Simultaneous determination of 46 semi-volatile organic compounds in water by liquid-liquid extraction-gas chromatography-mass spectrometry

doi:10.3724/SP.J.1123.2020.07006

Abstract

Abstract:

Semi-volatile organic compounds (SVOCs) include polycyclic aromatic hydrocarbons (PAHs), phthalic acid esters (PAEs), organochlorine pesticides (OCPs) and nitrobenzenes (NBs). Most of them have carcinogenic, teratogenic, mutagenic and endocrine disrupting effects. Therefore, rapid and accurate determination of SVOCs in water is very important. As the most traditional pretreatment method, liquid-liquid extraction (LLE) has the advantages of wide extraction range, high extraction efficiency, simple operation and lower cost, which is very suitable for the simultaneous extraction of multiclass SVOCs. Dichloromethane has good solubility for most SVOCs, and is slightly soluble in water with low boiling point. It is a good broad-spectrum extractive solvent of organic compounds. But at present, there is no detection standard of SVOCs in water in China. In this study, three factors including nitrogen blowing temperature, pH of water sample and extraction time were optimized. It was aimed to establish a liquid-liquid extraction-gas chromatography-mass spectrometry (GC-MS) method for the simultaneous determination of the 46 SVOCs in water. At first, the effect of nitrogen blowing temperature (30, 35, 40 ℃) was investigated. The results showed that under different nitrogen blowing temperature, the recoveries of the 46 SVOCs were slightly different, but the differences were not significant. Considering the recovery and concentration efficiency, the nitrogen blowing temperature was finally set at 35 ℃. Dichloromethane was selected as the LLE solvent of the SVOCs and its extraction efficiency was investigated. The recoveries of the 46 SVOCs were satisfactory for the determination. Then sample pH (neutral and alkaline condition) was investigated. Most of the SVOCs in this paper have no obvious acid-base property. The extraction effect of water sample under neutral conditions was the best and the most stable, and under alkaline condition, the recovery of each substance was generally low. Finally, extraction time (7, 10, 15 min) was studied. In a certain range, with the increase of extraction time, the recovery also increased, but when the time increased to 15 min, the recovery of some compounds increased or decreased, and the time-consuming was longer, the recovery of most substances could meet the requirements when the extraction time was set to 10 min. The optimized experimental conditions were determined as follows: under neutral conditions, the water sample was extracted by dichloromethane for three times, each extraction time was 10 min, and concentrated at the nitrogen blowing temperature of 35 ℃. GC-MS was used for detection, and internal standard method was used for quantitative analysis. The results showed that the linearity of the method was good in the range of 20-2000 μg/L, the correlation coefficients (r ²) were no less than 0.9916, the limits of detection (LODs, S/N=3) ranged from 0.28 to 16.55 ng/L, and the limits of quantification (LOQs, S/N=10) ranged from 0.92 to 55.16 ng/L. The average recovery was 63.6%-125% at three spiked levels of 0.02, 0.2, 0.4 μg/L, with the relative standard deviations (n=6) ranging from 1.03% to 17.0%. This method was applied for the determination of 27 surface water samples in Jinan section of the Yellow River. The pollutants were mainly PAEs and PAHs, while NBs were not detected, only two kinds of OCPs were detected at some sites. The method is simple, universal, accurate and precise, and has low detection limit. It is suitable for the simultaneous determination of the 46 SVOCs in surface water and groundwater.

Key words: gas chromatography-mass spectrometry (GC-MS), liquid-liquid extraction (LLE), semi-volatile organic compounds (SVOCs)

CLC Number:

O658

LIU Lingling, ZHANG Lijun, DONG Xiliang, CHEN Xiaomei, ZHAO Chuanming. Simultaneous determination of 46 semi-volatile organic compounds in water by liquid-liquid extraction-gas chromatography-mass spectrometry[J]. Chinese Journal of Chromatography, 2021, 39(5): 510-517.

Figures/Tables 4

Table 1 Retention times, quantitative ions and qualitative ions of the 46 semi-volatile organic compounds (SVOCs), five surrogate standards (SSs) and five internal standards (ISs)

No.	Compound	Abbreviation	t_R/ min	Quantitative ion (m/z)	Qualitative ions (m/z)		IS		Type
1	nitrobenzene (硝基苯)	NB	7.93	77	51/123	NAP-d₈		NBs
2	naphthalene (萘)	NAP	9.43	128	129	NAP-d₈		PAHs
3	dimethyl phthalate (邻苯二甲酸二甲酯)	DMP	13.68	163	77	ACE-d₁₀		PAEs
4	acenaphthylene (苊烯)	ACY	13.70	152	151/153	ACE-d₁₀		PAHs
5	acenaphthene (苊)	ACE	14.50	153	152/154	ACE-d₁₀		PAHs
6	2,4-dinitrotoluene (2,4-二硝基甲苯)	2,4-DNT	15.73	165	63/89	ACE-d₁₀		NBs
7	fluorene (芴)	FL	17.27	166	82/163	ACE-d₁₀		PAHs
8	diethyl phthalate (邻苯二甲酸二乙酯)	DEP	17.59	149	177	ACE-d₁₀		PAEs
9	α-benzenehexachloride (α-六六六)	α-BHC	20.99	181	109/183	PHE-d₁₀		OCPs
10	hexachlorobenzene (六氯苯)	HCB	21.40	284	282/286	PHE-d₁₀		OCPs
11	β-benzenehexachloride (β-六六六)	β-BHC	22.75	181	109/183	PHE-d₁₀		OCPs
12	γ-benzenehexachloride (γ-六六六)	γ-BHC	23.09	181	109/183	PHE-d₁₀		OCPs
13	phenanthrene (菲)	PHE	23.58	178	176/179	PHE-d₁₀		PAHs
14	anthracene (蒽)	ANT	23.89	178	176/179	PHE-d₁₀		PAHs
15	δ-benzenehexachloride (δ-六六六)	δ-BHC	24.69	181	109/183	PHE-d₁₀		OCPs
16	heptachlor (七氯)	/	27.60	100	272/274	PHE-d₁₀		OCPs
17	aldrin (艾氏剂)	/	29.72	66	220/263	PHE-d₁₀		OCPs
18	di-n-butyl phthalate (邻苯二甲酸二正丁酯)	D(n)BP	29.76	149	76/150	PHE-d₁₀		PAEs
19	heptachlor epoxide (环氧化七氯)	/	32.31	353	351/355	CHR-d₁₂		OCPs
20	fluoranthene (荧蒽)	FLU	32.40	202	200/203	CHR-d₁₂		PAHs
21	α-chlordane (α-氯丹)	/	33.78	373	375/377	CHR-d₁₂		OCPs
22	pyrene (芘)	PYR	33.94	202	200/203	CHR-d₁₂		PAHs
23	α-endosulfan (α-硫丹)	/	34.47	195	339/341	CHR-d₁₂		OCPs
24	γ-chlordane (γ-氯丹)	/	34.72	375	237/272	CHR-d₁₂		OCPs
25	dieldrin (狄氏剂)	/	36.06	79	263/279	CHR-d₁₂		OCPs
26	p,p'-1,1-dichloro-2,2-bis(4-chorophenyl)ethylene (p,p'-滴滴伊)	p,p'-DDE	36.31	246	176/248	CHR-d₁₂		OCPs
27	endrin (异狄氏剂)	/	37.32	263	81/82	CHR-d₁₂		OCPs
28	β-endosulfan (β-硫丹)	/	37.93	195	207/339	CHR-d₁₂		OCPs
29	p,p'- bis(4-chlorophenyl)-1,1-dichloroethane (p,p'-滴滴滴)	p,p'-DDD	38.81	235	165/237	CHR-d₁₂		OCPs
30	o,p'-dichlorodiphenyltrichloroethane (o,p'-滴滴涕)	o,p'-DDT	38.95	235	165/237	CHR-d₁₂		OCPs
31	endrin aldehyde (异狄氏剂醛)	/	39.13	67	250/345	CHR-d₁₂		OCPs
32	endosulfan sulfate (硫丹硫酸酯)	/	40.55	272	387/422	CHR-d₁₂		OCPs
33	p,p'-dichlorodiphenyltrichloroethane (p,p'-滴滴涕)	p,p'-DDT	41.01	235	165/237	CHR-d₁₂		OCPs
34	benzyl butyl phthalate (邻苯二甲酸丁基苄基酯)	BBP	41.09	149	91/206	CHR-d₁₂		PAEs
35	endrin ketone (异狄氏剂酮)	/	43.16	317	67/147	CHR-d₁₂		OCPs
36	benzo[a]anthracene (苯并[a]蒽)	BaA	43.33	228	226/229	CHR-d₁₂		PAHs
37	chrysene ( $屈艹$ )	CHR	43.61	228	226/229	CHR-d₁₂		PAHs
38	methoxychlor (甲氧滴滴涕)	/	44.61	227	152/228	CHR-d₁₂		OCPs
39	mirex (灭蚁灵)	/	46.25	272	270/274	CHR-d₁₂		OCPs
40	di-n-octyl phthalate (邻苯二甲酸二正辛酯)	D(n)OP	50.88	149	279	PER-d₁₂		PAEs
41	benzo[b]fluoranthene (苯并[b]荧蒽)	BbF	51.07	252	126/250	PER-d₁₂		PAHs
42	benzo[k]fluoranthene (苯并[k]荧蒽)	BkF	51.23	252	126/250	PER-d₁₂		PAHs
43	benzo[a]pyrene (苯并[a]芘)	BaP	53.05	252	250/253	PER-d₁₂		PAHs
44	indeno[1,2,3-cd]pyrene (茚并(1,2,3-cd)芘)	InP	59.80	276	138/274	PER-d₁₂		PAHs
45	dibenzo[a,h]anthracene (二苯并[a,h]蒽)	DahA	60.13	278	139/276	PER-d₁₂		PAHs
46	benzo[g,h,i]perylene (苯并[g,h,i]芘)	BghiP	61.08	276	138/274	PER-d₁₂		PAHs
SS1	nitrobenzene-d₅ (硝基苯-d₅)	NB-d₅	7.90	82	54/128	NAP-d₈		SS
SS2	2-fluorobiphenyl (2-氟联苯)	/	12.07	172	170/171	NAP-d₈		SS
SS3	2,4,5,6-tetrachloro-m-xylene (四氯间二甲苯)	/	18.41	207	242/244	PHE-d₁₀		SS
SS4	p-terphenyl-d₁₄ (4,4'-三联苯-d₁₄)	/	36.25	244	243/245	CHR-d₁₂		SS
No.	Compound	Abbreviation	t_R/ min	Quantitative ion (m/z)	Qualitative ions (m/z)		IS		Type
SS5	decachlorobiphenyl (十氯联苯)	PCB209	54.10	498	178/214	PHE-d₁₀		SS
IS1	naphthalene-d₈ (萘-d₈)	NAP-d₈	9.39	136	108			IS
IS2	acenaphthene-d₁₀(苊-d₁₀)	ACE-d₁₀	14.38	164	160/162			IS
IS3	phenanthrene-d₁₀ (菲-d₁₀)	PHE-d₁₀	23.44	188	160/189			IS
IS4	chrysene-d₁₂ ( $屈艹$ -d₁₂)	CHR-d₁₂	43.45	240	236/241			IS
IS5	perylene-d₁₂(苝-d₁₂)	PER-d₁₂	53.47	264	263/260			IS

Table 1 Retention times, quantitative ions and qualitative ions of the 46 semi-volatile organic compounds (SVOCs), five surrogate standards (SSs) and five internal standards (ISs)

No.	Compound	Abbreviation	t_R/ min	Quantitative ion (m/z)	Qualitative ions (m/z)		IS		Type
1	nitrobenzene (硝基苯)	NB	7.93	77	51/123	NAP-d₈		NBs
2	naphthalene (萘)	NAP	9.43	128	129	NAP-d₈		PAHs
3	dimethyl phthalate (邻苯二甲酸二甲酯)	DMP	13.68	163	77	ACE-d₁₀		PAEs
4	acenaphthylene (苊烯)	ACY	13.70	152	151/153	ACE-d₁₀		PAHs
5	acenaphthene (苊)	ACE	14.50	153	152/154	ACE-d₁₀		PAHs
6	2,4-dinitrotoluene (2,4-二硝基甲苯)	2,4-DNT	15.73	165	63/89	ACE-d₁₀		NBs
7	fluorene (芴)	FL	17.27	166	82/163	ACE-d₁₀		PAHs
8	diethyl phthalate (邻苯二甲酸二乙酯)	DEP	17.59	149	177	ACE-d₁₀		PAEs
9	α-benzenehexachloride (α-六六六)	α-BHC	20.99	181	109/183	PHE-d₁₀		OCPs
10	hexachlorobenzene (六氯苯)	HCB	21.40	284	282/286	PHE-d₁₀		OCPs
11	β-benzenehexachloride (β-六六六)	β-BHC	22.75	181	109/183	PHE-d₁₀		OCPs
12	γ-benzenehexachloride (γ-六六六)	γ-BHC	23.09	181	109/183	PHE-d₁₀		OCPs
13	phenanthrene (菲)	PHE	23.58	178	176/179	PHE-d₁₀		PAHs
14	anthracene (蒽)	ANT	23.89	178	176/179	PHE-d₁₀		PAHs
15	δ-benzenehexachloride (δ-六六六)	δ-BHC	24.69	181	109/183	PHE-d₁₀		OCPs
16	heptachlor (七氯)	/	27.60	100	272/274	PHE-d₁₀		OCPs
17	aldrin (艾氏剂)	/	29.72	66	220/263	PHE-d₁₀		OCPs
18	di-n-butyl phthalate (邻苯二甲酸二正丁酯)	D(n)BP	29.76	149	76/150	PHE-d₁₀		PAEs
19	heptachlor epoxide (环氧化七氯)	/	32.31	353	351/355	CHR-d₁₂		OCPs
20	fluoranthene (荧蒽)	FLU	32.40	202	200/203	CHR-d₁₂		PAHs
21	α-chlordane (α-氯丹)	/	33.78	373	375/377	CHR-d₁₂		OCPs
22	pyrene (芘)	PYR	33.94	202	200/203	CHR-d₁₂		PAHs
23	α-endosulfan (α-硫丹)	/	34.47	195	339/341	CHR-d₁₂		OCPs
24	γ-chlordane (γ-氯丹)	/	34.72	375	237/272	CHR-d₁₂		OCPs
25	dieldrin (狄氏剂)	/	36.06	79	263/279	CHR-d₁₂		OCPs
26	p,p'-1,1-dichloro-2,2-bis(4-chorophenyl)ethylene (p,p'-滴滴伊)	p,p'-DDE	36.31	246	176/248	CHR-d₁₂		OCPs
27	endrin (异狄氏剂)	/	37.32	263	81/82	CHR-d₁₂		OCPs
28	β-endosulfan (β-硫丹)	/	37.93	195	207/339	CHR-d₁₂		OCPs
29	p,p'- bis(4-chlorophenyl)-1,1-dichloroethane (p,p'-滴滴滴)	p,p'-DDD	38.81	235	165/237	CHR-d₁₂		OCPs
30	o,p'-dichlorodiphenyltrichloroethane (o,p'-滴滴涕)	o,p'-DDT	38.95	235	165/237	CHR-d₁₂		OCPs
31	endrin aldehyde (异狄氏剂醛)	/	39.13	67	250/345	CHR-d₁₂		OCPs
32	endosulfan sulfate (硫丹硫酸酯)	/	40.55	272	387/422	CHR-d₁₂		OCPs
33	p,p'-dichlorodiphenyltrichloroethane (p,p'-滴滴涕)	p,p'-DDT	41.01	235	165/237	CHR-d₁₂		OCPs
34	benzyl butyl phthalate (邻苯二甲酸丁基苄基酯)	BBP	41.09	149	91/206	CHR-d₁₂		PAEs
35	endrin ketone (异狄氏剂酮)	/	43.16	317	67/147	CHR-d₁₂		OCPs
36	benzo[a]anthracene (苯并[a]蒽)	BaA	43.33	228	226/229	CHR-d₁₂		PAHs
37	chrysene ( $屈艹$ )	CHR	43.61	228	226/229	CHR-d₁₂		PAHs
38	methoxychlor (甲氧滴滴涕)	/	44.61	227	152/228	CHR-d₁₂		OCPs
39	mirex (灭蚁灵)	/	46.25	272	270/274	CHR-d₁₂		OCPs
40	di-n-octyl phthalate (邻苯二甲酸二正辛酯)	D(n)OP	50.88	149	279	PER-d₁₂		PAEs
41	benzo[b]fluoranthene (苯并[b]荧蒽)	BbF	51.07	252	126/250	PER-d₁₂		PAHs
42	benzo[k]fluoranthene (苯并[k]荧蒽)	BkF	51.23	252	126/250	PER-d₁₂		PAHs
43	benzo[a]pyrene (苯并[a]芘)	BaP	53.05	252	250/253	PER-d₁₂		PAHs
44	indeno[1,2,3-cd]pyrene (茚并(1,2,3-cd)芘)	InP	59.80	276	138/274	PER-d₁₂		PAHs
45	dibenzo[a,h]anthracene (二苯并[a,h]蒽)	DahA	60.13	278	139/276	PER-d₁₂		PAHs
46	benzo[g,h,i]perylene (苯并[g,h,i]芘)	BghiP	61.08	276	138/274	PER-d₁₂		PAHs
SS1	nitrobenzene-d₅ (硝基苯-d₅)	NB-d₅	7.90	82	54/128	NAP-d₈		SS
SS2	2-fluorobiphenyl (2-氟联苯)	/	12.07	172	170/171	NAP-d₈		SS
SS3	2,4,5,6-tetrachloro-m-xylene (四氯间二甲苯)	/	18.41	207	242/244	PHE-d₁₀		SS
SS4	p-terphenyl-d₁₄ (4,4'-三联苯-d₁₄)	/	36.25	244	243/245	CHR-d₁₂		SS
No.	Compound	Abbreviation	t_R/ min	Quantitative ion (m/z)	Qualitative ions (m/z)		IS		Type
SS5	decachlorobiphenyl (十氯联苯)	PCB209	54.10	498	178/214	PHE-d₁₀		SS
IS1	naphthalene-d₈ (萘-d₈)	NAP-d₈	9.39	136	108			IS
IS2	acenaphthene-d₁₀(苊-d₁₀)	ACE-d₁₀	14.38	164	160/162			IS
IS3	phenanthrene-d₁₀ (菲-d₁₀)	PHE-d₁₀	23.44	188	160/189			IS
IS4	chrysene-d₁₂ ( $屈艹$ -d₁₂)	CHR-d₁₂	43.45	240	236/241			IS
IS5	perylene-d₁₂(苝-d₁₂)	PER-d₁₂	53.47	264	263/260			IS

Fig. 1 TIC of the 46 SVOCs (2000 μg/L), five SSs (2000 μg/L) and five ISs (800 μg/L) Nos. 1-46, SS1-SS5 and IS1-IS5 were the same as those in Table 1

Fig. 2 Effect of different extraction times on the recoveries of the 46 SVOCs (n=3) Nos. 1-46 were the same as those in Table 1.

Table 2 Linear equations, correlation coefficients (r2), LODs, LOQs, spiked recoveries and RSDs of the 46 SVOCs and five SSs

Compound	r²	Linear equation	LOD/ (ng/L)	LOQ/ (ng/L)	0.02 μg/L		0.2 μg/L		0.4 μg/L
Compound	r²	Linear equation	LOD/ (ng/L)	LOQ/ (ng/L)	Recovery/%	RSD/%	Recovery/%	RSD/%	Recovery/%	RSD/%
NB	0.9968	y=0.1478x	1.18	3.92	92.6	2.19	96.7	13.1	97.3	8.83
NAP	0.9997	y=0.8037x	0.36	1.20	93.1	2.79	95.1	14.0	103	6.58
DMP	0.9988	y=0.8904x	0.32	1.05	105	7.03	109	14.7	106	7.99
ACY	0.9995	y=1.5014x	0.28	0.92	89.0	1.03	88.4	12.5	80.7	4.85
ACE	0.9993	y=1.0285x	0.35	1.17	91.5	2.58	91.1	12.9	100	7.36
2,4-DNT	0.9921	y=0.1181x	4.55	15.17	112	7.09	113	12.4	115	5.05
FL	0.9987	y=1.2091x	0.72	2.41	99.3	2.56	96.5	7.67	107	5.71
DEP	0.9979	y=0.8836x	0.99	3.29	111	3.05	116	10.1	113	4.48
α-BHC	0.9986	y=0.0931x	2.39	7.98	101	2.59	107	14.5	110	2.53
HCB	0.9998	y=0.2157x	1.09	3.65	96.3	3.62	96.2	10.2	103	3.92
β-BHC	0.9976	y=0.0705x	2.74	9.14	125	4.41	122	5.30	117	3.70
γ-BHC	0.9979	y=0.0757x	2.82	9.41	113	2.96	108	7.44	107	8.26
PHE	0.9996	y=0.8830x	0.49	1.63	111	3.84	110	9.14	110	5.09
ANT	0.9987	y=0.8224x	0.52	1.72	97.4	5.21	72.9	1.23	78.0	3.08
δ-BHC	0.9980	y=0.0721x	2.99	9.98	101	4.62	99.9	6.09	101	4.09
Heptachlor	0.9957	y=0.0516x	4.23	14.11	115	3.87	108	4.77	109	4.51
Aldrin	0.9990	y=0.0721x	0.70	2.32	118	1.46	114	8.67	114	3.78
D(n)BP	0.9933	y=0.7073x	2.09	6.97	99.5	9.19	97.4	8.70	110	3.81
Heptachlor epoxide	0.9965	y=0.0757x	3.08	10.26	103	6.24	104	8.51	106	3.10
FLU	0.9986	y=0.9876x	0.45	1.50	107	3.50	105	4.91	105	1.76
α-Chlordane	0.9976	y=0.1282x	1.78	5.94	102	5.78	102	6.69	100	3.25
PYR	0.9986	y=1.0056x	0.44	1.46	114	3.06	107	3.81	105	2.16
α-Endosulfan	0.9993	y=0.0213x	8.38	27.94	102	4.86	103	6.25	102	3.71
γ-Chlordane	0.9995	y=0.1028x	3.22	10.74	100	5.33	100	6.26	97.2	4.45
Dieldrin	0.9990	y=0.0806x	3.53	11.78	104	2.93	105	2.93	107	3.70
p,p'-DDE	0.9997	y=0.2042x	1.22	4.08	101	4.33	101	4.45	102	3.36
Endrin	0.9978	y=0.0123x	16.55	55.16	112	12.8	115	13.4	110	3.19
β-Endosulfan	0.9972	y=0.0231x	9.70	32.33	110	6.49	111	5.92	107	4.54
p,p'-DDD	0.9969	y=0.2911x	0.83	2.77	111	5.55	115	5.77	108	4.75
o,p'-DDT	0.9936	y=0.1616x	1.53	5.09	90.7	9.16	102	9.25	106	3.43
Endrin aldehyde	0.9988	y=0.0491x	4.91	16.35	87.7	6.75	78.3	8.40	82.4	5.43
Endosulfan sulfate	0.9968	y=0.0456x	4.01	13.36	116	4.99	114	6.76	114	3.79
p,p'-DDT	0.9938	y=0.1278x	1.56	5.19	97.1	9.88	107	8.66	108	3.91
BBP	0.9923	y=0.1936x	1.39	4.62	105	16.2	113	17.0	109	2.57
Endrin ketone	0.9964	y=0.0393x	6.02	20.07	114	5.17	116	5.44	108	3.77
BaA	0.9992	y=0.8580x	0.45	1.49	115	1.67	109	2.09	106	2.60
CHR	0.9998	y=0.5762x	0.64	2.12	116	4.75	112	1.52	106	3.36
Methoxychlor	0.9916	y=0.2006x	1.70	5.68	77.7	6.06	88.2	4.22	90.1	3.07
Mirex	0.9983	y=0.1595x	1.43	4.75	108	3.59	107	3.22	105	1.93
D(n)OP	0.9944	y=0.4437x	1.19	3.95	97.1	12.7	106	9.99	105	2.46
BbF	0.9986	y=0.9327x	0.43	1.43	71.3	5.50	76.2	5.87	77.1	2.23
BkF	0.9991	y=0.9372x	0.44	1.46	72.2	1.87	72.6	2.32	73.3	6.86
BaP	0.9991	y=0.8403x	0.47	1.58	87.6	5.41	71.1	11.6	81.2	6.69
InP	0.9947	y=0.8127x	0.51	1.70	63.6	6.10	71.0	6.92	84.2	2.77
DahA	0.9938	y=0.2950x	1.36	4.52	67.1	8.09	81.0	3.11	84.9	2.45
BghiP	0.9985	y=0.8231x	0.51	1.69	66.2	6.99	73.3	4.21	77.1	2.58
SS1	0.9974	y=0.1522x	/	/	93.4	2.61	101	10.6	101	8.84
SS2	0.9998	y=0.6873x	/	/	92.3	3.85	97.1	13.6	95.3	9.28
SS3	0.9921	y=0.1181x	/	/	89.6	4.24	96.9	17.0	98.1	4.92
SS4	0.9996	y=0.1550x	/	/	109	2.56	109	3.14	111	3.09
SS5	0.9995	y=0.1566x	/	/	76.9	5.91	76.2	4.98	76.3	5.97

Table 2 Linear equations, correlation coefficients (r2), LODs, LOQs, spiked recoveries and RSDs of the 46 SVOCs and five SSs

Compound	r²	Linear equation	LOD/ (ng/L)	LOQ/ (ng/L)	0.02 μg/L		0.2 μg/L		0.4 μg/L
Compound	r²	Linear equation	LOD/ (ng/L)	LOQ/ (ng/L)	Recovery/%	RSD/%	Recovery/%	RSD/%	Recovery/%	RSD/%
NB	0.9968	y=0.1478x	1.18	3.92	92.6	2.19	96.7	13.1	97.3	8.83
NAP	0.9997	y=0.8037x	0.36	1.20	93.1	2.79	95.1	14.0	103	6.58
DMP	0.9988	y=0.8904x	0.32	1.05	105	7.03	109	14.7	106	7.99
ACY	0.9995	y=1.5014x	0.28	0.92	89.0	1.03	88.4	12.5	80.7	4.85
ACE	0.9993	y=1.0285x	0.35	1.17	91.5	2.58	91.1	12.9	100	7.36
2,4-DNT	0.9921	y=0.1181x	4.55	15.17	112	7.09	113	12.4	115	5.05
FL	0.9987	y=1.2091x	0.72	2.41	99.3	2.56	96.5	7.67	107	5.71
DEP	0.9979	y=0.8836x	0.99	3.29	111	3.05	116	10.1	113	4.48
α-BHC	0.9986	y=0.0931x	2.39	7.98	101	2.59	107	14.5	110	2.53
HCB	0.9998	y=0.2157x	1.09	3.65	96.3	3.62	96.2	10.2	103	3.92
β-BHC	0.9976	y=0.0705x	2.74	9.14	125	4.41	122	5.30	117	3.70
γ-BHC	0.9979	y=0.0757x	2.82	9.41	113	2.96	108	7.44	107	8.26
PHE	0.9996	y=0.8830x	0.49	1.63	111	3.84	110	9.14	110	5.09
ANT	0.9987	y=0.8224x	0.52	1.72	97.4	5.21	72.9	1.23	78.0	3.08
δ-BHC	0.9980	y=0.0721x	2.99	9.98	101	4.62	99.9	6.09	101	4.09
Heptachlor	0.9957	y=0.0516x	4.23	14.11	115	3.87	108	4.77	109	4.51
Aldrin	0.9990	y=0.0721x	0.70	2.32	118	1.46	114	8.67	114	3.78
D(n)BP	0.9933	y=0.7073x	2.09	6.97	99.5	9.19	97.4	8.70	110	3.81
Heptachlor epoxide	0.9965	y=0.0757x	3.08	10.26	103	6.24	104	8.51	106	3.10
FLU	0.9986	y=0.9876x	0.45	1.50	107	3.50	105	4.91	105	1.76
α-Chlordane	0.9976	y=0.1282x	1.78	5.94	102	5.78	102	6.69	100	3.25
PYR	0.9986	y=1.0056x	0.44	1.46	114	3.06	107	3.81	105	2.16
α-Endosulfan	0.9993	y=0.0213x	8.38	27.94	102	4.86	103	6.25	102	3.71
γ-Chlordane	0.9995	y=0.1028x	3.22	10.74	100	5.33	100	6.26	97.2	4.45
Dieldrin	0.9990	y=0.0806x	3.53	11.78	104	2.93	105	2.93	107	3.70
p,p'-DDE	0.9997	y=0.2042x	1.22	4.08	101	4.33	101	4.45	102	3.36
Endrin	0.9978	y=0.0123x	16.55	55.16	112	12.8	115	13.4	110	3.19
β-Endosulfan	0.9972	y=0.0231x	9.70	32.33	110	6.49	111	5.92	107	4.54
p,p'-DDD	0.9969	y=0.2911x	0.83	2.77	111	5.55	115	5.77	108	4.75
o,p'-DDT	0.9936	y=0.1616x	1.53	5.09	90.7	9.16	102	9.25	106	3.43
Endrin aldehyde	0.9988	y=0.0491x	4.91	16.35	87.7	6.75	78.3	8.40	82.4	5.43
Endosulfan sulfate	0.9968	y=0.0456x	4.01	13.36	116	4.99	114	6.76	114	3.79
p,p'-DDT	0.9938	y=0.1278x	1.56	5.19	97.1	9.88	107	8.66	108	3.91
BBP	0.9923	y=0.1936x	1.39	4.62	105	16.2	113	17.0	109	2.57
Endrin ketone	0.9964	y=0.0393x	6.02	20.07	114	5.17	116	5.44	108	3.77
BaA	0.9992	y=0.8580x	0.45	1.49	115	1.67	109	2.09	106	2.60
CHR	0.9998	y=0.5762x	0.64	2.12	116	4.75	112	1.52	106	3.36
Methoxychlor	0.9916	y=0.2006x	1.70	5.68	77.7	6.06	88.2	4.22	90.1	3.07
Mirex	0.9983	y=0.1595x	1.43	4.75	108	3.59	107	3.22	105	1.93
D(n)OP	0.9944	y=0.4437x	1.19	3.95	97.1	12.7	106	9.99	105	2.46
BbF	0.9986	y=0.9327x	0.43	1.43	71.3	5.50	76.2	5.87	77.1	2.23
BkF	0.9991	y=0.9372x	0.44	1.46	72.2	1.87	72.6	2.32	73.3	6.86
BaP	0.9991	y=0.8403x	0.47	1.58	87.6	5.41	71.1	11.6	81.2	6.69
InP	0.9947	y=0.8127x	0.51	1.70	63.6	6.10	71.0	6.92	84.2	2.77
DahA	0.9938	y=0.2950x	1.36	4.52	67.1	8.09	81.0	3.11	84.9	2.45
BghiP	0.9985	y=0.8231x	0.51	1.69	66.2	6.99	73.3	4.21	77.1	2.58
SS1	0.9974	y=0.1522x	/	/	93.4	2.61	101	10.6	101	8.84
SS2	0.9998	y=0.6873x	/	/	92.3	3.85	97.1	13.6	95.3	9.28
SS3	0.9921	y=0.1181x	/	/	89.6	4.24	96.9	17.0	98.1	4.92
SS4	0.9996	y=0.1550x	/	/	109	2.56	109	3.14	111	3.09
SS5	0.9995	y=0.1566x	/	/	76.9	5.91	76.2	4.98	76.3	5.97

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