tests:collision:mock_data
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| tests:collision:mock_data [2016/12/16 13:52] – v.henault-brunet | tests:collision:mock_data [2022/10/24 12:27] (current) – external edit 127.0.0.1 | ||
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| ====== Mock data ====== | ====== Mock data ====== | ||
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| - | + | [[:tests:collision:mock_data:Challenge_4|Challenge | |
| - | ===== Challenge 1: single mass clusters ===== | + | |
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| - | ==== Isolated models: ==== | + | |
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| - | The N-body models can be described as: | + | |
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| - | - Initial conditions: Plummer (1911), N = 32768, all stars the same mass | + | |
| - | - No primordial binaries, no central black hole | + | |
| - | - Isolation | + | |
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| - | The data has the following format. Note that the first column can be used to recognise binaries (MN=2). The single components of the binaries are not given. | + | |
| - | ^ $M\times N$ ^ $X$ ^ $Y$ ^ $Z$ ^ $V_x$ ^ $V_y$ ^ $V_z$ ^ | + | |
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| - | - {{:data:32k_logt4.tab.gz}} $T=10^4$ | + | |
| - | - {{:data:32k_logt5.tab.gz}} $T=10^5$ | + | |
| - | - {{: | + | |
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| - | ==== Tidally limited models: ==== | + | |
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| - | The N-body models can be described as: | + | |
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| - | - Initial conditions: Plummer (1911), N = 65536, all stars the same mass | + | |
| - | - No primordial binaries, no central black hole | + | |
| - | - Circular orbit in a weak tidal field due to a point-mass galaxy with initially r_jacobi/ | + | |
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| - | The model was ran until complete dissolution (roughly 6e5 N-body times) with Sverre Aarseth' | + | |
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| - | Below are 3 snapshots at interesting moments of the evolution. The Heggie & Mathieu (1986) N-body units are used: G=M=r_vir=1 (i.e. the mass of individual stars is m=1/65536). The 6 columns contain: | + | |
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| - | ^ $X$ ^ $Y$ ^ $Z$ ^ $V_x$ ^ $V_y$ ^ $V_z$ ^ | + | |
| - | | [NBODY] | + | |
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| - | - {{: | + | |
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| - | Update 14-Oct-2014: | + | |
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| - | Update: 29 Okt 2014: New version of the 10 snapshots above: | + | |
| - | - Removed the individual components of binaries, and added the binary com pos and vel in the end of the file | + | |
| - | - New first column with MxN = 1 for single stars and MxN = 2 for binaries | + | |
| - | - New column (8) = 1 if r<rt | + | |
| - | - New column (9) = 1 if E_Jacobi < E_crit | + | |
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| - | Update 29-Nov-2014: | + | |
| - | - Fixed bug in energy computation | + | |
| - | - New column (8): phi (= specific potential) | + | |
| - | - New column (9); E_J = jacobi energy (see e.g. Fukushige & Heggie (2000), below equation 3) | + | |
| - | - Added top line with: N, rt, E_crit | + | |
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| - | First line: N, rt, E_crit | + | |
| - | ^ $M\timesN$ | $X$ ^ $Y$ ^ $Z$ ^ $V_x$ ^ $V_y$ ^ $V_z$ ^ $\phi$ ^ $E_J$ ^ r < rt ^ E<Ecrit ^ | + | |
| - | | [NBODY] | [NBODY] | + | |
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| - | For the last snapshot a table with specific energy and the z-component | + | |
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| - | Note: the initial Jacobi radius of this model was $r_{\rm J}= 78.17$, such that the angular frequency of the orbit is $\Omega = 8.354\times 10^{-4}$ and the critical energy $E_{\rm crit} = -7.469\times 10^{-3}$ at T=323790 . | + | |
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| - | Illustration of the model evolution, moments of the snapshots are marked with dashed lines: | + | |
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| - | Properties of the clusters: | + | |
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| - | ^ Cluster ^ Mass ^ $r_{\rm c}$ ^ $r_{\rm h}$ ^ $r_{\rm J}$ ^ | + | |
| - | |1 | 0.975|$5.25\times 10^{-3}$ |1.143| 77.3| | + | |
| - | |2 | 0.953|$8.61\times 10^{-3}$ |1.334| 76.6| | + | |
| - | |3 | 0.238|$0.199$ | + | |
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| - | ===== Challenge 2: Multi-mass clusters (no stellar evolution) ===== | + | |
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| - | Data: Snapshots of simulations with a mass function. | + | |
| - | - N <~= $10^5$, initial half-mass radius 2.25 pc, Henon isochrone model | + | |
| - | - Initial half-mass relaxation time =~ 350 Myr | + | |
| - | - no primordial binaries | + | |
| - | - Galaxy = singular isothermal sphere with Vc = 220 kms/s | + | |
| - | - Orbit: circular orbit at RG = 4 kpc | + | |
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| - | The $10^5$ stars were evolved with SSE (Hurley et al. 2000) to an age of 12 Gyr assuming a metallicity of [Fe/H] = -2 **before** the N-body model was run. Then an assumption was made about the retention fraction | + | |
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| - | The properties of the snapshots are: | + | |
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| - | ^ Name ^ f_retention NSs ^ f_rentention BHs ^ age ^ N(NS)_remaining ^ N(BH)_remaining ^ | + | |
| - | | cluster1 | 1 | 1 | 0.25 Gyr | 613 | 171 | | + | |
| - | | cluster1 | 1 | 1 | 0.5 Gyr | 591 | 146 | | + | |
| - | | cluster1 | 1 | 1 | 0.75 Gyr | 559 | 134 | | + | |
| - | | cluster1 | 1 | 1 | 1 Gyr | 548 | 119 | | + | |
| - | | cluster7 | 0.1 | 0.1 | 2 Gyr | 51 | 0 | | + | |
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| - | Format of the snapshots are: | + | |
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| - | ^ $KSTAR$ ^ $m$^ $X$ ^ $Y$ ^ $Z$ ^ $V_x$ ^ $V_y$ ^ $V_z$ ^ | + | |
| - | | | [Msun] ||[pc]| | + | |
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| - | No retention: | + | |
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| - | The definition of the stellar types (KSTAR) used in the '' | + | |
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| - | ===== Challenge 3. Clusters in tidal fields with stellar evolution ===== | + | |
| - | (Simulations ran and kindly made available by Holger Baumgardt)\\ | + | |
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| - | Here we consider 2 clusters which are slightly more realistic: | + | |
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| - | - IC: King (1966) W_0 = 5 model, N = 131072, Kroupa (2001) mass function between 0.1-15 Msun (no black-holes). | + | |
| - | - No primordial binaries, no central black hole, circular orbit in logarithmic halo with V = 220 km/s. | + | |
| - | - Z = 0.001 | + | |
| - | - Stellar evolution and mass-loss according to Hurley et al. (2000, 2002) | + | |
| - | - Two Galactocentric radii: 8.5 kpc and 15 kpc. | + | |
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| - | Below are 2 snapshots at an age of roughly 10 Myr, 100 Myr, 1Gyr and 12 Gyr. The columns are the same as in Challenge 2. | + | |
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| - | Final list of snapshots used in Sollima et al. in prep, columns are: | + | |
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| - | ^ $m$ ^ $X$ ^ $Y$ ^ $Z$ ^ $V_x$ ^ $V_y$ ^ $V_z$ ^ kstar ^ logL ^ logTeff ^ | + | |
| - | | [Msun] |[pc] |[pc] |[pc] | [km/s |[km/s] |[km/s] | | + | |
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| - | The definition of the stellar types (KSTAR) used in the '' | + | |
| - | ===== Appendix | + | The definition of the stellar types (KSTAR) used in the '' |
| - | ==== Stellar types in '' | ||
| - | There 23 possible stellar types (KSTAR) in '' | ||
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| - | 10 | ||
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| - | 14 Black hole. | ||
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| - | 21 First Roche stage (inactive). | ||
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tests/collision/mock_data.1481896360.txt.gz · Last modified: 2022/10/24 12:26 (external edit)