植物源生物炭材料的制备及其在农药残留领域中的应用进展

doi:10.3724/SP.J.1123.2021.10024

摘要/Abstract

摘要：

随着农药的广泛使用,其已普遍存在于环境中,对人们的身体健康产生巨大影响。因此,环境中农药残留的去除和分析检测对保护人体安全健康至关重要。同时,农药在环境中残留浓度低,需要一种对目标物有较强选择性和富集作用,并对环境影响小的前处理吸附剂。植物源生物炭是由植物源生物质作为碳源衍生得到的材料,其比表面积大、孔容量高、表面官能团可调节,且环境相容性好,其原料植物源生物质的价格低廉、来源广泛并可再生,是一种廉价高效的吸附剂。该文主要综述了近10年来植物源生物炭用于环境中农药残留去除和分析检测前处理的应用进展。其中在农药残留去除方面的应用主要包括降低农药在土壤中的移动性,修复手性农药造成的污染,负载降解农药的细菌及作为化肥的缓释载体。在农药残留分析检测前处理方面,植物源生物炭可用作分散固相萃取、固相微萃取和磁性固相萃取的吸附剂来选择性吸附水果和蔬菜中的有机磷类和三唑类农药,以及水环境中的有机氯类农药。另外,还介绍了植物源生物炭的吸附机理,详细阐述了基于计算模拟如密度泛函理论、分子动力学模拟和巨正则蒙特卡洛模拟的吸附机理研究并讨论了其优势。最后,总结了植物源生物炭在农药去除和农药残留分析检测前处理方面应用的优势,指出了其在农药残留领域应用待解决的问题。

关键词: 制备方法, 农药去除, 残留分析, 理论计算, 植物源生物炭材料, 综述

Abstract:

Pesticides such as insecticides, fungicides, and herbicides play an important role in the global agricultural industry as they reduce the occurrence of crop diseases, kill pests, and remove weeds. On the other hand, these pesticides are a double-edged sword because they have both acute effects and chronic adverse effects on human health. The widespread use of pesticides has led to their persistence in soil, water, and agricultural products, thus posing a serious threat to public health. Therefore, the removal and analysis of pesticides are critical to protecting human safety and health. When removing pesticides from the environment, it is imperative to ensure high removal efficiency while preventing secondary pollution to the environment. Because of the low concentrations of pesticide residue in the environment, complex matrix, and large throughput of pesticide residue analysis, a low-cost fast pre-treatment technique that has strong selectivity and an enrichment effect on the target pesticide residue, with little environmental impact, is required. Plant biomass-derived biochar is obtained from wheat straw, corn cob, rice husk, etc. This material has a large specific surface area, high pore capacity, tunable surface functional groups, and good environmental compatibility, which make it an inexpensive and efficient adsorbent. Hence, there is a need to systematically review the knowledge regarding the application of plant-based biochar on pesticide removal and pesticide residue analysis. This paper reviews the application progress of plant biomass-derived biochar in the above mentioned two areas over the last decade. The pesticide removal applications include reducing the mobility of pesticides in soil, eliminating the pollution caused by chiral pesticides, loading pesticide-degrading bacteria, and releasing fertilizers sustainably when removing pesticide. As mentioned above, plant biomass-derived biochar has a large specific surface area, a high number of functional groups on the surface, and good environmental compatibility. Therefore, it can effectively remove pesticides or their metabolites from the environment without causing any secondary pollution. During pre-treatment, plan biomass-derived biochar is used as an adsorbent for dispersive solid-phase extraction, solid-phase microextraction, and magnetic solid-phase extraction to selectively adsorb organophosphorus and triazole pesticides in fruits and vegetables, as well as organochlorine pesticides in the aquatic environment. This paper also introduces the adsorption mechanism of plant biomass-derived biochar, where studies based on computational simulations such as the density functional theory, molecular dynamics simulation, and giant canonical Monte Carlo simulation are carefully discussed. The benefits of adopting computational simulations are also mentioned. Finally, this paper summarizes the advantages and disadvantages of using plant biomass-derived biochar in pesticide removal and pre-treatment, as well as the future research trends in this area.

Key words: preparation method, pesticide removal, residues analysis, theoretical calculation, plant biomass-derived biochar, review

中图分类号:

O658

张贤钊, 甄大卫, 刘丰茂, 彭庆蓉, 王宗义. 植物源生物炭材料的制备及其在农药残留领域中的应用进展[J]. 色谱, 2022, 40(6): 499-508.

ZHANG Xianzhao, ZHEN Dawei, LIU Fengmao, PENG Qingrong, WANG Zongyi. Progress in preparation of plant biomass-derived biochar and application in pesticide residues field[J]. Chinese Journal of Chromatography, 2022, 40(6): 499-508.

图/表 5

图1 植物源生物质的组成

Fig. 1 Composition of plant biomass

表1 化学活化生物炭材料的性质

Table 1 Properties of biomass-derived biochar by chemical activation

Activator	Physical and chemical properties	Ref.
H₃PO₄	larger surface area and larger portion of mesoporous	[26]
HNO₃	increased the cation exchange capacity and number of carboxylic acid groups	[27]
H₂SO₄	increase the porosity in carbon structure and number of -SO₃H groups	[28]
KOH	higher microporosity and the larger specific surface area	[29]
ZnCl₂	larger specific surface area and mesoporous structure	[30]

图2 生物炭对土壤中农药的吸附与环境修复作用

Fig. 2 Adsorption of pesticides and environmental remediation in soil by biochar a. sorption of four herbicides and a metabolite of indaziflam on a fresh macadamia nut biochar[39]; b. biochar improves soil polluted by chiral pesticides[44]. CK: control check; WBC: woodchip biochar.

图3 用于样品前处理的生物炭材料

Fig. 3 Biochar for sample pre-treatment a. the possible structure revolution of biochar under different modifications for dispersive solid-phase extraction[57]; b. SEM of solid-phase extraction material derived from banana peel[58]; c. SEM of magnetic porous carbon prepared from waste biomass for magnetic solid-phase extraction[59].

图4 农药在生物炭表面的吸附机理

Fig. 4 Mechanism of adsorption of pesticides on the surface of biochar

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