\relax \ifx\hyper@anchor\@undefined \global \let \oldcontentsline\contentsline \gdef \contentsline#1#2#3#4{\oldcontentsline{#1}{#2}{#3}} \global \let \oldnewlabel\newlabel \gdef \newlabel#1#2{\newlabelxx{#1}#2} \gdef \newlabelxx#1#2#3#4#5#6{\oldnewlabel{#1}{{#2}{#3}}} \AtEndDocument{\let \contentsline\oldcontentsline \let \newlabel\oldnewlabel} \else \global \let \hyper@last\relax \fi \providecommand*\HyPL@Entry[1]{} \citation{hundhausen72a} \citation{wang07a} \HyPL@Entry{0<>} \citation{sonett65a} \citation{gosling78a} \citation{gosling78a} \citation{wang07a} \citation{wang10a} \citation{winterhalter94a} \citation{winterhalter94a} \citation{gosling81a} \citation{gosling81a} \citation{winterhalter94a} \citation{crooker04d} \citation{neugebauer04a} \@writefile{toc}{\contentsline {section}{\numberline {1}Introduction}{2}{section.1.1}} \@writefile{lof}{\contentsline {figure}{\numberline {1}{\ignorespaces A selection of meridional slices from a global MHD simulation of CR 2060, which occurred between 08/14/2007 and 09/10/2007. Grey-scale images are Simulated polarized brightness (pB) images and the colored lines are magnetic field lines drawn from equally-spaced points in latitude on the solar surface. The field lines have been color-coded so that blue/red lines are field lines that open into the heliosphere and are inwardly/outwardly directed, while green field lines connect back to the Sun at both ends, i.e., they are closed field lines. }}{3}{figure.1.1}} \newlabel{fig:streamer-selection}{{1}{3}{ A selection of meridional slices from a global MHD simulation of CR 2060, which occurred between 08/14/2007 and 09/10/2007. Grey-scale images are Simulated polarized brightness (pB) images and the colored lines are magnetic field lines drawn from equally-spaced points in latitude on the solar surface. The field lines have been color-coded so that blue/red lines are field lines that open into the heliosphere and are inwardly/outwardly directed, while green field lines connect back to the Sun at both ends, i.e., they are closed field lines. \relax }{figure.1.1}{}} \citation{neugebauer62a} \citation{gosling81a} \citation{wang90a} \citation{wang07a} \citation{wang03b} \citation{cranmer07a} \citation{wang09a} \citation{cranmer10a} \citation{suess09a} \citation{uzzo03a} \citation{crooker04c} \citation{wang96a} \citation{fisk96a} \citation{antiochos11a} \citation{lionello05a} \citation{wang96a} \citation{suess09a} \citation{liu09a} \citation{cranmer07a} \@writefile{lof}{\contentsline {figure}{\numberline {2}{\ignorespaces An illustration of the salient features of the EF and BL models for: (a) a dipolar streamer and (b) a unipolar streamer. }}{5}{figure.1.2}} \newlabel{streamer-illustration-1}{{2}{5}{ An illustration of the salient features of the EF and BL models for: (a) a dipolar streamer and (b) a unipolar streamer. \relax }{figure.1.2}{}} \citation{wang97a} \@writefile{lof}{\contentsline {figure}{\numberline {3}{\ignorespaces Expansion factor (at $30 R_{\odot }$, solid line) is plotted logarithmically as a function of latitude and compared with a set of magnetic field lines drawn out to $6 R_{\odot }$ for CR 2060 at $215^{\circ }$ longitude. }}{6}{figure.1.3}} \newlabel{fl-expfac-215}{{3}{6}{ Expansion factor (at $30 R_{\odot }$, solid line) is plotted logarithmically as a function of latitude and compared with a set of magnetic field lines drawn out to $6 R_{\odot }$ for CR 2060 at $215^{\circ }$ longitude. \relax }{figure.1.3}{}} \newlabel{ws-eq}{{1}{6}{Introduction\relax }{equation.1.1}{}} \citation{wang90a} \citation{cranmer10a} \citation{laming04a} \citation{fisk96a} \citation{antiochos11a} \citation{wang90a} \citation{arge00a} \citation{wang90a} \citation{arge04c} \citation{wang90a} \citation{riley01a} \newlabel{eq-ws}{{2}{8}{Introduction\relax }{equation.1.2}{}} \newlabel{eq-dchb}{{3}{8}{Introduction\relax }{equation.1.3}{}} \citation{hakamada81a} \citation{wang97a} \citation{cism11a} \citation{arge03a} \citation{riley11a} \@writefile{lof}{\contentsline {figure}{\numberline {4}{\ignorespaces Computed coronal hole boundaries at $1 R_{\odot }$ (top), distance from the coronal hole boundary at $30 R_{\odot }$ (middle), and expansion factor at $30 R_{\odot }$ (bottom) for CR 2060.}}{10}{figure.1.4}} \newlabel{ch-dchb-expfac}{{4}{10}{ Computed coronal hole boundaries at $1 R_{\odot }$ (top), distance from the coronal hole boundary at $30 R_{\odot }$ (middle), and expansion factor at $30 R_{\odot }$ (bottom) for CR 2060}{figure.1.4}{}} \@writefile{toc}{\contentsline {section}{\numberline {2}Unipolar Streamers in the Corona}{10}{section.1.2}} \citation{sarabhai63a} \@writefile{toc}{\contentsline {section}{\numberline {3}Solar Wind Speed from Unipolar Streamers}{11}{section.1.3}} \@writefile{lof}{\contentsline {figure}{\numberline {5}{\ignorespaces Comparison of model results with white light synoptic maps from COR1 and COR2 instruments on board STEREO A and B spacecraft. The images were assembled from east limb observations and have been arbitrarily scaled to bring out the structure contained within each. }}{12}{figure.1.5}} \newlabel{fig:pb-maps-comp}{{5}{12}{ Comparison of model results with white light synoptic maps from COR1 and COR2 instruments on board STEREO A and B spacecraft. The images were assembled from east limb observations and have been arbitrarily scaled to bring out the structure contained within each. \relax }{figure.1.5}{}} \citation{neugebauer04a} \@writefile{lof}{\contentsline {figure}{\numberline {6}{\ignorespaces (Top) Coronal holes for CR 2060 computed from the MHD solution and color-coded according to the observed underlying photospheric magnetic field. The trajectory of the ACE spacecraft is superimposed, together with the mapped source regions of the plasma measured at ACE. (Middle) Photospheric magnetic field (color contours), location of the neutral line (black line), and mapped source regions of ACE measurements color-coded according to the observed {\it in-situ} polarity of the magnetic field embedded in the plasma. (Bottom) Ballistically-mapped ACE speed (red/blue) and plasma density (green). The speed has been color-coded according to the measured polarity of the {it in-situ} magnetic field. }}{13}{figure.1.6}} \newlabel{fig:cr2060-ch-br-v}{{6}{13}{ (Top) Coronal holes for CR 2060 computed from the MHD solution and color-coded according to the observed underlying photospheric magnetic field. The trajectory of the ACE spacecraft is superimposed, together with the mapped source regions of the plasma measured at ACE. (Middle) Photospheric magnetic field (color contours), location of the neutral line (black line), and mapped source regions of ACE measurements color-coded according to the observed {\it in-situ} polarity of the magnetic field embedded in the plasma. (Bottom) Ballistically-mapped ACE speed (red/blue) and plasma density (green). The speed has been color-coded according to the measured polarity of the {it in-situ} magnetic field. \relax }{figure.1.6}{}} \citation{riley11a} \@writefile{lof}{\contentsline {figure}{\numberline {7}{\ignorespaces (Top) Selection of meridional slices of pB with field lines superimposed, equally spaced in longitude. Field lines colored blue (red) open into the heliosphere and are inward (outward), while field lines drawn in green are closed. The sold black line indicates the latitude of the ACE spacecraft during this interval. }}{14}{figure.1.7}} \newlabel{fig:cr2060-pb-field}{{7}{14}{ (Top) Selection of meridional slices of pB with field lines superimposed, equally spaced in longitude. Field lines colored blue (red) open into the heliosphere and are inward (outward), while field lines drawn in green are closed. The sold black line indicates the latitude of the ACE spacecraft during this interval. \relax }{figure.1.7}{}} \@writefile{toc}{\contentsline {section}{\numberline {4}Model Predictions of Solar Wind Speed from Unipolar Streamers}{14}{section.1.4}} \citation{wang07a} \citation{wang10a} \citation{riley11a} \@writefile{lof}{\contentsline {figure}{\numberline {8}{\ignorespaces (a) Solar wind speed map at $30 R_{\odot }$ produced by the DCHB model. Superimposed are: (1) The HCS (white curve); and (2) the trajectory of the ACE spacecraft (red). (b) Solar wind speed map at $30 R_{\odot }$ produced from the WS model. The HCS and ACE trajectory as also shown as black traces. (c) Solar wind speed at $30 R_{\odot }$ as determined from: (1) ballistically mapping ACE {it in-situ} measurements back from 1 AU (red); (2) extracting from the DCHB model (blue); and (3) extracting from the WS model (green). (d) Solar wind speed at 1 AU. Both the DCHB and WS model results were `evolved' using the technique described by \citet {riley11a}. }}{16}{figure.1.8}} \newlabel{fig:dchb-ws-comp}{{8}{16}{ (a) Solar wind speed map at $30 R_{\odot }$ produced by the DCHB model. Superimposed are: (1) The HCS (white curve); and (2) the trajectory of the ACE spacecraft (red). (b) Solar wind speed map at $30 R_{\odot }$ produced from the WS model. The HCS and ACE trajectory as also shown as black traces. (c) Solar wind speed at $30 R_{\odot }$ as determined from: (1) ballistically mapping ACE {it in-situ} measurements back from 1 AU (red); (2) extracting from the DCHB model (blue); and (3) extracting from the WS model (green). (d) Solar wind speed at 1 AU. Both the DCHB and WS model results were `evolved' using the technique described by \citet {riley11a}. \relax }{figure.1.8}{}} \@writefile{lof}{\contentsline {figure}{\numberline {9}{\ignorespaces (a) Solar wind speed; (b) number density; (c) proton temperature; and (d) magnetic field strength as a function of Carrington longitude (at 1 AU) for Carrington rotation 2060. Two density enhancements are labeled `B' and `C' and discussed in more detail in the text. }}{17}{figure.1.9}} \newlabel{fig:ts-cr2060}{{9}{17}{ (a) Solar wind speed; (b) number density; (c) proton temperature; and (d) magnetic field strength as a function of Carrington longitude (at 1 AU) for Carrington rotation 2060. Two density enhancements are labeled `B' and `C' and discussed in more detail in the text. \relax }{figure.1.9}{}} \@writefile{toc}{\contentsline {section}{\numberline {5}Summary and Discussion}{17}{section.1.5}} \citation{wang07a} \citation{sheeley97a} \citation{wang10a} \citation{wang10a} \citation{gosling78a} \citation{wang10a} \citation{wang90a} \citation{wang94a} \citation{wang97b} \citation{wang10a} \citation{riley06b} \@writefile{lof}{\contentsline {figure}{\numberline {10}{\ignorespaces A selection of magnetic field lines for CR 2060 at a longitude of $215^{\circ }$ are shown at successively smaller scales: (a) $R_{max} = 6 R_{\odot }$; (b) $R_{max} = 2 R_{\odot }$; and (c) $R_{max} = 1.5 R_{\odot }$. For (a) and (b), 185 field lines equally separated in latitude were drawn. For (c), 370 field lines were drawn. The apparently intersecting field lines is a projection effect due to field lines having different ending longitudes. }}{19}{figure.1.10}} \newlabel{fl-zoom}{{10}{19}{ A selection of magnetic field lines for CR 2060 at a longitude of $215^{\circ }$ are shown at successively smaller scales: (a) $R_{max} = 6 R_{\odot }$; (b) $R_{max} = 2 R_{\odot }$; and (c) $R_{max} = 1.5 R_{\odot }$. For (a) and (b), 185 field lines equally separated in latitude were drawn. For (c), 370 field lines were drawn. The apparently intersecting field lines is a projection effect due to field lines having different ending longitudes. \relax }{figure.1.10}{}} \bibstyle{spr-mp-sola} \bibdata{/Users/pete/Dropbox/riley-papers/references/riley-refs-v2.11} \bibcite{antiochos11a}{{1}{2011}{{Antiochos \textit {et~al.}}}{{}}} \bibcite{arge04c}{{2}{2004}{{{Arge}}}{{}}} \bibcite{arge00a}{{3}{2000}{{Arge and Pizzo}}{{}}} \bibcite{arge03a}{{4}{2003}{{{Arge} \textit {et~al.}}}{{}}} \bibcite{cranmer10a}{{5}{2010}{{{Cranmer}}}{{}}} \bibcite{cranmer07a}{{6}{2007}{{{Cranmer}, {van Ballegooijen}, and {Edgar}}}{{}}} \bibcite{crooker04d}{{7}{2004a}{{{Crooker} \textit {et~al.}}}{{}}} \bibcite{crooker04c}{{8}{2004b}{{{Crooker} \textit {et~al.}}}{{}}} \bibcite{cism11a}{{9}{2011}{{{Farrell}}}{{}}} \bibcite{fisk96a}{{10}{1996}{{Fisk}}{{}}} \bibcite{gosling78a}{{11}{1978}{{{Gosling} \textit {et~al.}}}{{}}} \bibcite{gosling81a}{{12}{1981}{{{Gosling} \textit {et~al.}}}{{}}} \bibcite{hakamada81a}{{13}{1981}{{{Hakamada} and {Akasofu}}}{{}}} \bibcite{hundhausen72a}{{14}{1972}{{{Hundhausen}}}{{}}} \bibcite{laming04a}{{15}{2004}{{{Laming}}}{{}}} \bibcite{lionello05a}{{16}{2005}{{{Lionello} \textit {et~al.}}}{{}}} \bibcite{liu09a}{{17}{2010}{{{Liu} \textit {et~al.}}}{{}}} \bibcite{neugebauer62a}{{18}{1962}{{{Neugebauer} and {Snyder}}}{{}}} \bibcite{neugebauer04a}{{19}{2004}{{{Neugebauer} \textit {et~al.}}}{{}}} \bibcite{riley01a}{{20}{2001}{{Riley, Linker, and Miki\'c}}{{}}} \bibcite{riley06b}{{21}{2006}{{{Riley} \textit {et~al.}}}{{}}} \bibcite{riley11a}{{22}{2011}{{{Riley} \textit {et~al.}}}{{}}} \bibcite{sarabhai63a}{{23}{1963}{{Sarabhai}}{{}}} \bibcite{sheeley97a}{{24}{1997}{{{Sheeley} \textit {et~al.}}}{{}}} \bibcite{sonett65a}{{25}{1965}{{{Sonett} and {Colburn}}}{{}}} \bibcite{suess09a}{{26}{2009}{{{Suess} \textit {et~al.}}}{{}}} \bibcite{uzzo03a}{{27}{2003}{{{Uzzo} \textit {et~al.}}}{{}}} \bibcite{wang94a}{{28}{1994}{{{Wang}}}{{}}} \bibcite{wang97a}{{29}{1997}{{Wang and Sheeley}}{{}}} \bibcite{wang90a}{{30}{1990}{{Wang and {Sheeley}}}{{}}} \bibcite{wang03b}{{31}{2003}{{{Wang} and {Sheeley}}}{{}}} \bibcite{wang96a}{{32}{1996}{{Wang, Hawley, and Sheeley~Jr}}{{}}} \bibcite{wang09a}{{33}{2009}{{{Wang}, {Ko}, and {Grappin}}}{{}}} \bibcite{wang07a}{{34}{2007}{{{Wang}, {Sheeley}, and {Rich}}}{{}}} \bibcite{wang97b}{{35}{1997}{{{Wang} \textit {et~al.}}}{{}}} \bibcite{wang10a}{{36}{2010}{{{Wang} \textit {et~al.}}}{{}}} \bibcite{winterhalter94a}{{37}{1994}{{{Winterhalter} \textit {et~al.}}}{{}}} \global\@namedef{@lastpage@1}{23}