Solid phase extraction triazine herbicide in water with magnetic ionic liquid graphene

doi:10.11894/iwt.2019-0928

Abstract

Abstract:

The magnetic ionic liquid graphene(MILG) was synthesized by microemulsion coprecipitation method and used as the magnetic solid-phase extracts. Quantitative analysis of seven types of triazine herbicides in environmental water samples was investigated by ultra-high-performance liquid chromatography tandem mass spectrometry. Under the neutral solution, the optimal extraction efficiency was obtained when the extracting amount of MILG and adsorption time was 10 mg and 20 min, respectively. The limits of detection of the method ranged from 1.1 ng/L to 2.8 ng/L for 7 types triazine herbicides. The proposed method was applied to the extraction of triazine herbicide in actual water samples, the recovery was between 57.8%-101.2%, and RSD was less than 9.1%.

Key words: ionic liquid, graphene, magnetic solid phase extraction, triazine herbicides

摘要：

采用微乳共沉淀法制备磁性离子液体石墨烯（MILG），将其作为磁性固相萃取吸附剂，结合超高效液相色谱-串联质谱法实现对环境水样中7种三嗪类除草剂的定量分析。通过对影响因素的优化，在中性溶液中采用10 mgMILG作为萃取剂，吸附20 min萃取效果最佳。7种三嗪类除草剂的检出限为1.1~2.8 ng/L，实际水样中加标回收率为57.8%~101.2%，相对标准偏差在9.1%以内。

关键词: 离子液体, 石墨烯, 磁性固相萃取, 三嗪类除草剂

CLC Number:

O657

Xiumin Bao,Zhan'en Zhang,Zichun Shao,Jing Xie,Jie Xu,Youyi Wu,Shiqian Gao. Solid phase extraction triazine herbicide in water with magnetic ionic liquid graphene[J]. Industrial Water Treatment, 2020, 40(11): 106-110.

鲍秀敏,张占恩,邵子纯,解竞,徐劼,吴友谊,高仕谦. 磁性离子液体石墨烯-固相萃取水中三嗪类除草剂[J]. 工业水处理, 2020, 40(11): 106-110.

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URL: https://www.iwt.cn/EN/10.11894/iwt.2019-0928

https://www.iwt.cn/EN/Y2020/V40/I11/106

Figures/Tables 8

References 16

1	Qi Xiaoying , Pu Kanyi , Li Hai , et al. Amphiphilic graphene composites[J]. Angewandte Chemie International Edition, 2010, 49 (49): 9426- 9429. doi: 10.1002/anie.201004497
2	Wang Xiluan , Shi Gaoquan . Introduction to the chemistry of graphene[J]. Physical Chemistry Chemical Physics, 2015, 17 (43): 28484- 28504. doi: 10.1039/C5CP05212B
3	Loh K P , Bao Q , Ang P K , et al. The chemistry of graphene[J]. Journal of Materials Chemistry, 2010, 20 (12): 2277- 2289. doi: 10.1039/b920539j
4	Sharma R , Baik J H , Perera C J , et al. Anomalously large reactivity of single graphene layers and edges toward electron transfer chemistries[J]. Nano Letters, 2010, 10 (2): 398- 405. doi: 10.1021/nl902741x
5	Bai Song , Shen Xiaoping . Graphene-inorganic nanocomposites[J]. RSC Advances, 2012, 2 (1): 64- 98. doi: 10.1039/C1RA00260K
6	Acik M , Chabal Y J . Nature of graphene edges:A review[J]. Japanese Journal of Applied Physics, 2011, 50 (7): 070101- 070117. doi: 10.1143/JJAP.50.070101
7	Georgakilas V , Otyepka M , Bourlinos A B , et al. Functionalization of graphene:Covalent and non-covalent approaches, derivatives and applications[J]. Chemical Reviews, 2012, 112 (11): 6156- 6214. doi: 10.1021/cr3000412
8	Fareghi-Alamdari R , Nadiri N M , Hazarkhani H . Synthesis and characterization of a new hydroxyl functionalized diacidic ionic liquid as catalyst for the preparation of diester plasticizers[J]. Journal of Molecular Liquids, 2017, 227, 153- 160. doi: 10.1016/j.molliq.2016.11.121
9	Venkateswara Rao C , Rout A , Mishra S , et al. Thermophysical properties of neat and radiolytically degraded acidic extractants present in room temperature ionic liquid[J]. Journal of Radioanalytical and Nuclear Chemistry, 2019, 321 (3): 907- 916. doi: 10.1007/s10967-019-06648-w
10	周刚, 罗志刚. 离子液体微乳液合成纳米材料的研究进展[J]. 食品安全质量检测学报, 2013, 4 (5): 1308- 1312. URL
11	Sayah S , Ghamouss F , Santos-Pena J , et al. The intriguing properties of 1-ethyl-3-methylimidazolium bis(fluorosulfonyl) imide ionic liquid[J]. Journal of Solution Chemistry, 2018, 48 (7): 992- 1008. URL
12	Song Xuyan , Li Dan , Li Ran , et al. Ionic liquid modified inorganic nanoparticles for gaseous phenol adsorption[J]. Journal of Wuhan University of Technology Materials Science Edition, 2019, 34 (4): 787- 790. doi: 10.1007/s11595-019-2118-7
13	Kholghi E S , Kowsari E , Chinnappan A , et al. Study of silanized-TiO₂ nanoparticles modification by ionic liquid for white electronic ink applications[J]. Journal of Materials Science:Materials in Electronics, 2019, 30 (12): 11307- 11316. doi: 10.1007/s10854-019-01478-8
14	Zhang Lingyun , Guan Hangmin , Dong Qiang , et al. Synthesis and characterization of NiZnFeO and MnZnFeO nanoparticles by waterin-oil microemulsion[J]. Integrated Ferroelectrics An International Journal, 2014, 154 (1): 103- 109. doi: 10.1080/10584587.2014.904170
15	朱小波.离子液体修饰磁性石墨烯基纳米复合材料的制备与应用研究[D].兰州:西北师范大学, 2015.
16	张丽媛, 姚笛, 李娜, 等. 离子液体均相液液微萃取-高效液相色谱法测定婴儿奶粉中5种三嗪类除草剂[J]. 色谱, 2015, 33 (7): 753- 758. URL

三嗪类除草剂	保留时间/min	母离子m/z	子离子m/z	碰撞能量/eV
西玛通	0.94	198.1	100.2，68.3	27，32
莠去通	1.07	212.1	100.2，170.1	18，28
特丁通	1.31	226.1	69.2，170.1	17，36
草净津	0.97	241.0	68.3，214.0	17，36
西玛津	0.95	202.0	68.4，132.2	20，33
特丁津	1.23	230.0	68.4，174.1	16，35
异戊乙净	1.59	256.0	68.4，186.1	20，41

三嗪类除草剂	保留时间/min	母离子m/z	子离子m/z	碰撞能量/eV
西玛通	0.94	198.1	100.2，68.3	27，32
莠去通	1.07	212.1	100.2，170.1	18，28
特丁通	1.31	226.1	69.2，170.1	17，36
草净津	0.97	241.0	68.3，214.0	17，36
西玛津	0.95	202.0	68.4，132.2	20，33
特丁津	1.23	230.0	68.4，174.1	16，35
异戊乙净	1.59	256.0	68.4，186.1	20，41

三嗪类除草剂	线性范围/（ng·L^-1）	线性回归方程	相关系数r²	检出限/（ng·L^-1）	RSD/%	富集倍数
西玛通	5~1 000	y=2 343.5x+9 566.3	0.999 3	1.5	3.4	694
莠去通	5~1 000	y=4 652.5x-13 631.0	0.999 5	1.8	4.1	855
特丁通	5~1 000	y=11 997.0x-38 751.0	0.999 1	2.1	1.6	895
草净津	5~1 000	y=330.43x+3 694.8	0.998 7	2.8	6.8	491
西玛津	5~1 000	y=170.3x+963.57	0.998 5	2.5	6.2	502
特丁津	5~1 000	y=4 708.2x+6 695.0	0.998 9	1.8	4.8	722
异戊乙净	5~1 000	y=22 852.0x+315 332	0.999 5	1.1	2.4	877

三嗪类除草剂	线性范围/（ng·L^-1）	线性回归方程	相关系数r²	检出限/（ng·L^-1）	RSD/%	富集倍数
西玛通	5~1 000	y=2 343.5x+9 566.3	0.999 3	1.5	3.4	694
莠去通	5~1 000	y=4 652.5x-13 631.0	0.999 5	1.8	4.1	855
特丁通	5~1 000	y=11 997.0x-38 751.0	0.999 1	2.1	1.6	895
草净津	5~1 000	y=330.43x+3 694.8	0.998 7	2.8	6.8	491
西玛津	5~1 000	y=170.3x+963.57	0.998 5	2.5	6.2	502
特丁津	5~1 000	y=4 708.2x+6 695.0	0.998 9	1.8	4.8	722
异戊乙净	5~1 000	y=22 852.0x+315 332	0.999 5	1.1	2.4	877

三嗪类除草剂	加标值/（ng·L^-1）	水样1^#			水样2^#
三嗪类除草剂	加标值/（ng·L^-1）	检出值/（ng·L^-1）	加标回收率/%	RSD/%	检出值/（ng·L^-1）	加标回收率/%	RSD/%
西玛通	20	19.33	87.0	2.9	20.14	88.4	3.6
	100	97.2	88.9	3.6	103.28	89.0	5.8
莠去通	20	19.1	85.0	3.8	18.72	87.5	5.2
	100	89.42	86.9	3.4	97.85	86.7	3.0
特丁通	20	18.5	83.4	3.1	20.62	83.3	2.0
	100	99.1	85.3	3.2	99.47	87.7	3.0
草净津	20	20.43	64.2	9.1	13.27	64.0	6.0
	100	98.13	62.6	6.6	114.73	64.8	6.3
西玛津	20	21.22	61.3	4.5	22.47	59.7	4.9
	100	103.5	63.7	3.7	101.48	57.8	3.9
特丁津	20	17.2	86.9	2.6	19.41	82.2	3.3
	100	93.4	90.0	1.7	103.94	84.2	3.1
异戊乙净	20	18.4	94.8	2.3	20.4	95.0	3.2
	100	87.11	101.2	4.6	93.5	97.4	2.0

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