snapec, bsnapec: galaxy cluster spectrum using SN yields

This model calculates the spectrum for a galaxy cluster using the apec model with relative abundances based on SN yields. The relative amounts of SNIa and SNII can be set and there are a wide variety of different SN yield calculations available. It is straightforward to add the results of new yield calculations as they become available in the literature. This model is described in Bulbul, Smith & Loewenstein (2012). All the standard apec xset options can be used.

The parameters are:

par1	plasma temperature, keV
par2	number of SNe (in units of $10^9$)
par3	percentage of SNIa
par4	SNIa yield model
par5	SNII yield model
par6	Redshift, z
norm	${10^{-14}\over{4\pi[D_A(1+z)]^2}}\int n_en_HdV$, where $D_A$ is the angular diameter distance to the source (cm), $dV$ is the volume element (cm$^3$), and $n_e$ and $n_H$ are the electron and H densities (cm$^{-3}$), respectively

The parameters for the bsnapec variant with a parameter for the velocity broadening are:

par1	plasma temperature, keV
par2	number of SNe (in units of $10^9$)
par3	percentage of SNIa
par4	SNIa yield model
par5	SNII yield model
par6	Redshift, z
par7	Gaussian sigma for velocity broadening (km/s)
norm	${10^{-14}\over{4\pi[D_A(1+z)]^2}}\int n_en_HdV$, where $D_A$ is the angular diameter distance to the source (cm), $dV$ is the volume element (cm$^3$), and $n_e$ and $n_H$ are the electron and H densities (cm$^{-3}$), respectively

The yield models available are as followed:

Number	Model	Reference
1	SN Type Ia, W7	R1, Table 2, Z=1.0
2	SN Type II, m$_{\rm u}$=13	R1, Table 1
3	SN Type II, m$_{\rm u}$=15	R1, Table 1
4	SN Type II, m$_{\rm u}$=18	R1, Table 1
5	SN Type II, m$_{\rm u}$=20	R1, Table 1
6	SN Type II, m$_{\rm u}$=25	R1, Table 1
7	SN Type II, m$_{\rm u}$=40	R1, Table 1
8	SN Type II, m$_{\rm u}$=70	R1, Table 1
9	SN Type II, m$_{\rm u}$=average (0-50)	R1, Table 2
10	SN Type II, m$_{\rm u}$=average (0-70)	R1, Table 2
11	SN Type II, m$_{\rm u}$=11, Z=1.0	R2, Table 5a
12	SN Type II, m$_{\rm u}$=12, Z=1.0	R2, Table 5a
13	SN Type II, m$_{\rm u}$=13, Z=1.0	R2, Table 5a
14	SN Type II, m$_{\rm u}$=15, Z=1.0	R2, Table 5a
15	SN Type II, m$_{\rm u}$=18, Z=1.0	R2, Table 5a
16	SN Type II, m$_{\rm u}$=19, Z=1.0	R2, Table 5a
17	SN Type II, m$_{\rm u}$=20, Z=1.0	R2, Table 5a
18	SN Type II, m$_{\rm u}$=22, Z=1.0	R2, Table 5a
19	SN Type II, m$_{\rm u}$=25, Z=1.0	R2, Table 5a
20	SN Type II, m$_{\rm u}$=30A, Z=1.0	R2, Table 5b
21	SN Type II, m$_{\rm u}$=30B, Z=1.0	R2, Table 5b
22	SN Type II, m$_{\rm u}$=35A, Z=1.0	R2, Table 5b
23	SN Type II, m$_{\rm u}$=35B, Z=1.0	R2, Table 5b
24	SN Type II, m$_{\rm u}$=35C, Z=1.0	R2, Table 5b
25	SN Type II, m$_{\rm u}$=40A, Z=1.0	R2, Table 5b
26	SN Type II, m$_{\rm u}$=40B, Z=1.0	R2, Table 5b
27	SN Type II, m$_{\rm u}$=40C, Z=1.0	R2, Table 5b
28	SN Type II, m$_{\rm u}$=12, Z=0.1	R2, Table 10a (P12A)
29	SN Type II, m$_{\rm u}$=13, Z=0.1	R2, Table 10a (P13A)
30	SN Type II, m$_{\rm u}$=15, Z=0.1	R2, Table 10a (P15A)
31	SN Type II, m$_{\rm u}$=18, Z=0.1	R2, Table 10a (P18A)
32	SN Type II, m$_{\rm u}$=20, Z=0.1	R2, Table 10a (P20A)
33	SN Type II, m$_{\rm u}$=22, Z=0.1	R2, Table 10a (P22A)
34	SN Type II, m$_{\rm u}$=25, Z=0.1	R2, Table 10a (P25A)
35	SN Type II, m$_{\rm u}$=30A, Z=0.1	R2, Table 10b (P30A)
36	SN Type II, m$_{\rm u}$=30B, Z=0.1	R2, Table 10b (P30B)
37	SN Type II, m$_{\rm u}$=35A, Z=0.1	R2, Table 10b (P35A)
38	SN Type II, m$_{\rm u}$=35B, Z=0.1	R2, Table 10b (P35B)
39	SN Type II, m$_{\rm u}$=35C, Z=0.1	R2, Table 10b (P35C)
40	SN Type II, m$_{\rm u}$=40A, Z=0.1	R2, Table 10b (P40A)
41	SN Type II, m$_{\rm u}$=40B, Z=0.1	R2, Table 10b (P40B)
42	SN Type II, m$_{\rm u}$=40C, Z=0.1	R2, Table 10b (P40C)
43	SN Type II, m$_{\rm u}$=11, Z=0.01	R2, Table 12a (P12A)
44	SN Type II, m$_{\rm u}$=13, Z=0.01	R2, Table 12a (P13A)
45	SN Type II, m$_{\rm u}$=15, Z=0.01	R2, Table 12a (P15A)
46	SN Type II, m$_{\rm u}$=18, Z=0.01	R2, Table 12a (P18A)
47	SN Type II, m$_{\rm u}$=20, Z=0.01	R2, Table 12a (P20A)
48	SN Type II, m$_{\rm u}$=22, Z=0.01	R2, Table 12a (P22A)
49	SN Type II, m$_{\rm u}$=25, Z=0.01	R2, Table 12a (P25A)
50	SN Type II, m$_{\rm u}$=30A, Z=0.01	R2, Table 12b (T30A)
51	SN Type II, m$_{\rm u}$=30B, Z=0.01	R2, Table 12b (T30B)
52	SN Type II, m$_{\rm u}$=35A, Z=0.01	R2, Table 12b (T35A)
53	SN Type II, m$_{\rm u}$=35B, Z=0.01	R2, Table 12b (T35B)
54	SN Type II, m$_{\rm u}$=35C, Z=0.01	R2, Table 12b (T35C)
55	SN Type II, m$_{\rm u}$=40A, Z=0.01	R2, Table 12b (T40A)
56	SN Type II, m$_{\rm u}$=40B, Z=0.01	R2, Table 12b (T40B)
57	SN Type II, m$_{\rm u}$=40C, Z=0.01	R2, Table 12b (T40C)
58	SN Type II, m$_{\rm u}$=12, Z=0.0001	R2, Table 14a (U12A)
59	SN Type II, m$_{\rm u}$=13, Z=0.0001	R2, Table 14a (U13A)
60	SN Type II, m$_{\rm u}$=15, Z=0.0001	R2, Table 14a (U15A)
61	SN Type II, m$_{\rm u}$=18, Z=0.0001	R2, Table 14a (U18A)
62	SN Type II, m$_{\rm u}$=20, Z=0.0001	R2, Table 14a (U20A)
63	SN Type II, m$_{\rm u}$=22, Z=0.0001	R2, Table 14a (U22A)
64	SN Type II, m$_{\rm u}$=25, Z=0.0001	R2, Table 14a (U25A)
65	SN Type II, m$_{\rm u}$=12, Z=0.0001	R2, Table 14b (U30A)
66	SN Type II, m$_{\rm u}$=13, Z=0.0001	R2, Table 14b (U30B)
67	SN Type II, m$_{\rm u}$=15, Z=0.0001	R2, Table 14b (U35A)
68	SN Type II, m$_{\rm u}$=18, Z=0.0001	R2, Table 14b (U35B)
69	SN Type II, m$_{\rm u}$=20, Z=0.0001	R2, Table 14b (U35C)
70	SN Type II, m$_{\rm u}$=22, Z=0.0001	R2, Table 14b (U40A)
71	SN Type II, m$_{\rm u}$=25, Z=0.0001	R2, Table 14b (U40B)
72	SN Type II, m$_{\rm u}$=25, Z=0.0001	R2, Table 14b (U40C)
73	SN Type II, m$_{\rm u}$=12, Z=0	R2, Table 16a (Z12A)
74	SN Type II, m$_{\rm u}$=13, Z=0	R2, Table 16a (Z13A)
75	SN Type II, m$_{\rm u}$=15A, Z=0	R2, Table 16a (Z15A)
76	SN Type II, m$_{\rm u}$=18, Z=0	R2, Table 16a (Z18A)
77	SN Type II, m$_{\rm u}$=20, Z=0	R2, Table 16a (Z20A)
78	SN Type II, m$_{\rm u}$=22, Z=0	R2, Table 16a (Z22A)
79	SN Type II, m$_{\rm u}$=25, Z=0	R2, Table 16a (Z25A)
80	SN Type II, m$_{\rm u}$=15B, Z=0	R2, Table 16a (Z15B)
81	SN Type II, m$_{\rm u}$=30A, Z=0	R2, Table 16b (Z30A)
82	SN Type II, m$_{\rm u}$=30B, Z=0	R2, Table 16b (Z30B)
83	SN Type II, m$_{\rm u}$=10-50	R3, Table 3
84	SN Type I, W7	R3, Table 3
85	SN Type I, W70	R3, Table 3
86	SN Type I, WDD1	R3, Table 3
87	SN Type I, WDD2	R3, Table 3
88	SN Type I, WDD3	R3, Table 3
89	SN Type I, CDD1	R3, Table 3
90	SN Type I, CDD3	R3, Table 3
91	SN Type II, m$_{\rm u}$=13, Z=0	R4, Table 2
92	SN Type II, m$_{\rm u}$=15, Z=0	R4, Table 2
93	SN Type II, m$_{\rm u}$=18, Z=0	R4, Table 2
94	SN Type II, m$_{\rm u}$=20, Z=0	R4, Table 2
95	SN Type II, m$_{\rm u}$=25, Z=0	R4, Table 2
96	SN Type II, m$_{\rm u}$=30, Z=0	R4, Table 2
97	SN Type II, m$_{\rm u}$=40, Z=0	R4, Table 2
98	SN Type II, m$_{\rm u}$=13, Z=0.001	R4, Table 2
99	SN Type II, m$_{\rm u}$=15, Z=0.001	R4, Table 2
100	SN Type II, m$_{\rm u}$=18, Z=0.001	R4, Table 2
101	SN Type II, m$_{\rm u}$=20, Z=0.001	R4, Table 2
102	SN Type II, m$_{\rm u}$=25, Z=0.001	R4, Table 2
103	SN Type II, m$_{\rm u}$=30, Z=0.001	R4, Table 2
104	SN Type II, m$_{\rm u}$=40, Z=0.001	R4, Table 2
105	SN Type II, m$_{\rm u}$=13, Z=0.004	R4, Table 2
106	SN Type II, m$_{\rm u}$=15, Z=0.004	R4, Table 2
107	SN Type II, m$_{\rm u}$=18, Z=0.004	R4, Table 2
108	SN Type II, m$_{\rm u}$=20, Z=0.004	R4, Table 2
109	SN Type II, m$_{\rm u}$=25, Z=0.004	R4, Table 2
110	SN Type II, m$_{\rm u}$=30, Z=0.004	R4, Table 2
111	SN Type II, m$_{\rm u}$=40, Z=0.004	R4, Table 2
112	SN Type II, m$_{\rm u}$=13, Z=0.02	R4, Table 2
113	SN Type II, m$_{\rm u}$=15, Z=0.02	R4, Table 2
114	SN Type II, m$_{\rm u}$=18, Z=0.02	R4, Table 2
115	SN Type II, m$_{\rm u}$=20, Z=0.02	R4, Table 2
116	SN Type II, m$_{\rm u}$=25, Z=0.02	R4, Table 2
117	SN Type II, m$_{\rm u}$=30, Z=0.02	R4, Table 2
118	SN Type II, m$_{\rm u}$=40, Z=0.02	R4, Table 2
119	SN Type Ia, W7	R5
120	SN Type Ia, cDEF	R5
121	SN Type Ia, CDDT	R5
122	SN Type Ia, ODDT	R5

The references are

R1	Tsujimoto et al. (1995)
R2	Woosley & Weaver (1995)
R3	Iwamoto et al. (1999)
R4	Nomoto et al. (2006)
R5	Maeda et al. (2010)

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Last modified: Friday, 23-Aug-2024 13:20:40 EDT