2017MNRAS.464.4255P

Query : 2017MNRAS.464.4255P

2017MNRAS.464.4255P - Mon. Not. R. Astron. Soc., 464, 4255-4281 (2017/February-1)

The JCMT Gould Belt Survey: first results from SCUBA-2 observations of the Cepheus Flare region.

PATTLE K., WARD-THOMPSON D., KIRK J.M., DI FRANCESCO J., KIRK H., MOTTRAM J.C., KEOWN J., BUCKLE J., BEAULIEU S.F., BERRY D.S., BROEKHOVEN-FIENE H., CURRIE M.J., FICH M., HATCHELL J., JENNESS T., JOHNSTONE D., NUTTER D., PINEDA J.E., QUINN C., SALJI C., TISI S., WALKER-SMITH S., HOGERHEIJDE M.R., BASTIEN P., BRESNAHAN D., BUTNER H., CHEN M., CHRYSOSTOMOU A., COUDE S., DAVIS C.J., DRABEK-MAUNDER E., DUARTE-CABRAL A., FIEGE J., FRIBERG P., FRIESEN R., FULLER G.A., GRAVES S., GREAVES J., GREGSON J., HOLLAND W., JONCAS G., KNEE L.B.G., MAIRS S., MARSH K., MATTHEWS B.C., MORIARTY-SCHIEVEN G., MOWAT C., RAWLINGS J., RICHER J., ROBERTSON D., ROSOLOWSKY E., RUMBLE D., SADAVOY S., THOMAS H., TOTHILL N., VITI S., WHITE G.J., WOUTERLOOT J., YATES J. and ZHU M.

Abstract (from CDS):

We present observations of the Cepheus Flare obtained as part of the James Clerk Maxwell Telescope (JCMT) Gould Belt Legacy Survey (GBLS) with the SCUBA-2 instrument. We produce a catalogue of sources found by SCUBA-2, and separate these into starless cores and protostars. We determine masses and densities for each of our sources, using source temperatures determined by the Herschel Gould Belt Survey. We compare the properties of starless cores in four different molecular clouds: L1147/58, L1172/74, L1251 and L1228. We find that the core mass functions for each region typically show shallower-than-Salpeter behaviour. We find that L1147/58 and L1228 have a high ratio of starless cores to Class II protostars, while L1251 and L1174 have a low ratio, consistent with the latter regions being more active sites of current star formation, while the former are forming stars less actively. We determine that if modelled as thermally supported Bonnor-Ebert spheres, most of our cores have stable configurations accessible to them. We estimate the external pressures on our cores using archival ¹³CO velocity dispersion measurements and find that our cores are typically pressure confined, rather than gravitationally bound. We perform a virial analysis on our cores, and find that they typically cannot be supported against collapse by internal thermal energy alone, due primarily to the measured external pressures. This suggests that the dominant mode of internal support in starless cores in the Cepheus Flare is either non-thermal motions or internal magnetic fields.

Journal keyword(s): stars: formation - dust, extinction - submillimetre: ISM - submillimetre: ISM

Nomenclature: Table 3: [PWK2017] NNN (Nos 1-117).

CDS comments: Table 3 : IRAS 20359+6475 is a misprint for IRAS 20359+6745

Simbad objects: 145

Full paper

View the references in ADS

Number of rows : 145

N	Identifier	Otype	ICRS (J2000) RA	ICRS (J2000) DEC	Mag U	Mag B	Mag V	Mag R	Mag I	Sp type	#ref 1850 - 2024	#notes
1	NAME Per Arm	PoG	03 30	+45.0						~	1513	0
2	NAME Ophiuchus Molecular Cloud	SFR	16 28 06	-24 32.5						~	3629	1
3	LBN 028.77+03.43	HII	18 31 26.5	-02 04 22						~	230	2
4	[PWK2017] 3	cor	20 35 41.760	+67 52 48.00						~	1	0
5	IRAS 20353+6742	Y*O	20 35 46.325	+67 53 02.00						~	37	0
6	LDN 1152	DNe	20 35 50.2	+67 54 22						~	73	0
7	[PWK2017] 4	cor	20 35 54.720	+67 54 10.80						~	1	0
8	[PWK2017] 20	cor	20 36 05.760	+67 56 45.60						~	1	0
9	2MASS J20361165+6757093	Y*O	20 36 11.6602336896	+67 57 09.417927024						~	10	0
10	IRAS 20359+6745	Y*O	20 36 19.8634846200	+67 56 31.695275256			17.81	16.02	14.34	~	38	0
11	[PWK2017] 19	cor	20 38 04.570	+67 55 51.60						~	1	0
12	[PWK2017] 16	cor	20 38 06.960	+67 55 30.00						~	1	0
13	NAME LDN 1157-mm	Y*O	20 39 06.2	+68 02 15						~	189	0
14	LDN 1157	DNe	20 39 06.4	+68 02 13						~	572	0
15	LDN 1148	DNe	20 40 31.6	+67 21 45						~	65	0
16	LDN 1147	DNe	20 40 32	+67 20.7						~	35	0
17	BD+67 1263	*	20 42 35.7041079168	+67 36 35.124652332		10.28	10.04			A6V	6	0
18	[PWK2017] 13	cor	20 43 10.560	+67 51 00.00						~	1	0
19	LDN 1155C	DNe	20 43 18.1	+67 50 36						~	30	0
20	[PWK2017] 14	cor	20 43 18.240	+67 50 56.40						~	1	0
21	[PWK2017] 12	cor	20 43 24.480	+67 53 09.60						~	1	0
22	[PWK2017] 17	cor	20 43 25.680	+67 52 22.80						~	1	0
23	[PWK2017] 18	cor	20 43 29.760	+67 52 55.20						~	1	0
24	LDN 1155	DNe	20 43.5	+67 41						~	27	0
25	[PWK2017] 15	cor	20 43 49.200	+67 51 00.00						~	1	0
26	LDN 1158	DNe	20 44.5	+67 41						~	35	0
27	[PWK2017] 9	cor	20 44 47.520	+67 44 24.00						~	1	0
28	[PWK2017] 7	cor	20 44 48.480	+67 43 12.00						~	1	0
29	[PWK2017] 10	cor	20 44 50.880	+67 44 13.20						~	1	0
30	[PWK2017] 8	cor	20 44 51.600	+67 43 40.80						~	1	0
31	V* PV Cep	Or*	20 45 53.9540390184	+67 57 38.679941304		19.27	17.46	15.98	14.60	A5	269	3
32	[PWK2017] 103	cor	20 54 49.440	+77 32 24.00						~	1	0
33	[PWK2017] 114	cor	20 54 49.440	+77 43 33.60						~	1	0
34	[PWK2017] 105	cor	20 54 59.040	+77 50 34.80						~	1	0
35	[PWK2017] 110	cor	20 55 11.280	+77 33 21.60						~	1	0
36	[PWK2017] 112	cor	20 55 18.480	+77 45 46.80						~	1	0
37	[PWK2017] 101	cor	20 55 54.240	+77 42 46.80						~	1	0
38	[PWK2017] 115	cor	20 56 18.000	+77 24 57.60						~	1	0
39	[PWK2017] 108	cor	20 56 27.370	+77 24 43.20						~	1	0
40	[PWK2017] 100	cor	20 56 41.280	+77 41 24.00						~	1	0
41	[PWK2017] 104	cor	20 56 42.240	+77 40 55.20						~	1	0
42	IRAS 20582+7724	Y*O	20 57 12.9250225656	+77 35 43.656301932						~	117	0
43	LDN 1228	DNe	20 57 13	+77 35.8						~	128	0
44	[PWK2017] 102	cor	20 57 13.680	+77 44 06.00						~	1	0
45	[PWK2017] 117	cor	20 57 17.050	+77 33 21.60						~	1	0
46	[PWK2017] 99	cor	20 57 18.240	+77 37 51.60						~	1	0
47	[PWK2017] 106	cor	20 57 39.600	+77 43 37.20						~	1	0
48	[PWK2017] 107	cor	20 57 47.760	+77 37 19.20						~	1	0
49	[PWK2017] 98	cor	20 58 02.160	+77 33 18.00						~	1	0
50	[PWK2017] 113	cor	20 58 19.920	+77 42 36.00						~	1	0
51	[PWK2017] 116	cor	20 58 30.240	+77 42 43.20						~	1	0
52	[PWK2017] 109	cor	20 58 49.680	+77 47 16.80						~	1	0
53	V* FT Cep	Y*O	20 59 22.8556258080	+68 14 43.702003140		19.37	16.41	14.79	13.30	~	16	1
54	[PWK2017] 26	cor	21 00 17.280	+68 12 46.80						~	1	0
55	[PWK2017] 22	Y*O	21 00 19.680	+68 13 22.80						~	1	0
56	LDN 1174	DNe	21 00 22.4	+68 12 53						~	65	0
57	[PWK2017] 25	Y*O	21 00 23.040	+68 13 12.00						~	1	0
58	[PWK2017] 44	cor	21 00 23.520	+68 08 13.20						~	1	0
59	[PWK2017] 42	cor	21 00 24.250	+68 14 06.00						~	1	0
60	[PWK2017] 38	cor	21 00 28.560	+68 07 08.40						~	1	0
61	[PWK2017] 43	cor	21 00 37.920	+68 06 18.00						~	1	0
62	JCMTSE J210129.7+681029	Y*O	21 01 27.1	+68 10 38						~	4	0
63	[PWK2017] 29	cor	21 01 28.320	+68 08 20.40						~	1	0
64	[PWK2017] 36	cor	21 01 31.200	+68 05 38.40						~	1	0
65	[PWK2017] 34	cor	21 01 31.200	+68 07 19.20						~	1	0
66	[PWK2017] 41	Y*O	21 01 32.640	+68 08 38.40						~	1	0
67	2MASS J21013280+6811204	Y*O	21 01 32.80200	+68 11 20.4936						~	7	0
68	[PWK2017] 35	Y*O	21 01 34.320	+68 08 16.80						~	1	0
69	NGC 7023	RNe	21 01 36.9	+68 09 48						~	702	0
70	HD 200775	Ae*	21 01 36.9205762896	+68 09 47.789578836	7.34	7.754	7.427	8.13		B2Ve	557	0
71	JCMTSE J210142.4+681200	cor	21 01 40.810	+68 12 03.60						~	2	0
72	[PWK2017] 51	cor	21 01 51.600	+67 44 06.00						~	1	0
73	[PWK2017] 53	cor	21 01 52.080	+67 43 40.80						~	1	0
74	[PWK2017] 39	cor	21 01 56.390	+68 06 39.60						~	1	0
75	[PWK2017] 33	cor	21 02 00.720	+68 07 12.00						~	1	0
76	[PWK2017] 40	cor	21 02 00.960	+68 13 01.20						~	1	0
77	[PWK2017] 45	cor	21 02 09.120	+68 07 08.40						~	1	0
78	[PWK2017] 28	cor	21 02 11.040	+68 09 54.00						~	1	0
79	[PWK2017] 49	cor	21 02 13.200	+67 54 03.60						~	1	0
80	[PWK2017] 27	cor	21 02 13.920	+68 09 14.40						~	1	0
81	[PWK2017] 52	cor	21 02 14.8	+67 51 09						~	2	0
82	[PWK2017] 50	cor	21 02 20.640	+67 45 36.00						~	1	0
83	IRAS 21017+6742	Y*O	21 02 21.23	+67 54 20.2						~	33	1
84	LDN 1172	DNe	21 02 27.7	+67 54 08						~	57	0
85	[PWK2017] 54	cor	21 02 29.760	+67 53 24.00						~	1	0
86	2MASS J21022993+6754083	Y*O	21 02 29.935	+67 54 08.33						~	4	0
87	[PWK2017] 46	cor	21 02 39.600	+68 11 24.00						~	1	0
88	[PWK2017] 55	cor	21 02 41.280	+67 54 10.80						~	1	0
89	[PWK2017] 37	cor	21 02 48.720	+68 11 45.60						~	1	0
90	[PWK2017] 31	cor	21 03 15.120	+68 11 16.80						~	1	0
91	[PWK2017] 30	cor	21 03 20.160	+68 11 31.20						~	1	0
92	NAME Cepheus Region	reg	21 20 00.0	+72 30 00						~	113	0
93	LDN 1241	DNe	21 50.0	+76 44						~	19	0
94	LDN 1247	DNe	22 21.9	+75 06						~	18	0
95	[PWK2017] 78	cor	22 27 31.440	+75 11 24.00						~	1	0
96	[PWK2017] 85	cor	22 27 31.680	+75 12 07.20						~	1	0
97	[PWK2017] 83	cor	22 27 37.690	+75 12 14.40						~	1	0
98	[PWK2017] 89	cor	22 27 38.870	+75 11 45.60						~	1	0
99	[PWK2017] 66	cor	22 28 15.360	+75 14 38.40						~	1	0
100	[PWK2017] 67	cor	22 28 24.720	+75 14 56.40						~	1	0
101	[PWK2017] 71	cor	22 29 41.520	+75 13 30.00						~	1	0
102	IRAS 22290+7458	Y*O	22 29 59.537	+75 14 04.41						~	25	1
103	NAME LDN 1251 A IRS 3	Y*O	22 30 31.8	+75 14 09						~	19	0
104	LDN 1251A	DNe	22 30 31.8	+75 14 17						~	75	2
105	NAME LDN 1251 A IRS 4	Y*O	22 31 05.6	+75 13 37						~	21	0
106	[PWK2017] 62	cor	22 31 12.480	+75 12 57.60						~	1	0
107	[PWK2017] 63	cor	22 31 22.080	+75 12 28.80						~	1	0
108	IRAS 22331+7502	Y*O	22 34 11.9044831272	+75 18 10.099564812		17.12	15.42	13.80	12.53	K5	16	0
109	2MASS J22344051+7517444	Y*O	22 34 40.5153159264	+75 17 44.407040388						~	6	0
110	[PWK2017] 74	cor	22 35 04.800	+75 13 01.20						~	1	0
111	2MASS J22351668+7518471	Y*O	22 35 16.6780675800	+75 18 47.074335120		17.34	15.89	14.38	13.31	M0	15	0
112	IRAS 22343+7501	Y*O	22 35 24.42480	+75 17 03.7320			22.99	20.22	17.76	~	44	0
113	[PWK2017] 87	cor	22 35 31.440	+75 21 54.00						~	1	0
114	[PWK2017] 70	cor	22 35 34.080	+75 21 18.00						~	1	0
115	[PWK2017] 88	cor	22 35 38.880	+75 21 25.20						~	1	0
116	LDN 1251C	DNe	22 35 40.0	+75 18 06						~	22	1
117	[PWK2017] 86	cor	22 35 42.000	+75 18 54.00						~	1	0
118	[PWK2017] 68	cor	22 35 52.320	+75 18 57.60						~	1	0
119	[PWK2017] 77	cor	22 35 59.760	+75 07 48.00						~	1	0
120	LDN 1251	DNe	22 36.1	+75 16						~	111	0
121	[PWK2017] 79	cor	22 36 07.200	+75 07 58.80						~	1	0
122	[PWK2017] 96	cor	22 36 18.720	+75 22 15.60						~	1	0
123	[PWK2017] 73	cor	22 36 40.800	+75 08 31.20						~	1	0
124	[PWK2017] 81	cor	22 37 00.000	+75 15 21.60						~	1	0
125	[PWK2017] 97	cor	22 37 00.710	+75 08 42.00						~	1	0
126	[PWK2017] 94	cor	22 37 08.880	+75 08 49.20						~	1	0
127	[PWK2017] 95	cor	22 37 34.570	+75 11 34.80						~	1	0
128	[PWK2017] 90	cor	22 37 44.160	+75 09 43.20						~	1	0
129	[PWK2017] 80	cor	22 38 21.600	+75 13 01.20						~	1	0
130	[PWK2017] 92	cor	22 38 44.400	+75 14 02.40						~	1	0
131	LDN 1251B	DNe	22 38 46.79	+75 11 32.6						~	51	1
132	2MASS J22384807+7511488	Y*O	22 38 48.07	+75 11 48.9						~	5	0
133	[PWK2017] 59	cor	22 38 56.160	+75 11 42.00						~	1	0
134	[PWK2017] 58	cor	22 39 04.560	+75 12 00.00						~	1	0
135	[PWK2017] 72	cor	22 39 13.200	+75 10 44.40						~	1	0
136	[PWK2017] 65	cor	22 39 16.080	+75 09 43.20						~	1	0
137	[PWK2017] 93	cor	22 39 17.520	+75 13 44.40						~	1	0
138	LDN 1251E	DNe	22 39 18.3	+75 14 31						~	18	0
139	[PWK2017] 75	cor	22 39 24.240	+75 12 39.60						~	1	0
140	JCMTSE J223931.5+751055	cor	22 39 30.000	+75 10 58.80						~	2	0
141	JCMTSE J223938.4+751206	cor	22 39 38.400	+75 12 03.60						~	2	0
142	NAME Cepheus Flare	MoC	23 34	+72.0						~	128	0
143	V* XX Cep	SB*	23 38 20.2850614704	+64 20 02.699063196		9.47	9.18			A7V	161	0
144	NAME Gould Belt	PoG	~	~						~	873	1
145	NAME Local Bubble	ISM	~	~						~	898	0

To bookmark this query, right click on this link: simbad:objects in 2017MNRAS.464.4255P and select 'bookmark this link' or equivalent in the popup menu