Study of Local Heliospheric Current Sheet Variations from Multi-Spacecraft Observations D. Arrazola · J.J. Blanco · J. Rodríguez-Pacheco · M.A. Hidalgo.

Slides:

Advertisements

Similar presentations

J. T. Gosling Laboratory for Atmospheric and Space Physics

Advertisements

Uncovering the Global Slow Solar Wind Liang Zhao and Thomas H. Zurbuchen Department of Atmospheric, Oceanic and Space Sciences, University of Michigan.

ILWS Conference, October 5, 2009 Extension of Magnetic Clouds in the Inner Heliosphere as observed from Multi- Spacecraft Aline de Lucas Alisson Dal Lago.

The Johns Hopkins University Applied Physics Laboratory SHINE 2005, July 11-15, 2005 Transient Shocks and Associated Energetic Particle Events Observed.

THREE-DIMENSIONAL ANISOTROPIC TRANSPORT OF SOLAR ENERGETIC PARTICLES IN THE INNER HELIOSPHERE CRISM- 2011, Montpellier, 27 June – 1 July, Collaborators:

MURI,2008 Electric Field Variability and Impact on the Thermosphere Yue Deng 1,2, Astrid Maute 1, Arthur D. Richmond 1 and Ray G. Roble 1 1.HAO National.

Olga Khabarova & Vladimir obridko Heliophysical Laboratory, Institute of Terrestrial Magnetism, Ionosphere and Radio Wave Propagation RAS (IZMIRAN), Moscow,

The Radial Variation of Interplanetary Shocks C.T. Russell, H.R. Lai, L.K. Jian, J.G. Luhmann, A. Wennmacher STEREO SWG Lake Winnepesaukee New Hampshire.

Solar and Interplanetary Sources of Geomagnetic disturbances Yu.I. Yermolaev, N. S. Nikolaeva, I. G. Lodkina, and M. Yu. Yermolaev Space Research Institute.

U N C L A S S I F I E D Operated by the Los Alamos National Security, LLC for the DOE/NNSA Pitch angle evolution of energetic electrons at geosynchronous.

Grad-Shafranov reconstruction of a bipolar Bz signature in an earthward jet in the tail Hiroshi Hasegawa (2007/02/14)

Interaction of coronal mass ejections with large-scale structures N. Gopalswamy, S. Yashiro, H. Xie, S. Akiyama, and P. Mäkelä IHY – ISWI Regional meeting.

Study of Galactic Cosmic Rays at high cut- off rigidity during solar cycle 23 Partha Chowdhury 1 and B.N. Dwivedi 2 1 Department of Physics, University.

Reviewing the Summer School Solar Labs Nicholas Gross.

Spatial distribution of the auroral precipitation zones during storms connected with magnetic clouds O.I. Yagodkina 1, I.V. Despirak 1, V. Guineva 2 1.

Anti-parallel versus Component Reconnection at the Magnetopause K.J. Trattner Lockheed Martin Advanced Technology Center Palo Alto, CA, USA and the Polar/TIMAS,

1 Diagnostics of Solar Wind Processes Using the Total Perpendicular Pressure Lan Jian, C. T. Russell, and J. T. Gosling How does the magnetic structure.

Five Spacecraft Observations of Oppositely Directed Exhaust Jets from a Magnetic Reconnection X-line Extending > 4.3 x 10 6 km in the Solar Wind Gosling.

RHESSI/GOES Observations of the Non-flaring Sun from 2002 to J. McTiernan SSL/UCB.

Magnetic Reconnection in the Solar Wind Gosling, Phan, et al.

Identifying and Modeling Coronal Holes Observed by SDO/AIA, STEREO /A and B Using HMI Synchronic Frames X. P. Zhao, J. T. Hoeksema, Y. Liu, P. H. Scherrer.

1 Synoptic Maps of Magnetic Field from MDI Magnetograms: polar field interpolation. Y. Liu, J. T. Hoeksema, X. P. Zhao, R. M. Larson – Stanford University.

1 July 31, 2007 SHINE 2007 – Heliospheric Plasma Sheet The Unusual Heliospheric Current Sheet at the End of Cycle 23 A Comparison of Cycles 21,22,& 23.

1 A Statistical Study about Transequatorial loops Jie Chen National Astronomical Observatories Chinese Academy of Sciences.

Study of magnetic helicity in solar active regions: For a better understanding of solar flares Sung-Hong Park Center for Solar-Terrestrial Research New.

Absence of a Long Lasting Southward Displacement of the HCS Near the Minimum Preceding Solar Cycle 24 X. P. Zhao, J. T. Hoeksema and P. H. Scherrer Stanford.

Identifying Interplanetary Shock Parameters in Heliospheric MHD Simulation Results S. A. Ledvina 1, D. Odstrcil 2 and J. G. Luhmann 1 1.Space Sciences.

1 Dynamic Motion of Bow Shock and Magnetopause Observed by THEMIS Hui Zhang (BU) Q.-G. Zong (Umass Lowell) D. G. Sibeck (GSFC) T. A. Fritz (BU)

Copyright © 2009 Pearson Education, Inc. Lecture 8 - Magnetism.

V. M. Sorokin, V.M. Chmyrev, A. K. Yaschenko and M. Hayakawa Strong DC electric field formation in the ionosphere over typhoon and earthquake regions V.

Thomas Zurbuchen University of Michigan The Structure and Sources of the Solar Wind during the Solar Cycle.

Comparison on Calculated Helicity Parameters at Different Observing Sites Haiqing Xu (NAOC) Collaborators: Hongqi, Zhang, NAOC Kirill Kuzanyan, IZMIRAN,

Case Studies of Interplanetary Coronal Mass Ejections Interplanetary Coronal Mass Ejections – Different Phases of the Cycle Of particular interest to the.

Response of the Polar Cusp and the Magnetotail to CIRs Studied by a Multispacecraft Wavelet Analysis Axel Korth 1, Ezequiel Echer 2, Fernando L. Guarnieri.

New STEREO/SECCHI Processing for Heliospheric Transients David F. Webb ISR, Boston College, MA, USA New England Space Science Consortium.

Ed Stone Symposium February 11, 2006 Voyager Observations of Galactic and Anomalous Cosmic Rays in the Heliosheath F.B. M c Donald 1, W.R. Webber 2, E.C.

The dayside magnetopause in the spring of 2004: A case study and a statistical report A. Blăgău (1, 2), B. Klecker (1), G. Paschmann (1), M. Scholer (1),

A new stationary analytical model of the heliospheric current sheet and the plasma sheet Roman Kislov IKI RAS 2015

27-Day Variations Of The Galactic Cosmic Ray Intensity And Anisotropy In Different Solar Magnetic Cycles ( ) M.V. Alania, A. Gil, K. Iskra, R.

5. Walen Test analysis The Walen Test results for Cluster 3 are as expected for a reconnection event. The test over the leading edge shows a positive correlation.

Composition and spectral properties of the 1 AU quiet- time suprathermal ion population during solar cycle23 M Al-Dayeh, M I Desai, J R Dwyer, H K Rassoul,

Interplanetary Shocks in the Inner Solar System: Observations with STEREO and MESSENGER During the Deep Solar Minimum of 2008 H.R. Lai, C.T. Russell, L.K.

Simultaneous in-situ observations of the feature of a typical FTE by Cluster and TC1 Zhang Qinghe Liu Ruiyuan Polar Research Institute of China

1 Mei Zhang （ National Astronomical Observatory, Chinese Academy of Sciences ） Solar cycle variation of kinetic helicity Collaborators: Junwei Zhao (Stanford,

Guan Le NASA Goddard Space Flight Center Challenges in Measuring External Current Systems Driven by Solar Wind-Magnetosphere Interaction.

Catalogued parameters… Current sheet normal vector and velocity, derived using a timing analysis. Later used to calculate an accurate measure of current.

Adjustable magnetospheric event- oriented magnetic field models N. Yu. Ganushkina (1), M. V. Kubyshkina (2), T. I. Pulkkinen (1) (1) Finnish Meteorological.

Intermittency Analysis and Spatial Dependence of Magnetic Field Disturbances in the Fast Solar Wind Sunny W. Y. Tam 1 and Ya-Hui Yang 2 1 Institute of.

17th Cluster workshop Uppsala, Sweden , May 12-15, 2009

Global Structure of the Inner Solar Wind and it's Dynamic in the Solar Activity Cycle from IPS Observations with Multi-Beam Radio Telescope BSA LPI Chashei.

WG3 Session#3 Thursday PM: This session focused on the global effects of the Sun as seen in the outer heliosphere. The largest solar energetic particle.

SEP Event Onsets: Far Backside Solar Sources and the East-West Hemispheric Asymmetry S. W. Kahler AFRL Space Vehicles Directorate, Kirtland AFB, New Mexico,

Radio and Space Plasma Physics Group Tracking solar wind structures from the Sun through to the orbit of Mars A.O. Williams 1, N.J.T. Edberg 1,2, S.E.

Centre for fusion, space and astrophysics Signatures of Outflowing Transients Adjacent to the Heliospheric Current Sheet Multi-spacecraft Observations.

Measurements of the Orientation of the Heliospheric Magnetic Field Neil Murphy Jet Propulsion Laboratory.

二维电磁模型基本方程与无量纲化基本方程. 无量纲化方程化为二维时的方程时间上利用蛙跳格式网格划分.

Cosmic Ray Positron Fraction Observations during the A- Magnetic Solar Minimum John Clem and Paul Evenson* * Presenter AESOP Departing Esrange, Sweden.

The heliospheric magnetic flux density through several solar cycles Géza Erdős (1) and André Balogh (2) (1) MTA Wigner FK RMI, Budapest, Hungary (2) Imperial.

Earth’s Magnetosphere Space Weather Training Kennedy Space Center Space Weather Research Center.

Magnetic cloud erosion by magnetic reconnection

GROUND-LEVEL EVENT (GLE)

35th International Cosmic Ray Conference

Olga Khabarova 1, valentina zharkova 2 & vladimir kuznetsov 1

Lecture 12 The Importance of Accurate Solar Wind Measurements

Evolution of solar wind structures between Venus and Mars orbits

Solar Modulation Davide Grandi AMS Group-INFN Milano-Bicocca.

Investigations of CME in muon flux detected in hodoscopic mode

Series of high-frequency slowly drifting structure mapping the magnetic field reconnection M. Karlicky, A&A, 2004, 417,325.

V1 and V2 Measurements of Galactic and Anomalous Cosmic Rays in the Outer Heliosphere and the Heliosheath during Solar Cycle #23 W.R. Webber (The.

Presentation transcript:

Study of Local Heliospheric Current Sheet Variations from Multi-Spacecraft Observations D. Arrazola · J.J. Blanco · J. Rodríguez-Pacheco · M.A. Hidalgo

Study of Local Heliospheric Current Sheet Variations from Multi-Spacecraft Observations OBJECTIVE This study analyzes changes in the local HCS structure, mostly in terms of its local orientation, using multipoint spacecraft observations. Our aim is to analyze the role of the solar wind and the magnetic connectivity among the observation points, trying to distinguish if these changes are due to the HCS local shape or to temporal variations.

Study of Local Heliospheric Current Sheet Variations from Multi-Spacecraft Observations HCS HELIOSPHERIC CURRENT SHEET

Study of Local Heliospheric Current Sheet Variations from Multi-Spacecraft Observations Data Analysis Ascending phase of Cycle 23 ACE - Magnetic Field Experiment (1-s) Solar Wind Electron, Proton and Alpha Monitor Wind - Magnetic Field Instrument (3-s) Solar Wind Experiment 3D-Plasma and Energetic Particle Minimum cycle ( ) ACE - Wind - Magnetometer MAG (IMPACT) (1-s) Solar Wind Data (PLASTIC) Twin STEREO … …

Study of Local Heliospheric Current Sheet Variations from Multi-Spacecraft Observations Data Analysis. Criteria to identify HCS Crossings

Data Analysis. Criteria to identify HCS Crossings Study of Local Heliospheric Current Sheet Variations from Multi-Spacecraft Observations January 15, The change in Bx, By sign is clearly for whole spacecrafts. The electron pitch angle into the red boxes on the right panel. In this period, sunward IMF is connected to the northern solar magnetic hemisphere (B x 0) and the anti-sunward IMF to the southern hemisphere. Before crossing, IMF moves sunward in all spacecrafts.

Study of Local Heliospheric Current Sheet Variations from Multi-Spacecraft Observations Data Analysis. HCS local orientation determination MVA presumes the one-dimensional nature of the current sheet and uses Gauss law to require that the projection of B along a to-be-determined direction n should be constant. Its purpose is to find an estimator of the normal direction (Sonnerup, 1998). This method is used to calculate the orientation of a discontinuity and consist in solve the real symmetric matrix of covariance. CVA technique uses (Scudder, 2005), like MVA, the covariance matrix, but unlike it, uses the maximum eigenvalue to find a normal vector to the coplanarity plane of the current sheet. HYTARO method is based on a local magnetic topology (Blanco et al., 2003). as a starting point that let us to apply only two consecutive rotations once the field orientation is defined from a constant initial magnetic field (B 0 ). This method is going to be used to calculate time crossing of each event analyzed.

Study of Local Heliospheric Current Sheet Variations from Multi-Spacecraft Observations Data Analysis. Compare observations

Study of Local Heliospheric Current Sheet Variations from Multi-Spacecraft Observations Data Analysis. The evolution of the HCS local orientation and the magnetic connection among the different observation sites have been evaluated. Elapsed time (  t el ) and expected time (  t ex ) have been compared. The magnetic connection parameter (C) is a rough estimation of connection between two observation points. Higher values of C parameter imply worse connections. Relation between the LOCAL ORIENTATION and the MAGNETIC CONNECTION The local orientation of the HCS will be similar from one to another satellite when the spacecraft are well connected

Study of Local Heliospheric Current Sheet Variations from Multi-Spacecraft Observations HCS crossing ( ) The vertical lines marks the reversal times and the continuous lines represented the HYTARO results for the data interval used. The horizontal segments ended in arrows show the elapsed times. On 15 January the HCS was observed by the four spacecraft before a SIR arrival. No large variations in the HCS local variation were observed. Poor magnetic connection from the observed elapsed and expected time  a different HCS region was observed.

Study of Local Heliospheric Current Sheet Variations from Multi-Spacecraft Observations HCS Crossings as observed by ACE and Wind (Ascending phase of the Solar cycle) Mean angle ranges: from 4º to 62º Mean angle shows a rising trend when the distance between spacecraft increases. With the elapsed time, this trend is not so clear. With magnetic connection (C), the same trend is observed.

Study of Local Heliospheric Current Sheet Variations from Multi-Spacecraft Observations HCS Crossings as observed by ACE, Wind and Twin STEREO (Solar minimum) Mean angle shows a rising trend up to 5000R E. This trend changes at larger distances. When the C parameter becomes worse, the angle shows a growing trend. At distances larger than 5000 R E, the local HCS orientation has an evolution related to: a continuous interaction with the solar wind a worse magnetic connection.

Study of Local Heliospheric Current Sheet Variations from Multi-Spacecraft Observations Conclusions During the ascending solar cycle phase: The interaction between the HCS and the solar wind is very effective according to the observed poor magnetic connectivity. During minimum solar cycle: Results show a growing trend between the variation of the HCS local inclination and spacecraft distances up to 5000 R E (<10 hours). For larger distances the results show a decreasing trend. Summary: The spatial variation in the HCS local shape is in the range of hundreds of R E. The poor magnetic connection (C) observed is due to an effective interaction between the solar wind and the HCS.