Charting circumstellar chemistry of carbon-rich asymptotic giant branch stars - I. ALMA 3 mm spectral surveys

Open Access

This article has an erratum: [https://doi.org/10.1051/0004-6361/202554249e]

Table B.1

Details of all detected transitions in the ALMA Band 3 survey.

Molecule	Transition	Rest Freq. (GHz)	E_up/k_B (K)	∫ S _uldv (Jy km/s)

				15194	15082	07454
HC₅N	32-31	85.201340	67.5	–	–	2.2(0.1)
C¹³CCCH	N= 9-8, J=19/2-17/2	85.201897	20.4	9.4(0.4)	–	–
C¹³CH	N= 1-0, J=3/2-1/2	85.229326	4.1	bl.	–	–
C¹³CCCH	N= 9-8, J=17/2-15/2	85.239907	20.5	bl.	–	–
C¹³CH	N= 1-0, J=1/2-1/2	85.314378	4.1	bl.	–	–
CC¹³CCH	N= 9-8, J=19/2-17/2	85.331904	20.5	bl.	–	–
c-C₃H₂	2_1,2-1_0,1	85.338894	6.4	19.7(0.5)	2.9(0.2)	0.6(0.1)
CC¹³CCH	N= 9-8, J=17/2-15/2	85.370342	20.5	5.9(0.4)	-	-
C₄H	N = 9-8, J = 19/2-17/2	85.634004	20.5	33.8 (0.4)	5.9(0.2)	0.8(0.1)
C₄H	N = 9-8, J = 17/2-15/2	85.672582	20.6	32.9(0.4)	6.6(0.2)	0.7(0.1)
²⁹SiO	2-1	85.759194	6.2	9.5(0.4)	2.5(0.2)	1.3(0.1)
C₄H, ν₇ = 2⁰	N=9-8, J=19/2-17/2	86.047530	397.6	bl.	-	-
HC¹⁵N	1-0	86.054966	4.1	bl.	-	-
C₄H, ν₇ = 2⁰	N=9-8, J=17/2-15/2	86.105294	397.6	3.0(0.7)	-	-
CCS	76-65	86.181391	23.3	0.8(0.3)	-	0.3(0.1)
H¹³CN	1-0	86.339921	4.1	249.5(0.4)	48.7(0.2)	37.8(0.1)
Si¹³CC	4_1,4-3_1,3	86.562636	12.3	6.0(0.4)	–	–
SiO	2-1	86.846985	6.3	95.7(0.4)	35.8(0.2)	15.3(0.1)
u	-	86.886000	–	1.0(0.3)	–	–
SiN?	N=2-1, J=3/2-1/2	87.049857	6.3	–	–	–
HN¹³C	1-0	87.090825	4.2	13.2(0.4)	–	–
C₄H, ν₇ = 1	J=19/2-17/2,n=3/2, l=e	87.142857	265.5	2.9(0.7)	–	–
C₂H	N=1-0^(a)	87.316898	4.2	264.3(1.0)	58.5(0.6)	7.6(0.2)
	J=63/2-61/2, Ω=3/2, l=e	87.321504	67.9	bl.	bl.	–
	J=63/2-61/2, Ω=3/2, l=f	87.347994	67.9	2.1(0.5)	0.6(0.2)	–
C₄H, ν₇ = 1	J=19/2-17/2,Ω=3/2, l=f	87.371999	265.5	5.0(0.6)	2.0(0.3)	–
c-C₃H₂	5_4,2-5_3,3	87.435318	45.3	bl.	bl.	–
³⁰SiS	5-4	87.550558	12.6	bl.	bl.	bl.
SiN	N=2-1, J=5/2-3/2	87.559811	6.3	bl.	bl.	–
u	–	87.590000	–	1.0(0.3)	–	–
H¹³CC¹³CN	10-9	87.773712	23.2	4.2(0.3)	–	–
H¹³C¹³CCN	10-9	87.841102	23.2	2.9(0.3)	–	–
HC₅N	33-32	87.863630	71.7	4.8(0.2)	6.2(0.1)	2.0(0.1)
C₆H	J=63/2-61/2, Ω=1/2, 1=f	87.921593	90.7	2.5(0.5)	0.6(0.2)	–
C₆H	J=63/2-61/2, Ω=1/2, 1=e	87.967595	90.7	1.7(0.4)	1.1(0.2)	–
HCN, ν₁ = 1?	1-0	88.006690	4768.7	–	–	–
HCN, ν₃ = 1?	1-0	88.027280	3021.1	–	–	–
				15194	15082	07454
H¹³CCCN	10-9	88.166832	23.3	14.9(0.2)	1.8(0.1)	1.3(0.1)
Si³⁴S	5-4	88.285828	12.7	–	0.7(0.1)	0.3(0.1)
C¹³CCN	N=9-8^(a)	88.561247	11.8	9.0(0.4)	–	–
HCN	1-0	88.631602	4.3	324.4(0.2)	224.8(0.1)	81.2(0.1)
CC¹³CN	N=9-8, J=19/2-17/2	88.711791	11.8	4.9(0.2)	–	–
CC¹³CN	N=9-8, J=17/2-15/2	88.730291	11.8	4.5(0.2)	–	–
l-C₄H₂	10_1,10-9_1,9	88.940236	37.0	1.8(0.5)	1.5(0.4)	–
C₃N	9-8 (A)	89.045592	21.4	18.1 (0.2)	10.4 (0.1)	2.0(0.1)
C₃N	9-8 (B)	89.064352	21.4	18.1 (0.2)	10.0(0.1)	1.8(0.1)
HCN, ν₂ = 2	1₀-0₀	89.087690	2035.0	2.5(0.2)	2.9(0.3)	0.7(0.1)
²⁹SiS	5-4	89.103749	12.8	2.5(0.2)	1.7(0.1)	0.4(0.1)
l-C₄H₂	10_3,8-9_3,7	89.289791	145.2	bl.	bl.	–
l-C₄H₂	10_3,7-9_3,6	89.289793	145.2	bl.	bl.	–
¹³CH₃CN	5₄-4₄	89.304386	127.4	bl.	–	–
1-C₄H₂	10_2,9-9_2,8	89.305141	77.6	bl.	bl.	–
1-C₄H₂	10_2,8-9_2,7	89.307563	77.6	bl.	bl.	–
¹³CH₃CN	5₃-4₃	89.316149	77.3	bl.	–	–
¹³CH₃CN	5₂-4₂	89.324555	41.5	bl.	–	–
¹³CH₃CN	5₁-4₁	89.329599	20.0	bl.	–	–
¹³CH₃CN	5₀-4₀	89.331282	12.9	bl.	–	–
l-C₄H₂	10_1,9-9_1,8	89.687047	37.2	bl.	bl.	–
C₆H	J=65/2-63/2, Ω=3/2, l=e	90.093295	72.2	3.5(0.5)	–	–
C₆H	J=65/2-63/2, Ω=3/2, l=f	90.121407	72.2	3.6(0.5)	–	–
HC¹³C¹³CN	10-9	90.204324	23.8	3.3(0.3)	–	–
HC₅N	34-33	90.525890	76.0	3.9(0.2)	5.8(0.1)	1.8(0.1)
³⁰SiC₂	4_0,4-3_0,3	90.562283	10.9	1.2(0.4)	0.9(0.3)	–
HC¹³CCN	10-9	90.593059	23.9	16.4(0.2) (bl.)	2.3(0.4) (bl.)	1.2(0.1)
HCC¹³CN	10-9	90.601777	23.9	16.4(0.2) (bl.)	2.3(0.4) (bl.)	1.3(0.1)
HNC	1-0	90.663568	4.4	74.9(0.2)	36.5(0.1)	6.7(0.1)
CCS	7₇-6₆	90.686381	26.1	1.8(0.4)	2.1(0.4)	–
C₆H	J=65/2-63/2, Ω=1/2, l=f	90.712181	95.0	3.3(0.6)	–	–
C₆H	J=65/2-63/2, Ω=1/2, l=e	90.759297	95.1	bl.	bl.	–
SiS	5-4	90.771564	13.1	44.4(0.2)	22.9(0.1)	9.9(0.1)
Si¹³CC	4_0,4-3_0,3	90.848527	11.0	6.9(0.2)	–	–
	J=155/2-153/2, Ω=3/2bbm	90.924649	171.2	4.0(0.6)	–	–
HC₃N	10-9	90.979023	24.0	75.6(0.5)	56.1(0.3)	24.7(0.1)
¹³CCCCH	N=10-9, J=21/2-19/2	91.875516	24.3	3.6(0.4)	–	-
¹³CCCCH	N=10-9, J=19/2-17/2	91.906057	24.3	3.4(0.4)	–	-
CH₃CN	5-4^(a)	91.979995	41.8	15.4(0.8)	4.0(0.3)	bl.
Si¹³CC	4_2,3-3_2,2	92.064397	18.5	4.3(0.4)	–	–
CCC¹³CH	N=10-9, J=21/2-19/2	92.277460	24.4	4.1(0.4)	–	–
CCC¹³CH	N=10-9, J=19/2-17/2	92.314915	24.4	6.0(0.4)	–	–
Si¹³CC	4_3,2-3_3,1	92.375409	27.9	2.7(0.4)	–	–
Si¹³CC	4_3,1-3_3,0	92.402216	27.9	2.6(0.4)	–	–
¹³CS	2-1	92.494308	6.7	37.2(0.5)	2.9(0.3)	2.1(0.1)
SiC₂	4_0,4-3_0,3	93.063639	11.2	39.7(0.4)	15.0(0.2)	5.5(0.1)
HC₅N	35-34	93.188123	80.5	–	–	1.6(0.1)
Si¹³CC	4_2,2-3_2,1	93.432836	18.6	2.6(0.4)	–	–
C₄H, ν₇ = 1	J=19/2-17/2, Ω=1/2, l=f	93.863370	272.1	bl.	bl.	bl.
CCS	7₈-6₇	93.870107	19.9	bl.	bl.	bl.
SiC₂	4_2,3-3_2,2	94.245393	19.1	26.4(0.4)	2.4(0.2)	3.8(0.1)
C¹³CCCH	N=10-9, J=21/2-19/2	94.670247	25.0	5.4(0.4)	–	–
C¹³CCCH	N=10-9, J=19/2-17/2	94.708239	25.0	4.7(0.4)	–	–
CC¹³CCH	N=10-9, J=21/2-19/2	94.814723	25.0	4.4(0.4)	–	–
CC¹³CCH	N=10-9, J=19/2-17/2	94.853133	25.0	6.4(0.4)	–	–
C₄H	N = 10-9, J = 21/2-19/2	95.150389	25.1	42.7(0.4)	9.3(0.3)	0.9(0.1)
C₄H	N = 10-9, J = 19/2-17/2	95.188949	25.1	43.5(0.4)	7.4(0.3)	1.0(0.1)
SiC₂	4_2,2-3_2,1	95.579381	19.2	22.6(0.4)	12.0(0.3)	4.1(0.1)
C₄H, ν₇ = 2⁰	N=10-9, J=21/2-19/2	95.611500	561.5	2.5(0.8)	–	–
C₄H, ν₇ = 2⁰	N=10-9, J=19/2-17/2	95.667900	561.5	3.2(0.8)	–	–
HC₅N	36-35	95.850335	85.1	–	–	1.5(0.1)
C³⁴S	2-1	96.412950	6.9	13.0(0.4)	6.6(0.2)	3.7(0.1)
C₄H, ν₇ = 1	J=21/2-19/2,Ω=3/2, l=e	96.478780	270.1	2.1(0.7)	–	–
H¹³CC¹³CN?	11-10	96.550615	27.8	-	-	-
C₄H, ν7 = 1	J=21/2-19/2,Ω=3/2, l=f	96.741210	270.2	2.7(0.9)	-	-
H¹³CCCN	11-10	96.983001	27.9	10.3(0.4)	-	1.3(0.1)
C³³S	2-1	97.172064	7.0	2.8(0.5)	-	-
CS, v = 1?	2-1	97.270980	1837.4	-	-	-
Si¹³CC	4_1,3-3_1,2	97.295257	13.6	7.4(0.5)	-	-
CS	2-1	97.980953	7.1	252.5(0.5)	127.7(0.2)	55.6(0.1)
C₃H	J=9/2-7/2, Ω=1/2^(a)	98.012070	12.5	20.9(0.7)	-	1.9(0.1)
C¹³CCN	N=10-9^(a)	98.401860	14.8	17.0(2.3)	-	-
HC₅N	37-36	98.512524	89.8	-	-	1.7(0.1)
CC¹³CN	N=10-9, J=21/2-19/2	98.569079	14.8	3.9(0.5)	-	-
CC¹³CN	N=10-9, J=19/2-17/2	98.587484	14.8	5.2(0.5)	-	-
C₃N	10-9 (A)	98.940005	26.1	16.7 (0.5)	10.5(0.2)	3.2(0.1)
C₃N	10-9 (B)	98.958774	26.1	19.0(0.5)	11.5(0.2)	2.9(0.1)
HC¹³C¹³CN	11-10	99.224259	28.6	3.1(0.4)	-	-
HC¹³CCN	11-10	99.651849	28.7	13.8(0.1) (bl.)	2.4(0.4) (bl.)	1.7(0.1)
HCC¹³CN	11-10	99.661467	28.7	13.8(0.1) (bl.)	2.4(0.4) (bl.)	1.6(0.1)
CCS	87-76	99.866521	28.1	3.1(0.8)	1.3(0.4)	0.5(0.1)
HC₃N	11-10	100.076392	28.8	71.8(0.2)	65.5(0.1)	27.5(0.1)
u	–	100.407000	-	1.1(0.3)	-	-
¹³CCCCH	N=11-10, J=23/2-21/2	101.063060	29.1	6.5(0.2)	-	-
¹³CCCCH	N=11-10, J=21/2-19/2	101.094030	29.1	6.3(0.2)	-	-
HC₅N	38-37	101.174677	94.7	3.2(0.2)	3.6(0.1)	1.4(0.1)
CCC¹³CH	N=11-10, J=23/2-21/2	101.506343	29.2	7.7(0.2)	-	-
CCC¹³CH	N=11-10, J=21/2-19/2	101.543766	29.2	7.9(0.2)	-	-
³⁰SiS, v = 5	6-5	102.548508	5206.0	3.0(0.5)	-	-
C₄H, ν7 = 1	J=21/2-19/2 Ω1/2, l=e	103.266200	277.0	3.1(1.0)	-	-
C₃H	J=9/2-7/2, Ω=3/2^(a)	103.319530	32.9	4.7(0.7)	-	-
C₄H, ν7 = 1	J=21/2-19/2 Ω=1/2, l=f	103.576590	277.1	5.0(1.0)	-	-
CCS	8₈-7₇	103.640759	31.1	3.2(1.0)	-	-
HC₅N	39-38	103.836817	99.7	-	-	1.3(0.1)
C¹³CCCH	N=11-10, J=23/2-21/2	104.138540	30.0	9.8(0.5)	-	-
C¹³CCCH	N=11-10, J=21/2-19/2	104.176220	30.0	8.8(0.5)	-	-
CC¹³CCH	N=11-10, J=23/2-21/2	104.297340	30.0	8.8(0.5)	-	-
CC¹³CCH	N=11-10, J=21/2-19/2	104.335720	30.1	10.3(0.5)	-	-
C₄H	N = 11-10, J = 23/2-21/2	104.666566	30.1	53.7(0.5)	5.6(0.3)	1.3(0.1)
C₄H	N = 11-10, J = 21/2-19/2	104.705110	30.2	55.5(0.5)	10.6(0.3)	1.0(0.1)
³⁰SiS	6-5	105.059203	17.6	-	-	0.5(0.1)
C₄H, ν₇ = 2⁰	N=11-10, J=23/2-21/2	105.174600	566.5	2.6(0.8)	-	-
C₄H, ν₇ = 2⁰	N=11-10, J=21/2-19/2	105.230990	566.5	5.0(0.8)	-	-
H¹³CCCN	12-11	105.799113	33.0	9.0(0.5)	-	1.2(0.1)
C₄H, ν₇ = 1	J=23/2-21/2,Ω=3/2, l=e	105.837997	219.2	4.6(1.2)	-	-
Si³⁴S	6-5	105.941503	17.8	2.2(0.5)	-	0.5(0.1)
C₄H, ν₇ = 1	J=23/2-21/2,Ω=3/2, l=f	106.133368	219.2	3.2(0.9)	-	-
CCS	8₉-7₈	106.347726	25.0	3.0(1.0)	-	0.6(0.2)
HC₅N	40-39	106.498910	104.8	-	-	1.2(0.1)
²⁹SiS	6-5	106.922980	18.0	3.0(0.5)	-	0.8(0.1)
Si¹³CC	5_1,5-4_1,4	107.971477	17.5	6.5(0.5)	-	-
C¹³CCN	N=11-10^(a)	108.242334	18.1	bl.	-	-
HC¹³C¹³CN	12-11	108.244051	33.8	bl.	-	-
SiS, v = 1	6-5	108.394291	1089.3	-	-	-
CC¹³CN	N=11-10, J=23/2-21/2	108.426168	18.1	bl.	-	-
CC¹³CN	N=11-10, J=21/2-19/2	108.444688	18.1	3.1(0.5)	-	-
¹³CN	N= 1-0	108.780201	5.2	bl.	bl.	bl.
HC¹³CCN	12-11	108.710532	33.9	8.8(0.1) (bl.)	-	1.6(0.1)
HCC¹³CN	12-11	108.720999	33.9	8.8(0.1) (bl.)	-	1.4(0.1)
C₃N	11-10 (A)	108.834250	31.3	10.7(0.6)	4.7(0.2)	3.8(0.1)
C₃N	11-10 (B)	108.853005	31.3	16.4(0.6)	6.2(0.2)	3.6(0.1)
SiS	6-5	108.924301	18.3	46.1(0.6)	26.9(0.2)	11.6(0.1)
HC₅N	41-40	109.160973	110.0	bl.	bl.	bl.
HC₃N	12-11	109.173634	34.1	57.8(0.6)	50.1(0.3)	32.5(0.1)
¹³CO	1-0	110.201354	5.3	119.6(1.6)	-	18.4(0.2)
¹³CCCCH	N=12-11, J=25/2-23/2	110.250280	34.4	4.4(0.5)	-	-
¹³CCCCH	N=12-11, J=23/2-21/2	110.281796	34.4	6.2(0.7)	-	-
CH₃CN	6-5^(a)	110.374989	47.1	bl.	bl.	bl.
CCC¹³CH	N=12-11, J=25/2-23/2	110.735027	34.5	5.2(0.6)	-	-
CCC¹³CH	N=12-11, J=23/2-21/2	110.772434	34.6	7.0(0.6)	-	-
HC5N	42-41	111.823024	115.4	-	-	1.2(0.1)
Si¹³CC	5_0,5-4_0,4	112.593212	16.4	8.0(0.6)	-	-
C₄H, ν₇ = 1?	J=23/2-21/2,Ω=1/2, 1=e	112.922950	282.5	-	-	-
C₄H, ν₇ = 1?	J=23/2-21/2Ω=1/2, 1=f	113.266080	282.5	-	-	-
CN	N= 1-0^(a)	113.488120	5.4	179.0(2.0)	188.0(1.0)	256.5(0.4)
C¹³CCCH	N=12-11, J=25/2-23/2	113.606341	35.4	7.4(0.6)	-	-
C¹³CCCH	N=12-11, J=23/2-21/2	113.644283	35.5	6.9(0.6)	-	-
CC¹³CCH	N=12-11, J=25/2-23/2	113.779720	35.5	9.1(0.6)	-	-
CC¹³CCH	N=12-11, J=23/2-21/2	113.818080	35.5	13.1(0.6)	-	-
C₄H	N = 12-11, J = 25/2-23/2	114.182514	35.6	59.2(0.9)	14.9(0.7)	1.6(0.2)
C₄H	N = 12-11, J = 23/2-21/2	114.221044	35.6	66.6(0.9)	17.7(0.7)	2.0(0.2)
H¹³CCCN	13-12	114.614995	38.5	6.8(0.9)	-	1.5(0.2)
CO	1-0	115.271202	5.5	439.2(2.0)^(b)	120.8(1.1)	166.7(0.5)
SiC₂	5_0,5-4_0,4	115.382389	16.8	53.1(0.9)	28.2(0.7)	13.0(0.2)

Notes. All transitions listed are in the ground vibrational state unless otherwise specified. ^(a)Lines with hyperfine components where only the frequency of one of the components has been listed, but the integrated intensity given has been summed over all detected components. ^(b)The extended CO emission in IRAS 15194-5115 is not fully recovered by the observations. The line intensity given is hence underestimated. bl. indicates blends, either between hyperfine components of the same transition, or between different lines. A ‘?’ next to the molecule name indicates a tentative detection. The values in parentheses are the uncertainties obtained from the rms noise.

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