多孔氮化硼掺杂聚吡咯-2,3,3-三甲基吲哚固相微萃取涂层的制备及多环芳烃的检测

doi:10.3724/SP.J.1123.2023.03015

摘要/Abstract

摘要：

多环芳烃(PAHs)是持久性有机污染物中的一种,大部分具有较强的致癌、致畸和致突变性,对生态环境和人类健康易造成严重威胁。由于环境样品基质复杂且其中PAHs含量低,因此在仪器分析之前需要对环境样品进行必要的前处理。萃取材料的特性是决定大部分前处理技术萃取效率的关键。基于此,本文以低成本且富含较多官能团的吡咯(py)、2,3,3-三甲基吲哚(2,3,3-TMe@In)为单体,多孔氮化硼为掺杂物,采用电化学循环伏安法制备出多孔氮化硼掺杂聚吡咯-2,3,3-三甲基吲哚(Ppy/P2,3,3-TMe@In/BN)复合涂层,通过扫描电子显微镜、热稳定性分析、傅里叶红外光谱等手段对Ppy/P2,3,3-TMe@In/BN进行表征,结果表明:该涂层呈现出多孔、多褶皱的枝状结构,该结构有利于增加涂层的比表面积,从而实现对PAHs的大量富集;在320 ℃解吸温度下,涂层材料的色谱基线基本稳定,表明该涂层具有良好的热稳定性。将其修饰在不锈钢丝表面制成固相微萃取涂层,结合气相色谱-氢火焰离子化检测器,对影响萃取和分离萘(NAP)、苊(ANY)、芴(FLU)3种PAHs的条件进行优化,建立了用于以上3种PAHs检测的分析方法。该方法具有检出限低(10.6~14.5 ng/L, S/N=3)、稳定性好、萃取效率高等优势。将该方法应用于2种环境水样中3种PAHs的检测,在水样1中检测到少量的ANY(1.39 μg/L)。通过向2种水样中加入低(1 μg/L)、中(10 μg/L)、高(50 μg/L)3个水平的标准溶液考察了该方法的可靠性,得到了满意的回收率(82.5%~113.9%)。实验结果表明,所建立的分析方法可实现对环境水样中这3种PAHs的有效检测。

关键词: 固相微萃取, 气相色谱, 循环伏安法, 多环芳烃, 环境水样

Abstract:

Most polycyclic aromatic hydrocarbons (PAHs), which are persistent organic pollutants, have strong carcinogenicity, teratogenicity, and mutagenicity, and pose serious threats to the ecological environment and human health. Owing to the complexity of the matrix and low PAH content of environmental samples, separating and enriching PAHs in environmental samples is necessary prior to their detection. Solid-phase microextraction (SPME) technology is commonly used to detect PAHs owing to its advantages of simple operation, online connection with other instruments, low solvent usage, and integrability of sampling separation, enrichment, and desorption. The extraction coating is the core of this technology, and the type and thickness of the coating are important factors affecting the sensitivity and accuracy of the analysis. Common commercial extraction coatings include polydimethylsiloxane and quartz fiber; however, these materials have a number of disadvantages, such as poor thermal stability and high cost. Several methods, including electrochemical, sol-gel, molecular imprinting, and other coating methods, have been developed to prepare SPME coatings. Electrochemical methods have attracted considerable attention because of their simplicity, short duration, and high coating stability. In the development of an electrochemical method, the selection of the conductive polymer is of particular importance. Polypyrroles (Ppy) are easily synthesized and have numerous advantages, such as good conductivity and stable chemical properties. Thus, their use as a substrate material for SPME coatings is beneficial for improving the overall stability of the coating. Copolymerization with other polymers can enhance the adsorption performance of such coatings via synergistic effects. When doped with inorganic materials with high thermal stability, the composite coating can exhibit high temperature resistance.

In this study, a porous boron nitride-doped Ppy-2,3,3-trimethylindole (Ppy/P2,3,3-TMe@In/BN) composite was prepared as a new SPME copolymer coating to detect three PAHs: naphthalene (NAP), acenaphthene (ANY), and fluorene (FLU). Scanning electron microscopy, thermal stability analysis, Fourier transform infrared spectroscopy, and other techniques were used to characterize the Ppy/P2,3,3-TMe@In/BN composite coating. The results showed that the coating featured a large number of porous and wrinkled dendritic structures, which increased the specific surface area of the composite coating and enabled the extensive enrichment of the three PAHs. When the sample inlet temperature of the chromatograph is 320 ℃, the chromatographic baseline of the coating is basically stable. Compared with commercial coatings, the prepared coating had better thermal stability. The coating formed stable intermolecular forces with the three PAHs owing to its numerous carbon-carbon double bonds (C=C), hydrogen bonds, and other structures, thereby achieving excellent enrichment of the target analytes. Compared with Ppy, Ppy/PIn, Ppy/P2,3,3-TMe@In, Ppy/BN, and polydimethylsiloxane (PDMS) coatings, the prepared Ppy/P2,3,3-TMe@In/BN composite coating exhibited better extraction effects for the three PAHs. The Ppy/P2,3,3-TMe@In/BN composite coating was polymerized on the surface of a stainless-steel wire by cyclic voltammetry and combined with gas chromatography-hydrogen flame ionization detection (GC-FID) to optimize the conditions influencing the extraction and separation of the three PAHs, thereby establishing a highly sensitive analytical method for detecting NAP, ANY, and FLU. This method had low limits of detection (LODs) of 10.6-14.5 ng/L (S/N=3) and high stability. The SPME-GC-FID method was used to detect the three PAHs in two environmental water samples, and a small amount of ANY (1.39 μg/L) was detected in one water sample. Satisfactory recoveries (82.5%-113.9%) were obtained when both water samples were spiked with the three PAHs at three levels. The experimental results indicate that the established analytical method can detect the three PAHs in environmental water samples.

Key words: solid-phase microextraction (SPME), gas chromatography (GC), cyclic voltammetry (CV), polycyclic aromatic hydrocarbons (PAHs), environmental water samples

中图分类号:

O658

杜洁, 孙鹏超, 张梦露, 连泽特, 原凤刚, 王刚. 多孔氮化硼掺杂聚吡咯-2,3,3-三甲基吲哚固相微萃取涂层的制备及多环芳烃的检测[J]. 色谱, 2023, 41(9): 789-798.

DU Jie, SUN Pengchao, ZHANG Menglu, LIAN Zete, YUAN Fenggang, WANG Gang. Preparation of porous boron nitride-doped polypyrrole-2,3,3-trimethylindole solid-phase microextraction coating for polycyclic aromatic hydrocarbon detection[J]. Chinese Journal of Chromatography, 2023, 41(9): 789-798.

图/表 12

图 1 (a)py与2,3,3-TMe@In的体积比与(b)BN质量浓度对Ppy/P2,3,3-TMe@In/BN萃取多环芳烃效率的影响(n=3)

Fig. 1 Influence of (a) volume ratio of py and 2,3,3-TMe@In and (b) BN mass concentration on the extraction efficiency of Ppy/P2,3,3-TMe@In/BN fiber for the PAHs (n=3) Common experimental conditions: mass concentration of PAHs, 15 μg/L; extraction temperature, 45 ℃; NaCl mass concentration, 300 g/L; stirring rate, 600 r/min; extraction time, 35 min; desorption time, 5 min; desorption temperature, 280 ℃. py: pyrrole; 2,3,3-TMe@In: 2,3,3-trimethylindole; Ppy/P2,3,3-TMe@In/BN: porous boron nitride-doped Ppy-2,3,3-trimethylindole composite. PAHs: polycyclic aromatic hydrocarbons; NAP: naphthalene; ANY: acenaphthene; FLU: fluorene.

图 2 (a) Ppy、(b) Ppy/P2,3,3-TMe@In和(c) Ppy/ P2,3,3-TMe@In/BN的红外光谱图

Fig. 2 FTIR spectra of (a) Ppy, (b) Ppy/P2,3,3-TMe@In and (c) Ppy/P2,3,3-TMe@In/BN

图 3 Ppy/P2,3,3-TMe@In/BN涂层的热稳定性

Fig. 3 Thermostability of Ppy/P2,3,3- TMe@In/BN coating

图 4 (a)BN、(b)Ppy、(c)Ppy/P2,3,3-TMe@In和(d)Ppy/P2,3,3-TMe@In/BN涂层的SEM图像

Fig. 4 SEM images of (a) BN, (b) Ppy, (c) Ppy/P2,3,3-TMe@In and (d) the coating of Ppy/P2,3,3-TMe@In/BN

图 5 (a)萃取温度、(b)萃取时间、(c)NaCl质量浓度和(d)搅拌速率对Ppy/P2,3,3-TMe@In/BN涂层萃取效率的影响(n=3)

Fig. 5 Influence of (a) extraction temperature, (b) extraction time, (c) mass concentration of NaCl and (d) stirring rate on the extraction efficiency of Ppy/P2,3,3-TMe@In/BN coating (n=3) Other conditions are the same as that in Fig. 1.

图 6 (a)解吸温度和(b)解吸时间对目标物质解吸效果的影响(n=3)

Fig. 6 Influence of (a) desorption temperature and (b) desorption time on desorption efficiency of target analytes (n=3) Other conditions are the same as that in Fig. 1.

图 7 Ppy、Ppy/PIn、Ppy/P2,3,3-TMe@In、Ppy/BN、Ppy/P2,3,3-TMe@In/BN和PDMS对多环芳烃的萃取效率比较(n=3)

Fig. 7 Comparison of the extraction efficiency of the Ppy, Ppy/Pin, Ppy/P2,3,3-TMe@In, Ppy/BN, Ppy/P2,3,3-TMe@In/BN and PDMS for the PAHs (n=3) Other conditions are the same as that in Fig. 1.

表 1 基于Ppy/P2,3,3-TMe@In/BN涂层的SPME-GC-FID法测定多环芳烃的分析参数

Table 1 Analytical parameters for PAHs measured with Ppy/P2,3,3-TMe@In/BN fiber based SPME-GC-FID method

Analyte	LOD/ (ng/L)	Linear range/ (μg/L)	Regression equation	Correlation coefficient	RSDs/%
Analyte	LOD/ (ng/L)	Linear range/ (μg/L)	Regression equation	Correlation coefficient	One fiber (n=5)	Fiber to fiber (n=5)
NAP	10.6	0.05-80	Y=3.43×10⁴X+8.0×10⁵	0.9974	5.41	9.13
ANY	14.5	0.05-80	Y=9.20×10⁴X+1.4×10⁶	0.9968	7.73	12.1
FLU	12.8	0.05-80	Y=7.53×10⁴X+8.1×10⁵	0.9983	6.37	9.94

图 8 萃取效率随使用次数的变化

Fig. 8 Variation of extraction efficiency with the times used Other conditions are the same as that in Fig. 1.

表 2 3种PAHs在环境水样中3个水平下的加标回收率及精密度(n=3)

Table 2 Spiked recoveries and precisions of the three PAHs at three levels in environmental water samples (n=3)

Sample No.	Analyte	Background/ (μg/L)	1 μg/L		10 μg/L		50 μg/L
Sample No.	Analyte	Background/ (μg/L)	Rec./%	RSD/%	Rec./%	RSD/%	Rec./%	RSD/%
1	NAP	ND	85.7	8.2	84.5	7.9	94.0	3.7
	ANY	1.39	88.4	7.5	113.9	6.4	110.0	5.1
	FLU	ND	83.5	7.1	93.6	8.2	101.0	5.3
2	NAP	ND	87.4	6.7	86.1	5.0	96.3	4.9
	ANY	ND	92.8	8.8	100.6	6.9	105.0	2.8
	FLU	ND	82.5	6.9	108.7	8.3	102.0	3.6

图 9 水样1和水样2的色谱图

Fig. 9 Chromatograms of water sample 1 and water sample 2

表 3 本方法与文献报道的水样中PAHs检测方法的比较

Table 3 Comparison of PAHs detection methods in water samples between this method and literature reports

Coating	Method	Analytes	LODs/(ng/L)	Rec./%	RSDs/%	Ref.
ZIF-8	SPME-GC-FID	ANY, FLU	40-230	88.3-105.3	3.1-7.3	[26]
TiO₂NTs/Ti	SPME-HPLC	NAP, FLU	30-50	97.8-111	3.7-8.9	[27]
Ppy/P2,3,3-TMe@In/BN	SPME-GC-FID	NAP, ANY, FLU	10.6-14.5	82.5-113.9	2.8-8.8	this work

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