4pi Models of CMEs and ICMEs

A. Kageyama; A. Shanmugaraju; A.W. Hood; B. Fong; B. Kliem; B. van der Holst; B. Vršnak; B.C. Low; B.C. Low; B.J. Lynch; C. Jacobs; C. Jacobs; C. Jacobs; C. Marqué; C. Ronchi; C.-H. Lin; C.J. Farrugia; C.J. Schrijver; C.P.T. Groth; D. Odstrcil; D.A. Calhoun; D.L. de Zeeuw; D.N. Baker; D.V. Reames; E. Chané; E. Chané; E.K.J. Kilpua; G. Dalakishvili; G. Dalakishvili; G. Tóth; G.M. Lindsay; H. Cremades; H. Fichtner; H.-R. Müller; H.J. Fahr; I.I. Roussev; I.I. Roussev; J. Kleimann; J. Kleimann; J. Lin; J. Pomoell; J. Pomoell; J.A. Linker; J.J. Aly; J.T. Gosling; K. Hakamada; K. Hayashi; L. Burlaga; L.A. Rachmeler; M. Vandas; M. Zhang; M.L. De Rosa; M.L. Kaiser; M.S. Nakwacki; N. Gopalswamy; N. Lugaz; N.A. Schwadron; O. Cohen; O.C. St. Cyr; P. MacNeice; P. Riley; P. Riley; P.A. Sturrock; P.F. Chen; P.F. Chen; P.J. Cargill; R. Kataoka; R. Keppens; R. Schwenn; R.A. Howard; R.L. Moore; R.M.E. Illing; R.S. Steinolfson; S.A. Maloney; S.D. King; S.E. Gibson; S.F. Martin; S.J. Tappin; S.K. Antiochos; S.R. Cranmer; S.T. Wu; T. Amari; T. Detman; T. Howard; T. Laitinen; T. Török; T. Török; T.A. Howard; T.G. Forbes; T.G. Forbes; T.G. Forbes; T.G. Forbes; T.R. Metcalf; V.S. Titov; W. Sun; W.B. Manchester; W.B. Manchester; W.B. Manchester IV; X. Feng; X. Feng; Y. Deng; Y. Fan; Y. Fan; Y. Fan; Y. Li; Y. Wang; Y. Wang; Z. Mikic; Z. Mikic

research

4pi Models of CMEs and ICMEs

Authors: A. Kageyama
A. Shanmugaraju
A.W. Hood
B. Fong
B. Kliem
B. van der Holst
B. Vršnak
B.C. Low
B.C. Low
B.J. Lynch
C. Jacobs
C. Jacobs
C. Jacobs
C. Marqué
C. Ronchi
C.-H. Lin
C.J. Farrugia
C.J. Schrijver
C.P.T. Groth
D. Odstrcil
D.A. Calhoun
D.L. de Zeeuw
D.N. Baker
D.V. Reames
E. Chané
E. Chané
E.K.J. Kilpua
G. Dalakishvili
G. Dalakishvili
G. Tóth
G.M. Lindsay
H. Cremades
H. Fichtner
H.-R. Müller
H.J. Fahr
I.I. Roussev
I.I. Roussev
J. Kleimann
J. Kleimann
J. Lin
J. Pomoell
J. Pomoell
J.A. Linker
J.J. Aly
J.T. Gosling
K. Hakamada
K. Hayashi
L. Burlaga
L.A. Rachmeler
M. Vandas
M. Zhang
M.L. De Rosa
M.L. Kaiser
M.S. Nakwacki
N. Gopalswamy
N. Lugaz
N.A. Schwadron
O. Cohen
O.C. St. Cyr
P. MacNeice
P. Riley
P. Riley
P.A. Sturrock
P.F. Chen
P.F. Chen
P.J. Cargill
R. Kataoka
R. Keppens
R. Schwenn
R.A. Howard
R.L. Moore
R.M.E. Illing
R.S. Steinolfson
S.A. Maloney
S.D. King
S.E. Gibson
S.F. Martin
S.J. Tappin
S.K. Antiochos
S.R. Cranmer
S.T. Wu
T. Amari
T. Detman
T. Howard
T. Laitinen
T. Török
T. Török
T.A. Howard
T.G. Forbes
T.G. Forbes
T.G. Forbes
T.G. Forbes
T.R. Metcalf
V.S. Titov
W. Sun
W.B. Manchester
W.B. Manchester
W.B. Manchester IV
X. Feng
X. Feng
Y. Deng
Y. Fan
Y. Fan
Y. Fan
Y. Li
Y. Wang
Y. Wang
Z. Mikic
Z. Mikic
Publication date: 28 March 2012
Publisher: 'Springer Science and Business Media LLC'
Doi

Abstract

Coronal mass ejections (CMEs), which dynamically connect the solar surface to the far reaches of interplanetary space, represent a major anifestation of solar activity. They are not only of principal interest but also play a pivotal role in the context of space weather predictions. The steady improvement of both numerical methods and computational resources during recent years has allowed for the creation of increasingly realistic models of interplanetary CMEs (ICMEs), which can now be compared to high-quality observational data from various space-bound missions. This review discusses existing models of CMEs, characterizing them by scientific aim and scope, CME initiation method, and physical effects included, thereby stressing the importance of fully 3-D ('4pi') spatial coverage.Comment: 14 pages plus references. Comments welcome. Accepted for publication in Solar Physics (SUN-360 topical issue

Similar works

Full text

Available Versions

Crossref

info:doi/10.1007%2Fs11207-012-...

Last time updated on 11/12/2019