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Global MHD Simulation with BATSRUS from CCMC ESS 265 UCLA1 (Yasong Ge, Megan Cartwright, Jared Leisner, and Xianzhe Jia)

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Presentation on theme: "Global MHD Simulation with BATSRUS from CCMC ESS 265 UCLA1 (Yasong Ge, Megan Cartwright, Jared Leisner, and Xianzhe Jia)"— Presentation transcript:

1 Global MHD Simulation with BATSRUS from CCMC ESS 265 UCLA1 (Yasong Ge, Megan Cartwright, Jared Leisner, and Xianzhe Jia)

2 Outline Description of Model Global Magnetophere Dayside Magnetopause and Solar Wind Cusp Region Investigation Magnetotail Investigation

3 BATS-R-US Model BATS-R-US, the Block-Adaptive-Tree- Solarwind-Roe-Upwind-Scheme, was developed by the Computational Magnetohydrodynamics (MHD) Group at the University of Michigan, now Center for Space Environment Modeling (CSEM). It was designed using the Message Passing Interface (MPI) and the Fortran90 standard and executes on a massively parallel computer system. The BATS-R-US code solves 3D MHD equations in finite volume form using numerical methods related to Roe's Approximate Riemann Solver. BATSRUS uses an adaptive grid composed of rectangular blocks arranged in varying degrees of spatial refinement levels. The magnetospheric MHD part is attached to an ionospheric potential solver that provides electric potentials and conductances in the ionosphere from magnetospheric field- aligned currents.

4 Input parameters and boundary conditions Fixed Solar Wind velocity of 400km/s, solar wind density of 5X10 6 protons/m 3 and temperature of 1X10 5. Two hours initialization with steady southward IMF. Turning IMF northward for the last two hours. Default ionosphere without corotation.

5 Magnetic field lines t=00:00

6 Magnetic field lines t=01:00

7 Magnetic field lines t=01:58

8 Magnetic field lines t=02:00

9 Magnetic field lines t=02:04

10 Magnetic field lines t=02:06

11 Magnetic field lines t=02:08

12 Magnetic field lines t=02:16

13 Magnetic field lines t=02:30

14 Magnetic field lines t=02:46

15 Magnetic field lines t=03:00

16 Magnetic field lines t=03:16

17 Magnetic field lines t=03:20

18 Magnetic field lines t=03:30

19 Magnetic field lines t=03:46

20 Magnetic field lines t=04:00

21 Pressure + Velocity vectors t= 00:00 Equatorial view Noon-Midnight meridian view

22 Pressure + Velocity vectors t= 01:00 Equatorial view Noon-Midnight meridian view

23 Pressure + Velocity vectors t= 01:58 Equatorial view Noon-Midnight meridian view

24 Pressure + Velocity vectors t= 02:00 Equatorial view Noon-Midnight meridian view

25 Pressure + Velocity vectors t= 02:04 Equatorial view Noon-Midnight meridian view

26 Pressure + Velocity vectors t= 02:06 Equatorial view Noon-Midnight meridian view

27 Pressure + Velocity vectors t= 02:08 Equatorial view Noon-Midnight meridian view

28 Pressure + Velocity vectors t= 02:16 Equatorial view Noon-Midnight meridian view

29 Pressure + Velocity vectors t= 02:30 Equatorial view Noon-Midnight meridian view

30 Pressure + Velocity vectors t= 02:46 Equatorial view Noon-Midnight meridian view

31 Pressure + Velocity vectors t= 03:00 Equatorial view Noon-Midnight meridian view

32 Pressure + Velocity vectors t= 03:16 Equatorial view Noon-Midnight meridian view

33 Pressure + Velocity vectors t= 03:20 Equatorial view Noon-Midnight meridian view

34 Pressure + Velocity vectors t= 03:30 Equatorial view Noon-Midnight meridian view

35 Pressure + Velocity vectors t= 03:46 Equatorial view Noon-Midnight meridian view

36 Pressure + Velocity vectors t= 04:00 Equatorial view Noon-Midnight meridian view

37 Plasma temperature t= 00:00

38 Plasma temperature t= 01:00

39 Plasma temperature t= 01:58

40 Plasma temperature t= 02:00

41 Plasma temperature t= 02:04

42 Plasma temperature t= 02:06

43 Plasma temperature t= 02:08

44 Plasma temperature t= 02:16

45 Plasma temperature t= 02:30

46 Plasma temperature t= 02:46

47 Plasma temperature t= 03:00

48 Plasma temperature t= 03:16

49 Plasma temperature t= 03:20

50 Plasma temperature t= 03:30

51 Plasma temperature t= 03:46

52 Plasma temperature t= 04:00

53 J y t= 00:00

54 J y t= 01:00

55 J y t= 01:58

56 J y t= 02:00

57 J y t= 02:16

58 J y t= 02:30

59 J y t= 02:46

60 J y t= 03:00

61 J y t= 03:16

62 J y t= 03:20

63 J y t= 03:30

64 J y t= 03:46

65 J y t= 04:00

66 Ionospheric potential + velocity vectors

67

68

69

70

71

72

73

74 Summary for Global View 3D B field lines show tail flaring on southward IMF and flux return (tail field relaxation) on northward IMF. NENL retreats a while after IMF turning. Plasma pressure in magnetosheath increases temporarily just after northward IMF hits magnetophere. Magnetosheath flows rotate to field-aligned. Two convection cells in tail shows the ground state of magnetophere. Thin plasma sheet is present on southward IMF and has a large y range. Plasma sheet density and size in y direction decrease, but plasma expansion in z direction follows the NENL retreating. Thin current sheet also is shown at Jy plot. Southward IMF gives strong magnetopause current, and the current fades off after IMF turning. DP-2 current system is shown when IMF is southward and dies off when IMF is turned northward.

75 Pressure(color) and velocity(vector) and B field lines at t=0:00 Left is noon-midnight meridianRight is equatorial plane

76 Pressure(color) and velocity(vector) and B field lines at t=1:00 Left is noon-midnight meridianRight is equatorial plane

77 Pressure(color) and velocity(vector) and B field lines at t=1:58 Left is noon-midnight meridianRight is equatorial plane

78 Pressure(color) and velocity(vector) and B field lines at t=2:00 Left is noon-midnight meridianRight is equatorial plane

79 Pressure(color) and velocity(vector) and B field lines at t=2:04 Left is noon-midnight meridianRight is equatorial plane

80 Pressure(color) and velocity(vector) and B field lines at t=2:06 Left is noon-midnight meridianRight is equatorial plane

81 Pressure(color) and velocity(vector) and B field lines at t=2:08 Left is noon-midnight meridianRight is equatorial plane

82 Pressure(color) and velocity(vector) and B field lines at t=2:16 Left is noon-midnight meridianRight is equatorial plane

83 Pressure(color) and velocity(vector) and B field lines at t=2:30 Left is noon-midnight meridianRight is equatorial plane

84 Pressure(color) and velocity(vector) and B field lines at t=2:46 Left is noon-midnight meridianRight is equatorial plane

85 Pressure(color) and velocity(vector) and B field lines at t=3:16 Left is noon-midnight meridianRight is equatorial plane

86 Pressure(color) and velocity(vector) and B field lines at t=3:00 Left is noon-midnight meridianRight is equatorial plane

87 Pressure(color) and velocity(vector) and B field lines at t=3:30 Left is noon-midnight meridianRight is equatorial plane

88 Pressure(color) and velocity(vector) and B field lines at t=3:46 Left is noon-midnight meridianRight is equatorial plane

89 Pressure(color) and velocity(vector) and B field lines at t=4:00 Left is noon-midnight meridianRight is equatorial plane

90 Summary for Magnetopause At the dayside magnetosheath, the plasma pressure increases due to the turning of IMF from southward to northward and the turning off of dayside reconnection. Plasma pressure in dayside magnetosheath finally falls off. Pressure stabilizes at subsolar point between t = 2:46 and 3:00 Magnetic field flux piles up at dayside magnetopause due to the turning of IMF.

91 Pressure(color) and velocity(vector) and B field lines at t=0:00

92 Pressure(color) and velocity(vector) and B field lines at t=1:00

93 Pressure(color) and velocity(vector) and B field lines at t=1:58

94 Pressure(color) and velocity(vector) and B field lines at t=2:00

95 Pressure(color) and velocity(vector) and B field lines at t=2:04

96 Pressure(color) and velocity(vector) and B field lines at t=2:06

97 Pressure(color) and velocity(vector) and B field lines at t=2:08

98 Pressure(color) and velocity(vector) and B field lines at t=2:12

99 Pressure(color) and velocity(vector) and B field lines at t=2:16

100 Pressure(color) and velocity(vector) and B field lines at t=2:30

101 Pressure(color) and velocity(vector) and B field lines at t=2:46

102 Pressure(color) and velocity(vector) and B field lines at t=3:00

103 Pressure(color) and velocity(vector) and B field lines at t=3:30

104 Pressure(color) and velocity(vector) and B field lines at t=3:46

105 Pressure(color) and velocity(vector) and B field lines at t=4:00

106 LogT(color) and JXB(vector) and B field lines at t=0:00

107 LogT(color) and JXB(vector) and B field lines at t=1:00

108 LogT(color) and JXB(vector) and B field lines at t=1:58

109 LogT(color) and JXB(vector) and B field lines at t=2:00

110 LogT(color) and JXB(vector) and B field lines at t=2:04

111 LogT(color) and JXB(vector) and B field lines at t=2:06

112 LogT(color) and JXB(vector) and B field lines at t=2:08

113 LogT(color) and JXB(vector) and B field lines at t=2:12

114 LogT(color) and JXB(vector) and B field lines at t=2:16

115 LogT(color) and JXB(vector) and B field lines at t=2:30

116 LogT(color) and JXB(vector) and B field lines at t=2:46

117 LogT(color) and JXB(vector) and B field lines at t=3:00

118 LogT(color) and JXB(vector) and B field lines at t=3:16

119 LogT(color) and JXB(vector) and B field lines at t=3:30

120 LogT(color) and JXB(vector) and B field lines at t=3:46

121 LogT(color) and JXB(vector) and B field lines at t=4:00

122 Summary for Cusp Region In the cusp, the pressure decreases significantly as the IMF turns northward. At cusp region, flow is parallel the magnetopause when IMF is southward, then rotates counter-clockwise until it points perpendicular to the magnetopause. This is the inflow of solar wind particles due to reconnection. The cusp region immigrates northward in northward IMF. Magnetopause moves out, polar cap shrinks (green lines). Hot particle concentration moves up from the ram side to the upper flank, settling in the region of reconnection. Polar cap disappears? JxB force goes from about equal between polar and closed field lines to much larger on northern side of reconnection region (not exactly sure what to make of this...current in reconnection region is predominantly field-aligned?).

123 B field lines in tail at t=0:00

124 B field lines in tail at t=1:00

125 B field lines in tail at t=1:58

126 B field lines in tail at t=2:00

127 B field lines in tail at t=2:04

128 B field lines in tail at t=2:06

129 B field lines in tail at t=2:08

130 B field lines in tail at t=2:10

131 B field lines in tail at t=2:16

132 B field lines in tail at t=2:30

133 B field lines in tail at t=2:46

134 B field lines in tail at t=3:00

135 B field lines in tail at t=3:16

136 B field lines in tail at t=3:20

137 B field lines in tail at t=3:22

138 B field lines in tail at t=3:24

139 B field lines in tail at t=3:26

140 B field lines in tail at t=3:28

141 B field lines in tail at t=3:30

142 B field lines in tail at t=3:46

143 B field lines in tail at t=4:00

144 Number Density and Velocity in tail at t=0:00

145 Number Density and Velocity in tail at t=1:00

146 Number Density and Velocity in tail at t=1:58

147 Number Density and Velocity in tail at t=2:00

148 Number Density and Velocity in tail at t=2:04

149 Number Density and Velocity in tail at t=2:06

150 Number Density and Velocity in tail at t=2:08

151 Number Density and Velocity in tail at t=2:16

152 Number Density and Velocity in tail at t=2:30

153 Number Density and Velocity in tail at t=2:46

154 Number Density and Velocity in tail at t=3:00

155 Number Density and Velocity in tail at t=3:16

156 Number Density and Velocity in tail at t=3:30

157 Number Density and Velocity in tail at t=3:46

158 Number Density and Velocity in tail at t=4:00

159 Summary from Tail View Dayside reconnection in southward IMF transports magnetic flux into tail. Tail is flaring due to flux pile-up. Near-Earth reconnection sustains when IMF is southward. Northward IMF decreases dayside reconnection rate and tail reconnection return flux back to dayside. NENL retreats from ~20 R E to distant tail after 3:16. Plasma sheet tenuates and extends tailward with the retreating of neutral line.

160 Summary Dayside reconnection due to southward IMF erodes dayside magnetosphere and magnetic flux piles up at tail. Northward IMF ceases (almost) dayside reconnection and erosion of dayside magnetosphere. Tail reconnection returns flux back to dayside, and magnetosphere relaxes to the ground state.

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