Title Modulacija galaktičkih kozmičkih zraka međuplanetarnim udarnim valom
Title (english) Galactic cosmic rays modulation by interplanetary shock wave
Author Anamarija Kirin
Mentor Bojan Vršnak (mentor)
Committee member Tihomir Surić (predsjednik povjerenstva)
Committee member Bojan Vršnak (član povjerenstva)
Committee member Maro Cvitan (član povjerenstva)
Granter University of Zagreb Faculty of Science (Department of Physics) Zagreb
Defense date and country 2021-04-26, Croatia
Scientific / art field, discipline and subdiscipline NATURAL SCIENCES Physics
Universal decimal classification (UDC ) 53 - Physics
Abstract Kozmičkim zrakama naziva se sveukupni tok visokoenergetskih čestica koji dolazi iz svemira i dopire do Zemlje. Galaktičke kozmičke zrake (eng. Galactic Cosmic Rays, GCR) potječu izvan Sunčevog sustava i imaju najveće energije. Tok GCR-a moduliran je Sunčevom aktivnošću tako da pojačana Sunčeva aktivnost štiti Zemlju od GCR-a. Promatramo sporadične promjene toka GCR uzrokovane koroninim izbačajima (tzv. Forbusheva smanjenja) koje obično traju oko tjedan dana i imaju nagli nastanak i postupni oporavak. Najveća opažena Forbusheva smanjena, vezana uz koronine izbačaje s udarnim valom, odvijaju se u dva koraka. Prvi korak smanjenja posljedica je udarnog vala i trubulentnog magnetskog polja iza njega, a drugi korak nastaje zbog magnetske strukture koroninog izbačaja. Udarni val i turbulentno područje iza njega znatno se razlikuju po dimenzijama, ali i fizikalnim mehanizmima koji uzrokuju smanjenje toka čestica pa je važno razdvojiti njihov utjecaj i proučavati ih zasebno. Ovdje se detaljno razmatraju procesi koji se javljaju pri prolasku visoko-energetskih čestica kroz udarni val, te je predstavljen model temeljen na jednočestičnom pristupu koji je opravdan s obzirom na mali broj zastupljenih čestica. Udarni val modeliran je strukturom unutar koje se magnetsko polje linearno mijenja. Numerički izračunate putanje čestica pokazuju širok spektar ponašanja čestica ovisno o svojstvima udarnog vala (jakost magnetskog polja, kut između silnica magnetskog polja i normale udarnog vala te debljina udarnog vala) i karakteristika same čestice (energija čestice i upadni kut). Rezultati pokazuju da se čestice viših energija teže reflektiraju. S druge strane udarni valovi veće debljine i te oni s jačim magnetkim poljem lakše reflektiraju čestice. Osim udarnog vala, smanjenje toka GCR uzrokuje i sama magnetska struktura CME-a. U nastavku je proširen analitički difuzijsko-ekspanzijski model Forbushevog smanjenja, ForbMod, tako da u obzir uzima čestice energija u rasponu od 50 MeV do 100 GeV. Na temelju izmjerenih Forbushevih smanjenja i difuzijsko-ekspanzijskog modela određen je aksijalni magnetski tok u blizini Sunca za nekoliko događaja u periodu od travnja 2010. do svibnja 2014. godine.
Abstract (english) Galactic cosmic rays (GCR) consist of high-energy particles that originate far outside solar system and reach the Earth. Studies show that for every decrease in GCR intensity there is an increase in interplanetary magnetic field (IMF). Interplanetary magnetic field can be increased due to different phenomena in solar atmosphere, such as coronal mass ejections (CMEs) – phenomena driven by the energy released from magnetic field. Furthermore, for every increase in IMF there is a decrease in GCR intensity. Such a short-term depression in the GCR count is called Forbush decrease (FDs) and it is named after the American physicist Scott E. Forbush who discovered it in 1937. Forbush decreases can be observed by particle detectors several days after the CME. Forbush decreases caused by fast coronal mass ejections (CMEs) often show a two-step decrease where the first step is attributed to the shock/sheath region, while the second step is attributed to the closed magnetic structure. Since the difference in size of shock and sheath region is significant, and since there are observed effects that can be related to shocks and not necessarily to the sheath region we expect that the physical mechanisms governing the interaction with GCRs in these two regions are different. We therefore aim to analyse interaction of GCRs with heliospheric shocks only. First we study the role of two physical mechanisms that could directly affect the galactic cosmic ray (GCR) count rate in the shock-sheath region ahead of the CME. These are the magnetic mirror effect at the shock front and the magnetic field compression behind the shock. The effects of the mentioned two mechanisms for the shock-related phase of the FD are quantified by employing a simplified magnetic configuration that includes an oblique magnetohydrodynamical (MHD) fast-mode shock. Using the jump relations at the shock we determine the fraction of GCR particles that are mirrored at the shock, as well as the increase of the unit-area flux of the transmitted particles due to the compression of the magnetic field in the downstream region. A combination of these two effects results in a decrease of the GCR count rate. The calculated FD amplitudes attain values up to 45 %, which is much larger than are the observed amplitudes. This confirms that the magnetic mirror approximation is not a valid one which is already indicated by the fact that the shock thickness is much smaller than the gyro-radius of the GCR particle (proton). In the next step we approximate the shock by a structure where the magnetic field linearly changes with position within this structure. We assume protons of different energy, different pitch angle and different incoming direction and also vary the shock parameters such as the magnetic field strength and orientation, as well as the shock thickness. We solve the set of three differential equations to obtain proton trajectories for different initial speed components, i.e. different initial conditions. The results are in an agreement with observations and demonstrate that protons with higher energies are less likely to be reflected. Also, thicker shocks and shocks iv with stronger field reflect protons more efficiently. In the second part of this research we focus on the magnetic structure of the CME. We use the observationally obtained FD amplitude to determine the flux rope (FR) expansion parameters. We use the diffusion-expansion model, ForbMod (Dumbović et al., 2018). This model is based on the assumption that the FR is a long expanding cylinder and GCR particles enter the FR via perpendicular diffusion. In the original model it is assumed that all particles have the same energy, i.e. rigidity of 1 GV which corresponds to the most common energy in energy spectrum. Parameters of expansion can be analytically expressed according to Eq. (1) in Rodari et al. (2018). We compare the values obtained by this simple model with the values obtained numerically from the same model adjusted to include particles with energies ranging from 50 MeV to 100 GeV. In that case expansion parameters can not be expressed analytically and have to be calculated numerically. The values obtained both ways are then used to determine axial magnetic flux near the Sun. These values of magnetic flux are compared to the values obtained using Eq. (6) in Scolini et al., (2020). They use an independent method based on the connection between CME kinematics and magnetic reconnection during and immediately after the eruption. Results indicate that ForbMod model is not applicable for the events where the expansion speed is small or even negative. For these events, magnetic fluxes were several orders of magnitude larger than expected. The smallest discrepancies in results are found in the events where the power-law index of magnetic flux expansion are large.
Keywords
galaktičke kozmičke zrake
Forbusheva smanjenja
magnetohidrodinamički udarni valovi
koronini izbačaji
usukano magnetsko uže
Keywords (english)
galactic gosmic rays
Forbush decreases
magnetohydrodynamical shock waves
coronal mass ejections
flux rope
Language croatian
URN:NBN urn:nbn:hr:217:958837
Promotion 2021
Study programme Title: Physics Study programme type: university Study level: postgraduate Academic / professional title: doktor/doktorica znanosti, područje prirodnih znanosti, polje fizika (doktor/doktorica znanosti, područje prirodnih znanosti, polje fizika)
Type of resource Text
Extent XVI, 81 str.
File origin Born digital
Access conditions Open access
Terms of use
Created on 2021-05-03 11:35:01