 23 (SC23) and 2019 is in the minimum phase between SC24 and SC25. The bottom panel shows the Mäntsälä data availability with the universal time (UT) given as the vertical axis. Smoothing was performed to give a general indication for the reader. The legend is given on the right. It can be noticed that during the year 2014-2015 where the coverage was "low", there were still over 30,000 10 s GIC data intervals available. The top coverage occurred between 2007-2013 and 2016-2019 with over 100,000 10 s intervals at all UTs. The difference between year 2014 and 2015 and the maximum coverage is only a factor of 3 times. We conclude that the GIC data coverage at Mäntsälä over the interval of study was quite good.
For our study, Mäntsälä GIC data was available for 128,506 h out of 184,080 h possible (21 years), or 69.8% of the time. We have used cutoff intensities of > 10 A and > 30 A for this present study. There were 605 > 10 A and 21 > 30 A GIC events found in this study.
The Mäntsälä GICs were noted to develop with time. GIC events could be as short as 20 s and as long as 13 min. The average duration was~2 min. In this paper we plot the event at the time of the peak intensity, rounded to the nearest minute.

Solar wind data
The solar wind and IMF data (1 min time resolution) were obtained from the OMNI website (https://omniweb.gsfc.nasa. gov/). The solar wind data for the 29-30 October and 30-31 October 2003 "Halloween storms" were obtained from R. Skoug and were used in the Mannucci et al. (2005) paper. The magnetic field components are given in geocentric solar magnetospheric (GSM) coordinates.

Geomagnetic activity data: magnetic storms
The geomagnetic SYM-H and Dst indices were obtained from the World Data Center for Geomagnetism, Kyoto, Japan (http://wdc.kugi.kyoto-u.ac.jp/). The 1 min average SYM-H indices and the 1 h Dst indices will be used to identify magnetic storm occurrences and intensities.
Magnetic storms are identified by the criteria SYM-H À50 nT (Gonzalez et al., 1994). For each magnetic storm that occurred related to Mäntsälä GIC events > 10 A, the peak storm intensity (to the nearest nT) will be given. In addition, we will identify superstorms with SYM-H À250 nT (Tsurutani et al., 1992;Gonzalez et al., 2007;Echer et al., 2008a;Meng et al., 2019) to indicate a higher-level cutoff of storm intensity. Superstorms will be shown to play a major role with the production of GICs.
The causes of magnetic storms have been well established to be due to the process of magnetic reconnection between southward IMFs (Bs) and the northward magnetic fields of the Earth's dayside magnetopause (Dungey, 1961) and the formation of a magnetospheric ring current (Williams, 1985;Daglis et al., 1999). This relationship between the IMF Bs and magnetic storms has been well documented in the literature (e.g., Gonzalez & Tsurutani, 1987;Tsurutani et al., 1988;Gonzalez et al., 1989Gonzalez et al., , 2007Zhang et al., 2007;Echer et al., 2008b;Meng et al., 2019) and will be noted in the examination of magnetic storm events.
IMF northward (Bn) turnings cause cessation of ongoing geomagnetic activity and lead to geomagnetic quiet conditions (Tsurutani & Gonzalez, 1995;Du et al., 2008). Several of the latter cases will be noted in the results of this paper.

Geomagnetic activity data: substorms
The geomagnetic AL and AU indices were obtained from the World Data Center for Geomagnetism, Kyoto, Japan (http:// wdc.kugi.kyoto-u.ac.jp/). The 1 min average,~12 station AL and AU indices are located near the auroral oval and are best used to identify substorms during relatively low to moderate level geomagnetic activity.
The 1 min average SML and SMU indices were taken from the SuperMAG network (http://supermag.jhuapl.edu/). These indices are based on~300 ground-based magnetometers and give much finer spatial scale resolution plus subauroral latitudinal coverage. The SML and SMU indices are particularly useful during magnetic storms when auroras occur at locations below the auroral oval (at midlatitudes).
Isolated substorms, those that occur outside of magnetic storms have been shown to be caused by IMF Bs intervals (Tsurutani & Meng, 1972;Meng et al., 1973). The IMF Bs turnings led to substorm onsets and subsequent IMF Bn turnings led to substorm terminations. What is the difference between IMF Bs for substorms and the much larger magnetic storms? The IMF Bs for isolated substorms were of a shorter-duration (~30 min to~1 h compared to~1 h to~3 h) and of lower intensities (~5 to~10 nT in comparison to~20 to~100 nT).

Interplanetary shocks
Interplanetary fast forward shocks ("shocks") will be identified by their abrupt increases in solar wind velocity (Vsw), density (Nsw), temperature (Tsw), and IMF magnitude (Bo). Interplanetary fast reverse shocks are noted by their abrupt increases in Vsw and simultaneous decreases in Nsw, Tsw and Bo (Kennel et al., 1985;Stone & Tsurutani, 1985;Tsurutani & Stone, 1985;Tsurutani et al., 2011). To identify the properties of the shocks (quasi-parallel: Kennel et al., 1984a, b or quasiperpendicular, Mach number, ram pressure), detailed high resolution upstream and downstream plasma and magnetic field properties must be used to identify the shock normal direction relative to the upstream magnetic field and the Rankine-Hugoniot relations to obtain the shock Mach number. These detailed calculations will be foregone for the present. In this study we will tentatively identify shocks by their jump conditions alone. A more detailed study of shocks and their GIC effects will be postponed for a second, follow-up study. Why is it necessary to eventually identify shocks using the Rankine-Hugoniot conservation equations? One objective is to separate shocks from other features such as waves and tangential discontinuities (TDs). Possible density changes across TDs or compressive waves can also produce magnetospheric compressions or rarefactions.
Compression of the magnetosphere/magnetotail by interplanetary shocks can cause the triggering of substorms in the nightside magnetosphere. These triggered substorms can be particularly intense (Hajra & Tsurutani, 2018). For this reason, in the text that follows and in the Appendix, we have given the UT of the shocks. The local time (LT) of Finland is UT + 3 h. Thus, one can determine the LT of Mäntsälä when the shock impingement occurred on the magnetosphere. At this time we do not know whether the shock created the GIC or whether the sharp onset of the substorm triggered by the shock caused the GIC. This topic is delayed for a future study.

Interplanetary PPs (High-Plasma Densities:
ICME loops? and filaments?) Interplanetary high plasma density features of the plasma parcels (PPs) impacting the magnetosphere/magnetotail will have the same effect as interplanetary shocks. They will compress the magnetosphere and magnetotail.

Interplanetary sheaths
The sheath upstream of an interplanetary coronal mass ejection (ICME) is composed of slow solar wind plasma and magnetic fields that have been compressed, heated and swept up by the shock (Tsurutani et al., 1988). This sheath plasma and magnetic fields are therefore totally different than the ICME plasma and magnetic fields. The sheath will be referred to separately in this paper. We have also identified geoeffective solar wind events that do not have shocks. We have called these upstream regions "pileup" events without examining them in further detail here.

CMEs and their parts (loops, MCs and filaments)
A CME at the Sun has three parts: a bright outer loop, a dark region and a filament (Illing & Hundhausen, 1986;Chen, 2011). We distinguish interplanetary CMEs (ICMEs) from solar CMEs because not all three parts of a solar CME reach the Earth. In this study we have identified primarily ICME magnetic clouds (MCs; Burlaga et al., 1981) as being geoeffective and causing magnetic storms. Farrugia et al. (1997) and Tsurutani & Gonzalez (1997) have argued that the MC portion of an ICME is the dark region of a CME detected near the Sun. In this study we use the criterion of low plasma b (the ratio of the plasma thermal pressure to the magnetic pressure) to identify MCs.
Another feature of ICMEs at 1 AU are high density loops and filaments. The bright outer loop plasma and magnetic field data were identified at 1 AU by Tsurutani & Gonzalez (1995) and Tsurutani et al. (1998a). ICME filament high plasma densities were first identified in interplanetary data at 1 AU by Burlaga et al. (1998). It is possible that the high-density PPs identified in this study causing GICs are loops and filaments. Figure 2 shows the solar wind parameters, IMF and geomagnetic activity indices in the top 11 panels. The Mäntsälä GIC data is shown in the bottom panel. The parameters given in the various panels are identified in the figure caption. There is a shock at~0612 UT on day 302 indicated by the vertical black dashed line.

Results
The SYM-H index shows that this was a double dip main phase superstorm with a peak intensity of À390 nT at~0148 UT on day 303. The partial cause of the first dip in the magnetic storm was the negative Bz (IMF Bs) just prior to and just after the shock (see blue trace). That and the energetic plasma injection due to the SSS (note the intense negative SML and AL at the shock; to be discussed below) triggered by the shock caused the first dip storm. This magnetic storm (and the SSS) occurred during the interplanetary sheath region of the event, from the shock at~0612 UT until~0938 UT. After the termination of the sheath, a MC follows. The MC ends at~0244 UT on day 303. The MC Bz component is first positive (IMF Bn) and then negative (IMF Bs), consistent with a giant magnetic flux rope (Burlaga et al., 1981). The IMF Bs of the MC starts at 1436 UT on day 302 and ends at~0210 UT on day 303. The IMF Bs causes the second and major dip of the magnetic storm. The shock occurred at the same time as a GIC peak of 25 A. Mäntsälä was at~0912 LT (morning sector) at the time of the event. The shock also triggered a sharp onset of a two-peak SSS that lasted from~0613 UT to~0752 UT. The two peaks had intensities of SML = À3177 nT at 0624 UT and À3548 nT at 0648 UT, respectively. Associated with the first SSS were 4 GICs of intensities > 30 A. The 30 A level is indicated by a horizontal red line. The GIC intensities and times were: 33 A at 0646 UT, 57 A at 0657 UT, 51 A at 0703 UT and 52 A at 0727 UT. The SSS peaks occurred when SYM-H was +13 nT (the SYM-H index was not pressure corrected).
Note that enhanced GIC activity (< 10 A) is present throughout the entire~21 h of the superstorm. Strong GIC activity extends from the beginning of the storm main phase to the start of the storm recovery phase. There are 168 GIC events with intensities > 10 A in the two main phases of this double dip storm. However, the most intense GIC events occurred in the first SSS immediately after the shock.
We point out several more GICs with intensities > 30 A. There is a GIC of 30 A at 2230 UT (0130 LT) near the maximum of the second dip of the superstorm. This GIC is associated with an intense substorm of SML = À2340 nT. There is a 36 A GIC at 0110 UT (0410 LT) on day 303 at the start of the second dip storm recovery phase. There is no obvious substorm relationship for that event.
The 29-30 October 2003 Halloween superstorm had the greatest number of GICs > 10 A (168) in the 21-year data study. These two days of a superstorm also had the greatest number of GICs > 30 A (6) in the study. The 57 A GIC at 0657 UT on day 302 was the most intense GIC detected in this study. Figure 3 shows the second Halloween magnetic storm on days 303-304 of year 2003. A sheath Bs upstream of an ICME causes a superstorm of intensity SYM-H = À432 nT. A solar wind density spike (PP) at~1949 UT (2249 LT) caused a SI + of 61 nT and triggered a short duration SSS of SML = À3872 nT. A GIC of 49 A occurred at the time of the shock/SSS onset.
A second short duration SML = À2724 nT SSS occurred in the storm main phase. It is associated with a double GIC event with peaks of 33 A and 27 A. There are two clusters of GICs with > 10 A intensities in the storm recovery phase. They are associated with substorm intervals of peak SML intensities of À1821 nT and À797 nT, respectively. In the first cluster there is a GIC of 30 A at 0213 UT on day 304. In the second cluster B.T. Tsurutani and R. Hajra: J. Space Weather Space Clim. 2021, 11, 23 there is a 27 A GIC at 0536 UT on day 304. There is another GIC cluster, well after storm recovery, with 16 A at 1119 UT, 19 A at 1152 UT, 14 A at 1227 UT and 16 A at 1246 UT on day 304.
There were 90 GICs with > 10 A intensities on day 304. There were 3 GICs with > 30 A intensities. This second Halloween storm had the second-most GICs in the 21-year study. It should be noted that this second Halloween superstorm had a higher SYM-H peak intensity than the first superstorm, but had fewer GICs in both intensity categories. Figure 4 shows a magnetic storm with peak intensity SYM-H = À319 nT associated with a complex corotating interaction region (CIR;Smith & Wolfe, 1976;Tsurutani et al., 1997Tsurutani et al., , 2006. The peak in the storm intensity occurred at 0011 UT on day 98. An IMF Bs of intensity~27 to~32 nT was present from the shock (denoted by the vertical black dashed line) to the CIR interface at~2316 UT day 97. This Bs caused the main phase of the storm. The strong shock at~1643 UT (1943 LT) created only a sublevel GIC event. Mäntsälä was in the dusk-midnight sector at the time of shock impingement.
The shock also triggered a long-duration intense substorm with peak SML intensity of À2314 nT. A 20 A GIC occurred at the substorm peak.
A short-duration substorm of SML = À1844 nT at 2328 UT (day 97) is associated with a GIC intensity of 23 A.
The substorm spike is not present in the AL index, indicating that either the substorm was located at latitudes below Mäntsälä or that the substorm occurred at a longitude between the widely separated AL index stations. The substorm is coincident in time with an increase in solar wind ram pressure from~9.5 tõ 25.6 nPa. There were 16 GICs >10 A intensities that occurred during these two days. Figure 5 shows an interplanetary sheath Bs causing a SYM-H = À176 nT magnetic storm. The storm peak occurred at 2104 UT day 311. The shock is indicated by a vertical black dashed line at 0958 UT (1248 LT). The shock did not cause a GIC above the study threshold. Mäntsälä was in the noon sector at the time of shock arrival.
A 19 A GIC occurred at~1807 UT on day 311 time-coincident with a solar wind PP with density Nsw = 33 cm À3 (shown by a vertical red dashed line). The upstream solar wind density prior to the PP was~5 cm À3 , so the ram pressure increase across the PP was a factor of~6.6 times. This PP may be a coronal loop carried out to 1 AU. Such a high level of ram pressure increase is greater than most shock compressions. This GIC event is the largest for this interplanetary interval. Mäntsälä was in the dusk-midnight sector at the time of the GIC. There were only 3 GICs with > 10 A intensities on these two days.
In Figure 6, the sheath Bs ahead of an ICME caused a magnetic storm of intensity SYM-H = À101 nT. The MC within the ICME had Bz~0 nT, so it made the storm only slightly more  B.T. Tsurutani and R. Hajra: J. Space Weather Space Clim. 2021, 11, 23 intense. The storm peak occurred at~0612 UT on day 22. There were 12 GICs with > 10 A intensities in these two days.
A strong shock at 1702 UT (2012 LT) on 21 January is denoted by a vertical black dashed line. The shock triggered a sharp onset of a SSS with peak SML value of À4418 nT. The shock or the SSS onset caused a GIC of 13 A. Mäntsälä was in the dusk-midnight sector at the time. During the decay phase of the SSS there was a large cluster of GICs reaching a peak intensity of 27 A at~1910 UT. The peak GIC occurred at the same time as a sharp interplanetary density spike (PP) with a peak density of 55 cm À3 . The upstream density was~11 cm À3 , thus the ram pressure increases was~5 times. This is another example of an abrupt solar wind density increase causing an intense GIC.
There is another GIC of intensity 22 A at~2015 UT on day 21. There is no obvious interplanetary phenomenon that appears to be the cause. There is no substorm feature at this time.
Following the 22 A GIC is a PP at~2052 UT. This is associated with a heliospheric current sheet (HCS) crossing (Smith et al., 1978). The HCS is identified by sharp reversals in the sign of both IMF Bx and By components. This causes a GIC but below the 10 A threshold of this study. Figure 7 shows a different type of interplanetary event than the previous examples. This is a "slow" ICME where the peak solar wind speed Vsw is only~520 km s À1 (such slow ICMEs have been noted before: Tsurutani et al., 2004). There is no shock and sheath ahead of the ICME, but there is a "pileup" region there. The Bs in the pileup region causes a moderate magnetic storm of SYM-H peak = À61 nT. The MC Bz = 0 nT causes the lengthening of the storm main and recovery phases. During the storm main phase there are substorms with a peak SML value of À848 nT. There are no GICs above study threshold in this time interval.
An intense GIC of 20 A occurs at~1924 UT on day 58. The cause of this is a sharp change of the IMF orientation from a Bs direction to a Bn direction (a Bn turning). This occurs at the boundary between the pileup region and the MC (Bn fields). There is also a solar wind ram pressure decrease at that time associated with the low plasma b of the MC. The IMF Bn turning terminates the substorm activity, so there is no substorm associated with this event. Figure 8 shows another different type of solar wind event, that of an interval of low solar wind speed Vsw with a peak value of only~420 km s À1 . There is no shock/sheath, ICME (MC or filament), CIR or HSS involved in this event. Embedded within the low-speed solar wind is a long period Bz wave where the IMF Bs reaches~23 nT. This southward IMF leads to a SMY-H = À153 nT magnetic storm. The storm peak occurs at~1253 UT on day 274. There were 13 GICs with > 10 A intensities in these two days.
Throughout the relatively long main phase of the magnetic storm and in the beginning of the recovery phase, there is high and continuous substorm activity, noted by the SML indices. A double GIC event of 28 A and 19 A intensities occurs at  B.T. Tsurutani and R. Hajra: J. Space Weather Space Clim. 2021, 11, 23 ~1629 UT and 1647 UT, respectively. This double GIC is associated with a short duration substorm spike of SML = À1906 nT. This occurred in the beginning of the storm recovery phase. There is no obvious interplanetary cause of this substorm. There is no particular IMF Bs or Bn turnings or Nsw features present at this time.

Analyses using all GIC > 10 A events
The Appendix shows all of the GIC > 10 A data in 48 plots (Figs. A1 through A48) and summaries. We use this full set of data to obtain some pertinent statistical information.
Almost all of the 48 event intervals were associated with geomagnetic storm intervals. About 21% were associated with superstorms (SMY-H À250 nT), 60% with intense storms (À250 nT < SYM-H À100 nT), 17% with moderate storms (À100 nT < SYM-H À50 nT), and 2% with non-storms (SYM-H > À50 nT). Although the GIC > 10 A events were generally associated with storm intervals, they were not necessarily associated with magnetic storm main phases. Examples to the contrary were shown in Figures 2 through 8. There are many such examples in the Appendix.
GICs > 10 A were found to be associated with shocks, solar wind PPs, and IMF Bn and Bs turnings/intensifications. Many of the intense GIC events were associated with two or more interplanetary features.
To better understand the subset of interplanetary shockrelated GICs > 10 A, the intensity and local times of all events are indicated in Figure 9. Local noon is at the top of the figure and local midnight at the bottom. The GIC intensity scale is given on the left. It should be noted that all shocks caused a measurable GIC at Mäntsälä (see Appendix and Figs. 2,4,5 and 6 for details), but typically below the 10 A level (there were over 300 shocks that occurred during the study interval). Events with below threshold intensities are not indicated in the above figure. Figure 9 shows that there were only 11 shock events (out of over~300) that were time co-incident with GIC events above the 10 A level at Mäntsälä. Thus, in general, shocks are not geoeffective at high levels of GIC intensities. This is currently being studied to better understand this feature.
It is noted from Figure 9 that shock-related GICs with intensities > 10 A can be detected at all local times. If only the most intense events are considered, there is a preference for morning and afternoon hours. However, it is noted that the largest event occurred near the dawn sector.

Analyses using all GIC > 30 A events
It is useful to identify the interplanetary and solar wind causes of the most intense GIC events, those with intensities of > 30 A. This value of > 30 A is an arbitrarily chosen one. Figure 10 and Table 1 give the detailed information of all Mäntsälä GICs with > 30 A intensities. There are only 21 > 30 A GIC events in the 21-year study period. Thus, these  B.T. Tsurutani and R. Hajra: J. Space Weather Space Clim. 2021, 11, 23 events are quite rare. One of these > 30 A events was related to a shock and six were related to ram pressure increases caused by PPs. Figure 10 gives the information in a graphic format and Table 1 in a tabular form. The plot format in Figure 10 is the same as for Figure 9 but here all > 30 A GICs are shown independent of whether they were shock-related or not.
The local time distribution of the GICs in Figure 10 can be viewed as having two parts. There is a broad nightside distribution centered roughly at local midnight but extending from 2000 LT to~0500 LT. One might have the suspicion that these events may be substorm-related GICs. There is also a narrow region located in the morning-noon sector,~1000 LT. These GIC events might be suspected to be PP-related events.
It should be noted that 4 of the events (with peaks 33 A, 57 A, 51 A, 52 A) at~1000 LT GIC events are those from 29 to 30 October 2003, the first Halloween storm (Table 1). These events were associated with a SSS (see Discussion of Fig. 2). How does a substorm cause dayside GIC events?
Another one of the GIC events (32 A) at~1000 LT is associated with a large solar wind PP on day 328, 2001 (see Table 1 and Fig. 3 discussion). So, we are seeing GICs (> 30 A) on the dayside associated with both substorms and PPs. It is clear that solar wind shocks and PPs could cause both dayside and nightside GICs. However, substorms causing dayside GICs are interesting and new and needs to be investigated further. Table 1 shows the details of the 21 > 30 A GIC events. The columns are, starting on the far left: the event interval (day/year), the LT, the GIC intensity, the peak magnetic storm SYM-H intensity, the related substorm peak SML intensity, and the peak solar wind density Nsw. The density value is only listed if an interplanetary PP was involved in the GIC event, thus the many blank boxes. The sixth column from the left indicates if an interplanetary PP or shock was related to an immediate GIC (a "Yes" response). If the PP or shock triggered a substorm and the substorm intensified with time and was later responsible for the GIC, a "No" is indicated. The next two columns indicate if the GIC is associated with an interplanetary sheath event or an ICME MC event.
There are several pertinent features that can be noted from the table. All of the events occurred between years from 2000 to 2004 and from 2012 to 2017. This corresponds to the solar cycle maximum to the declining phase for the first interval, and from the rising phase to the declining phase for the second interval (see the top panel of Fig. 1 for reference to solar cycle phases). About half of the GIC > 30 A events are related to sheaths upstream of ICMEs and half to MCs within ICMEs. There were no CIRs involved with these 21 intense GIC events.
Of the 21 GIC > 30 A events, 16 (~76%) were related to superstorms (SYM-H À250 nT). Sixteen (76%) of the GICs > 30 A were associated with either SSSs (SML < À2500 nT) or with intense (À2500 nT < SML < À2000 nT) substorms. There is one event associated with a shock/superstorm event (5%). The other 5 were associated with lesser intensity substorms. From all of the above, it is clear that GICs > 30 A events are associated with extremely intense magnetospheric and ionospheric geomagnetic activity.

Discussion and conclusions 4.1 Superstorms
Sixteen of the 21 Mäntsälä GIC > 30 A events were associated with superstorms (SYM-H À250 nT). This does not mean that superstorms are causing the GICs, but that the enormous solar wind energy being pumped into the magnetosphere is leading to conditions conducive for the occurrence of particularly strong substorms. The prime examples for this were the first two Halloween storms on 29-30 and 30-31 October 2003 (see also Viljanen et al., 2010 using a different data interval). Between the two superstorms, 9 GICs with intensities > 30 A and 258 GICs with intensities > 10 A occurred. These are good fractions (~43% and~43%, respectively) of all of the events detected in the 21 years of study. It should be mentioned that these were not the largest magnetic storms. There were more intense storms with far fewer and considerably lower intensity GIC events. It is noted that the EUV solar flare (28 October 2003) related to the 29-30 October 2003   Figure 9.
B.T. Tsurutani and R. Hajra: J. Space Weather Space Clim. 2021, 11, 23 Halloween storm was the most intense on record. This caused the greatest dayside flare-related ionospheric Total Electron Content (TEC) increase (~30%) on record . Mannucci et al. (2005) indicated that the 30-31 October 2003 Halloween superstorm had the largest dayside ionospheric "superfountain" uplift on record. Whether these ionospheric effects caused these two storms to have far more intense GIC events or not is unclear at this time.
Pulkkinen et al. (2005) reported high-voltage power transmission system failures in southern Sweden during the 30-31 October 2003 Halloween superstorm. The interplanetary cause of one GIC reported by Pulkkinen et al. (2005) was identified in this paper. It was a modest solar wind pressure pulse (PP) that created a large SI + in SYM-H (+61 nT), a SML = À3872 nT SSS onset and a 49 A GIC at Mäntsälä, Finland (at 2249 LT). This GIC event was reported earlier relative to Figure 3 and is shown in Figure 10. This was the largest GIC event that occurred during the 30-31 October 2003 superstorm.

Substorms, intense substorms and SSSs
When one narrows the GICs to the most intense > 30 A events (Table 1), it is apparent that substorms play a major role. It can be noted that 16 of the 21 GIC > 30 A events are associated with intense substorms with SML < À2000 nT intensities. Nine of the events were SSSs (SML < À2500 nT). Substorms with such large intensities are relatively rare. The largest GIC was 57 A and was associated with a SSS (Fig. 10).
An event not covered in this study interval was the 1989 Hydro Quebec GIC-induced power outage. The magnetic storm was of superstorm intensity (Dst = À589 nT), even larger than any of the storm events covered in this study. Boteler (2019) recently concluded that a shock-triggered SSS caused the GIC which led to the collapse of the electric power grid. Earlier it was noted that magnetic storms were caused by intense magnetic reconnection between interplanetary Bs and the Earth's magnetopause magnetic fields. In this study we have found that shock triggering of intense substorms may initiate storms as well. Nightside injection of energetic plasma deep into the

Interplanetary PPs
From Table 1, it is noted that 6 out of the 21 Mäntsälä > 30 A GICs were due to PPs. PPs being time-coincident with Mäntsälä GICs is a new discovery. PPs are the second most geoeffective interplanetary cause (after substorms) for > 30 A GICs. Why were these PPs more geoeffective than shocks? The plasma density increase across a shock is a maximum of~4 (Kennel et al., 1985), but statistically only a factor of 1-3 (Tsurutani & Lin, 1985). Several of the geoeffective PPs were noted to have considerably higher density increases than~4.
What are these interplanetary PP structures? It is possible that they are the high-density loops seen in coronagraph images when CMEs are close to the Sun. At 1 AU the coronal loops should appear between the upstream shock and the MC portion of the ICMEs. Events of this type are noted in Figures 5, A9, A18 and A32. Ion charge state analyses will be useful to verify this.
Could some of the PPs be ICME filaments? From the Lepri & Zurbuchen (2010) A16). These filaments are shaded in the corresponding figures. Neither of the two filaments were associated with specific GICs above the study threshold.
We have identified other "possible" filaments which were geoeffective in producing Mäntsälä >10 A GICs. Because the events are of short durations, they could have easily been missed in the Lepri & Zurbuchen (2010) study. These PP events occurred on the sunward side of the MCs. In the text, we have used the modifier "possible" because we have not examined ion charge states data yet. And to further complicate matters, experts indicate that some filaments may not contain definitive ionic features. So, it is possible that we will not be able to obtain a final answer, even with further study.
Since PP impingements onto the magnetosphere is the same physical mechanism (an enhanced ram pressure pulse) as interplanetary shocks (the downstream enhanced densities sunward of forward shocks), it can be expected that PPs will cause GICs in the same locations as shocks have been noted to do: auroral latitudes, midlatitudes and at the equator. Future researchers should be aware of this new development.

Shocks
Shocks played a large role in the intense GIC events at Mäntsälä. There were 11 shock-related GICs > 10 A. However only one of these had an intensity > 30 A and thus shocks are apparently the third most important phenomena (after substorms and PP events) in this highest GIC intensity category.
There were over~300 shocks identified in the study interval. It can be therefore concluded that shocks in general are not typically geoeffective at the Mäntsälä > 10 A level or > 30 A level. Of course, this is not to say that shock-induced GIC intensities could not be greater than found in this survey. Tsurutani & Lakhina (2014) have shown that considerable stronger shocks at the Earth are theoretically possible.

Final comments
In the literature, it has been assumed that dayside GICs associated with shock impingements onto the magnetosphere are due to a compressional wave propagating through the magnetosphere to the ionosphere causing dB/dt current events there (Araki et al., 1993;Tsurutani & Lakhina, 2014). However, there are other paths that the signals may take. It is known that shocks cause betatron acceleration of pre-existing dayside outer zone magnetospheric~10 to 100 keV electrons and protons, accelerate the particles primarily in their perpendicular energies, leading to plasma instabilities (Kennel & Petschek, 1966;Tsurutani & Lakhina, 1997), plasma wave generation, and dayside auroral and subauroral and conductivity enhancements (Zhou & Tsurutani, 1999;Tsurutani et al., 2001a). If dayside auroral oval electric fields exist (Maezawa, 1976), a sudden ionospheric conductivity enhancement will cause dayside GICs much in the same way that the auroral electrojet on the nightside causes GICs. Interplanetary shock impingements also trigger nightside substorms (Heppner, 1955;Zhou & Tsurutani, 2001;Tsurutani & Zhou, 2003;Hajra & Tsurutani, 2018). So, at the present time if a shock impinges upon the magnetosphere and a GIC occurs at the same time, we are not certain which particular physical mechanism caused the GIC.
What is it about the auroral electrojet or auroral particle precipitation that causes the dB/dt at the surface of the Earth? Is it a rapid spatial motion of the electrojet current overhead? Or is it a sudden increase or decrease of that current (note that sudden current decreases also cause a dB/dt)? Or could it be due to sudden magnetic field-aligned precipitation of electrons or protons into the auroral ionosphere? Substorms involve rapid plasmasheet injections, more spatially limited than that during magnetic storms (Tsurutani & Gonzalez, 2007). This injection can cause Pc5 and Ps6 pulsations. Which of these possibilities are the causes of GICs? At this time, we do not have answers. Possibly all of the above! And perhaps the causes are different for different substorm GIC events. To obtain definitive answers would require both detailed local magnetic field measurements and auroral all sky images to identify the dB/dt causes. This is beyond the scope of the present paper, but has been mentioned for readers interested in doing such detailed studies in the future.
In a converse sense we do not know how the nightside auroral ionospheric currents are connected to the dayside ionosphere. It has been shown that during HILDCAA (high-intensity long-duration continuous auroral activity, Tsurutani & Gonzalez, 1987) not only are the nightside and dayside auroral zones connected but there are auroras over the polar caps as well (Guarnieri, 2006;Guarnieri et al., 2006a, b). Plasma waves in the polar cap boundary layer show a continuous, unbroken oval circulating the magnetic pole (Tsurutani et al., 1998b(Tsurutani et al., , 2001b. Thus, does it make sense that a SSS originating on the nightside might expand and cause a GIC at~1000 LT on the dayside? Or is it possible that the auroras and the electrojet were only present at 1000 LT for the 29-30 October 2003 SSS? Zhou & Tsurutani (2004) noted dawn and dusk auroras during a high-speed solar wind stream. They suggested a mechanism of the Kelvin-Helmholz instability instead of magnetic reconnection for the solar wind energy input into the magnetosphere. Figure 11 shows the equivalent ionospheric currents flowing at~100 km altitude in the northern hemisphere at 0657 UT on B.T. Tsurutani and R. Hajra: J. Space Weather Space Clim. 2021, 11, 23 29 October 2003, corresponding to the~57 A GIC at Mäntsälä (0957 LT). Strong currents of~3000 A km À1 can be noted around Mäntsälä (60.6°N, 25.2°E geographic) during the GIC peak occurrence.
What is particularly striking about the~57 A GIC event (and other > 30 A GICs during the first SSS of the 29 October 2003 superstorm) was that the GIC occurred when Mäntsälä was on the dayside (see discussion with Fig. 10)! This is not our traditional view of the Akasofu (1964) picture of substorms being confined to the midnight sector.
We mention that for a related event, a shock-triggered SSS (SML = À4418 nT) occurring on 21 January 2005, Hajra & Tsurutani (2018) showed that there was a general lack of auroral forms in the midnight sector, and intense auroras at dusk and at dawn. Unfortunately, the images did not go beyond dawn (in Fig. 2 of that paper). Figure 11 above clearly shows strong ionospheric currents flowing on the dayside during the 29 October 2003 SSS at 0657 UT that are most probably related to the intense GIC. It is possible that this may be a new type of "substorm".
As previously mentioned, this paper is intended to be only a top-level survey. Much more detailed work is needed to understand the details of the physical causes of GICs. We hope, the reader will be encouraged to carry out such studies.
For pipeline mitigation techniques at auroral latitudes, we quote Campbell (1980) concerning the Alaska pipeline: "Pipe corrosion occurs at the underground, exposed pipe points of coating holes and scratches where current can enter or leave the pipe. Such corrosion is proportional to the current density through the exposed points and decreases with the period of the current variation. The Alaska oil pipeline has been protected with sacrificial zinc electrodes that ground the pipe at regularly spaced intervals along the underground route to bleed the current away from the holes in the pipe coating." The Finnish natural gas pipeline mitigation technique is the same, using sacrificial electrodes (Pirjola & Lehtinen, 1985). For the Maritimes and Northeast pipeline in New England, they have used a slightly different technique because of the high resistivity of the soil in that region (Rix & Boteler, 2001). They have used "impressed current type cathode protection rather than passive anodes". From reading some of the current literature (see Gummow & Eng, 2002;Popov & Lee, 2018;Googan, 2020), it seems that both of these techniques work quite well. Concerning more equatorward latitude pipelines, during magnetic storms the electrojet comes down to midlatitudes. Fortunately, these events do not occur very often and when they do, they only last from a few hours to a few days (Gonzalez et al., 1994). Pipelines at subauroral latitudes are not nearly as vulnerable to magnetic storms as are electrical power systems.
Some pertinent comments from previous publications should be given to the readership concerning superstorms. It has been argued in Tsurutani et al. (2020) that it would take a very fast CME to cause a magnetic storm of the intensity of the Carrington 1-2 September 1859 storm (Tsurutani et al., 2003). The Carrington storm had an estimated intensity of Dst~À1760 nT, the largest in recorded history and~3 times larger than the 1989 Hydro Quebec power outage. The transit time for the CME to go from the Sun to Earth was~17 h 40 min (Carrington, 1859). Thus Tsurutani et al. (2020) indicated that CME transit times less than 24 h would be most important for events of this type. We have identified the transit time of the 29-30 October 2003 CME. The elapsed time from observing the halo CME near Sun at 1130 UT on 28 September (https://cdaw.gsfc.nasa.gov/CME_ list/UNIVERSAL/2003_10/univ2003_10.html) to the detection of the fast forward shock at the Earth's bow shock nose at 0612 UT on 29 September, is~19 h. Thus, it seems that CMEs with transit times of <~24 h will be particularly geoeffective in causing GICs at subauroral latitudes. However as shown in the statistical results of this papers GICs at Mäntsälä and storm intensities do not have a one-to-one relationship. The general relationship is, however, good enough to use for forwarnings of possible GIC events. At this time we do not have enough knowledge to make more concrete predictions.
As mentioned previously, this paper is intended as a "toplevel" survey. No effort was made to understand the "details" of the physical causes of GICs. To state that a "shock", a "magnetic storm", "a supersubstorm (SSS)" or "a plasma parcel (PP)" caused or was related to a GIC, is not a detailed understanding of the dB/dt that caused a particular GIC. More work needs to be done. But this indeed can be exciting for the young, energetic researchers who wish to make progress in this important field. The solar wind and interplanetary magnetic field data were obtained from the OMNI website (https://omniweb.gsfc.nasa. gov/). The solar wind data for the 29-30 October and 30-31 October 2003 "Halloween storms" were obtained from R. Skoug. The geomagnetic SYM-H, Dst, AL and AU indices were obtained from the World Data Center for Geomagnetism, Kyoto, Japan (http://wdc.kugi.kyoto-u.ac.jp/). The SML and SMU indices were taken from the SuperMAG network (http://supermag.jhuapl.edu/). Ionospheric equivalent currents were obtained from the International Monitor for Auroral Geomagnetic Effects (IMAGE) of Space and Earth Observation Centre, Finnish Meteorological Institute (https:// space.fmi.fi/). The editor thanks two anonymous reviewers for their assistance in evaluating this paper.

Appendix
In the narrative below, we discuss the interplanetary and magnetospheric/ionospheric features time-coincident with the Mäntsälä, Finland geomagnetically induced current (GIC) events with intensities > 10 A. We show the interplanetary data so that the readership can note the relationship between GICs >10 A and their interplanetary causes. The figures and related text will also describe the Mäntsälä GICs in relation to geomagnetic storm and substorm activity. Many of the GIC events occur before, during, or after magnetic storms, so a broad swath of relevant interplanetary data is shown for each event.
Day 13 (13 January), 1999 (Fig. A1). A CIR caused double dip storm with SYM-H peak value of À111 nT. The two longduration substorms caused the double dip storm. There is a small sublevel GIC with the forward shock which occurred at 1054 UT (1354 LT). At the time Mäntsälä was in the afternoon sector. A sharp Bs increase caused the second dip of the storm and a SML = À1189 nT peak long-duration substorm. A GIC cluster with 10 A and 13 A peak intensity events occurred near the end of the substorm with a sharp SMU increase to 469 nT. The storm recovery phase begins after this last substorm.
Day 49 (18 February), 1999 (Fig. A2). Double dip magnetic storm of intensity SYM-H = À128 nT (in first dip). The storm is caused by the sheath Bs. The MC causes the second storm dip. A shock occurred at~0247 UT (0547 LT) and caused a sublevel GIC. At the time Mäntsälä was in the dawn sector. There was a GIC cluster with peak 12 A event at the beginning of the storm second dip recovery phase. The GIC cluster was associated with a substorm with intensity SML = À1604 nT.
Days 265-266 (22-23 September), 1999 (Fig. A3). Two shocks, two sheaths, and a MC event. The second sheath Bs caused both a storm of intensity SYM-H = À166 nT and a long-duration substorm of SML = À1608 nT. The shocks at 1223 UT (1523 LT) and~1942 UT (2242 LT) created sublevel GIC events. At the times of the two shocks Mäntsälä was in the afternoon and midnight sectors, respectively. Although the second sheath Bs appears to have caused the magnetic storm, the substorm may have contributed greatly. A cluster of GICs is related to the substorm but there is only one event above threshold, 11 A. The GIC cluster occurs during the storm main phase and the start of the recovery phase (at the end of the substorm).
Days 97-98 (6-7 April), 2000 (Fig. A4). This event was previously discussed in Results section (Fig. 4). A complex CIR associated superstorm with peak intensity SYM-H = À319 nT at~0011 UT day 98. There was a~constant Bs of intensity~30 nT from the shock to the CIR interface at 2316 UT day 97. The shock triggered a long-duration intense substorm with peak SML intensity of -2314 nT. This intense substorm contributed to the storm initial intensification. The strong shock at~1643 UT (1943 LT) created a sublevel GIC event. Mäntsälä was in dusk sector at the time. A 20 A GIC occurs at the substorm peak several hours later. A second peak GIC of 23 A was associated with a short duration substorm of SML = -1844 nT intensity at 2328 UT day 97 in the storm main phase. This substorm spike was not present in the AL indices. The substorm is coincident in time with a solar wind ram pressure increase to~26 nPa. The high solar wind densities on the B.T. Tsurutani and R. Hajra: J. Space Weather Space Clim. 2021, 11, 23 solar side of the interface of the CIR is unusual. 16 > 10 A GICs occurred during this interval.
Day 145 (May 24), 2000 (Fig. A5). A complex CIR causes a magnetic storm of peak intensity SYM-H = À173 nT. The main phase of the storm is caused by a long-duration intense substorm with SML = À2121 nT peak intensity. The substorm causes a GIC cluster with two events of 10 A and 11 A intensities. , 2000 (Fig. A6). A SYM-H = À347 nT superstorm caused by Bs fields in the upstream sheath and following MC Bs fields. A 16 A GIC is associated with the shock/short-duration SML = À2112 nT intense substorm (the shock is noted by a SI + of 84 nT at~1439 UT (1739 LT) (the interplanetary data is low resolution for this part of the event). At the time of the shock, Mäntsälä was in the dusk sector. There are many more intense substorms after the shock but no corresponding GICs above the study threshold. The biggest GIC spike of 30 A occurs in beginning of the storm main phase and the decay phase of a short-duration SSS of SML intensity À3077 nT at 1901 UT (2201 LT). Mäntsälä was in the duskmidnight sector at the time. In the storm recovery phase, there is a 17 A GIC associated with a SML = À1033 nT substorm. There were 30 >10 A GICs during this event. At~1200 UT day 198, there is an ICME filament indicated by the vertical shading. It is associated with small GICs below the study threshold.
A long-duration intense substorm of SML = À2216 nT (or the Bs) caused the storm main phase and also a GIC cluster with 2 peak intensities of 13 A and 14 A. A GIC of intensity 15 A occurred at the end of the intense substorm, coincident with an IMF Bs-to-Bn turning. GICs of 13 A at 0342 UT (0642 LT) and 13 A at 1001 UT (1301 LT) on day 262 were present in the storm recovery phase. Both were not associated with any obviously related substorm or interplanetary feature.
Days 278-279 (4-5 October), 2000 (Fig. A8). Two shocks and two sheaths caused a SYM-H = À187 nT triple dip storm. The weak shock at~1413 UT (1713 LT) and pre-existing Bs fields formed the first À185 nT storm. The shock created a substorm of intensity SML = À1435 nT and a GIC of sublevel intensity. The second shock occurred at 0326 UT (0626 LT) on day 279 and caused a sublevel GIC. The second sheath Bs interval creates a SYM-H = À187 nT storm and a substorm of SML = À1947 nT. A second interval of sheath IMF Bs created a SSS of SML = À2787 nT and the third (but lesser) dip of the storm. The SSS does not cause a GIC with intensities above threshold. In the storm recovery phase, there is a short-duration substorm with SML peak intensity of only À1158 nT that causes a double GIC of 13 A and 11 A intensities. This substorm is not apparent in the AL index.
Days 311-312 (6-7 November), 2000 (Fig. A9). This event was previously discussed in Results section (Fig. 5). A constant Bs in a sheath caused a SYM-H = À176 nT magnetic storm with peak at~2104 UT day 311. The strong shock at~0948 UT (1248 LT) did not cause a GIC above study level threshold. Mäntsälä was in the noon sector at the time of the event.   Figure A1. B.T. Tsurutani and R. Hajra: J. Space Weather Space Clim. 2021, 11, 23 A 19 A GIC occurred in the storm main phase with no apparent strong substorm relationship. An unusual sharp short-duration PP of 33 cm À3 is related to the GIC. This increased the solar wind ram pressure by a factor of 6.6 times. This PP may be a coronal loop that has propagated to 1 AU.
Day 315 (10 November), 2000 (Fig. A10). A high-speed (Vsw = 920 km s À1 ) sheath and intermittent Bs fields caused a SYM-H = À105 nT magnetic storm. An interplanetary shock at~0629 UT (0929 LT) ahead of an ICME triggers a 10 A GIC spike. Only a moderate intensity substorm was triggered by the shock. Mäntsälä was in the morning sector at the time of the shock. There were no GICs above threshold during the storm main phase. A MC followed the sheath but it had Bn fields and thus leads to the storm recovery phase.
Day 78 (19 March), 2001 (Fig. A11). A double magnetic storm of peak intensity SYM-H = À164 nT is caused by a sheath (first dip) and MC (second dip). There is a 16 A GIC in beginning main phase of the storm. The GIC occurred during the decay of a Nsw = 33 cm À3 solar wind density spike. There is no particularly strong substorm relationship. This GIC event does not have an obvious interplanetary or magnetospheric cause.
Day 90 (31 March), 2001 (Fig. A12). A superstorm of SYM-H = À437 nT was caused by sheath fields ahead of an ICME (whose MC Bs caused a second, less intense storm of SYM-H = À269 nT). The shock at~0101 UT (0401 LT) triggered a short-duration substorm of SML = À1541 nT and a GIC below threshold. Mäntsälä was in the midnight-dawn sector at the time. Two GICs with~14 A intensities occurred in the initial phase before the storm main phase. These were associated with substorm activity. A 12 A GIC event occurred in the storm main phase. All 3 GIC events were associated with substorm activity. In the second, lesser intensity storm, there are 3 large sharp onset substorms of peak intensities SML = À2459, À1721 nT and À1404 nT. The first substorm event caused a 13 A GIC. The second and third substorm-related GICs had intensities of 16 A and 13 A.
Day 101-102 (11-12 April), 2001 (Fig. A13). A shock and sheath with intermittent Bs ahead of a MC caused a superstorm main phase of SYM-H = À280 nT. The MC begins with intense IMF Bs which may contribute to the peak of the storm main phase. The shock at~1345 UT (1645 LT) triggers a SSS of SML = À2923 nT intensity but there is no GIC above the 10 A threshold. Mäntsälä was in the afternoon-dusk sector at the time. A GIC of 18 A occurs at the beginning of the storm main phase and occurred in a substorm-intense interval. A 22 A GIC occurred later in the storm main phase and is associated with a substorm SMU = 1191 nT peak intensity. This substorm shows up more strongly in SMU rather than SML. A 16 A GIC is noted at the start of the storm recovery phase. This occurred as the substorm activity was subsiding and there was no 1-to-1 relationship with a substorm.
Day 118 (28 April), 2001 (Fig. A14). An ICME event that does not cause a magnetic storm (SYM-H = À34 nT). The strong shock at~0502 UT (0802 LT) caused a SI+ of 75 nT. The shock also triggered a sudden onset substorm of SML = À498 nT intensity. The SMU intensity was larger, 777 nT. A 13 A GIC occurred at the same time as the shock and   Figure A1. B.T. Tsurutani and R. Hajra: J. Space Weather Space Clim. 2021, 11, 23 substorm sudden onset. At the time of the shock, Mäntsälä was in the morning sector. There was no intense Bs in the sheath or MC, thus there was no storm.
Day 268-269 (25-26 September), 2001 (Fig. A15). A SYM-H = À118 nT magnetic storm caused by a sheath upstream of an ICME. The shock at~2027 UT (2327 LT) triggered a short-duration substorm of SML = À1544 nT intensity and a below threshold GIC event. At the time of the shock Mäntsälä was in the midnight sector. A 20 A GIC was associated with an intense substorm spike of SML = À2264 nT occurring in the storm main phase. The intense substorm was caused by a strong solar wind density spike of Nsw = 69 cm À3 .
Days 294-295 (21-22 October), 2001 (Fig. A16). An ICME related SYM-H = À219 nT magnetic storm. The strong shock at 1649 UT (1949 LT) created a sudden onset of a SML = À1148 nT substorm and a GIC below study threshold. At the time of the shock, Mäntsälä was in the dusk-midnight sector. In the storm main phase, an 11 A GIC is associated with a SML = À1824 nT short-duration substorm. A second larger 18 A GIC occurs within a long-duration SML = À1160 nT substorm. Both the latter GIC and substorm onset occur at the same time as a Nsw = 65 cm À3 solar wind density spike. This occurred in the storm recovery phase. Two more GICs of 12 A and 13 A intensity occur in a multiple substorm period. There is no obvious 1-to-1 relationship between the GICs and the substorms for these two GIC events. A ICME filament is indicated by the vertical shading at~1200 UT day 295. There are some small GICs present during the interval but they are below the study threshold.
Day 310 (6 November), 2001 (Fig. A17). The sheath portion of an ICME (there is a data gap) causes a SYM-H = À320 nT superstorm. Although the shock occurred in a data gap, a clear SI + of intensity 86 nT at~0153 UT (0453 LT) and a correlated 32 A GIC were present. Mäntsälä was in the dawn sector. The shock triggered a short-duration SML = À2301 nT intense substorm. There were intense SML =~À2300 nT substorm activities (following the initial intense substorm) with many GIC events with intensities up to 27 A. In the storm recovery phase two SSSs of even greater intensities of SML = À2839 nT and À2494 nT occurred, but these did not cause GICs above the study threshold.
Day 328 (24 November), 2001 (Fig. A18). A sheath upstream of an ICME caused a double dip magnetic storm of SYM-H = À233 nT peak intensity. The MC had a northward IMF orientation and caused the recovery phase of the storm. The shock occurred at~0600 UT (0900 LT), when Mäntsälä was in the morning sector. The shock triggered a long-duration SSS which peaked at SML = À3839 nT hours later. Either the shock or the onset of the SSS caused a 21 A GIC. The SSS peak was correlated with a 32 A GIC. Later GICs of 25 A and 26 A were associated with the decay phase of the SSS. The SSS was triggered/enhanced in intensity by a Nsw = 65 cm À3 (PP) and an IMF Bn turning. The PP may be a coronal loop portion of the ICME. In the second dip of the storm, another SSS of SML = À3281 nT peak intensity caused GICs of 12, 10 and 11 A. There were 40 >10 A GICs in this day.   Figure A1. The horizontal red line in GIC panel indicates the GIC = 30 A level. The vertical shading represents a ICME filament identified by Lepri & Zurbuchen (2010).
Day 107 (17 April), 2002 (Fig. A19). A storm of SYM-H = À100 nT is caused by the sheath ahead of an ICME. The shock at~1107 UT (1407 LT) was time-coincident with a GIC of 19 A and a SML = À1523 nT sharp onset substorm. Mäntsälä was in the afternoon sector at the time of the shock. There were no GICs of threshold intensities during the storm main phase.
Day 143 (May 23), 2002 (Fig. A20). A double dip magnetic storm with peak intensity SYM-H = À115 nT was caused by a compound interplanetary event: shock/sheath, MC, and a possible filament. A Bs field in the MC caused the first storm dip and the following Bs interval at the onset of the high-density possible filament (35 cm À3 ) at~1546 UT (1846 LT), indicated by the vertical red dashed line, caused the second storm dip. The shock at~1051 UT (1351 LT) created a SML = À662 nT substorm and a 10 A GIC. The substorm is not detected in the AL index nor the SML indices. It is noted by the SMU index alone (SMU = 1726 nT). Mäntsälä was in the afternoon sector during this event. The filament Bs caused the second dip of the storm. The possible filament and its Bs triggered a SML = À1760 nT long-duration substorm and many GICs, but not above the 10 A threshold of this study. It is possible that this substorm caused the second dip of the two-dip storm.
Days 250-251 (7-8 September), 2002 (Fig. A21). A double dip storm with peak intensity SYM-H = À168 nT was caused by sheath Bs variations ahead of a MC. The shock at~1637 UT (1937 LT) created a GIC but below the threshold of this study. Mäntsälä was in the dusk sector at the time. There were three clear GICs of 26, 21 and 24 A intensities. The first GIC is correlated with an IMF Bn turning ending the first dip storm. The Bn turning started the recovery of the first dip storm. There was no substorm associated with the GIC. The second GIC had no obvious substorm or interplanetary related features. The third GIC occurred in the beginning of the storm recovery phase and was associated with a substorm of SML = À1116 nT intensity.
Days 274-275 (1-2 October), 2002 (Fig. A22). This event was previously discussed in Results section (Fig. 8). A lowspeed solar wind at Vsw~420 km s À1 with a long-period Bz wave with Bs reaching~23 nT caused a SYM-H = À153 nT magnetic storm (peak at~1253 UT day 274). There was geomagnetic auroral zone activity in this low-speed solar wind. A SML = À1906 nT short-duration substorm spike caused a double GIC of 28 A and 19 A intensities. The GICs occurred in the beginning of the storm recovery phase. There is no obvious interplanetary cause of this substorm.
Day 297 (24 October), 2002 (Fig. A23). A high-speed stream of Vsw~800 km s À1 peak speed caused a CIR and HILDCAA-like interval. The Bs in the CIR caused a day-long SYM-H = À88 nT magnetic storm. There were no shocks. The CIR double Bs feature caused two long-duration substorms with peak intensities of SML = À1306 nT and À1112 nT. Neither substorm caused a GIC of intensity over the study level. A double GIC of 19 A and 14 A were associated with a much smaller substorm of SML = À993 nT intensity.
Days [149][150], 2003 (Fig. A24). A double shock/sheath event. The second sheath Bs caused a SYM-H = À164 nT magnetic storm. The MC had a Bn field and caused the storm recovery phase. The first shock at~1226 UT   Figure A1.
B.T. Tsurutani and R. Hajra: J. Space Weather Space Clim. 2021, 11, 23 (1526 LT) did not trigger a substorm nor a GIC of study level intensity. The second shock occurred at 1913 UT (2213 LT) and triggered an intense substorm of SML intensity À2461 nT. The shock-related GIC did not reach the study threshold. Mäntsälä was in the afternoon sector during the first shock and in the dusk-midnight sector during the second shock. A cluster of GICs with peaks of 11 A, 11 A, 11 A and 12 A occurred in the storm main phase but there are no obvious 1-to-1 correlations with substorm peaks.
Day 287 (14 October), 2003 (Fig. A25). CIR Bs fields caused a double dip magnetic storm of SYM-H = À103 nT intensity. There was no shock. The CIR double dip wave in Bz causing two long-duration substorms with peak intensities of SML = À1447 nT and À1385 nT. The two substorms caused the double dip magnetic storm. The first substorm peak causes a GIC of 29 A. The second substorm caused GICs, but below the study threshold. The high-speed stream proper had a peak speed of 750 km s À1 .
Days 302-303 (29-30 October), 2003 (Fig. A26). This event was previously discussed in Results section (Fig. 2). A sheath and MC Bs caused the first October Halloween superstorm of intensity SYM-H = À390 nT. This was a double dip magnetic storm with the sheath causing the first dip and a MC Bs causing the second dip. The strong shock at~0612 UT (0912 LT) and triggered the sharp onset of a long duration, two-peak SSS of SML = À3177 nT (at 0624 UT) and À3548 nT (at 0648 UT) intensity and a cluster of GICs of 33 A (at 0646 UT), 57 A (at 0657 UT), 51 A (at 0703 UT) and 52 A (at 0727 UT) later in the event. Either the shock or the onset of the SSS caused a GIC of 25 A. Mäntsälä was in the morning sector at the time of the largest GICs. There are many GICs > 10 A in the two main phases of this double dip storm. However, the most intense events occurred in the first SSS immediately after the shock. There is a GIC of 30 A at 2230 UT (0130 LT) day 302 at the start of the second dip storm. This is associated with an intense storm of SML = À2340 nT. There is a 36 A GIC at 0110 UT (0410 LT) day 303 at the start of the recovery phase of the second dip storm.
Days 303-304 (30-31 October), 2003 (Fig. A27). This event was previously discussed in Results section (Fig. 3). The second "Halloween" superstorm. A sheath Bs upstream of an ICME causes the second October Halloween storm of intensity SYM-H = À432 nT. A solar wind density spike (PP) at~1949 UT (2249 LT) (denoted by the SI + of~61 nT) created a GIC of 49 A and a short-duration SSS of amplitude SML = À3872 nT. Mäntsälä was in the midnight sector at the time. A second short-duration SML = À2724 nT SSS occurred in the storm main phase. It is associated with a double GIC of 33 and 27 A. There are two clusters of GICs with > 10 A intensities in the storm recovery phase. They are associated with substorm intervals of peak intensities of SML = À1821 and À797 nT, respectively. In the first cluster there is a GIC of 30 A at 0213 UT on day 304. In the second cluster there is a 27 A GIC at 0536 UT day 304. There is a fourth GIC cluster with 16 A at 1119 UT, 19 A at 1152 UT, 16 A at 1119 UT, 14 A at 1227 UT and 16 A at 1246 UT. There were 90 GICs > 10 A and 3 GICs > 30 A.    Figure A1.
B.T. Tsurutani and R. Hajra: J. Space Weather Space Clim. 2021, 11, 23 sheath, Bs in an ICME MC followed by a possible filament. The shock at~0803 UT (1103 LT) only created a small GIC below the study threshold and a SML = -2031 nT short-duration sharp onset intense substorm. Mäntsälä was in the noon sector at the time of the shock. In the MC generated storm main phase, there are 4 large GICs. A short-duration substorm detected only in SMU (912 nT) is coincident with the first GIC of 23 A at 1408 UT. The next two GICs of 19 A (at 1518 UT) and 24 A (at 1640 UT) are not related to any obvious substorm features. A SSS of SML = À4141 nT intensity at 1634 UT caused the largest (double) GIC of 19 A and 24 A. These may be associated with a sharp solar wind density spike of 25 cm À3 . The density spike is the onset of a possible ICME filament. There is a 16 A GIC in the storm recovery phase caused by the last, isolated substorm of amplitude SML = À1714 nT.
Day 326 (22 November), 2003 (Fig. A29). This interval was a HSS with a relatively constant Vsw~540-640 km s À1 speed. The IMF Bs peak of À9.2 nT generated a magnetic storm of SYM-H = À97 nT. There was no obvious shock and/or CIR. In the first Bs interval there is a cluster of substorms with SML peaks all of~À1500 nT intensities. One large GIC of 14 A is associated with one short-duration substorm of intensity SML = À1561 nT. This substorm cannot be detected in the AL index. It is most remarkable in the SMU index. The other substorms with the same intensities did not generate GICs above the study threshold.
Day 344 (10 December), 2003 (Fig. A30). A pure HSS event with a peak speed of Vsw = 840 km s À1 caused a magnetic storm of SYM-H = À71 nT intensity. Alfvénic Bs fluctuations caused a HILDCAA interval with lots of substorms, but no SSSs. One isolated 11 A GIC is caused by a substorm with SML peak intensity of À1830 nT. This substorm is not detected in the AL index.
Day 94 (3 April), 2004 (Fig. A31). A moderate speed ICME whose upstream sheath/pileup region caused a double dip magnetic storm of SYM-H = À149 nT intensity. The peak speed of the ICME is only~496 km s À1 in a background Vsw 400 km s À1 . The storm double dip is caused by a long Bz wave giving 2 intervals of Bs in the sheath ahead of the MC. The MC has a Bn field and leads to the storm recovery phase. The shock at~1413 UT (1713 LT) did not cause a GIC with intensity above study level. At the time Mäntsälä was in the dusk sector. One GIC of 11 A occurred at the cusp between the first dip storm and the second dip storm. There was no obvious substorm or solar wind feature associated with this GIC.
Days 312-313 (7-8 November), 2004 (Fig. A32). A triple dip SYM-H = À382 nT superstorm caused by a sheath Bs interval and a MC Bs interval. There were three shocks and sheaths in this interplanetary event but the first two shocks were not geoeffective. Both the first shock at the beginning of day 312 and the second shock at~1056 UT (1356 LT) day 312 created below threshold GIC events. The third shock at~1829 UT (2129 LT) was time-coincident with a 11 A GIC event. Mäntsälä was in the dusk sector during the second shock and in the dusk-midnight sector during the third shock. There are   Figure A1. B.T. Tsurutani and R. Hajra: J. Space Weather Space Clim. 2021, 11, 23 two GIC event clusters occurring in the storm main phase. The largest GIC event of 35 A occurred in the first cluster during an intense substorm of SML amplitude À2071 nT. The intense substorm was triggered by a solar wind PP and a sharp Bs intensification. The PP had a peak density of~29 cm À3 . It could possibly a loop portion of the ICME. The second GIC cluster had many GICs > 10 A (peak of~29 A) and occurred near third dip storm maximum. These individual GICs within the clusters do not appear to have one-to-one associations with substorm peak intensities. The GICs appear to be terminated by a reverse shock which decreased the IMF Bs. There were 38 > 10 A GIC events during these two days.
Day 314 (9 November), 2004 (Fig. A33). A shock/sheath, shock/sheath and MC compound event causing a triple dip superstorm with intensities of À139 nT, À271 nT and À282 nT, respectively. The first dip storm is caused by the first sheath Bs, the second dip storm by the second sheath Bs and the third storm by the MC Bs. The first shock at~0932 UT (1232 LT) triggered a GIC below the study threshold. The second shock at~1850 UT (2150 LT) also did not trigger a GIC above the study threshold. At the time of these two shocks, Mäntsälä was in the noon sector and dusk-midnight sectors, respectively. The second shock triggered an intense substorm which reached a peak value of SML = À2264 nT hours later. The substorm was due to sheath Bs which caused the second dip storm main phase. The second storm has a peak intensity of SYM-H = 271 nT at 2103 UT day 314. This substorm onset is caused by a sharp Bs intensification associated with the shock compression of preexisting Bs fields. This intense substorm caused a cluster of three GICs with 43, 42 and 21 A intensities. There were 20 GIC >10 A intensities during this day.
Day 21 (21 January), 2005 (Fig. A34). This event was previously discussed in Results section (Fig. 6). An ICME preceded by a strong shock/sheath. The sheath caused a storm of SYM-H = À101 nT. The shock at~1712 UT (2012 LT) was time-coincident with a GIC of 13 A and triggered a sharp onset of a SSS which reached a peak value of SML = À4418 nT. Mäntsälä was in the dusk-midnight sector at the time. During the SSS decay phase there is a cluster of GICs reaching 27 A. The GICs and substorm SMU intensification are associated with an unusual sharp interplanetary density spike up to Nsw = 55 cm À3 . There is another GIC of intensity 22 A at 2015 UT which is time-coincident with a sharp solar wind density spike to 42 cm À3 . There is no obvious substorm feature associated with this GIC. There were 12 GICs with > 10 A in this event.
Day 236 (24 August), 2005 (Fig. A35). A shock/sheath event ahead of an ICME event where the sheath Bs causes a magnetic storm of intensity SYM-H = À179 nT. The shock at 0614 UT (0914 LT) caused a GIC below the study threshold. Mäntsälä was in the morning sector at the time of the shock. In the storm main phase there are two SSSs with SML = À4046 nT and À3895 nT peak intensities. There are no GICs above threshold associated with these events. There is a cluster of GICs with peak intensity of 13 A that occur in the SSS decay phase. This is at the end of the storm main phase and beginning of the recovery phase. There is no 1-to-1 correlation with the substorms.   Figure A1. B.T. Tsurutani and R. Hajra: J. Space Weather Space Clim. 2021, 11, 23 Day 349 (15 December), 2006 (Fig. A36). An ICME event where the MC Bs caused a storm of SYM-H = À220 nT intensity. The strong shock at~1414 UT (1714 LT) triggered an intense substorm of SML = À2102 nT intensity. Due to a GIC data gap, it is unknown whether there a GIC above study threshold or not. In the storm main phase there is an intense substorm of SML = À2264 nT. A GIC of 14 A at 0055 UT is associated with the decay part of this substorm. There were three more GICs with > 10 A intensities. They occurred at 0148 UT, 0224 UT and 0518 UT and have intensities of 13 A, 11 A and 12 A, respectively. There are no obvious 1-to-1 GIC relationships with substorms.
Day 269 (26 September), 2011 (Fig. A37). A CIR and HSS event (maximum speed of Vsw = 734 km s À1 ) where the CIR Bs causes a storm of intensity SYM-H =À116 nT. The shock at 1236 UT (1536 LT) triggers a short-duration substorm of intensity SML = À866 nT but no GIC above study level. Mäntsälä was in the afternoon sector at the time of the shock. Two GICs of 12 and 16 A occurred in the storm main phase, but there are not obviously 1-to-1 associated with substorms. The first GIC occurs in the decay phase of an intense substorm of SML = À2006 nT and the second more intense event occurs when the SML level is < À500 nT (SML = À300 nT). The latter GIC is due to a solar wind plasma density spike. There is no associated substorm.
Day 58 (27 February), 2012 (Fig. A38). This event was previously discussed in Results section (Fig. 7). A Vsw 520 km s À1 slow ICME with no shock where the pileup Bs fluctuations lead to a storm of SYM-H = À61 nT. The MC Bz = 0 nT causes the storm recovery phase. In this pileup region, there are moderate SML values with a peak of À848 nT but no intense GICs. A GIC event of 20 A is associated with an IMF Bn turning at the sheath/MC boundary. There is also a solar wind ram pressure decrease at that time. There are no substorms or GICs associated with the MC interval with IMF Bn. A high plasma density region of 17.5 cm À3 follows the MC. This may be an ICME filament. The density causes a Bs interval and a substorm of SML = À1142 nT at 0736 UT (1036 LT) on day 59. The substorm only creates below threshold GICs.
Day 75 (15 March), 2012 (Fig. A39). The sheath Bs upstream of an ICME causes a magnetic storm of SYM-H = À79 nT. The MC Bz = 0 nT leads to the storm recovery phase. The shock at 1307 UT (1607 LT) causes a GIC below the study threshold. Mäntsälä was in the afternoon sector at that time. A GIC of 39 A occurs at 1703 UT (2003 LT) on day 75 in main phase of the magnetic storm. There is a solar wind spike of density 12 cm À3 at 1704 UT that is the cause of the GIC.
Day 76 (17 March), 2013 (Fig. A40). An upstream sheath double Bs event caused a SYM-H = À131 nT double dip magnetic storm. The shock at~0601 UT (0901 LT) triggered a SML = À958 nT substorm but no GIC above the study limit. Mäntsälä was in the morning sector at the time of the shock. There is a cluster of 3 GICs of 32, 20 and 14 A intensities in the storm main phase near the storm peak. The GICs occurred on the decay phase of the substorm when the SML intensity was À990 nT. There were no obvious one-to-one relationships   Figure A1. A ICME filament identified by Lepri & Zurbuchen (2010) is indicated by the vertical shading.
B.T. Tsurutani and R. Hajra: J. Space Weather Space Clim. 2021, 11, 23 between the GICs and substorm features. There were 7 GIC events with >10 A in this day.
Day 275 (2 October), 2013 (Fig. A41). A magnetic storm of intensity SYM-H = À90 nT caused by sheath Bs fields. The shock at~0156 UT (0456 LT) triggered a moderate intensity substorm and no GIC above the study limit. The sheath Bs fields caused two substorms, the first of SML = À2017 nT and a second of SML = À1963 nT. The substorms caused the storm main phase. The first substorm did not cause a GIC above the study limit. The second substorm causes a GIC of 15 A intensity.
Day 254 (11 September), 2015 (Fig. A42). A small Vsw = 640 km s À1 HSS, with presumably Bs (there is a data gap) that causes a SYM-H = À94 nT double dip storm. A GIC double event of 16 A occurred in an interplanetary data gap at the start of the storm recovery phase. The GIC occurs at the end of substorm activity in the recovery phase of a SML = À1014 nT substorm.
Day 280 (7 October), 2015 (Fig. A43). This is a double dip storm with intensities of SYM-H = À88 nT and À124 nT. The first storm was caused by small Bs in a Vsw~460 km s À1 slow solar wind. There were no major GICs associated with this event. The second storm is caused by CIR Bs (with no forward shock) ahead of a HSS of~650 km s À1 . There were two small clusters of GICs. The first had a peak intensity of 21 A and was associated with a substorm of SML = À1573 nT intensity. The second cluster reached 17 A and were not associated with                        B.T. Tsurutani and R. Hajra: J. Space Weather Space Clim. 2021, 11, 23 any obvious substorm spike. It was associated with an IMF Bsto-Bn turning at a solar wind ram pressure decrease caused by a fast reverse shock.
Day 354 (20 December), 2015 (Fig. A44). A slow Vsw 430 km s À1 ICME MC event. Pileup region Bs and MC Bs created a double dip storm with SYM-H = À77 nT and À170 nT intensities. The pileup region Bs created the first storm dip and the slow MC Bs the second dip. There is no shock. There are no intense GICs in the first dip storm. Although the MC contains a constant Bs field here is a lot of auroral (SML) activity throughout the second dip storm. A double peak GIC of 14 and 18 A intensities is associated with an intense substorm of SML = À2106 nT. There are 3 more GIC clusters of smaller intensities with peak GICs > 10 A that appear to be associated with smaller amplitude substorms.
Day 66 (6 March), 2016 (Fig. A45). A slow speed stream/ HSS (Vsw~590 km s À1 ) interaction created a CIR, and the Bs in the CIR caused a SYM-H = À110 nT storm. There was no shock. Within the CIR are Bz fluctuations superposed on a constant Bs biased interval, the latter of which caused the storm main phase. There is large geomagnetic activity up to SML = À1207 nT but no associated GICs above study threshold. A 20 A GIC event was caused by a SML = À1105 nT short duration substorm. This SME spike was not detected in the AL index. This GIC occurred at storm maximum.
Day 287 (Oct 13), 2016 (Fig. A46). A low speed MC of Vsw~410 km s À1 with peak magnetic field magnitude of 24 nT and peak Bs of~21 nT caused a SYM-H = À114 nT magnetic storm. There is a large cluster of GICs with peak values reaching 12 A occurring near the storm peak. The GICs were associated with large substorms which have a peak intensity of SML = À2230 nT. One substorm of SML = À1323 nT intensity is correlated with a GIC spike of 12 A intensity.
Day 356 (21 December), 2016 (Fig. A47). A Vsw~650 km s À1 HSS Bs created a weak magnetic storm of SYM-H = À52 nT. A small long duration Bs (with oscillations) caused a cluster of high frequency substorms with a delayed peak intensity of SML = À1721 nT. The peak of the substorm is associated with a~10 A GIC cluster. In the cluster there is one event with magnitude greater than 10 A.
Days 251 (8 September), 2017 (Fig. A48). A double dip magnetic storm of SYM-H = À146 nT and À115 nT were generated by the upstream shock/sheath Bs and the trailing MC Bs, respectively. The shock compresses pre-existing Bs leading to a storm of À146 nT. The shock at~2303 UT (0203 LT) causes a GIC below the study threshold. At the time of the shock Mäntsälä was in the midnight-dawn sector. A cluster of substorms occurred in the first storm main phase. A maximum intensity GIC of 28 A is correlated with a short duration SML = À3712 nT supersubstorm. There is a cluster of intense substorms/SSSs with amplitudes up to SML = À2511 nT and GICs up to 18 A intensity associated with the second storm main phase. There are no obvious 1-to-1 relationships between GIC events and substorms. The largest GIC of this interval occurred in the storm recovery phase, had an intensity of 30 A and cannot be associated with any large substorm or any solar wind feature. B.T. Tsurutani and R. Hajra: J. Space Weather Space Clim. 2021, 11, 23