Physical Processes Involved in the EUV “Surge” Event of 9 May 2012

López Fuentes, M.; Mandrini, C.H.; Poisson, M.; Démoulin, P.; Cristiani, G.; López, F.M.; Luoni, M.L.

doi:10.1007/s11207-018-1384-4

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López Fuentes, M.; Mandrini, C.H.; Poisson, M.; Démoulin, P.; Cristiani, G.; López, F.M.; Luoni, M.L. "Physical Processes Involved in the EUV “Surge” Event of 9 May 2012" (2018) Solar Physics. 293(12)

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Abstract:

We study an extreme ultraviolet (EUV) confined ejection observed on 9 May 2012 in Active Region (AR) NOAA 11476. For the analysis we use observations in multiple wavelengths (EUV, X-rays, Hα , and magnetograms) from a variety of ground- and space-based instruments. The magnetic configuration showed two rotating bipoles within the following polarity of the AR. This evolution was present some tens of hours before the studied event and continued thereafter. During this period, the magnetic flux of both bipoles continuously decreased. A mini-filament with a length of ≈30″ lay along the photospheric inversion line of the largest bipole. The mini-filament was observed to erupt, accompanied by an M4.7 flare (SOL20120509T12:23:00). This injected dense material as well as twist along closed loops in the form of a very broad ejection whose morphology resembled that of typical Hα surges. We conclude that the flare and eruption can be explained as due to two reconnection processes, one occurring below the erupting mini-filament, and another above it. This second process injects the mini-filament plasma within the reconnected closed loops linking the main AR polarities. By analyzing the magnetic topology using a force-free model of the coronal field, we identify the location of quasi-separatix layers, where reconnection is prone to occur, and present a detailed interpretation of the chromospheric and coronal eruption observations. In particular, this event, in contrast to what has been proposed in several models explaining surges and/or jets, is not produced by magnetic flux emergence, but by magnetic flux cancellation accompanied by the rotation of the bipoles. In fact, the conjunction of these two processes, flux cancellation and bipole rotations, is at the origin of a series of events, homologous to the event we analyze in this article, which occurred in AR 11476 from 8 to 10 May 2012. © 2018, Springer Media B.V.

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Documento:	Artículo
Título:	Physical Processes Involved in the EUV “Surge” Event of 9 May 2012
Autor:	López Fuentes, M.; Mandrini, C.H.; Poisson, M.; Démoulin, P.; Cristiani, G.; López, F.M.; Luoni, M.L.
Filiación:	Instituto de Astronomía y Física del Espacio (IAFE), CONICET-UBA, Buenos Aires, Argentina Facultad de Ciencias Exactas y Naturales (FCEN), UBA, Buenos Aires, Argentina LESIA, Observatoire de Paris, Université PSL, CNRS, Sorbonne Université, Univ. Paris Diderot, Sorbonne Paris Cité, 5 place Jules Janssen, Meudon, Paris, 92195, France Instituto de Ciencias Astronómicas, de la Tierra y del Espacio (ICATE), CONICET, San Juan, Argentina
Palabras clave:	Active Regions, Models; Flares, Relation to Magnetic Field; Jets; Magnetic Reconnection, Observational Signatures; Surges
Año:	2018
Volumen:	293
Número:	12
DOI:	http://dx.doi.org/10.1007/s11207-018-1384-4
Título revista:	Solar Physics
Título revista abreviado:	Sol. Phys.
ISSN:	00380938
Registro:	https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_00380938_v293_n12_p_LopezFuentes

Referencias:

Adams, M., Sterling, A.C., Moore, R.L., Gary, G.A., A small-scale eruption leading to a blowout macrospicule jet in an on-disk coronal hole (2014) Astrophys. J., 783, p. 11. , ADS
Alissandrakis, C.E., On the computation of constant alpha force-free magnetic field (1981) Astron. Astrophys., 100, p. 197. , ADS
Antiochos, S.K., DeVore, C.R., Klimchuk, J.A., A model for solar coronal mass ejections (1999) Astrophys. J., 510, p. 485. , ADS
Aulanier, G., Pariat, E., Démoulin, P., Current sheet formation in quasi-separatrix layers and hyperbolic flux tubes (2005) Astron. Astrophys., 444, p. 961. , ADS
Aulanier, G., Török, T., Démoulin, P., DeLuca, E.E., Formation of torus-unstable flux ropes and electric currents in erupting sigmoids (2010) Astrophys. J., 708, p. 314. , ADS
Bagalá, L.G., Bauer, O.H., Fernández Borda, R., Francile, C., Haerendel, G., Rieger, R., Rovira, M.G., The new H α solar telescope at the German–Argentinian solar observatory (1999) Magnetic Fields and Solar Processes, 448, p. 469. , Wilson A., (ed), ESA Special Publication, ADS
Bagalá, L.G., Mandrini, C.H., Rovira, M.G., Démoulin, P., Magnetic reconnection: a common origin for flares and AR interconnecting arcs (2000) Astron. Astrophys., 363, p. 779. , ADS
Brooks, D.H., Kurokawa, H., Berger, T.E., An H α surge provoked by moving magnetic features near an emerging flux region (2007) Astrophys. J., 656, p. 1197. , ADS
Büchner, J., Locating current sheets in the solar corona (2006) Space Sci. Rev., 122, p. 149. , ADS
Canfield, R.C., Reardon, K.P., Leka, K.D., Shibata, K., Yokoyama, T., Shimojo, M., H alpha surges and X-ray jets in AR 7260 (1996) Astrophys. J., 464, p. 1016. , ADS
Chae, J., Qiu, J., Wang, H., Goode, P.R., Extreme-ultraviolet jets and H α surges in solar microflares (1999) Astrophys. J. Lett., 513, p. L75. , ADS
Chandra, R., Mandrini, C.H., Schmieder, B., Joshi, B., Cristiani, G.D., Cremades, H., Pariat, E., Uddin, W., Blowout jets and impulsive eruptive flares in a bald-patch topology (2017) Astron. Astrophys., 598. , ADS
Cristiani, G., Martinez, G., Mandrini, C.H., Giménez de Castro, C.G., da Silva, C.W., Rovira, M.G., Kaufmann, P., Spatial characterization of a flare using radio observations and magnetic field topology (2007) Solar Phys., 240, p. 271. , ADS
Démoulin, P., Extending the concept of separatrices to QSLs for magnetic reconnection (2006) Adv. Space Res., 37, p. 1269. , ADS
Démoulin, P., Hénoux, J.C., Priest, E.R., Mandrini, C.H., Quasi-separatrix layers in solar flares. I. Method (1996) Astron. Astrophys., 308, p. 643. , ADS
Démoulin, P., Bagalá, L.G., Mandrini, C.H., Hénoux, J.C., Rovira, M.G., Quasi-separatrix layers in solar flares. II. Observed magnetic configurations (1997) Astron. Astrophys., 325, p. 305. , ADS
Effenberger, F., Thust, K., Arnold, L., Grauer, R., Dreher, J., Numerical simulation of current sheet formation in a quasi-separatrix layer using adaptive mesh refinement (2011) Phys. Plasmas, 18, p. 32902
Fernandez Borda, R.A., Mininni, P.D., Mandrini, C.H., Gómez, D.O., Bauer, O.H., Rovira, M.G., Automatic solar flare detection using neural network techniques (2002) Solar Phys., 206, p. 347. , ADS
Foukal, P.V., (2004) Solar Astrophysics, p. 480. , 2, ADS
Golub, L., Deluca, E., Austin, G., Bookbinder, J., Caldwell, D., Cheimets, P., The X-Ray Telescope (XRT) for the Hinode mission (2007) Solar Phys., 243, p. 63. , ADS
Green, L.M., López fuentes, M.C., Mandrini, C.H., Démoulin, P., Van Driel-Gesztelyi, L., Culhane, J.L., The magnetic helicity budget of a cme-prolific active region (2002) Solar Phys., 208, p. 43. , ADS
Guglielmino, S.L., Bellot Rubio, L.R., Zuccarello, F., Aulanier, G., Vargas Domínguez, S., Kamio, S., Multiwavelength observations of small-scale reconnection events triggered by magnetic flux emergence in the solar atmosphere (2010) Astrophys. J., 724, p. 1083. , ADS
Guo, Y., Démoulin, P., Schmieder, B., Ding, M.D., Vargas Domínguez, S., Liu, Y., Recurrent coronal jets induced by repetitively accumulated electric currents (2013) Astron. Astrophys., 555. , ADS
Harrison, R.A., Sime, D.G., Pearce, G., The surge events of June 28 and October 30, 1980 (1990) Astron. Astrophys., 238, p. 347. , ADS
Heyvaerts, J., Priest, E., Rust, D.M., An emerging flux model for solar flares (1977) Solar Phys., 53, p. 255. , ADS
Howard, R.A., Moses, J.D., Vourlidas, A., Newmark, J.S., Socker, D.G., Plunkett, S.P., Sun Earth connection coronal and heliospheric investigation (SECCHI) (2008) Space Sci. Rev., 136, p. 67. , ADS
Janvier, M., Aulanier, G., Pariat, E., Démoulin, P., The standard flare model in three dimensions. III. Slip-running reconnection properties (2013) Astron. Astrophys., 555. , ADS
Janvier, M., Savcheva, A., Pariat, E., Tassev, S., Millholland, S., Bommier, V., McCauley, P., Dougan, F., Evolution of flare ribbons, electric currents, and quasi-separatrix layers during an X-class flare (2016) Astron. Astrophys., 591. , ADS
Jibben, P., Canfield, R.C., Twist propagation in H α surges (2004) Astrophys. J., 610, p. 1129. , ADS
Joshi, N.C., Liu, C., Sun, X., Wang, H., Magara, T., Moon, Y.-J., The role of erupting sigmoid in triggering a flare with parallel and large-scale quasi-circular ribbons (2015) Astrophys. J., 812, p. 50. , ADS
Joshi, N.C., Sterling, A.C., Moore, R.L., Magara, T., Moon, Y.-J., Onset of a large ejective solar eruption from a typical coronal-jet-base field configuration (2017) Astrophys. J., 845, p. 26. , ADS
Joshi, N.C., Nishizuka, N., Filippov, B., Magara, T., Tlatov, A.G., Flux rope breaking and formation of a rotating blowout jet (2018) Mon. Not. Roy. Astron. Soc., 476, p. 1286. , ADS
Karpen, J.T., Antiochos, S.K., DeVore, C.R., The mechanisms for the onset and explosive eruption of coronal mass ejections and eruptive flares (2012) Astrophys. J., 760, p. 81. , ADS
Lemen, J.R., Title, A.M., Akin, D.J., Boerner, P.F., Chou, C., Drake, J.F., The atmospheric imaging assembly (AIA) on the solar dynamics observatory (SDO) (2012) Solar Phys., 275, p. 17. , ADS
Li, H., Yang, J., Jiang, Y., Bi, Y., Qu, Z., Chen, H., The surge-like eruption of a miniature filament associated with circular flare ribbon (2018) Astrophys. Space Sci., 363, p. 26. , ADS
Lin, R.P., Dennis, B.R., Hurford, G.J., Smith, D.M., Zehnder, A., Harvey, P.R., The Reuven Ramaty High-Energy Solar Spectroscopic Imager (RHESSI) (2002) Solar Phys., 210, p. 3. , ADS
Liu, Y., Kurokawa, H., On a surge: properties of an emerging flux region (2004) Astrophys. J., 610, p. 1136. , ADS
Liu, C., Deng, N., Liu, R., Ugarte-Urra, I., Wang, S., Wang, H., A standard-to-blowout jet (2011) Astrophys. J. Lett., 735, p. L18. , ADS
Longcope, D.W., Topological methods for the analysis of solar magnetic fields (2005) Living Rev. Solar Phys., 2, p. 7. , ADS
López Fuentes, M.C., Klimchuk, J.A., Mandrini, C.H., The temporal evolution of coronal loops observed by GOES SXI (2007) Astrophys. J., 657, p. 1127. , ADS
López Fuentes, M.C., Poisson, M., Mandrini, C.H., Luoni, M.L., Cristiani, G.D., Démoulin, P., Análisis de un evento eyectivo en una arcada cerrada (2015) CRAAA, 58, p. 37. , http://www.astronomiaargentina.org.ar/uploads/docs/craaa58.pdf
MacTaggart, D., Guglielmino, S.L., Haynes, A.L., Simitev, R., Zuccarello, F., The magnetic structure of surges in small-scale emerging flux regions (2015) Astron. Astrophys., 576. , ADS
Mandrini, C.H., Magnetic energy release: flares and coronal mass ejections (2010) IAU Symposium, 264, p. 257. , Kosovichev A.G., Andrei A.H., Rozelot J.-P., (eds), ADS
Mandrini, C.H., Démoulin, P., van Driel-Gesztelyi, L., Schmieder, B., Cauzzi, G., Hofmann, A., 3D magnetic reconnection at an X-ray bright point (1996) Solar Phys., 168, p. 115. , ADS
Mandrini, C.H., Démoulin, P., Schmieder, B., Deng, Y.Y., Rudawy, P., The role of magnetic bald patches in surges and arch filament systems (2002) Astron. Astrophys., 391, p. 317. , ADS
Mandrini, C.H., Demoulin, P., Schmieder, B., Deluca, E.E., Pariat, E., Uddin, W., Companion event and precursor of the X17 flare on 28 October 2003 (2006) Solar Phys., 238, p. 293. , ADS
Mandrini, C.H., Schmieder, B., Démoulin, P., Guo, Y., Cristiani, G.D., Topological analysis of emerging bipole clusters producing violent solar events (2014) Solar Phys., 289, p. 2041. , ADS
Mandrini, C.H., Baker, D., Démoulin, P., Cristiani, G.D., van Driel-Gesztelyi, L., Vargas Domínguez, S., Nuevo, F.A., Pick, M., Parallel evolution of quasi-separatrix layers and active region upflows (2015) Astrophys. J., 809, p. 73. , ADS
Masson, S., Pariat, E., Aulanier, G., Schrijver, C.J., The nature of flare ribbons in coronal null-point topology (2009) Astrophys. J., 700, p. 559. , ADS
Masson, S., Aulanier, G., Pariat, E., Klein, K.-L., Interchange slip-running reconnection and sweeping SEP beams (2012) Solar Phys., 276, p. 199. , ADS
Masson, S., Pariat, É., Valori, G., Deng, N., Liu, C., Wang, H., Reid, H., Flux rope, hyperbolic flux tube, and late extreme ultraviolet phases in a non-eruptive circular-ribbon flare (2017) Astron. Astrophys., 604. , ADS
Milano, L.J., Dmitruk, P., Mandrini, C.H., Gómez, D.O., Démoulin, P., Quasi-separatrix layers in a reduced magnetohydrodynamic model of a coronal loop (1999) Astrophys. J., 521, p. 889
Moore, R.L., Sterling, A.C., Panesar, N.K., Onset of the magnetic explosion in solar polar coronal X-ray jets (2018) Astrophys. J., 859, p. 3. , ADS
Moore, R.L., Cirtain, J.W., Sterling, A.C., Falconer, D.A., Dichotomy of solar coronal jets: standard jets and blowout jets (2010) Astrophys. J., 720, p. 757. , ADS
Moreno-Insertis, F., Galsgaard, K., Plasma jets and eruptions in solar coronal holes: a three-dimensional flux emergence experiment (2013) Astrophys. J., 771, p. 20. , ADS
Nóbrega-Siverio, D., Moreno-Insertis, F., Martínez-Sykora, J., The cool surge following flux emergence in a radiation-MHD experiment (2016) Astrophys. J., 822, p. 18. , ADS
Panesar, N.K., Sterling, A.C., Moore, R.L., Homologous jet-driven coronal mass ejections from solar active region 12192 (2016) Astrophys. J. Lett., 822, p. L23. , ADS
Panesar, N.K., Sterling, A.C., Moore, R.L., Chakrapani, P., Magnetic flux cancelation as the trigger of solar quiet-region coronal jets (2016) Astrophys. J. Lett., 832, p. L7. , ADS
Pariat, E., Antiochos, S.K., DeVore, C.R., A model for solar polar jets (2009) Astrophys. J., 691, p. 61. , ADS
Pariat, E., Antiochos, S.K., DeVore, C.R., Three-dimensional modeling of quasi-homologous solar jets (2010) Astrophys. J., 714, p. 1762. , ADS
Pariat, E., Aulanier, G., Démoulin, P., A new concept for magnetic reconnection: slip-running reconnection (2006) SF2A-2006: Semaine de L’Astrophysique Francaise, p. 559. , Barret D., Casoli F., Lagache G., Lecavelier A., Pagani L., (eds), ADS
Pariat, E., Dalmasse, K., DeVore, C.R., Antiochos, S.K., Karpen, J.T., Model for straight and helical solar jets. I. Parametric studies of the magnetic field geometry (2015) Astron. Astrophys., 573. , ADS
Pariat, E., Dalmasse, K., DeVore, C.R., Antiochos, S.K., Karpen, J.T., A model for straight and helical solar jets. II. Parametric study of the plasma beta (2016) Astron. Astrophys., 596. , ADS
Poisson, M., Mandrini, C.H., Démoulin, P., López Fuentes, M., Evidence of twisted flux-tube emergence in active regions (2015) Solar Phys., 290, p. 727. , ADS
Poisson, M., Démoulin, P., López Fuentes, M., Mandrini, C.H., Properties of magnetic tongues over a solar cycle (2016) Solar Phys., 291, p. 1625. , ADS
Polito, V., Del Zanna, G., Valori, G., Pariat, E., Mason, H.E., Dudík, J., Janvier, M., Analysis and modelling of recurrent solar flares observed with Hinode/EIS on March 9, 2012 (2017) Astron. Astrophys., 601. , ADS
Qiu, J., Gary, D.E., Flare-related magnetic anomaly with a sign reversal (2003) Astrophys. J., 599, p. 615. , ADS
Raouafi, N.E., Patsourakos, S., Pariat, E., Young, P.R., Sterling, A.C., Savcheva, A., Shimojo, M., Matsui, Y., Solar coronal jets: observations, theory, and modeling (2016) Space Sci. Rev., 201, p. 1. , ADS
Roy, J.R., The magnetic properties of solar surges (1973) Solar Phys., 28, p. 95. , ADS
Rust, D.M., Hildner, E., Hansen, R.T., Dryer, M., McClymont, A.N., McKenna-Lawlor, S.M.P., McLean, D.J., Tandberg-Hanssen, E., Mass ejections (1980) Skylab Solar Workshop II, p. 273. , Sturrock P.A., (ed), ADS
Savcheva, A.S., van Ballegooijen, A.A., DeLuca, E.E., Field topology analysis of a long-lasting coronal sigmoid (2012) Astrophys. J., 744, p. 78. , ADS
Savcheva, A., Pariat, E., McKillop, S., McCauley, P., Hanson, E., Su, Y., Werner, E., DeLuca, E.E., The relation between solar eruption topologies and observed flare features. I. Flare ribbons (2015) Astrophys. J., 810, p. 96. , ADS
Scherrer, P.H., Schou, J., Bush, R.I., Kosovichev, A.G., Bogart, R.S., Hoeksema, J.T., The Helioseismic and Magnetic Imager (HMI) investigation for the Solar Dynamics Observatory (SDO) (2012) Solar Phys., 275, p. 207. , ADS
Schmahl, E.J., The physical relationship between flares and surges observed in the extreme ultraviolet (1981) Solar Phys., 69, p. 135. , ADS
Schmieder, B., Mein, P., Simnett, G.M., Tandberg-Hanssen, E., An example of the association of X-ray and UV emission with H-alpha surges (1988) Astron. Astrophys., 201, p. 327. , ADS
Schmieder, B., Shibata, K., van Driel-Gesztelyi, L., Freeland, S., H alpha surges and associated soft X-ray loops (1995) Solar Phys., 156, p. 245. , ADS
Shen, Y., Liu, Y., Su, J., Deng, Y., On a coronal blowout jet: the first observation of a simultaneously produced bubble-like CME and a jet-like CME in a solar event (2012) Astrophys. J., 745, p. 164. , ADS
Shibata, K., Ishido, Y., Acton, L.W., Strong, K.T., Hirayama, T., Uchida, Y., Observations of X-ray jets with the YOHKOH soft X-ray telescope (1992) Publ. Astron. Soc. Japan, 44, p. L173. , ADS
Sterling, A.C., Moore, R.L., Falconer, D.A., Adams, M., Small-scale filament eruptions as the driver of X-ray jets in solar coronal holes (2015) Nature, 523, p. 437. , ADS
Sterling, A.C., Moore, R.L., Falconer, D.A., Panesar, N.K., Akiyama, S., Yashiro, S., Gopalswamy, N., Minifilament eruptions that drive coronal jets in a solar active region (2016) Astrophys. J., 821, p. 100. , ADS
Titov, V.S., Hornig, G., Démoulin, P., Theory of magnetic connectivity in the solar corona (2002) J. Geophys. Res., 107, p. 1164
Uddin, W., Schmieder, B., Chandra, R., Srivastava, A.K., Kumar, P., Bisht, S., Observations of multiple surges associated with magnetic activities in AR 10484 on 2003 October 25 (2012) Astrophys. J., 752, p. 70. , ADS
Vargas Domínguez, S., Kosovichev, A., Yurchyshyn, V., Multi-wavelength high-resolution observations of a small-scale emerging magnetic flux event and the chromospheric and coronal response (2014) Astrophys. J., 794, p. 140. , ADS
Webb, D.F., Howard, T.A., Coronal mass ejections: observations (2012) Living Rev. Solar Phys., 9, p. 3. , ADS
Wilmot-Smith, A.L., Hornig, G., Pontin, D.I., Magnetic braiding and parallel electric fields (2009) Astrophys. J., 696, p. 1339
Wyper, P.F., Antiochos, S.K., DeVore, C.R., A universal model for solar eruptions (2017) Nature, 544, p. 452. , ADS
Wyper, P.F., DeVore, C.R., Antiochos, S.K., A breakout model for solar coronal jets with filaments (2018) Astrophys. J., 852, p. 98. , ADS
Yang, S., Zhang, J., Mini-filament eruptions triggering confined solar flares observed by ONSET and SDO (2018) Astrophys. J. Lett., 860, p. L25. , ADS
Yokoyama, T., Shibata, K., Magnetic reconnection as the origin of X-ray jets and H α surges on the Sun (1995) Nature, 375, p. 42. , ADS
Yokoyama, T., Shibata, K., MHD simulation of solar coronal X-ray jets: emerging flux reconnection model (1996) Astrophys. Lett. Commun., 34, p. 133. , ADS
Young, P.R., Muglach, K., A coronal hole jet observed with Hinode and the solar dynamics observatory (2014) Publ. Astron. Soc. Japan, 66. , ADS
Young, P.R., Muglach, K., Solar dynamics observatory and Hinode observations of a blowout jet in a coronal hole (2014) Solar Phys., 289, p. 3313. , ADS
Zhao, J., Li, H., Pariat, E., Schmieder, B., Guo, Y., Wiegelmann, T., Temporal evolution of the magnetic topology of the NOAA active region 11158 (2014) Astrophys. J., 787, p. 88. , ADS

Citas:

---------- APA ----------

López Fuentes, M., Mandrini, C.H., Poisson, M., Démoulin, P., Cristiani, G., López, F.M. & Luoni, M.L. (2018) . Physical Processes Involved in the EUV “Surge” Event of 9 May 2012. Solar Physics, 293(12).
http://dx.doi.org/10.1007/s11207-018-1384-4

---------- CHICAGO ----------

López Fuentes, M., Mandrini, C.H., Poisson, M., Démoulin, P., Cristiani, G., López, F.M., et al. "Physical Processes Involved in the EUV “Surge” Event of 9 May 2012" . Solar Physics 293, no. 12 (2018).
http://dx.doi.org/10.1007/s11207-018-1384-4

---------- MLA ----------

López Fuentes, M., Mandrini, C.H., Poisson, M., Démoulin, P., Cristiani, G., López, F.M., et al. "Physical Processes Involved in the EUV “Surge” Event of 9 May 2012" . Solar Physics, vol. 293, no. 12, 2018.
http://dx.doi.org/10.1007/s11207-018-1384-4

---------- VANCOUVER ----------

López Fuentes, M., Mandrini, C.H., Poisson, M., Démoulin, P., Cristiani, G., López, F.M., et al. Physical Processes Involved in the EUV “Surge” Event of 9 May 2012. Sol. Phys. 2018;293(12).
http://dx.doi.org/10.1007/s11207-018-1384-4