Changes between Version 10 and Version 11 of TriggeredStarFormation
- Timestamp:
- 01/07/14 18:41:52 (11 years ago)
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TriggeredStarFormation
v10 v11 19 19 Simulation lasts till about $4t_{cc}$, which is about 1 million years. The wind should be turned off before that, so we are really looking at an extreme case where the wind lasts for unusually long time. [[BR]] 20 20 The simulation box has a resolution of 320 x 192 x 192, with 3 AMR levels of particle refinement. [[BR]] 21 The following figure shows the at 0.6 million years. (a) non-rotation Mach 1.5(case N), (b) non-rotation Mach 3.16(case N'), (c) parallel rotation Mach 1.5(case R1), (d) perpendicular rotation Mach 1.5(case R2).[[BR]][[BR]]21 The following figure shows the column density for different cases at 0.6 million years. (a) non-rotation Mach 1.5(case N), (b) non-rotation Mach 3.16(case N'), (c) parallel rotation Mach 1.5(case R1), (d) perpendicular rotation Mach 1.5(case R2).[[BR]][[BR]] 22 22 [[BR]][[BR]] 23 23 [[Image(fig2.png,60%)]] … … 39 39 http://www.pas.rochester.edu/~shuleli/tsf_paper/perrot.gif 40 40 [[BR]] 41 Generally, the evolution can be divided into three stages: As we can see the two rotating cases develop disks with the axis aligned with the initial rotation. The 3D rendering of cloud material tracer for case R1, is as follows: 42 [[BR]] 41 Generally, the evolution can be divided into three stages: As we can see the two rotating cases develop disks with the axis aligned with the initial rotation. The density comparison (slice through the center) is shown in the following figure: [[BR]][[BR]] 42 43 [[Image(http://www.pas.rochester.edu/~shuleli/0321/tsf_comparison.png,40%)]] 44 [[BR]][[BR]] 45 46 The 3D rendering of cloud material tracer for case R1, is as follows: 47 [[BR]][[BR]] 43 48 [[Image(http://www.pas.rochester.edu/~shuleli/tsf_paper/paper_figs/fig1.png, 40%)]] 44 49 [[BR]][[BR]] … … 91 96 92 97 '''MHD Triggering'''[[BR]] 93 When added magnetic field to the cloud, the triggering behavior can be very different. Here, we suppose the initial rotation to be zero first, and look at the case where there is a global uniform magnetic field along . 98 When added magnetic field to the cloud, the triggering behavior can be very different. Here, we suppose the initial rotation to be zero first, and look at the case where there is a global uniform magnetic field along the vertical axis. We assume Mach = 3, and the magnetic field has beta of 4. The density slice looks like:[[BR]][[BR]] 99 1 cloud crushing time: [[BR]] 100 [[Image(http://www.pas.rochester.edu/~shuleli/0321/tsfmach36v_0017.png,40%)]] 101 [[BR]][[BR]] 102 2.5 cloud crushing time: [[BR]] 103 [[Image(http://www.pas.rochester.edu/~shuleli/0321/tsfmach36v_0041.png,40%)]] 104 [[BR]][[BR]] 105 Density slice movie:[[BR]] 106 http://www.pas.rochester.edu/~shuleli/0321/tsfmach36v.gif 107 [[BR]][[BR]] 108 Column density movie: [[BR]] 109 http://www.pas.rochester.edu/~shuleli/0323/mach3bcd.gif 110 [[BR]][[BR]] 111 112 Next, we study if the field is contained within the cloud. We divide the simulations into categories where the contained field is either poloidal or toroidal, and look at the triggering behavior when the poloidal or toroidal axis is parallel or perpendicular to the incoming shock. As shown in our earlier paper about shock interaction with a magnetized clump, it is possible to form multiple compression cores in such a scenario. One natural question is, can we have formation of more than one stars within a single magnetized cloud? The following cut is taken from a simulation where the poloidal field has a maximum strength of beta = 1, incoming shock Mach = 1.5. We plot the column density as well as the 1/beta parameter (in the smaller frame).[[BR]][[BR]] 113 [[Image(http://www.pas.rochester.edu/~shuleli/mhdtsf/mhd_poloidal.png,70%)]] 114 [[BR]][[BR]] 115 The following figure is the toroidal field case:[[BR]][[BR]] 116 [[Image(http://www.pas.rochester.edu/~shuleli/mhdtsf/mhd_toroidal.png,70%)]] 117 [[BR]][[BR]] 118 Movies:[[BR]] 119 Poloidal contained field:[[BR]] 120 http://www.pas.rochester.edu/~shuleli/mhdtsf/tsfpol.gif 121 [[BR]] 122 Toroidal contained field:[[BR]] 123 http://www.pas.rochester.edu/~shuleli/mhdtsf/tsftor.gif 124 [[BR]] 94 125 95 126 96 127 97 Next, we study if the field is contained within the cloud. We divide the simulations into categories where the contained field is either poloidal or toroidal, and look at the triggering behavior when the poloidal or toroidal axis is parallel or perpendicular to the incoming shock. As shown in our earlier paper about shock interaction with a magnetized clump, it is possible to form multiple compression cores in such a scenario. One natural question is, can we have formation of more than one stars within a single magnetized cloud?[[BR]]98 128 99 129 130 131