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1. Transition to a weaker Sun: Changes in the solar atmosphere during the decay of the Modern Maximum

Author

Mursula, K., Pevtsov, A. A., Asikainen, T., Tähtinen, I., and Yeates, A. R.

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

The Sun experienced a period of unprecedented activity during the 20th century, now called the Modern Maximum (MM). The decay of the MM after cycle 19 has changed the Sun, the heliosphere, and the planetary environments in many ways. However, studies disagree on whether this decay has proceeded synchronously in different solar parameters or not. One key issue is if the relation between two long parameters of solar activity, the sunspot number and the solar 10.7cm radio flux, has remained the same during this decay. A recent study argues that there is an inhomogeneity in the 10.7cm radio flux in 1980, which leads to a step-like jump ("1980 jump") in this relation. Here we show that the relation between sunspot number and 10.7cm radio flux varies in time, not due to an inhomogeneous radio flux but due to physical changes in the solar atmosphere. We used radio fluxes at four different wavelengths measured in Japan, and studied their long-term relation with the sunspot number and the 10.7cm radio flux. We also used two other solar parameters, the MgII index and the number of active regions. We find that the 1980 jump is only the first of a series of 1-2-year "humps" that mainly occur during solar maxima. All radio fluxes increase with respect to the sunspot number from the 1970s to 2010s. These results reestablish the 10.7cm flux as a homogeneous measure of solar activity. The fluxes of the longer radio waves are found to increase with respect to the shorter waves, which suggests a long-term change in the solar radio spectrum. We also find that the MgII index and the number of active regions also increased with respect to the sunspot number, further verifying the difference in the long-term evolution in chromospheric and photospheric parameters. Our results provide evidence for important structural changes in solar magnetic fields and the solar atmosphere during the decay of the MM., Comment: 17 pages, 8 figures

Published
2024

2. FORESAIL-1 cubesat mission to measure radiation belt losses and demonstrate de-orbiting

Author

FORESAIL collaboration, Palmroth, M., Praks, J., Vainio, R., Janhunen, P., Kilpua, E. K. J., Ganushkina, N. Yu., Afanasiev, A., Ala-Lahti, M., Alho, A., Asikainen, T., Asvestari, E., Battarbee, M., Binios, A., Bosser, A., Brito, T., Envall, J., Ganse, U., George, H., Gieseler, J., Good, S., Grandin, M., Haslam, S., Hedman, H. -P., Hietala, H., Jovanovic, N., Kakakhel, S., Kalliokoski, M., Kettunen, V. V., Koskela, T., Lumme, E., Meskanen, M., Morosan, D., Mughal, M. Rizwan, Niemelä, P., Nyman, S., Oleynik, P., Osmane, A., Palmerio, E., Pfau-Kempf, Y., Peltonen, J., Plosila, J., Polkko, J., Poluianov, S., Pomoell, J., Price, D., Punkkinen, A., Punkkinen, R., Riwanto, B., Salomaa, L., Slavinskis, A., Säntti, T., Tammi, J., Tenhunen, H., Toivanen, P., Tuominen, J., Turc, L., Valtonen, E., Virtanen, P., and Westerlund, T.

Subjects
Physics - Space Physics
Abstract

Today, the near-Earth space is facing a paradigm change as the number of new spacecraft is literally sky-rocketing. Increasing numbers of small satellites threaten the sustainable use of space, as without removal, space debris will eventually make certain critical orbits unusable. A central factor affecting small spacecraft health and leading to debris is the radiation environment, which is unpredictable due to an incomplete understanding of the near-Earth radiation environment itself and its variability driven by the solar wind and outer magnetosphere. This paper presents the FORESAIL-1 nanosatellite mission, having two scientific and one technological objectives. The first scientific objective is to measure the energy and flux of energetic particle loss to the atmosphere with a representative energy and pitch angle resolution over a wide range of magnetic local times. To pave the way to novel model - in situ data comparisons, we also show preliminary results on precipitating electron fluxes obtained with the new global hybrid-Vlasov simulation Vlasiator. The second scientific objective of the FORESAIL-1 mission is to measure energetic neutral atoms (ENAs) of solar origin. The solar ENA flux has the potential to contribute importantly to the knowledge of solar eruption energy budget estimations. The technological objective is to demonstrate a satellite de-orbiting technology, and for the first time, make an orbit manoeuvre with a propellantless nanosatellite. FORESAIL-1 will demonstrate the potential for nanosatellites to make important scientific contributions as well as promote the sustainable utilisation of space by using a cost-efficient de-orbiting technology., Comment: 26 pages, 7 figures, 5 tables Published online in JGR: Space Physics on 21 May 2019

Published
2019
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3. European all-cause excess and influenza-attributable mortality in the 2017/18 season: should the burden of influenza B be reconsidered?

Author

Nielsen, J., Vestergaard, L.S., Richter, L., Schmid, D., Bustos, N., Asikainen, T., Trebbien, R., Denissov, G., Innos, K., Virtanen, M.J., Fouillet, A., Lytras, T., Gkolfinopoulou, K., Heiden, M. an der, Grabenhenrich, L., Uphoff, H., Paldy, A., Bobvos, J., Domegan, L., O'Donnell, J., Scortichini, M., de Martino, A., Mossong, J., England, K., Melillo, J., van Asten, L., de Lange, M. MA, Tønnessen, R., White, R.A., da Silva, S.P., Rodrigues, A.P., Larrauri, A., Mazagatos, C., Farah, A., Carnahan, A.D., Junker, C., Sinnathamby, M., Pebody, R.G., Andrews, N., Reynolds, A., McMenamin, J., Brown, C.S., Adlhoch, C., Penttinen, P., Mølbak, K., and Krause, T.G.

Published
2019
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6. Long-term evolution of solar coronal holes

Author

Mursula, K. (Kalevi), Asikainen, T. (Timo), Hamada, A. (Amr), Mursula, K. (Kalevi), Asikainen, T. (Timo), and Hamada, A. (Amr)

Abstract

Solar coronal holes are regions of open magnetic field lines in the solar corona. They are the source region of high-speed solar wind streams that play an important role for geomagnetic activity and are the most important driver of energetic particle precipitation into the Earth’s atmosphere. Understanding the evolution of coronal holes is critical for solar magnetism as well as for accurate space weather forecasts. Historically, coronal holes have been identified visually and hand-traced by experienced observers. In this thesis, we develop a novel automated method to identify coronal holes from the extreme ultraviolet synoptic maps by determining the intensity threshold of coronal hole regions separately for each synoptic map. We quantify the spatio-temporal evolution of coronal hole during solar cycles 23 and 24. We studied geomagnetic storms triggered by two sequences of high-speed streams from persistent low-latitude coronal hole sources, observed in the declining phase of solar cycle 23. We found a systematic change in the Bz(GSM)–Bz(GSE) difference which offers the first detailed analysis of the onset of the Rusell-McPherron mechanism, increasing geomagnetic activity of the negative polarity sequence as we approach the March equinox. We also present a novel homogenized solar extreme ultraviolet synoptic dataset based on full-disk images from Solar and Heliospheric Observatory/Extreme ultraviolet Imaging Telescope and Solar Dynamics Observatory/Atmospheric Imaging Assembly. These maps provide a systematic and homogenous view of the entire solar surface in the extreme ultraviolet wavelengths from 1996 until 2019. Using this long-running homogenized dataset of solar extreme ultraviolet observations together with the coronal hole automated identification algorithm, we prepared a 23-year (1996–2019) coronal hole synoptic dataset. This coronal hole dataset is combined with the MacIntosh Archive (1973–2009) to produce the longest dataset of equatorial corona

Published
2023

7. Long-term prediction of sudden stratospheric warmings with geomagnetic and solar activity

Author

Vokhmyanin, M. (Mikhail), Asikainen, T. (Timo), Salminen, A. (Antti), Mursula, K. (Kalevi), Vokhmyanin, M. (Mikhail), Asikainen, T. (Timo), Salminen, A. (Antti), and Mursula, K. (Kalevi)

Abstract

The polar vortex is a strong jet of westerly wind which forms each winter around the polar stratosphere. Sometimes, roughly every other winter, the polar vortex in the Northern Hemisphere experiences a dramatic breakdown and associated warming of the polar stratosphere. Such events are called sudden stratospheric warmings (SSWs) and they are known to have a significant influence on ground weather in Northern Eurasia and large parts of North America. Typically, these events are thought to occur due to planetary waves propagating to the stratosphere where they may disrupt the vortex. Here, we show that the SSW probability depends significantly on a favorable combination of geomagnetic and solar activity and the phase of the Quasi-Biennial Oscillation (QBO). Using logistic regression models, we find that more SSWs occur when early-winter geomagnetic activity (aa index) is low and QBO winds are easterly and when solar activity (F10.7 index) is high and QBO winds are westerly. We then examine the possibility of using these results to predict the occurrence probability of SSWs with several months lead time and evaluate the optimal lead times for all variables using cross-validation methods. As a result, we find that the SSW probability can be predicted rather well and we can issue a probabilistic SSW prediction for the coming winter season with a success ratio of about 86% already in the preceding August. The results presented here are an important step toward improving the seasonal predictability of wintertime weather using information about solar and geomagnetic activity.

Published
2023

9. Predicting the evolution of solar magnetic fields with SFT simulation using active regions based on predicted sunspot activity

Author

Tähtinen, I., Asikainen, T., and Mursula, K.

Abstract

Surface flux transport (SFT) simulations are commonly used to describe and forecast the evolution of solar surface magnetic fields. These simulations are driven by active regions (AR) emerging on the solar surface. Here we use SFT simulations to predict the photospheric magnetic fields several years up to one cycle into the future by predicting the level of sunspot activity and using a statistical relation between sunspots and active regions.Prediction of sunspot activity uses our recently developed statistical method, which employs past sunspot numbers and geomagnetic activity to predict the next cycle. We study how the properties of active regions depend on the sunspot numbers (SSN) and phase of the sunspot cycle. We then construct probability distributions of AR properties (magnetic flux, latitude, tilt angle) that are used to derive ARs for any SSN level and cycle phase. We use two types of ARs to drive SFT simulations: bipolar active regions, where the magnetic field is Gaussian-distributed around the bipole centers, and active regions obtained from observed magnetograms by bootstrap sampling.We describe these SFT simulations and compare the results of photospheric magnetic field evolution from the two types of ARs with each other and with the results of SFT simulations using observed active regions. We will also use the PFSS model and the simulated photospheric magnetic field to study the evolution of the open solar flux., The 28th IUGG General Assembly (IUGG2023) (Berlin 2023)

Published
2023
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12. HEPPA III intercomparison experiment on electron precipitation impacts, part I: Estimated ionization rates during a geomagnetic active period in April 2010

Author

Tyssøy, H. Nesse, Sinnhuber, M., Asikainen, T., Bender, S., Clilverd, M.A., Funke, B., Kamp, M., Pettit, J.M., Randall, C.E., Reddmann, T., Rodger, C.J., Rozanov, E., Smith‐Johnsen, C., Sukhodolov, T., Verronen, P.T., Wissing, J.M., Yakovchuk, O., Tyssøy, H. Nesse, Sinnhuber, M., Asikainen, T., Bender, S., Clilverd, M.A., Funke, B., Kamp, M., Pettit, J.M., Randall, C.E., Reddmann, T., Rodger, C.J., Rozanov, E., Smith‐Johnsen, C., Sukhodolov, T., Verronen, P.T., Wissing, J.M., and Yakovchuk, O.

Abstract

Precipitating auroral and radiation belt electrons are considered an important part of the natural forcing of the climate system. Recent studies suggest that this forcing is underestimated in current chemistry-climate models. The HEPPA III intercomparison experiment is a collective effort to address this point. Here, eight different estimates of medium energy electron (MEE) (urn:x-wiley:21699380:media:jgra56926:jgra56926-math-0001) ionization rates are assessed during a geomagnetic active period in April 2010. The objective is to understand the potential uncertainty related to the MEE energy input. The ionization rates are all based on the Medium Energy Proton and Electron Detector (MEPED) on board the NOAA/POES and EUMETSAT/MetOp spacecraft series. However, different data handling, ionization rate calculations, and background atmospheres result in a wide range of mesospheric electron ionization rates. Although the eight data sets agree well in terms of the temporal variability, they differ by about an order of magnitude in ionization rate strength both during geomagnetic quiet and disturbed periods. The largest spread is found in the aftermath of enhanced geomagnetic activity. Furthermore, governed by different energy limits, the atmospheric penetration depth varies, and some differences related to latitudinal coverage are also evident. The mesospheric NO densities simulated with the Whole Atmospheric Community Climate Model driven by highest and lowest ionization rates differ by more than a factor of eight. In a follow-up study, the atmospheric responses are simulated in four chemistry-climate models (CCM) and compared to satellite observations, considering both the CCM structure and the ionization forcing.

Published
2022

13. Heppa III Intercomparison Experiment on Electron Precipitation Impacts : 2. Model-Measurement Intercomparison of Nitric Oxide (NO) During a Geomagnetic Storm in April 2010

Author

Sinnhuber, M., Nesse Tyssøy, H., Asikainen, T., Bender, S., Funke, B., Hendrickx, Koen, Pettit, J. M., Reddmann, T., Rozanov, E., Schmidt, H., Smith-Johnsen, C., Sukhodolov, T., Szelag, M. E., van de Kamp, M., Verronen, P. T., Wissing, J. M., Yakovchuk, O. S., Sinnhuber, M., Nesse Tyssøy, H., Asikainen, T., Bender, S., Funke, B., Hendrickx, Koen, Pettit, J. M., Reddmann, T., Rozanov, E., Schmidt, H., Smith-Johnsen, C., Sukhodolov, T., Szelag, M. E., van de Kamp, M., Verronen, P. T., Wissing, J. M., and Yakovchuk, O. S.

Abstract

Precipitating auroral and radiation belt electrons are considered to play an important part in the natural forcing of the middle atmosphere with a possible impact on the climate system. Recent studies suggest that this forcing is underestimated in current chemistry-climate models. The HEPPA III intercomparison experiment is a collective effort to address this point. In this study, we apply electron ionization rates from three data-sets in four chemistry-climate models during a geomagnetically active period in April 2010. Results are evaluated by comparison with observations of nitric oxide (NO) in the mesosphere and lower thermosphere. Differences between the ionization rate data-sets have been assessed in a companion study. In the lower thermosphere, NO densities differ by up to one order of magnitude between models using the same ionization rate data-sets due to differences in the treatment of NO formation, model climatology, and model top height. However, a good agreement in the spatial and temporal variability of NO with observations lends confidence that the electron ionization is represented well above 80 km. In the mesosphere, the averages of model results from all chemistry-climate models differ consistently with the differences in the ionization-rate data-sets, but are within the spread of the observations, so no clear assessment on their comparative validity can be provided. However, observed enhanced amounts of NO in the mid-mesosphere below 70 km suggest a relevant contribution of the high-energy tail of the electron distribution to the hemispheric NO budget during and after the geomagnetic storm on April 6.

Published
2022
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14. Dependence of the global dayside reconnection rate on interplanetary magnetic field By and the earth’s dipole tilt

Author

Reistad, J. P. (Jone Peter), Holappa, L. (Lauri), Ohma, A. (Anders), Gabrielse, C. (Christine), Sur, D. (Dibyendu), Asikainen, T. (Timo), DeJong, A. (Anna), Reistad, J. P. (Jone Peter), Holappa, L. (Lauri), Ohma, A. (Anders), Gabrielse, C. (Christine), Sur, D. (Dibyendu), Asikainen, T. (Timo), and DeJong, A. (Anna)

Abstract

In the recent years, significant attention has been given to the combined effect of Interplanetary Magnetic Field (IMF) duskward component (By) and dipole tilt on the global magnetosphere-ionosphere system response. Numerous studies have pointed out that when the Earth’s magnetic dipole is tilted away from the Sun (negative dipole tilt during northern winter), and IMF has a positive By component, the effects on ionospheric currents, particle precipitation, ionospheric convection, and average size of the auroral oval, is significantly more enhanced, compared to when IMF By is negative. Furthermore, this IMF By polarity effect reverses when Earth’s dipole is tilted in the opposite direction. The underlying cause has remained unclear. Our analysis shows that substorms tend to be stronger during the same IMF By and dipole tilt polarity combination. Taken together with earlier results showing also more frequent substorms during the same conditions, our observations suggests that when IMF By and dipole tilt have opposite signs, there is a more efficient global dayside reconnection rate. We also show analysis of the occurrence frequency of periods of Steady Magnetospheric Convection, substorm onset latitude, and the isotropic boundary of proton precipitation, that are all consistent with our conclusion that the combination of IMF By and dipole tilt polarity affect the global dayside reconnection rate.

Published
2022

15. Magnetic storms during the space age:occurrence and relation to varying solar activity

Author

Mursula, K. (Kalevi), Qvick, T. (Timo), Holappa, L. (Lauri), Asikainen, T. (Timo), Mursula, K. (Kalevi), Qvick, T. (Timo), Holappa, L. (Lauri), and Asikainen, T. (Timo)

Abstract

We study the occurrence of magnetic storms in space age (1957–2021) using Dst and Dxt indices. We find 2,526/2,743 magnetic storms in the Dxt/Dst index, out of which 45% are weak, 40% moderate, 12% intense and 3% major storms. Occurrence of storms in space age follows the slow decrease of sunspot activity and the related change in solar magnetic structure. We quantify the sunspot—coronal mass ejection (CME) storm relation in the five cycles of space age. We explain how the varying solar activity changes the structure of the heliospheric current sheet (HCS), and how this affects the high-speed solar wind stream (HSS)/corotating interaction region (CIR) storms. Space age started with a record number of storms in 1957–1960, with roughly one storm per week. Solar polar fields attained their maximum in cycle 22, which led to an exceptionally thin HCS, and a space age record of large HSS/CIR storms in 1990s. In the minimum of cycle 23, for the only time in space age, CME storm occurrence reduced below that predicted by sunspots. Weak sunspot activity since cycle 23 has weakened solar polar fields and widened the HCS, which has decreased the occurrence of large and moderate HSS/CIR storms. Because of a wide HCS, the Earth has spent 50% of its time in slow solar wind since cycle 23. The wide HCS has also made large and moderate HSS/CIR storms occur in the early declining phase in recent cycles, while in the more active cycles 20–22 they occurred in the late declining phase.

Published
2022

16. Using mutual information to investigate non-linear correlation between AE index, ULF Pc5 wave activity and electron precipitation

Author

Hoilijoki, S. (Sanni), Kilpua, E. K. (Emilia K. J.), Osmane, A. (Adnane), Kalliokoski, M. M. (Milla M. H.), George, H. (Harriet), Savola, M. (Mikko), Asikainen, T. (Timo), Hoilijoki, S. (Sanni), Kilpua, E. K. (Emilia K. J.), Osmane, A. (Adnane), Kalliokoski, M. M. (Milla M. H.), George, H. (Harriet), Savola, M. (Mikko), and Asikainen, T. (Timo)

Abstract

In this study, we use mutual information from information theory to investigate non-linear correlation between geomagnetic activity indicated by auroral electrojet (AE) index with both the global ultra low frequency (ULF) Pc5 wave power and medium energy (≥30 keV) electron precipitation at the central outer radiation belt. To investigate the energy and magnetic local time (MLT) dependence of the non-linearity, we calculate the mutual information and Pearson correlation coefficient separately for three different energy ranges (30–100 keV, 100–300 keV and ≥300 keV) and four different MLT sectors (0–6, 6–12, 12–18, 18–24). We compare results from 2 years 2004 and 2007 representing geomagnetically more active and less active years, respectively. The correlation analysis between the AE index and electron precipitation shows a clear MLT and energy dependence in both active and quiet conditions. In the two lowest energy ranges of the medium energy electrons (30–100 keV and 100–300 keV) both non-linear correlation and Pearson correlation indicate strong dependence with the AE index in the dawn sector. The linear dependence indicated by the Pearson correlation coefficient decreases from dawn to dusk while the change in the non-linear correlation is smaller indicating an increase in the non-linearity from dawn to dusk. The non-linearity between the AE index and electron precipitation is larger at all MLT sectors except MLTs 6–12 during geomagnetically more active year when larger amount of the activity is driven by interplanetary coronal mass ejections (ICMEs) compared to lower activity year with high speed stream (HSS) and stream interaction region (SIR) driven activity. These results indicate that the processes leading to electron precipitation become more non-linear in the dusk and during geomagnetically more active times when the activity is driven by ICMEs. The non-linearity between the AE index and global ULF Pc5 activity is relatively low and seems not to be a

Published
2022

17. The Mansurov effect:statistical significance and the role of autocorrelation

Author

Edvartsen, J. (Jone), Maliniemi, V. (Ville), Tyssøy, H. N. (Hilde Nesse), Asikainen, T. (Timo), Hatch, S. (Spencer), Edvartsen, J. (Jone), Maliniemi, V. (Ville), Tyssøy, H. N. (Hilde Nesse), Asikainen, T. (Timo), and Hatch, S. (Spencer)

Abstract

The Mansurov effect is related to the interplanetary magnetic field (IMF) and its ability to modulate the global electric circuit, which is further hypothesized to impact the polar troposphere through cloud generation processes. We investigate the connection between IMF By-component and polar surface pressure by using daily ERA5 reanalysis for geopotential height since 1980. Previous studies produce a 27-day cyclic response during solar cycle 23 which appears to be significant according to conventional statistical tests. However, we show here that when statistical tests appropriate for strongly autocorrelated variables are applied, there is a fairly high probability of obtaining the cyclic response and associated correlation merely by chance. Our results also show that data from three other solar cycles produce similar cyclic responses as during solar cycle 23, but with seemingly random offset in respect to the timing of the signal. By generating random normally distributed noise with different levels of temporal autocorrelation and using the real IMF By-time series as forcing, we show that the methods applied to support the Mansurov hypothesis up to now are highly susceptible to random chance as cyclic patterns always arise as artifacts of the methods. The potential non-stationary behavior of the Mansurov effect makes it difficult to achieve solid statistical significance on decadal time scales. We suggest more research on, e.g., seasonal dependence of the Mansurov effect to understand better potential IMF effects in the atmosphere.

Published
2022

18. Effects of energetic electron precipitation on the northern wintertime atmosphere

Author

Asikainen, T. (Timo), Mursula, K. (Kalevi), Salminen, A. (Antti), Asikainen, T. (Timo), Mursula, K. (Kalevi), and Salminen, A. (Antti)

Abstract

This thesis studies the effect of energetic electron precipitation (EEP) on the Earth’s atmosphere, focusing on the northern wintertime stratosphere. EEP is driven by the interaction between the Earth’s magnetosphere and solar wind, a plasma stream from the Sun. Energetic electrons precipitate constantly from the near-Earth space to the high-latitude upper atmosphere. In the northern hemisphere, EEP has been found to affect in the lower atmosphere during the winter, most notably on the polar vortex, a wind system dominating winter stratosphere. Variations in polar vortex also extend to the surface, where EEP has been observed to affect large-scale weather modes. The aim of this thesis is to clarify the EEP effect on wintertime middle atmosphere and its dependence on atmospheric conditions. The EEP effect is also studied together with the other solar-related driver, solar radiation, and internal drivers of the atmosphere. This work utilizes newly calibrated and corrected satellite measurements of precipitating electron fluxes and surface measurements of geomagnetic activity to quantify EEP activity. The atmosphere is studied by using reanalysis datasets which are based on comprehensive observations and cover the whole globe from the surface to about 50 kilometer altitude. In this work we use different statistical methods to reliably distinguish the atmospheric variability related to EEP. Results of this thesis confirm the earlier findings that EEP significantly enhances the northern polar vortex. We also show that EEP is the main solar-related driver of the wintertime northern stratosphere. The EEP effect on the polar vortex is found to be particularly significant if the quasi-biennial oscillation (QBO), a wind mode in the equatorial stratosphere, is in the easterly phase. A remarkable interdependence is revealed between the EEP effect on the polar vortex and an extreme event of wintertime stratosphere, the sudden stratospheric warming (SSW). This thesis sho

Published
2022

19. Planetary waves controlling the effect of energetic electron precipitation on the northern polar vortex

Author

Salminen, A. (Antti), Asikainen, T. (Timo), Mursula, K. (Kalevi), Salminen, A. (Antti), Asikainen, T. (Timo), and Mursula, K. (Kalevi)

Abstract

Energetic electron precipitation (EEP) forms ozone-depleting nitrogen and hydrogen oxides in the high-latitude middle and upper atmosphere, leading to ozone destruction and temperature enhancement that can strengthen the winter polar vortex. This EEP effect on polar vortex depends on quasi-biennial oscillation and sudden stratospheric warmings, which earlier studies relate to planetary waves. We study here the possible modulation of the EEP effect by planetary waves. We perform a principal component analysis of the vertical component of Eliassen-Palm flux (EP flux) to examine the latitudinal pattern of planetary waves. We use a multilinear regression analysis to estimate the responses of zonal wind and EP flux divergence to EEP in the northern winter stratosphere by keeping the two leading principal components of vertical EP flux as controlling factors. We find that the EEP strengthens the polar vortex most systematically when planetary wave propagation is enhanced at mid-latitudes but reduced at polar latitudes.

Published
2022

20. Heppa III Intercomparison Experiment on Electron Precipitation Impacts: 2. Model-Measurement Intercomparison of Nitric Oxide (NO) During a Geomagnetic Storm in April 2010

Author

Ministerio de Ciencia e Innovación (España), European Commission, Sinnhuber, M., Nesse Tyssøy, H., Asikainen, T., Bender, S., Funke, Bernd, Hendrickx, K., Pettit, J.M., Reddmann, T., Rozanov, E., Schmidt, H., Smith-Johnsen, C., Sukhodolov, T., SzelÄ g, M. E., van de Kamp, M., Verronen, P. T., Wissing, J. M., Yakovchuk, O. S., Ministerio de Ciencia e Innovación (España), European Commission, Sinnhuber, M., Nesse Tyssøy, H., Asikainen, T., Bender, S., Funke, Bernd, Hendrickx, K., Pettit, J.M., Reddmann, T., Rozanov, E., Schmidt, H., Smith-Johnsen, C., Sukhodolov, T., SzelÄ g, M. E., van de Kamp, M., Verronen, P. T., Wissing, J. M., and Yakovchuk, O. S.

Abstract

Precipitating auroral and radiation belt electrons are considered to play an important part in the natural forcing of the middle atmosphere with a possible impact on the climate system. Recent studies suggest that this forcing is underestimated in current chemistry-climate models. The HEPPA III intercomparison experiment is a collective effort to address this point. In this study, we apply electron ionization rates from three data-sets in four chemistry-climate models during a geomagnetically active period in April 2010. Results are evaluated by comparison with observations of nitric oxide (NO) in the mesosphere and lower thermosphere. Differences between the ionization rate data-sets have been assessed in a companion study. In the lower thermosphere, NO densities differ by up to one order of magnitude between models using the same ionization rate data-sets due to differences in the treatment of NO formation, model climatology, and model top height. However, a good agreement in the spatial and temporal variability of NO with observations lends confidence that the electron ionization is represented well above 80 km. In the mesosphere, the averages of model results from all chemistry-climate models differ consistently with the differences in the ionization-rate data-sets, but are within the spread of the observations, so no clear assessment on their comparative validity can be provided. However, observed enhanced amounts of NO in the mid-mesosphere below 70 km suggest a relevant contribution of the high-energy tail of the electron distribution to the hemispheric NO budget during and after the geomagnetic storm on April 6. © 2021 The Authors.

Published
2022

21. HEPPA III Intercomparison Experiment on Electron Precipitation Impacts: 1. Estimated Ionization Rates During a Geomagnetic Active Period in April 2010

Author

Ministerio de Ciencia e Innovación (España), European Commission, Nesse Tyssøy, H., Sinnhuber, M., Asikainen, T., Bender, S., Clilverd, M. A., Funke, Bernd, van de Kamp, M., Pettit, J.M., Randall, C. E., Reddmann, T., Rodger, C. J., Rozanov, E., Smith-Johnsen, C., Sukhodolov, T., Verronen, P. T., Wissing, J. M., Yakovchuk, O., Ministerio de Ciencia e Innovación (España), European Commission, Nesse Tyssøy, H., Sinnhuber, M., Asikainen, T., Bender, S., Clilverd, M. A., Funke, Bernd, van de Kamp, M., Pettit, J.M., Randall, C. E., Reddmann, T., Rodger, C. J., Rozanov, E., Smith-Johnsen, C., Sukhodolov, T., Verronen, P. T., Wissing, J. M., and Yakovchuk, O.

Abstract

Precipitating auroral and radiation belt electrons are considered an important part of the natural forcing of the climate system. Recent studies suggest that this forcing is underestimated in current chemistry-climate models. The High Energy Particle Precipitation in the Atmosphere III intercomparison experiment is a collective effort to address this point. Here, eight different estimates of medium energy electron (MEE) urn:x-wiley:21699380:media:jgra56926:jgra56926-math-0001 ionization rates are assessed during a geomagnetic active period in April 2010. The objective is to understand the potential uncertainty related to the MEE energy input. The ionization rates are all based on the Medium Energy Proton and Electron Detector (MEPED) on board the NOAA/POES and EUMETSAT/MetOp spacecraft series. However, different data handling, ionization rate calculations, and background atmospheres result in a wide range of mesospheric electron ionization rates. Although the eight data sets agree well in terms of the temporal variability, they differ by about an order of magnitude in ionization rate strength both during geomagnetic quiet and disturbed periods. The largest spread is found in the aftermath of enhanced geomagnetic activity. Furthermore, governed by different energy limits, the atmospheric penetration depth varies, and some differences related to latitudinal coverage are also evident. The mesospheric NO densities simulated with the Whole Atmospheric Community Climate Model driven by highest and lowest ionization rates differ by more than a factor of eight. In a follow-up study, the atmospheric responses are simulated in four chemistry-climate models (CCM) and compared to satellite observations, considering both the CCM structure and the ionization forcing. © 2021. The Authors.

Published
2022

24. Heppa III Intercomparison Experiment on Electron Precipitation Impacts: 2. Model‐Measurement Intercomparison of Nitric Oxide (NO) During a Geomagnetic Storm in April 2010

Author

Sinnhuber, M., primary, Nesse Tyssøy, H., additional, Asikainen, T., additional, Bender, S., additional, Funke, B., additional, Hendrickx, K., additional, Pettit, J. M., additional, Reddmann, T., additional, Rozanov, E., additional, Schmidt, H., additional, Smith‐Johnsen, C., additional, Sukhodolov, T., additional, Szeląg, M. E., additional, van de Kamp, M., additional, Verronen, P. T., additional, Wissing, J. M., additional, and Yakovchuk, O. S., additional

Published
2021
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25. HEPPA III Intercomparison Experiment on Electron Precipitation Impacts: 1. Estimated Ionization Rates During a Geomagnetic Active Period in April 2010

Author

Nesse Tyssøy, H., primary, Sinnhuber, M., additional, Asikainen, T., additional, Bender, S., additional, Clilverd, M. A., additional, Funke, B., additional, van de Kamp, M., additional, Pettit, J. M., additional, Randall, C. E., additional, Reddmann, T., additional, Rodger, C. J., additional, Rozanov, E., additional, Smith‐Johnsen, C., additional, Sukhodolov, T., additional, Verronen, P. T., additional, Wissing, J. M., additional, and Yakovchuk, O., additional

Published
2021
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26. The magnitude of IMF By influences the magnetotail response to solar wind forcing

Author

Holappa, L. (L.), Robinson, R. M. (R. M.), Pulkkinen, A. (A.), Asikainen, T. (T.), and Mursula, K. (K.)

Subjects
substorms, solar wind
Abstract

The dynamics of substorms are known to be dominated by the North-South (Bz) component of the Interplanetary Magnetic Field (IMF), which is the most important driver of the dayside reconnection. Even though the dawn-dusk (By) component is also known to play a role in substorm dynamics, its effects are not yet fully understood. In this paper we study how IMF By modulates the onset latitude, strength and occurrence frequency of substorms as well as the isotropic boundary (IB) latitude of energetic protons. We show that the substorm onset latitude and the IB latitude are about one degree lower for large magnitude By (|By| < 3nT) than for small By. In contrast, the substorm occurrence frequency is larger for small |By|. We suggest that the magnetotail is more stable during large |By|, requiring the magnetotail lobes (and hence the polar cap) to contain more flux to initiate a substorm compared to the situation when By is small.

Published
2021

27. Heppa III intercomparison experiment on electron precipitation impacts:2. model-measurement intercomparison of nitric oxide (NO) during a geomagnetic storm in April 2010

Author

Sinnhuber, M. (M.), Nesse Tyssøy, H. (H.), Asikainen, T. (T.), Bender, S. (S.), Funke, B. (B.), Hendrickx, K. (K.), Pettit, J. M. (J. M.), Reddmann, T. (T.), Rozanov, E. (E.), Schmidt, H. (H.), Smith-Johnsen, C. (C.), Sukhodolov, T. (T.), Szeląg, M. E. (M. E.), van de Kamp, M. (M.), Verronen, P. T. (P. T.), Wissing, J. M. (J. M.), Yakovchuk, O. S. (O. S.), Sinnhuber, M. (M.), Nesse Tyssøy, H. (H.), Asikainen, T. (T.), Bender, S. (S.), Funke, B. (B.), Hendrickx, K. (K.), Pettit, J. M. (J. M.), Reddmann, T. (T.), Rozanov, E. (E.), Schmidt, H. (H.), Smith-Johnsen, C. (C.), Sukhodolov, T. (T.), Szeląg, M. E. (M. E.), van de Kamp, M. (M.), Verronen, P. T. (P. T.), Wissing, J. M. (J. M.), and Yakovchuk, O. S. (O. S.)

Abstract

Precipitating auroral and radiation belt electrons are considered to play an important part in the natural forcing of the middle atmosphere with a possible impact on the climate system. Recent studies suggest that this forcing is underestimated in current chemistry-climate models. The HEPPA III intercomparison experiment is a collective effort to address this point. In this study, we apply electron ionization rates from three data-sets in four chemistry-climate models during a geomagnetically active period in April 2010. Results are evaluated by comparison with observations of nitric oxide (NO) in the mesosphere and lower thermosphere. Differences between the ionization rate data-sets have been assessed in a companion study. In the lower thermosphere, NO densities differ by up to one order of magnitude between models using the same ionization rate data-sets due to differences in the treatment of NO formation, model climatology, and model top height. However, a good agreement in the spatial and temporal variability of NO with observations lends confidence that the electron ionization is represented well above 80 km. In the mesosphere, the averages of model results from all chemistry-climate models differ consistently with the differences in the ionization-rate data-sets, but are within the spread of the observations, so no clear assessment on their comparative validity can be provided. However, observed enhanced amounts of NO in the mid-mesosphere below 70 km suggest a relevant contribution of the high-energy tail of the electron distribution to the hemispheric NO budget during and after the geomagnetic storm on April 6.

Published
2021

28. HEPPA III intercomparison experiment on electron precipitation impacts:1. estimated ionization rates during a geomagnetic active period in April 2010

Author

Nesse Tyssøy, H. (H.), Sinnhuber, M. (M.), Asikainen, T. (T.), Bender, S. (S.), Clilverd, M. A. (M. A.), Funke, B. (B.), van de Kamp, M. (M.), Pettit, J. M. (J. M.), Randall, C. E. (C. E.), Reddmann, T. (T.), Rodger, C. J. (C. J.), Rozanov, E. (E.), Smith-Johnsen, C. (C.), Sukhodolov, T. (T.), Verronen, P. T. (P. T.), Wissing, J. M. (J. M.), Yakovchuk, O. (O.), Nesse Tyssøy, H. (H.), Sinnhuber, M. (M.), Asikainen, T. (T.), Bender, S. (S.), Clilverd, M. A. (M. A.), Funke, B. (B.), van de Kamp, M. (M.), Pettit, J. M. (J. M.), Randall, C. E. (C. E.), Reddmann, T. (T.), Rodger, C. J. (C. J.), Rozanov, E. (E.), Smith-Johnsen, C. (C.), Sukhodolov, T. (T.), Verronen, P. T. (P. T.), Wissing, J. M. (J. M.), and Yakovchuk, O. (O.)

Abstract

Precipitating auroral and radiation belt electrons are considered an important part of the natural forcing of the climate system. Recent studies suggest that this forcing is underestimated in current chemistry-climate models. The High Energy Particle Precipitation in the Atmosphere III intercomparison experiment is a collective effort to address this point. Here, eight different estimates of medium energy electron (MEE) (gt; 30 kev) ionization rates are assessed during a geomagnetic active period in April 2010. The objective is to understand the potential uncertainty related to the MEE energy input. The ionization rates are all based on the Medium Energy Proton and Electron Detector (MEPED) on board the NOAA/POES and EUMETSAT/MetOp spacecraft series. However, different data handling, ionization rate calculations, and background atmospheres result in a wide range of mesospheric electron ionization rates. Although the eight data sets agree well in terms of the temporal variability, they differ by about an order of magnitude in ionization rate strength both during geomagnetic quiet and disturbed periods. The largest spread is found in the aftermath of enhanced geomagnetic activity. Furthermore, governed by different energy limits, the atmospheric penetration depth varies, and some differences related to latitudinal coverage are also evident. The mesospheric NO densities simulated with the Whole Atmospheric Community Climate Model driven by highest and lowest ionization rates differ by more than a factor of eight. In a follow-up study, the atmospheric responses are simulated in four chemistry-climate models (CCM) and compared to satellite observations, considering both the CCM structure and the ionization forcing.

Published
2021

29. Explicit IMF By-dependence in geomagnetic activity:quantifying ionospheric electrodynamics

Author

Holappa, L. (L.), Robinson, R. M. (R. M.), Pulkkinen, A. (A.), Asikainen, T. (T.), Mursula, K. (K.), Holappa, L. (L.), Robinson, R. M. (R. M.), Pulkkinen, A. (A.), Asikainen, T. (T.), and Mursula, K. (K.)

Abstract

Geomagnetic activity is mainly driven by the southward (Bz) component of the interplanetary magnetic field (IMF), which dominates all solar wind coupling functions. Coupling functions also depend on the absolute value of the dawn-dusk (By) component of the IMF, but not on its sign. However, recent studies have shown that for a fixed level of solar wind driving, auroral electrojets in the Northern Hemisphere (NH) are stronger for By > 0 than for By < 0 during NH winter. In NH summer, the dependence on the By sign is reversed. While this By sign dependence, also called the explicit By-dependence, is very strong in the winter hemisphere, it is weak in the summer hemisphere. Moreover, the explicit By-dependence is much stronger in the westward electrojet than in the eastward electrojet. In this study, we study how the explicit IMF By-dependence is coupled with large-scale field-aligned currents (FACs) by using FAC measurements from the Active Magnetosphere and Planetary Electrodynamics Response Experiment and an empirical ionospheric conductance model. We model the complete ionospheric electrodynamics by solving the current continuity equation, and show that during periods of elevated solar wind driving (Bz < 0), the IMF By component modulates Regions 1 and 2 FACs in the dawn sector of the winter hemisphere. This leads to an explicit By-dependence in ionospheric conductance and the westward electrojet. We also show that the By-dependence of FACs and conductance is weak in the dusk sector, which explains the earlier observation of the weak By-dependence of the eastward electrojet.

Published
2021

30. A uniform series of low-latitude coronal holes in 1973–2018

Author

Hamada, A. (A.), Asikainen, T. (T.), Mursula, K. (K.), Hamada, A. (A.), Asikainen, T. (T.), and Mursula, K. (K.)

Abstract

Coronal holes (CHs) are regions in the solar corona characterized by plasma density lower than in the surrounding quiet Sun. Therefore they appear dark in images of the solar atmosphere made, e.g., in extreme ultraviolet (EUV). Identifying CHs on solar images is difficult since CH boundaries are not sharp, but typically obscured by magnetic structures of surrounding active regions. Moreover, the areas, shapes, and intensities of CHs appear differently in different wavelengths. Coronal holes have been identified both visually by experienced observers and, more recently, by automated detection methods using different techniques. In this article, we apply a recent, robust CH identification algorithm to a new set of homogenized EUV synoptic maps based on four EUV lines measured by the Solar and Heliospheric Observatory/Extreme ultraviolet Imaging Telescope (SOHO/EIT) in 1996–2018 and the Solar Dynamics Observatory/Atmospheric Imaging Assembly (SDO/AIA) in 2010–2018 and create corresponding CH synoptic maps. We also use CHs of the hand-drawn McIntosh archive (McA) from 1973–2009 to extend the CH database to earlier times. We discuss the success of the four EUV lines to find CHs at high or low latitudes, and confirm that the combined EIT 195 Å/AIA 193 Å series applies best for both polar and low-latitude CH detection. While the polar CH detection suffers from the vantage-point limitation, the low-latitude CH areas extracted from this line correlate with the McA CH data very well. Using the simultaneous measurements between EIT and McA and EIT and AIA, we scale the different data series to the same level and form the longest uniform series of low-latitude CHs in 1973–2018. We find that, while the solar cycle maxima of low-latitude CHs in the descending phase of Solar Cycles 21–23 attain roughly similar values, the corresponding maximum during Solar Cycle 24 is reduced by a factor of two. This suggests that magnetic flux emergence is crucial for the formation of lo

Published
2021

32. Explicit IMF \(B_y\) dependence in geomagnetic activity:modulation of precipitating electrons

Author

Holappa, L. (L.), Asikainen, T. (T.), and Mursula, K. (K.)

Subjects
solar wind, space weather, Physics::Space Physics, magnetosphere, ionosphere, Astrophysics::Earth and Planetary Astrophysics, energetic particles, geomagnetic activity, Physics::Atmospheric and Oceanic Physics, Physics::Geophysics
Abstract

The most important driver of geomagnetic activity is the north–south (\(B_z\)) component of the interplanetary magnetic field (IMF), which dominates the solar wind-magnetosphere coupling and all solar wind coupling functions. While the east–west (\(B_y\)) IMF component is also included in most coupling functions, its effect is always assumed to be symmetric with respect of its sign. However, recent studies have shown that, for a fixed value of any coupling function, geomagnetic activity is stronger for \(B_y > 0\) than for \(B_y < 0\) in Northern Hemisphere winter. In Southern Hemisphere winter, the dependence on the \(B_y\) sign is reversed. In this paper, we use measurements of National Oceanic and Atmospheric Administration Polar-Orbiting Operational Environmental Satellites to show that the flux of magnetospheric electrons precipitating into the atmosphere also exhibits an explicit \(B_y\) dependence. This \(B_y\) dependence is strong in the midnight and dawn sectors where it causes a related \(B_y\) effect in the westward electrojet and geomagnetic activity by modulating ionospheric conductivity.

Published
2020

33. Outer Van Allen belt trapped and precipitating electron flux responses to two interplanetary magnetic clouds of opposite polarity

Author

George, H. (Harriet), Kilpua, E. (Emilia), Osmane, A. (Adnane), Asikainen, T. (Timo), Kalliokoski, M. M. (Milla M. H.), Rodger, C. J. (Craig J.), Dubyagin, S. (Stepan), Palmroth, M. (Minna), George, H. (Harriet), Kilpua, E. (Emilia), Osmane, A. (Adnane), Asikainen, T. (Timo), Kalliokoski, M. M. (Milla M. H.), Rodger, C. J. (Craig J.), Dubyagin, S. (Stepan), and Palmroth, M. (Minna)

Abstract

Recently, it has been established that interplanetary coronal mass ejections (ICMEs) can dramatically affect both trapped electron fluxes in the outer radiation belt and precipitating electron fluxes lost from the belt into the atmosphere. Precipitating electron fluxes and energies can vary over a range of timescales during these events. These variations depend on the initial energy and location of the electron population and the ICME characteristics and structures. One important factor controlling electron dynamics is the magnetic field orientation within the ejecta that is an integral part of the ICME. In this study, we examine Van Allen Probes (RBSPs) and Polar Orbiting Environmental Satellites (POESs) data to explore trapped and precipitating electron fluxes during two ICMEs. The ejecta in the selected ICMEs have magnetic cloud characteristics that exhibit the opposite sense of the rotation of the north–south magnetic field component (BZ). RBSP data are used to study trapped electron fluxes in situ, while POES data are used for electron fluxes precipitating into the upper atmosphere. The trapped and precipitating electron fluxes are qualitatively analysed to understand their variation in relation to each other and to the magnetic cloud rotation during these events. Inner magnetospheric wave activity was also estimated using RBSP and Geostationary Operational Environmental Satellite (GOES) data. In each event, the largest changes in the location and magnitude of both the trapped and precipitating electron fluxes occurred during the southward portion of the magnetic cloud. Significant changes also occurred during the end of the sheath and at the sheath–ejecta boundary for the cloud with south to north magnetic field rotation, while the ICME with north to south rotation had significant changes at the end boundary of the cloud. The sense of rotation of BZ and its profile also clearly affects the coherence of the trapped and/or precipitating flux changes, ti

Published
2020

34. Comparing the effects of solar-related and terrestrial drivers on the northern polar vortex

Author

Salminen, A. (Antti), Asikainen, T. (Timo), Maliniemi, V. (Ville), Mursula, K. (Kalevi), Salminen, A. (Antti), Asikainen, T. (Timo), Maliniemi, V. (Ville), and Mursula, K. (Kalevi)

Abstract

Northern polar vortex experiences significant variability during Arctic winter. Solar activity contributes to this variability via solar irradiance and energetic particle precipitation. Recent studies have found that energetic electron precipitation (EEP) affects the polar vortex by forming ozone depleting NOx compounds. However, it is still unknown how the EEP effect compares to variabilities caused by, e.g., solar irradiance or terrestrial drivers. In this study we examine the effects of EEP, solar irradiance, El-Niño-Southern Oscillation (ENSO), volcanic aerosols and quasi-biennial oscillation (QBO) on the northern wintertime atmosphere. We use geomagnetic Ap-index to quantify EEP activity, sunspot numbers to quantify solar irradiance, Niño 3.4 index for ENSO and aerosol optical depth for the amount of volcanic aerosols. We use a new composite dataset including ERA-40 and ERA-Interim reanalysis of zonal wind and temperature and multilinear regression analysis to estimate atmospheric responses to the above mentioned explaining variables in winter months of 1957–2017. We confirm the earlier results showing that EEP and QBO strengthen the polar vortex. We find here that the EEP effect on polar vortex is stronger and more significant than the effects of the other drivers in almost all winter months in most conditions. During 1957–2017 the considered drivers together explain about 25–35% of polar vortex variability while the EEP effect alone explains about 10–20% of it. Thus, a major part of variability is not due to the linear effect by the studied explaining variables. The positive EEP effect is particularly strong if QBO-wind at 30 hPa has been easterly during the preceding summer, while for a westerly QBO the EEP effect is weaker and less significant.

Published
2020

35. Dependence of sudden stratospheric warmings on internal and external drivers

Author

Salminen, A. (A.), Asikainen, T. (T.), Maliniemi, V. (V.), Mursula, K. (K.), Salminen, A. (A.), Asikainen, T. (T.), Maliniemi, V. (V.), and Mursula, K. (K.)

Abstract

A sudden stratospheric warming (SSW) is a large‐scale disturbance of the wintertime stratosphere, which occurs especially in the Northern Hemisphere. Earlier studies have shown that SSW occurrence depends on atmospheric internal factors and on solar activity. We examine SSW occurrence in northern winters 1957/1958–2016/2017, considering several factors that may affect the SSW occurrence: Quasi‐Biennial Oscillation (QBO), El Niño–Southern Oscillation (ENSO), geomagnetic activity, and solar radiation. We confirm the well‐known result that SSWs occur more often in easterly QBO phase than in westerly phase. We show that this difference depends on how the QBO phase is determined. We find that the difference in SSW occurrence between easterly and westerly QBO winters strengthens (weakens) if geomagnetic activity or solar activity is low (high), or if the ENSO is in a cold (warm) phase. In easterly QBO phase significantly more SSWs occur during low geomagnetic activity than high activity.

Published
2020

36. Cosmic noise absorption signature of particle precipitation during interplanetary coronal mass ejection sheaths and ejecta

Author

Kilpua, E. (Emilia), Juusola, L. (Liisa), Grandin, M. (Maxime), Kero, A. (Antti), Dubyagin, S. (Stepan), Partamies, N. (Noora), Osmane, A. (Adnane), George, H. (Harriet), Kalliokoski, M. (Milla), Raita, T. (Tero), Asikainen, T. (Timo), Palmroth, M. (Minna), Kilpua, E. (Emilia), Juusola, L. (Liisa), Grandin, M. (Maxime), Kero, A. (Antti), Dubyagin, S. (Stepan), Partamies, N. (Noora), Osmane, A. (Adnane), George, H. (Harriet), Kalliokoski, M. (Milla), Raita, T. (Tero), Asikainen, T. (Timo), and Palmroth, M. (Minna)

Abstract

We study here energetic-electron (E>30 keV) precipitation using cosmic noise absorption (CNA) during the sheath and ejecta structures of 61 interplanetary coronal mass ejections (ICMEs) observed in the near-Earth solar wind between 1997 and 2012. The data come from the Finnish riometer (relative ionospheric opacity meter) chain from stations extending from auroral (IVA, 65.2∘ N geomagnetic latitude; MLAT) to subauroral (JYV, 59.0∘ N MLAT) latitudes. We find that sheaths and ejecta lead frequently to enhanced CNA (>0.5 dB) both at auroral and subauroral latitudes, although the CNA magnitudes stay relatively low (medians around 1 dB). Due to their longer duration, ejecta typically lead to more sustained enhanced CNA periods (on average 6–7 h), but the sheaths and ejecta were found to be equally effective in inducing enhanced CNA when relative-occurrence frequency and CNA magnitude were considered. Only at the lowest-MLAT station, JYV, ejecta were more effective in causing enhanced CNA. Some clear trends of magnetic local time (MLT) and differences between the ejecta and sheaths were found. The occurrence frequency and magnitude of CNA activity was lowest close to midnight, while it peaked for the sheaths in the morning and afternoon/evening sectors and for the ejecta in the morning and noon sectors. These differences may reflect differences in typical MLT distributions of wave modes that precipitate substorm-injected and trapped radiation belt electrons during the sheaths and ejecta. Our study also emphasizes the importance of substorms and magnetospheric ultra-low-frequency (ULF) waves for enhanced CNA.

Published
2020

37. Influence of enhanced planetary wave activity on the polar vortex enhancement related to energetic electron precipitation

Author

Asikainen, T. (Timo), Salminen, A. (Antti), Maliniemi, V. (Ville), Mursula, K. (Kalevi), Asikainen, T. (Timo), Salminen, A. (Antti), Maliniemi, V. (Ville), and Mursula, K. (Kalevi)

Abstract

The Northern polar vortex experiences considerable interannual variability, which is also reflected to tropospheric weather. Recent research has established a link between polar vortex variations and energetic electron precipitation (EEP) from the near‐Earth space into the polar atmosphere, which is mediated by EEP‐induced chemical changes causing ozone loss in the mesosphere and stratosphere. The most dramatic changes in the polar vortex are due to sudden stratospheric warmings (SSWs). Enhanced planetary wave convergence and meridional circulation may cause an SSW, a temporary breakdown of the polar vortex. Here we study the relation of SSWs to the atmospheric response to EEP in 1957–2017 using combined ERA‐40 and ERA‐Interim reanalysis data and geomagnetic activity as a proxy of EEP. We find that the EEP‐related enhancement of the polar vortex and other associated dynamical responses are seen only during winters when an SSW occurs and that the EEP‐related changes are observed systematically slightly before the SSW onset. We show that during these times, the planetary wave activity into the stratosphere is systematically increased, thus favoring enhanced wave‐mean‐flow interaction, which can dynamically amplify the initial polar vortex enhancement caused by ozone loss. These results highlight the importance of considering planetary wave activity as a necessary condition for observing the effects of EEP on the polar vortex.

Published
2020

38. New homogeneous dataset of solar EUV synoptic maps from SOHO/EIT and SDO/AIA

Author

Hamada, A. (A.), Asikainen, T. (T.), Mursula, K. (K.), Hamada, A. (A.), Asikainen, T. (T.), and Mursula, K. (K.)

Abstract

Synoptic maps of solar EUV intensities have been constructed for many decades in order to display the distribution of the different EUV emissions across the solar surface, with each map representing one Carrington rotation (i.e. one rotation of the Sun). This article presents a new solar EUV synoptic map dataset based on full-disk images from the Solar and Heliospheric Observatory/Extreme Ultraviolet Imaging Telescope (SOHO/EIT) and Solar Dynamics Observatory/Atmospheric Imaging Assembly (SDO/AIA). In order to remove the significant and complicated drift of EIT and AIA EUV intensities due to sensor degradation, we construct the synoptic maps in standardized intensity scale. We describe a method of homogenizing the SOHO/EIT maps with SDO/AIA maps by transforming the EIT intensity histograms to AIA levels. The new maps cover the years from 1996 to 2018 with 307 SOHO/EIT and 116 SDO/AIA synoptic maps, respectively. These maps provide a systematic and homogeneous view of the entire solar surface in four EUV wavelengths, and are well suited, e.g., for studying long-term coronal hole evolution.

Published
2020

45. HEPPA III Intercomparison Experiment on Electron Precipitation Impacts: 1. Estimated Ionization Rates During a Geomagnetic Active Period in April 2010.

Author

Tyssøy, H. Nesse, Sinnhuber, M., Asikainen, T., Bender, S., Clilverd, M. A., Funke, B., van de Kamp, M., Pettit, J. M., Randall, C. E., Reddmann, T., Rodger, C. J., Rozanov, E., Smith-Johnsen, C., Sukhodolov, T., Verronen, P. T., Wissing, J. M., and Yakovchuk, O.

Subjects
ELECTRON precipitation, VAN Allen radiation belts, MAGNETOSPHERE, GEOMAGNETISM, ELECTRON impact ionization
Abstract

Precipitating auroral and radiation belt electrons are considered an important part of the natural forcing of the climate system. Recent studies suggest that this forcing is underestimated in current chemistryclimate models. The High Energy Particle Precipitation in the Atmosphere III intercomparison experiment is a collective effort to address this point. Here, eight different estimates of medium energy electron (MEE) (>30 keV) ionization rates are assessed during a geomagnetic active period in April 2010. The objective is to understand the potential uncertainty related to the MEE energy input. The ionization rates are all based on the Medium Energy Proton and Electron Detector (MEPED) on board the NOAA/POES and EUMETSAT/MetOp spacecraft series. However, different data handling, ionization rate calculations, and background atmospheres result in a wide range of mesospheric electron ionization rates. Although the eight data sets agree well in terms of the temporal variability, they differ by about an order of magnitude in ionization rate strength both during geomagnetic quiet and disturbed periods. The largest spread is found in the aftermath of enhanced geomagnetic activity. Furthermore, governed by different energy limits, the atmospheric penetration depth varies, and some differences related to latitudinal coverage are also evident. The mesospheric NO densities simulated with the Whole Atmospheric Community Climate Model driven by highest and lowest ionization rates differ by more than a factor of eight. In a follow-up study, the atmospheric responses are simulated in four chemistry-climate models (CCM) and compared to satellite observations, considering both the CCM structure and the ionization forcing. [ABSTRACT FROM AUTHOR]

Published
2022
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46. Effect of energetic electron precipitation on the northern polar vortex:explaining the QBO modulation via control of meridional circulation

Author

Salminen, A. (A.), Asikainen, T. (T.), Maliniemi, V. (V.), and Mursula, K. (K.)

Subjects
polar vortex, QBO, ozone, stratosphere, energetic electron precipitation
Abstract

Energetic electron precipitation (EEP) affects the high‐latitude middle atmosphere by producing NOₓ compounds that destroy ozone. Earlier studies have shown that in the wintertime polar stratosphere, increased EEP enhances the westerly wind surrounding the pole, the polar vortex. This EEP effect has been found to depend on the quasi‐biennial oscillation (QBO) of equatorial winds, but the mechanism behind this modulation has so far remained unresolved. In this study we examine the atmospheric effect of EEP and its modulation by QBO using the corrected electron flux measurements by NOAA/POES satellites and the ERA‐Interim reanalysis data of zonal wind, temperature, and ozone in winter months of 1980–2016. We verify the EEP‐related strengthening of the polar vortex, warming (cooling) in the upper (lower) stratosphere and a reduction of ozone mass mixing ratio in the polar stratosphere. We also verify that the EEP effect is stronger and more significant especially in late winter, when the QBO at 30 hPa is easterly. We find here that the difference in the EEP effect between the two QBO phases is largest using a roughly 6‐month lag for QBO. We demonstrate that ozone mass mixing ratio in the lower polar stratosphere, a proxy for the strength of Brewer‐Dobson circulation, is also larger during QBO‐E than QBO‐W, with the difference maximizing when the QBO is lagged by 6 months. Our findings indicate that the modulation of the Brewer‐Dobson circulation by QBO controls how the EEP affects the polar vortex.

Published
2019

47. Assessing North Atlantic winter climate response to geomagnetic activity and solar irradiance variability

Author

Maliniemi, V. (Ville), Asikainen, T. (Timo), Salminen, A. (Antti), Mursula, K. (Kalevi), Maliniemi, V. (Ville), Asikainen, T. (Timo), Salminen, A. (Antti), and Mursula, K. (Kalevi)

Abstract

Recent studies suggest a response in the North Atlantic winter circulation which lags by a couple of years with respect to sunspot maximum. This has been explained by two different top‐down mechanisms: a solar wind driven particle effect in the polar atmosphere during the declining phase of the solar cycle, and the re‐emergence and amplification of heat anomalies in the Atlantic Ocean produced by enhanced solar ultraviolet (UV). Here we study how December to February climate is affected by two solar‐related drivers: geomagnetic activity (proxy of particle precipitation) and sunspot activity (proxy of solar UV) during 1948–2017. We use reanalysis data of sea‐level pressure (SLP) and zonal wind (U) to show that both geomagnetic activity and sunspot activity independently and simultaneously produce atmospheric circulation responses in the North Atlantic whose evolutions clearly differ from each other. Geomagnetic activity produces a strengthening of the polar vortex and a negative poleward SLP gradient between mid‐ and high latitudes, resembling a positive NAO‐type circulation pattern during December to February. Solar UV produces a positive U anomaly in the low‐latitude stratosphere during December, which moves poleward and downward during the winter resulting in a negative poleward SLP gradient between mid‐ and high latitudes during February. We find the lagged sunspot activity responses in SLP to form zonal pressure patterns (wave‐train structure) resembling the Eurasian pattern. Geomagnetic activity responses remain essentially the same when we introduce the lag with respect to sunspot activity supporting its independency as a driving mechanism. Our results suggest that solar wind related particle precipitation and (lagged) solar UV mechanism provide independent, significant circulation signals in the North Atlantic winter.

Published
2019

48. FORESAIL‐1 CubeSat mission to measure radiation belt losses and demonstrate deorbiting

Author

Palmroth, M. (M.), Praks, J. (J.), Vainio, R. (R.), Janhunen, P. (P.), Kilpua, E. K. (E. K. J.), Afanasiev, A. (A.), Ala-Lahti, M. (M.), Alho, A. (A.), Asikainen, T. (T.), Asvestari, E. (E.), Battarbee, M. (M.), Binios, A. (A.), Bosser, A. (A.), Brito, T. (T.), Dubart, M. (M.), Envall, J. (J.), Ganse, U. (U.), Ganushkina, N. Y. (N. Yu.), George, H. (H.), Gieseler, J. (J.), Good, S. (S.), Grandin, M. (M.), Haslam, S. (S.), Hedman, H.-P. (H.-P.), Hietala, H. (H.), Jovanovic, N. (N.), Kakakhel, S. (S.), Kalliokoski, M. (M.), Kettunen, V. V. (V. V.), Koskela, T. (T.), Lumme, E. (E.), Meskanen, M. (M.), Morosan, D. (D.), Rizwan Mughal, M. (M.), Niemelä, P. (P.), Nyman, S. (S.), Oleynik, P. (P.), Osmane, A. (A.), Palmerio, E. (E.), Peltonen, J. (J.), Pfau-Kempf, Y. (Y.), Plosila, J. (J.), Polkko, J. (J.), Poluianov, S. (S.), Pomoell, J. (J.), Price, D. (D.), Punkkinen, A. (A.), Punkkinen, R. (R.), Riwanto, B. (B.), Salomaa, L. (L.), Slavinskis, A. (A.), Säntti, T. (T.), Tammi, J. (J.), Tenhunen, H. (H.), Toivanen, P. (P.), Tuominen, J. (J.), Turc, L. (L.), Valtonen, E. (E.), Virtanen, P. (P.), Westerlund, T. (T.), Palmroth, M. (M.), Praks, J. (J.), Vainio, R. (R.), Janhunen, P. (P.), Kilpua, E. K. (E. K. J.), Afanasiev, A. (A.), Ala-Lahti, M. (M.), Alho, A. (A.), Asikainen, T. (T.), Asvestari, E. (E.), Battarbee, M. (M.), Binios, A. (A.), Bosser, A. (A.), Brito, T. (T.), Dubart, M. (M.), Envall, J. (J.), Ganse, U. (U.), Ganushkina, N. Y. (N. Yu.), George, H. (H.), Gieseler, J. (J.), Good, S. (S.), Grandin, M. (M.), Haslam, S. (S.), Hedman, H.-P. (H.-P.), Hietala, H. (H.), Jovanovic, N. (N.), Kakakhel, S. (S.), Kalliokoski, M. (M.), Kettunen, V. V. (V. V.), Koskela, T. (T.), Lumme, E. (E.), Meskanen, M. (M.), Morosan, D. (D.), Rizwan Mughal, M. (M.), Niemelä, P. (P.), Nyman, S. (S.), Oleynik, P. (P.), Osmane, A. (A.), Palmerio, E. (E.), Peltonen, J. (J.), Pfau-Kempf, Y. (Y.), Plosila, J. (J.), Polkko, J. (J.), Poluianov, S. (S.), Pomoell, J. (J.), Price, D. (D.), Punkkinen, A. (A.), Punkkinen, R. (R.), Riwanto, B. (B.), Salomaa, L. (L.), Slavinskis, A. (A.), Säntti, T. (T.), Tammi, J. (J.), Tenhunen, H. (H.), Toivanen, P. (P.), Tuominen, J. (J.), Turc, L. (L.), Valtonen, E. (E.), Virtanen, P. (P.), and Westerlund, T. (T.)

Abstract

Today, the near‐Earth space is facing a paradigm change as the number of new spacecraft is literally skyrocketing. Increasing numbers of small satellites threaten the sustainable use of space, as without removal, space debris will eventually make certain critical orbits unusable. A central factor affecting small spacecraft health and leading to debris is the radiation environment, which is unpredictable due to an incomplete understanding of the near‐Earth radiation environment itself and its variability driven by the solar wind and outer magnetosphere. This paper presents the FORESAIL‐1 nanosatellite mission, having two scientific and one technological objectives. The first scientific objective is to measure the energy and flux of energetic particle loss to the atmosphere with a representative energy and pitch angle resolution over a wide range of magnetic local times. To pave the way to novel model‐in situ data comparisons, we also show preliminary results on precipitating electron fluxes obtained with the new global hybrid‐Vlasov simulation Vlasiator. The second scientific objective of the FORESAIL‐1 mission is to measure energetic neutral atoms of solar origin. The solar energetic neutral atom flux has the potential to contribute importantly to the knowledge of solar eruption energy budget estimations. The technological objective is to demonstrate a satellite deorbiting technology, and for the first time, make an orbit maneuver with a propellantless nanosatellite. FORESAIL‐1 will demonstrate the potential for nanosatellites to make important scientific contributions as well as promote the sustainable utilization of space by using a cost‐efficient deorbiting technology.

Published
2019

49. New homogeneous composite of energetic electron fluxes from POES:2. Intercalibration of SEM‐1 and SEM‐2

Author

Asikainen, T. (T.) and Asikainen, T. (T.)

Abstract

One of the most popular long‐term data sets of energetic particles used in, for example, long‐term radiation belt studies and in atmospheric/climate studies is perhaps the NOAA/POES (Polar Orbiting Environmental Satellites) data set, which extends nearly continuously from 1979 to present. The present study aims to construct a new homogeneous long‐term composite record of daily latitude distributions of energetic electrons based on the MEPED (Medium Energy Proton and Electron Detector) data. Part 1 of this study corrected the data for temporally varying background noise related to cosmic rays and for the drift in the orientation of satellite orbital planes. The present paper addresses the final and most severe problem for the data homogeneity, caused by the difference of telescope pointing directions in older SEM‐1 and newer SEM‐2 versions of the MEPED instrument. Because the telescope pitch angles and the electron pitch angle distribution change with latitude, the difference in SEM‐1 and SEM‐2 fluxes depends on latitude and varies from time to time. The systematic flux differences between SEM‐1 and SEM‐2 can range between a factor of 1.5 to more than an order of magnitude. Novel statistical methodology based on principal components and canonical correlation mapping is presented here to robustly transform the daily SEM‐1 electron latitude distributions into SEM‐2 level. The data from different POES satellites are then combined into a spatially and temporally homogeneous composite series, which is well suited, for example, for long‐term studies of radiation belts and precipitation related atmospheric ionization and its chemical and dynamical effects in the atmosphere/climate system. This article is a companion to Asikainen and Ruopsa (2019), https://doi.org/10.1029/2018JA026214, http://urn.fi/urn:nbn:fi-fe2019042312984.

Published
2019

50. New homogeneous composite of energetic electron fluxes from POES satellites:1. Correction for background noise and orbital drift

Author

Asikainen, T. (Timo), Ruopsa, M. (Miro), Asikainen, T. (Timo), and Ruopsa, M. (Miro)

Abstract

One of the most popular long‐term data sets of energetic particles used in, for example, long‐term radiation belt studies and in atmospheric/climate studies is perhaps the National Oceanic and Atmospheric Administration/Polar Orbiting Environmental Satellites (POES) data set, which extends nearly continuously from 1979 to present. The energetic particle measurements by the Medium Energy Proton and Electron Detector instrument onboard the POES satellites have had many instrumental problems, which have made quantitative estimates of energetic particle fluxes somewhat difficult. However, in the recent years, these instrumental deficiencies have been studied and corrected. Here we aim to construct a new long‐term composite record of energetic electrons based on the Medium Energy Proton and Electron Detector data. In this study we point out that there are also other remaining factors, not related to instrument construction, which still severely impact the overall homogeneity of the 39‐year POES data set. We concentrate here on studying and correcting two issues: (1) temporally varying background noise related to cosmic rays and (2) drift in the orientation of satellite orbital planes, which changes the sampling location of the satellites over time. In particular, we show that the drift of satellite orbital planes leads to rather large changes in the electron fluxes over time, which could be misinterpreted as true temporal changes without the corrections. These changes can be rather large, a factor of 3 or more in the poleward edge of the precipitation zone, and are likely to have a large impact, for example, on atmospheric ionization estimates based on POES data. This article is a companion to Asikainen, T. ( 2019). New homogeneous composite of energetic electron fluxes from POES: 2. Intercalibration of SEM‐1 and SEM‐2. Journal of Geophysical Research: Space Physics, 124. https://doi.org/10.1029/2019JA026699, http://urn.fi/urn:nbn:fi-fe2019092630047.

Published
2019

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