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.

Slides:

Advertisements

Similar presentations

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

Advertisements

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:

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.

Lecture 4 The Formation and Evolution of CMEs. Coronal Mass Ejections (CMEs) Appear as loop like features that breakup helmet streamers in the corona.

MHD modeling of coronal disturbances related to CME lift-off J. Pomoell 1, R. Vainio 1, S. Pohjolainen 2 1 Department of Physics, University of Helsinki.

The Solar Wind and Heliosphere Bob Forsyth - 21 st / 22 nd October 2013 TOPICS The Sun – interior and atmosphere Origin of the solar wind Formation of.

Reviewing the Summer School Solar Labs Nicholas Gross.

The Solar Wind and Heliosphere Bob Forsyth - 15 th October 2007 TOPICS The Sun – interior and atmosphere Origin of the solar wind Formation of the heliosphere.

ESS 7 Lecture 14 October 31, 2008 Magnetic Storms

Physics of Dust Pickup in the Solar Wind: Contributions by STEREO C.T. Russell, L.K. Jian, J.G. Luhmann, D.R. Weimer STEREO Science Team Meeting February.

M. J. Reiner, 1 st STEREO Workshop, March, 2002, Paris.

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.

Understanding Magnetic Eruptions on the Sun and their Interplanetary Consequences A Solar and Heliospheric Research grant funded by the DoD MURI program.

When will disruptive CMEs impact Earth? Coronagraph observations alone aren’t enough to make the forecast for the most geoeffective halo CMEs. In 2002,

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

Solar Activity and VLF Prepared by Sheila Bijoor and Naoshin Haque Stanford University, Stanford, CA IHY Workshop on Advancing VLF through the Global AWESOME.

Coronal and Heliospheric Modeling of the May 12, 1997 MURI Event MURI Project Review, NASA/GSFC, MD, August 5-6, 2003 Dusan Odstrcil University of Colorado/CIRES.

The “cone model” was originally developed by Zhao et al. ~10 (?) years ago in order to interpret the times of arrival of ICME ejecta following SOHO LASCO.

Abstract For a while it seemed like a simple fluid-like, self-similar, Kolmogoroff cascade was the easy explanation for the nature and evolution of the.

The Sun and the Heliosphere: some basic concepts…

Numerical simulations are used to explore the interaction between solar coronal mass ejections (CMEs) and the structured, ambient global solar wind flow.

1 Mirror Mode Storms in Solar Wind and ULF Waves in the Solar Wind C.T. Russell, L.K. Jian, X. Blanco-Cano and J.G. Luhmann 18 th STEREO Science Working.

Locating the solar source of 13 April 2006 Magnetic Cloud K. Steed 1, C. J. Owen 1, L. K. Harra 1, L. M. Green 1, S. Dasso 2, A. P. Walsh 1, P. Démoulin.

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

Solar Drivers of Space Weather Steven Hill NOAA/SEC June 14, 2007 Research Experience for Undergraduates.

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

Space Weather from Coronal Holes and High Speed Streams M. Leila Mays (NASA/GSFC and CUA) SW REDISW REDI 2014 June 2-13.

Comparison of the 3D MHD Solar Wind Model Results with ACE Data 2007 SHINE Student Day Whistler, B. C., Canada C. O. Lee*, J. G. Luhmann, D. Odstrcil,

Arrival time of halo coronal mass ejections In the vicinity of the Earth G. Michalek, N. Gopalswamy, A. Lara, and P.K. Manoharan A&A 423, (2004)

Solar Wind and Coronal Mass Ejections

The Solar Wind.

Why Solar Electron Beams Stop Producing Type III Radio Emission Hamish Reid, Eduard Kontar SUPA School of Physics and Astronomy University of Glasgow,

Identifying the Role of Solar-Wind Number Density in Ring Current Evolution Paul O’Brien and Robert McPherron UCLA/IGPP.

Lessons for STEREO - learned from Helios Presented at the STEREO/Solar B Workshop, Rainer Schwenn, MPS Lindau The Helios.

ASEN5335- Aerospace Environments -- The Solar Wind 1 THE INTERPLANETARY MEDIUM AND IMF Consequently, the "spiral" pattern formed by particles spewing.

Forecast of Geomagnetic Storm based on CME and IP condition R.-S. Kim 1, K.-S. Cho 2, Y.-J. Moon 3, Yu Yi 1, K.-H. Kim 3 1 Chungnam National University.

CME-associated dimming regions Alysha Reinard 12, Doug Biesecker 1, Tim Howard 3 1 NOAA/SEC 2 University of Colorado 3 Montana State University SHINE 2006.

Radial Evolution of Major Solar Wind Structures Lan K. Jian Thanks to: C.T. Russell, J.G. Luhmann, R.M. Skoug Dept. of Earth and Space Sciences Institute.

1 Interplanetary Magnetic Flux Enhancements as seen by STEREO C.T. Russell, L.K. Jian and J.G. Luhmann 18 th STEREO Science Working Group April Meudon,

ENERGY ESTIMATION OF THE INTERPLANETARY PLASMA DURING STRONGEST GEOMAGNETIC STORMS OF THE CURRENT 24 SOLAR CYCLE ON MARCH 2015 The geomagnetic storms.

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.

GEOEFFECTIVE INTERPLANETARY STRUCTURES: 1997 – 2001 A. N. Zhukov 1,2, V. Bothmer 3, A. V. Dmitriev 2, I. S. Veselovsky 2 1 Royal Observatory of Belgium.

CME Propagation CSI 769 / ASTR 769 Lect. 11, April 10 Spring 2008.

A shock is a discontinuity separating two different regimes in a continuous media. –Shocks form when velocities exceed the signal speed in the medium.

Comparison of Heliospheric Magnetic Flux from Observations and the SAIC MHD Model S. T. Lepri, The University of Michigan S. K. Antiochos, Naval Research.

Modeling 3-D Solar Wind Structure Lecture 13. Why is a Heliospheric Model Needed? Space weather forecasts require us to know the solar wind that is interacting.

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

Correlation of magnetic field intensities and solar wind speeds of events observed by ACE. Mathew J. Owens and Peter J. Cargill. Space and Atmospheric.

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.

Variability of the Heliospheric Magnetic Flux: ICME effects S. T. Lepri, T. H. Zurbuchen The University of Michigan Department of Atmospheric, Oceanic,

Studies of Solar Wind Structures Using STEREO Lan K. Jian 1, C.T. Russell 1, J.G. Luhmann 2, A.B. Galvin 3, K. Simunac 3 1 Inst. Geophysics & Planetary.

Analysis of 3 and 8 April 2010 Coronal Mass Ejections and their Influence on the Earth Magnetic Field Marilena Mierla and SECCHI teams at ROB, USO and.

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

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.

1 Test Particle Simulations of Solar Energetic Particle Propagation for Space Weather Mike Marsh, S. Dalla, J. Kelly & T. Laitinen University of Central.

Manuela Temmer Institute of Physics, University of Graz, Austria Tutorial: Coronal holes and space weather consequences.

CME rate: 1/3 (4) day -1 at solar min (max) [LASCO CME catalogue. Yahsiro et al., 2005] |B| at 1 AU: 5 (8) nT at solar min (max) [OMNI data] D (fraction.

Poster X4.137 Solar Wind Trends in the Current Solar Cycle (STEREO Observations) A.B. Galvin* 1, K.D.C. Simunac 2, C. Farrugia 1 1.Space Science Center,

An Introduction to Observing Coronal Mass Ejections

Drivers and Solar Cycles Trends of Extreme Space Weather Disturbances

George C. Ho1, David Lario1, Robert B. Decker1, Mihir I. Desai2,

Session #8: Corotating Interaction Regions and the Connection Between Their Trailing Edge and Energetic Particle Acceleration at 1 AU Organizers: Robert.

Introduction to Space Weather Interplanetary Transients

A New Methodology to Predict the Axial ICME Magnetic Field at 1 AU

Solar Wind Transients and SEPs

Lecture 5 The Formation and Evolution of CIRS

Forbush and GCRDs First rigorous experimental observation of Cosmic Ray Flux Decrease was obtained by S. E. Forbush in , after deep statisitcal.

Introduction to Space Weather

Presentation transcript:

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. Jian, B.J. Anderson, J.G. Luhmann, A. Wennmacher STEREO Science Working Group Meeting 21 Trinity College Dublin, Ireland March 22-26,

Sources of Interplanetary Shocks: ICMEs The most energetic events on the Sun are those that produce Coronal Mass Ejections (CMEs). When these ejections reach 1 AU, they consist of a giant magnetic rope moving away from the Sun rapidly, expanding as it does and creating a disturbed plasma sheath and often a leading shock. We call these events ICMEs when detected far from the Sun. The rate of these ejections and their strength are very much solar cycle dependent. 2

Sources of Interplanetary Shocks: SIRs Much more steady are stream interaction regions (SIRs) often referred to as corotating interaction regions (CIRS) when the streams are very steady. SIRs get stronger with distance from the Sun and eventually lead to shock formation. SIRs are much less sensitive to activity changes during the solar cycle than ICMEs and occur at a near constant rate. 3

Solar Cycle Variation of Shocks at 1AU Wind, ACE and STEREO enable us to study interplanetary shocks for a period of 15 years. The number and strength of shocks depends on solar cycle phase and the level of activity on the Sun. When the Sun is producing strong ICMEs, the resultant shocks are strong. The extended solar minimum produced weak, mainly SIR-driven shocks at 1 AU. The situation is now beginning to change. 4

Shock Formation in Inner Heliosphere: Helios 1 and 2 Observations The closest measurements to the Sun were made on Helios 1 and 2 starting in 1974 and 1976 respectively going to 0.29 AU. Here is an example of a shock growing stronger near 0.47 AU by the overtaking of a leading shock by a trailing shock. As they move outward from the Sun, these shocks should grow stronger and weak compressional waves will steepen into shocks. 5

Identifying Shock Drivers with Helios: ICMEs We would like to identify what plasma structures lead to shocks in the solar wind. When a structure has a sheath and a trailing magnetic flux rope like here, it is probably an ICME. Unfortunately, the Helios plasma data is gappy and sometimes the driving mechanism is difficult to identify. 6

Identifying Shock Drivers with Helios: SIRs We can identify a stream interaction by the increasing plasma speed. Often a stream interaction leads to a density increase due to compression by the collision. There is also some intrinsic structure in the solar wind. This can be seen in the density panel here where there is an abrupt decrease in density at the stream interface. 7

Identifying Shock Drivers with Helios: Forward/Reverse Pair Shocks propagating away from the Sun are called forward shocks. Shock propagating toward the Sun are called reverse shocks. This example has both. 8

Shock Occurrence Rates in Inner Heliosphere Similar to observations at 1 AU, Helios data show that most shocks in the inner heliosphere are generated by ICMEs. A small fraction, increasing with heliocentric radius, are caused by SIRs. The occurrence rate of ICME-associated shocks in the Helios data is strongly correlated with solar activity, as it is at 1 AU. 9

Shock Strength and Distance The jump in magnetic field across the shock can be used as a proxy measure for shock strength when plasma conditions are unknown. The strength of the strongest shocks increases with distance from the Sun, but new weak shocks are being created by stream interactions as the solar wind propagates outwards. Hence the median strength does not change much with heliocentric distance. If we restrict our study to just quasi-perpendicular shocks (θ BN > 45°), the proxy measure is more accurate. This reduced sample gives the same result, a roughly constant median strength. 10

Shock Occurrence Rate: Helios vs. STEREO The number of shocks seen by Helios matches well the number observed by spacecraft at 1 AU (Wind and ACE) about 25 per year. This plot shows the heliocentric radial variation by shock type. As one moves away from the Sun, a larger number of shocks is produced by stream interactions. STEREO sees a similar number of shocks, but they are mainly of SIR origin. This is quite different than at Wind and ACE. STEREO was launched into the deepest and longest solar minimum in 200 years. Thus it would be helpful if we could measure the radial gradient of shocks contemporaneously with the STEREO data. Fortunately we can, using MESSENGER cruise data. 11

MESSENGER Shock Observations MESSENGER was launched in 2004, but its magnetometer boom was not deployed until 2005, so that the early measurements are contaminated by a strong spacecraft field. Data in 2007 and thereafter are excellent and can be used to search for shocks. The one-Hz data are useful, but two-Hertz data, that are available some of the time, are better. There are not many shocks seen during this period. We presume that they are all SIR-driven, but we do not have plasma data to check this. 12

MESSENGER Shock Rate Compared to STEREO’s Rate MESSENGER magnetic field data are available in the radial range of 0.3 to 0.7 AU. During the available period of observations only 3 events were seen. These are probably all SIR driven considering how low solar activity was at this time. We have converted these data to annual rates in three bins. While the statistical accuracy of these data are low, they are very consistent with the well-determined STEREO rates at 1 AU. It appears that the formation of shocks by SIRs in the inner heliosphere begins about 0.4 AU and their number grows with radial distance. 13

Summary Both ICMEs and SIRs generate shocks in the inner solar system. ICME-driven shocks start near the Sun and strengthen as they propagate. SIR-driven shocks begin at about 0.4 AU and continue to grow in strength and number with distance. ICME-driven shocks are strongly correlated with solar activity, in number and size. The predominance of SIR-driven shocks at 1 AU during the cycle 23/24 solar minimum follows directly from the near absence of ICMEs at the time and the growth of SIR shocks with increasing distance beginning at about 0.4 AU. 14