| Show | Sort | Join tables | Column | Constraint | Explain (UCD) |
| | | (ALL) | recno | | Record number assigned by the VizieR team. Should Not be used for identification. |
| | |  (ALL) | o/p | | Initial ortho-to-para H2 ratio |
| | | (ALL) | Params | (char) | List of physical parameters, H2-line fluxes and luminosities in C-type shock model |
| | | (1+2+7+8) | ColDen | (char) | List of Column Densities for this set of [o/p, nH, Vs] values in C-type shock model |
| | | (ALL) | nH | cm-3 | Initial density, nH=n(H)+2n(H2) |
| | | (ALL) | Vs | km/s | Shock velocity |
| | | (1+2+7+8) | B0 | 10-10T | Initial magnetic induction (microGauss) |
| | | (1+7) | L | cm | Shock width (region where Tn>50K) |
| | | (1+7) | t | yr | Flow time (for the neutrals to cross the width of the shock) |
| | | (1+7) | nH(50K) | cm-3 | Post-shock density at Tn=50K |
| | | (1+7) | |Vi-Vn|max | km/s | Maximum ion-neutral drift velocity |
ALL cols | | | |
| | | (1+7) | (H/nH)max | | Maximum value of n(H)/nH where nH=n(H)+2n(H2) |
| | | (1+7) | Tnmax | K | Maximum temperature of neutrals |
| | | (1+7) | TjCAM | K | Mean rotational excitation temperature for levels v=0,J=5...8 (Note 1)
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| | | (1+7) | Tjv:1 | K | Mean rotational excitation temperature for levels v=1,J=1...11 (Note 1)
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| | | (1+7) | (o/p)max | | Local ortho:para-H2 ratio at the rear of the shock (where Tn=50K) |
| | | (1+7) | N(o)/N(p) | | Ratio of column densities of ortho and para H2, at the rear of the shock |
| | | (1+7) | (o/p)CAM | | Mean of empirical o/p ratio for levels v=0,J=5...8 (Note 2)
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| | | (1+7) | (o/p)v:1 | | Mean of empirical o/p ratio for levels v=1,J=1...11 (Note 2)
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| | | (2+8) | Lmech | mW/m2 | Initial mechanical energy flux, Lmech=1/2.ρ.Vs3, where ρ=1.4nH.m(H) |
| | | (2+8) | pH2 | % | Percentage of Lmech radiated in all H2 lines included in the model |
| | | (2+8) | pCAM | % | Percentage of Lmech radiated in H2 transitions 0-0 S(2)...S(7). |
| | | (2+8) | 0-0(0) | mW/m2/sr | H2 line flux (Note 1)
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| | | (2+8) | 0-0(1) | mW/m2/sr | H2 line flux (Note 1)
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ALL cols | | | |
| | | (2+8) | 0-0(2) | mW/m2/sr | H2 line flux (Note 1)
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| | | (2+8) | 0-0(3) | mW/m2/sr | H2 line flux (Note 1)
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| | | (2+8) | 0-0(4) | mW/m2/sr | H2 line flux (Note 1)
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| | | (2+8) | 0-0(5) | mW/m2/sr | H2 line flux (Note 1)
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| | | (2+8) | 0-0(6) | mW/m2/sr | H2 line flux (Note 1)
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| | | (2+8) | 0-0(7) | mW/m2/sr | H2 line flux (Note 1)
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| | | (2+8) | 0-0(8) | mW/m2/sr | H2 line flux (Note 1)
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| | | (2+8) | 0-0(9) | mW/m2/sr | H2 line flux (Note 1)
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| | | (2+8) | 0-0(10) | mW/m2/sr | H2 line flux (Note 1)
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| | | (2+8) | 0-0(11) | mW/m2/sr | H2 line flux (Note 1)
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| | | (2+8) | 1-0(0) | mW/m2/sr | H2 line flux (Note 1)
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| | | (2+8) | 1-0(1) | mW/m2/sr | H2 line flux (Note 1)
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| | | (2+8) | 1-0(2) | mW/m2/sr | H2 line flux (Note 1)
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ALL cols | | | |
| | | (2+8) | 1-0(3) | mW/m2/sr | H2 line flux (Note 1)
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| | | (2+8) | 1-0(4) | mW/m2/sr | H2 line flux (Note 1)
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| | | (2+8) | 1-0(5) | mW/m2/sr | H2 line flux (Note 1)
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| | | (2+8) | 1-0(6) | mW/m2/sr | H2 line flux (Note 1)
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| | | (2+8) | 1-0(7) | mW/m2/sr | H2 line flux (Note 1)
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| | | (2+8) | 1-0(8) | mW/m2/sr | H2 line flux (Note 1)
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| | | (2+8) | 1-0(9) | mW/m2/sr | H2 line flux (Note 1)
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| | | (2+8) | 1-0(10) | mW/m2/sr | H2 line flux (Note 1)
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| | | (2+8) | 1-0(11) | mW/m2/sr | H2 line flux (Note 1)
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| | | (2+8) | 2-1(1) | mW/m2/sr | H2 line flux (Note 1)
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| | | (3+4+5+6+9+10+11+12) | V | | Vibrational state of the upper level |
| | | (3+4+5+6+9+10+11+12) | J | | Rotational state of the upper level |
| | | (3+4+5+6+9+10+11+12) | Evj/k | K | Energy of the upper level |
ALL cols | | | |
| | | (3+4+5+6+9+10+11+12) | ln(N(V,J)/g) | 0.43[cm-2] | ln (N(V,J)/g) value (Note 1)
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ALL cols | | | |