Statistical Distributions of Speeds of Coronal Mass Ejections 1 Big Bear Solar Obs, Big Bear, CA 92314; 2 Catholic University of America, Washington DC.

Slides:

Advertisements

Similar presentations

TRACE and RHESSI observations of failed eruption of magnetic flux rope and oscillating coronal loops Tomasz Mrozek Astronomical Institute University of.

Advertisements

Investigating the Origin of the Long-Duration High- Energy Gamma-Ray Flares Gerry Share, Jim Ryan and Ron Murphy (in absentia) Steering Committee Overseer.

Global Properties of Heliospheric Disturbances Observed by Interplanetary Scintillation M. Tokumaru, M. Kojima, K. Fujiki, and M. Yamashita (Solar-Terrestrial.

Observations on Current Sheet and Magnetic Reconnection in Solar Flares Haimin Wang and Jiong Qiu BBSO/NJIT.

The Physics of Solar Flares Examining Solar Flares and Radio Bursts By Caylin Mendelowitz and Claire Rosen.

Hot Precursor Ejecta and Other Peculiarities of the 2012 May 17 Ground Level Enhancement Event N. Gopalswamy 2, H. Xie 1,2, N. V. Nitta 3, I. Usoskin 4,

Forbush Decrease Prediction Based on Remote Solar Observations M. Dumbović, B. Vršnak Hvar Observatory, Faculty of Geodesy, University of Zagreb, Croatia.

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

Strength of Coronal Mass Ejection- driven Shocks Near the Sun and Its Importance in Predicting Solar Energetic Particle Events Chenglong Shen 1, Yuming.

Hard X-Ray Footpoint Motion in Spectrally Distinct Solar Flares Casey Donoven Mentor Angela Des Jardins 2011 Solar REU.

What can helicity redistribution in solar eruptions tell us about reconnection in these events? by Brian Welsch, JSPS Fellow (Short-Term ), Space Sciences.

Intense Flares Without Solar Energetic Particle Events N. V. Nitta (LMSAL), E. W. Cliver (AFRL), H. S. Hudson (UCB) Abstract: We study favorably located.

The Halo CMEs’ Speeds and Energy of Their Related Active Regions Yang Liu¹, and CDAW Source Identification Team² ¹Stanford University ² Including: E. Cliver,

Magnetic fields in the photosphere and heliosphere: structure, statistical parameters, turbulent state Valentyna I. Abramenko Big Bear Solar Observatory.

Two energy release processes for CMEs: MHD catastrophe and magnetic reconnection Yao CHEN Department of Space Science and Applied Physics Shandong University.

30-Day Science Plan Angelos Vourlidas, Russ Howard SECCHI Consortium Meeting IAS 8 March 2007.

The Hunt for a Link : Quantitative Connections Between Magnetic Fields and EIT Coronal Wave/CME Properties Prepared by James R. Robertson J.R. In conjunction.

Coronal IP Shocks Nat Gopalswamy NASA/GSFC Elmau CME Workshop, 2003 February 7 Plenary talk Sun Earth.

Rapid Changes in the Longitudinal Magnetic Field Associated with the July gamma -ray Flare Vasyl Yurchyshyn, Haimin Wang, Valentyna Abramenko,

September 2007LWS 2007 Halo CMEs and Configuration of the Ambient Magnetic Field Yang Liu – Stanford University

Discussion Summary: Group B –Solar Active Regions And Their Production of Flares and Coronal Mass Ejections Discussion Leaders: George Fisher Hugh Hudson.

CME Interactions and Particle Acceleration N. Gopalswamy (NASA/GSFC) 2003 February 11 Elmau CME workshop, Group-C Presentation (B. Klecker’s Group)

Coronal Ejecta in October - November of 2003 and predictions of the associated geomagnetic events 1 Big Bear Solar Observatory, New Jersey Institute of.

Distribution of the magnetic flux in elements of the magnetic field in an active region Valentyna Abramenko Big Bear Solar Observatory, NJIT.

Coronal Loop Oscillations and Flare Shock Waves H. S. Hudson (UCB/SSL) & A. Warmuth (Astrophysical Institute Potsdam) Coronal loop oscillations: (Fig.

AR 10759/ May Event Overview

Photospheric Sources of Very Fast (>1100km/s) Coronal Mass Ejections Recent studies show that only very fast CMEs (> 1100 km/s) are capable of producing.

Magnetic Field and Heating of the Corona Valentyna Abramenko and Vasyl Yurchyshyn Big Bear Solar Observatory.

UCB MURI Team Introduction An overview of ongoing work to understand a well observed, eruptive active region, along with closely related studies…..

Solar Origin of energetic particle events Near-relativistic impulsive electron events observed at 1 AU M. Pick, D. Maia, S.J. Wang, A. Lecacheux, D. Haggery,

An Automatic Detection Technique for Prominence Eruptions and Surges using SDO/AIA Images S. Yashiro 1,2, N. Gopalswamy 2, P. Mäkelä 1,2, S. Akiyama 1,2,

Valentina Abramenko 1 Gary Zank 2 Alexander Dosch 2 Vasyl Yurchyshyn Big Bear solar Observatory of NJIT, CA 2 – CSPAR, Univ. of Alabama in Nuntsville,

The Sun and the Heliosphere: some basic concepts…

A Catalog of Halo Coronal Mass Ejections from SOHO N. Gopalswamy 1, S. Yashiro 2, G. Michalek 3, H. Xie 3, G. Stenborg 2, A. Vourlidas 4, R. A. Howard.

Relation between Type II Bursts and CMEs Inferred from STEREO Observations N. Gopalswamy, W. Thompson, J. Davila, M. Kaiser NASA Goddard Space Flight Center,

1 THE RELATION BETWEEN CORONAL EIT WAVE AND MAGNETIC CONFIGURATION Speakers: Xin Chen

Signatures of Intermittent Turbulence in Hinode Quiet Sun Photosphere Valentina Abramenko, Big Bear Solar Observatory, USA, Plasma.

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)

Coronal Dynamics - Can we detect MHD shocks and waves by Solar B ? K. Shibata Kwasan Observatory Kyoto University 2003 Feb. 3-5 Solar B ISAS.

Coronal Sources of Impulsive Fe-Rich Solar Energetic Particle Events S. W. Kahler AFRL Space Vehicles Directorate, Kirtland AFB, NM, USA D. V. Reames IPST,

3D Reconnection Simulations of Descending Coronal Voids Mark Linton in collaboration with Dana Longcope (MSU)

2004 September 11CAWSES Theme 2 Meeting, Beijing Solar Sources of Geoeffective Disturbances N. Gopalswamy NASA/GSFC Greenbelt, MD

Connecting Near-Sun CME flux Ropes to the 1-AU Flux Ropes using the Flare-CME Relationship N. Gopalswamy, H. Xie, S. Yashiro, and S. Akiyama NASA/GSFC.

1 SEP “Campaign Events” for SHINE 2003 Question: Can we identify solar/interplanetary factors that drive SEP spectral and compositional variability at.

Flux Emergence Rate in Coronal Holes and in Adjacent Quiet-sun Regions Valentyna Abramenko Big Bear Solar Observatory Lennard Fisk Lennard Fisk University.

Valentina Abramenko, Vasyl Yurchyshyn, Philip R. Goode Big Bear Solar Observatory of NJIT SH31C-18 06: Size and Lifetime Distributions of Bright Points.

White light coronagraph showing prominances and streamers The Coronal Magnetic Field.

Modeling of CME-driven Shock propagation with ENLIL simulations using flux-rope and cone-model inputs Using observations from STEREO/SECCHI and SOHO/LASCO,

Type IV Radio Bursts and Source Regions Observed by NoRH: Results Sara Petty, CUA/ GSFC Advisor: Dr. Nat Gopalswamy Type IV Radio Bursts Revisited Research.

Math Graphing Linear Inequalities in Two Variables 1.

Chapter 20 Statistical Considerations Lecture Slides The McGraw-Hill Companies © 2012.

Flare Ribbon Expansion and Energy Release Ayumi ASAI Kwasan and Hida Observatories, Kyoto University Explosive Phenomena in Magnetized Plasma – New Development.

Inherent Length Scales and Apparent Frequencies of Periodic Solar Wind Number Density Structures Nicholeen Viall 1, Larry Kepko 2 and Harlan Spence 1 1.

Chi Square Test for Goodness of Fit Determining if our sample fits the way it should be.

ENLIL Modeling for the interaction event: Effect of Interacting CMEs on SEP Intensity NASA/GSFC H. Xie, N. Gopalswamy, P. Makela, S. Yashiro.

Summary Using 21 equatorial CHs during the solar cycle 23 we studied the correlation of SW velocity with the area of EIT CH and the area of NoRH RBP. SW.

On Coronal Mass Ejections and Configurations of the Ambient Magnetic Field Yang Liu Stanford University 3/17/ COSPAR 2008.

Complexity of Solar Eruptions Nat Gopalswamy, NASA GSFC, Greenbelt, MD

BBSO 2007 Science Planning. Focal Plane Instruments AO (Wenda, Nicolas, Deqing, Patricia and Park) AO (Wenda, Nicolas, Deqing, Patricia and Park) IRIM.

한 미 려 – Introduction (1) 2.Instrument & Observe 3.Science 2.

Interplanetary proton and electron enhancements associated with radio-loud and radio-quiet CME-driven shocks P. Mäkelä 1,2, N. Gopalswamy 2, H. Xie 1,2,

Diagnostic of Chromospheric Flare Plasma

SMALL SEP EVENTS WITH METRIC TYPE II RADIO BURSTS

The CME-Flare Relationship in Homologous Eruptive Events

Solar Sources of Wide Coronal Mass Ejections during the Ascending Phase of Cycle 24 Sachiko Akiyama1,2, Nat Gopalswamy2, Seiji Yashiro1,2 , and Pertti.

SEP EVENTS AND THE ROLE OF FLARES AND SHOCKS

Ju Jing, Vasyl B. Yurchyshyn, Guo Yang, Yan Xu, and Haimin Wang

Further Topics on Random Variables: 1

Berlin Chen Department of Computer Science & Information Engineering

16 Mathematics of Normal Distributions

Presentation transcript:

Statistical Distributions of Speeds of Coronal Mass Ejections 1 Big Bear Solar Obs, Big Bear, CA 92314; 2 Catholic University of America, Washington DC 20064; 3 New Jersey Inst. of Technology, Newark, NJ 07102; 4 NASA/GSFC, Greenbelt, MD Vasyl Yurchyshyn 1, Seiji Yashiro 2, Valentyna Abramenko 1, Haimin Wang 3, Nat Gopalswamy 4 DeceleratingCMEsAcceleratingCMEs We analyzed the distribution of speeds of 4315 CMEs published in The CME Catalog at the CDAW data center. We found that the speed distributions for accelerating and decelerating events are nearly identical (  2 =0.0033) and to a good approximation they can be fitted with a single log-normal distribution. This finding implies that, statistically, there is no physical distinction between the accelerating and the decelerating events.The log-normal distribution of CME speeds suggests that the same driving mechanism of a non-linear nature is acting in both slow and fast dynamical types of CMEs. liner-liner representation of the distribution of the number of CMEs, N, versus their speeds, v, determined from the linear fit log-liner representation of the above distribution can be modeled by a normal (gaussian) approximation The skewed form of the distribution suggests that it may be modeled either with a single log-normal distribution or a sum of a log-normal and a Gaussian distributions. It is said that if a random variable (in our case the speed of a CME) is log-normally distributed then its natural logarithm is normally distributed. The log-normal fit (solid line) captures the intensity of the observed distribution in all speed ranges. The two-component fit (dashed line) fails to accurately represent the data in the low speed range below 200 km/s. Because the single log-normal fit better models the data (  2 =10 versus  2 =39 for the two-component fit), while requiring less free parameters, we conclude that the speeds of CMEs are distributed log-normally. We separated all events into two groups based on the sign of the acceleration (determined from the 2 nd order fit). We found that the normal approximations for distribution of ln(v) determined for accelerating and decelerating events are the same (  2 =0.0033). The largest difference between them is that the accelerating CMEs, as a group, are slightly slower then the decelerating ones. This finding implies that, statistically, there is no physical distinction between the accelerating and the decelerating events. It also suggests that in the case there do exist two types of CMEs, the physical distinction between them can not be easily revealed. The single log-normal distribution suggests: i)that the same driving mechanism is acting in both dynamical types of CMEs; ii) that the speed distribution is a product of a a number of independent random variables, which may arise through the fragmentation process or a multiplicative random cascade; iii) the presence of nonlinear interactions and multiplicative processes in a system of many magnetic flux loops. The driving mechanism is then a multiple reconnection process in a fragmented magnetic field? SOHO is a project of international cooperation between ESA and NASA. This work was supported in part by National Science Fundation under grants ATM , ATM and ATM and by NASA NAG and NAG grants.