石油污染土壤中二苯并呋喃的热脱附特征与转化机制

摘要/Abstract

摘要： 研究了石油污染土壤中二苯并呋喃的热脱附去除特征及其物理脱附与化学转化机制。结果表明：加热300 ℃修复后土壤残留二苯并呋喃质量分数在24.46 μg/g以下，低于河北省及广东省地方标准一类建设用地风险筛选值；基础型、复合型、修正型3种指数衰减模型比一级/二级动力学模型更适合探究污染土壤中二苯并呋喃加热条件下的物理脱附行为；基于Criado和Coats-Redfern模型分析，适合揭示二苯并呋喃化学转化行为的首选模型分别是幂函数模型P2（初期）、收缩面模型R2（中期）以及收缩面模型R2、收缩模型R1和收缩体模型R3（后期）；在收缩模型R1阶段二苯并呋喃分子发生有效碰撞的频率显著高于其他模型阶段；热解初期需要的反应活化能最高，远高于热解中后期。

关键词: 石油污染土壤, 二苯并呋喃, 热脱附, 脱附机制, 化学转化机制

Abstract: This study investigated the removal characteristics of dibenzofuran and its mechanisms of physical desorption and chemical conversion during the thermal desorption of oil-contaminated soil. The results demonstrated that after remediation at 300 °C, the residual mass fraction of dibenzofuran in the soil was below 24.46 μg/g, which is lower than the risk screening values for Class I construction land as stipulated by the local standards of Hebei and Guangdong provinces. Among the kinetic models, three types of exponential decay models (basic, composite, and modified) were found to be more suitable for exploring the physical desorption behavior of dibenzofuran under heating conditions than first/second-order kinetic models. Analysis based on the Criado and Coats-Redfern models revealed that the most appropriate models for describing the chemical transformation behavior of dibenzofuran were the power function model P2 (initial stage), the contracting surface model R2 (middle stage), and the contracting surface model R2, contracting model R1, and contracting volume model R3 (late stage). The frequency of effective molecular collisions of dibenzofuran was significantly higher during the Contracting model R1 stage than in other model stages. Furthermore, the initial pyrolysis stage required the highest activation energy, substantially greater than that required in the middle and late stages.

Key words: petroleum-contaminated soil, dibenzofuran, thermal desorption, desorption mechanism, chemical conversion mechanism

刘畅杜天睿桑义敏何燎孙佳培周冰雨王清玥籍龙杰. 石油污染土壤中二苯并呋喃的热脱附特征与转化机制[J]. 石油炼制与化工, 2026, 57(3): 84-93.

参考文献

[1] KOBETI?OVá Klára, ?IMEK Zdeněk, BREZOVSKY Jan, et al. Toxic effects of nine polycyclic aromatic compounds on Enchytraeus crypticus in artificial soil in relation to their properties [J]. Ecotoxicology and Environmental Safety, 2011, 74(6): 1727-1733. [2] STOUT Scott Alan, EMSBO-MATTINGLY Stephen, DOUGLAS Gregory S, et al. Beyond 16 priority pollutant PAHs: A review of PACs used in environmental forensic chemistry [J]. Polycyclic Aromatic Compounds, 2015, 35(2-4): 285-315. [3] 张利文, 李美俊, 杨福林. 二苯并呋喃地球化学研究进展及作为油藏充注示踪标志物的化学机理[J]. 石油与天然气地质, 2012, 33(04): 633-9. [4] MOGASHANE Tumelo Monty, MOKOENA Lebohang, TSHILONGO James. A review on recent developments in the extraction and identification of polycyclic aromatic hydrocarbons from environmental samples [J]. Water, 2024, 16(17): 2520. [5] PATEL Avani Bharatkumar, SHAIKH Shabnam, JAIN Kunal R, et al. Polycyclic aromatic hydrocarbons: sources, toxicity, and remediation approaches [J]. Frontiers in Microbiology, 2020, 11: 562813. [6] ANYAHARA Jessica Nene. Effects of Polycyclic Aromatic Hydrocarbons (PAHs) on the environment: A systematic review [J]. International Journal of Advanced Academic Research, 2021, 7(3): 12-26. [7] GUPTA Amit Kumar, ROY Souradeep, NAGABOOSHANAM Shalini, et al. Label-free electrochemical detection of dibenzofuran using MnO? nanofibers [J]. IEEE Sensors Journal, 2020, 20(21): 12537-12542. [8] WANG Xudi, WU Yanan, FU Changai, et al. Metabolic cross-feeding between the competent degrader Rhodococcus sp. strain p52 and an incompetent partner during catabolism of dibenzofuran: Understanding the leading and supporting roles [J]. Journal of Hazardous Materials, 2024, 471: 134310. [9] LI Qinggang, WANG Xiaoyu, YIN Guangbo, et al. New metabolites in dibenzofuran cometabolic degradation by a biphenyl-cultivated Pseudomonas putida strain B6-2 [J]. Environmental Science Technology, 2009, 43(22): 8635-8642. [10] 刘欣. 二苯并呋喃微生物降解的分子机理研究 [D]. 上海交通大学, 2018. [11] HE Liao, SANG Yimin, YU Wang, et al. Sustainable remediation of dibenzofuran-contaminated soil by low-temperature thermal desorption: Robust decontamination and carbon neutralization [J]. Chemosphere, 2022, 302: 134810. [12] FERNáNDEZ Israel. Understanding the reactivity of polycyclic aromatic hydrocarbons and related compounds [J]. Chemical Science, 2020, 11(15): 3769-3779. [13] 黄涛, 骆文轩, 徐成华, 等. PAHs 污染土壤热脱附过程关键影响因素及脱附动力学研究 [J]. 土壤, 2024, 56(1): 143-154. [14] BE?IANU Camelia Smaranda, COZMA Petronela, RO?CA Mihaela, et al. Sorption of organic pollutants onto soils: surface diffusion mechanism of Congo red azo dye [J]. Processes, 2020, 8(12): 1639. [15] WANG Jianlong, GUO Xuan. Rethinking of the intraparticle diffusion adsorption kinetics model: Interpretation, solving methods and applications [J]. Chemosphere, 2022, 309: 136732. [16] DUBDUB Ibrahim, AL-YAARI Mohammed. Pyrolysis of mixed plastic waste: I. kinetic study [J]. Materials, 2020, 13(21): 4912. [17] RENOLDI F, LIETTI Luca, SAPONARO Sabrina, et al. Thermal desorption of a PAH-contaminated soil: a case study [J]. WIT Transactions on Ecology and the Environment, 2003, 64: 1123-1132. [18] LIU Chenfeng, SHI Huading, WANG Chen, et al. Thermal remediation of soil contaminated with polycyclic aromatic hydrocarbons: pollutant removal process and influence on soil functionality [J]. Toxics, 2022, 10(8): 474. [19] FALCIGLIA P P, GIUSTRA M G, VAGLIASINDI F G A. Low-temperature thermal desorption of diesel polluted soil: Influence of temperature and soil texture on contaminant removal kinetics [J]. Journal of Hazardous Materials, 2011, 185(1): 392-400. [20] ALHULAYBI Zaid, DUBDUB Ibrahim, AL-YAARI Mohammed, et al. Pyrolysis kinetic study of polylactic acid [J]. Polymers, 2022, 15(1): 12. [21] COATS A W, REDFERN J P. Kinetic parameters from thermogravimetric data [J]. Nature, 1964, 201(4914): 68-69. [22] CRIADO J M. Kinetic analysis of DTG data from master curves [J]. Thermochimica Acta, 1978, 24(1): 186-189. [23] NAWAZ Ahmad, KUMAR Pradeep. Pyrolysis behavior of low value biomass (Sesbania bispinosa) to elucidate its bioenergy potential: Kinetic, thermodynamic and prediction modelling using artificial neural network [J]. Renewable Energy, 2022, 200: 257-270. [24] 黄震, 冯冰冰, 张欣然, 等. 热分解动力学分析及计算模型的研究综述 [J]. 中国印刷与包装研究, 2014, 6(06): 4-17. [25] GUILLOTEAU Angélique, BEDJANIAN Yuri, NGUYEN Mai Lan, et al. Desorption of polycyclic aromatic hydrocarbons from a soot surface: three- to five-ring PAHs [J]. The Journal of Physical Chemistry A, 2010, 114(2): 942-948. [26] FALCIGLIA Pietro P, GUIDI Guido De, CATALFO Alfio, et al. Remediation of soils contaminated with PAHs and nitro-PAHs using microwave irradiation [J]. Chemical Engineering Journal, 2016, 296: 162-172. [27] MALLARD Isabelle, ST?DE Lars Wagner, RUELLAN Steven, et al. Synthesis, characterization and sorption capacities toward organic pollutants of new β-cyclodextrin modified zeolite derivatives [J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2015, 482: 50-57. [28] XIE Wei, GAO Zongming, LIU Kunlei, et al. Thermal characterization of organically modified montmorillonite [J]. Thermochimica Acta, 2001, 367: 339-350. [29] WANG Mei, KONG Deyang, LIU Lang, et al. In situ conductive heating for thermal desorption of volatile organic-contaminated soil based on solar energy [J]. Sustainability, 2024, 16(19): 8565. [30] LEE Yonghyeon, CUI Mingcan, CHOI Jongbok, et al. Degradation of polychlorinated dibenzo-p-dioxins and dibenzofurans in real-field soil by an integrated visible-light photocatalysis and solvent migration system with pn heterojunction BiVO4/Bi2O3 [J]. Journal of Hazardous Materials, 2018, 344: 1116-1125. [31] BIACHE Coralie, MANSUY-HUAULT Laurence, FAURE Pierre, et al. Effects of thermal desorption on the composition of two coking plant soils: impact on solvent extractable organic compounds and metal bioavailability [J]. Environmental Pollution, 2008, 156(3): 671-677. [32] 周翔. 苯系物在土壤中的吸附及热脱附行为研究 [D]. 兰州理工大学, 2022. [33] PATHAK Tara Sankar, YUN Jung-Ho, LEE Se-Jong, et al. Effect of cross-linker and cross-linker concentration on porosity, surface morphology and thermal behavior of metal alginates prepared from algae (Undaria pinnatifida) [J]. Carbohydrate Polymers, 2009, 78(4): 717-724. [34] 陈王若尘. 添加剂对焦化污染土壤性质及热脱附行为影响研究 [D]. 浙江大学, 2020. [35] DUBDUB Ibrahim. Kinetics study of polypropylene pyrolysis by non-isothermal thermogravimetric analysis [J]. Materials, 2023, 16(2): 584. [36] 韩宇辰, 黄震, 冯梅, 等. 可降解聚乳酸的热分解动力学研究 [J]. 包装工程, 2012, 33(19): 75-78. [37] Sun X, Zhao L, Hai J, et al. Mechanisms and extended kinetic model of thermal desorption in organic-contaminated soil [J]. Journal of Environmental Management, 2024, 361: 121169. [38] AGNIHOTRI Nidhi, MONDAL Monoj Kumar. Thermal analysis, kinetic behavior, reaction modeling, and comprehensive pyrolysis index of soybean stalk pyrolysis [J]. Biomass Conversion and Biorefinery, 2024, 14(13): 14977-14992. [39] Burnham A K, Weese R K, Weeks B L. A distributed activation energy model of thermodynamically inhibited nucleation and growth reactions and its application to the β? δ phase transition of HMX [J]. The Journal of Physical Chemistry B, 2004, 108(50): 19432-19441. [40] Graetz J, Reilly J J. Decomposition kinetics of the AlH3 polymorphs [J]. The Journal of Physical Chemistry B, 2005, 109(47): 22181-22185. [41] Liu J, Wang J, Li H, et al. Epitaxial crystallization of isotactic poly (methyl methacrylate) on highly oriented polyethylene [J]. The journal of physical chemistry B, 2006, 110(2): 738-742. [42] 高康,阮久莉,王艺博,等. 典型生物可降解塑料热处理特性及动力学 [J]. 中国环境科学, 2024, 44 (01): 231-241. [43] Liu Y, Sun Z, Ji L, et al. Systematic study on dynamic pyrolysis behaviors, products, and mechanisms of weathered petroleum-contaminated soil with Fe2O3 [J]. Science of The Total Environment, 2022, 834: 155197. [44] COENEN Kai, GALLUCCI Fausto, HENSEN Emiel, et al. Kinetic model for adsorption and desorption of H2O and CO2 on hydrotalcite-based adsorbents [J]. Chemical Engineering Journal, 2019, 355: 520-531. [45] LI B Y, TEE M Y, NGE K S, et al. Comparison kinetic analysis between coats-redfern and criado’s master plot on pyrolysis of horse manure [J]. Chemical Engineering Transactions, 2023, 106: 1273-1278. [46] Enell A, Reichenberg F, Ewald G, et al. Desorption kinetics studies on PAH-contaminated soil under varying temperatures [J]. Chemosphere, 2005, 61(10): 1529-1538. [47] Knopf D A, Ammann M, Berkemeier T, et al. Desorption lifetimes and activation energies influencing gas–surface interactions and multiphase chemical kinetics [J]. Atmospheric Chemistry and Physics, 2024, 24(6): 3445-3528. [48] Xu J, Liu S, Chen C. A Comparative Study of Microwave and Resistance Heating for the Efficient Thermal Desorption of Mineral Oil from Contaminated Soils [J]. Sustainability, 2024, 16(18): 8222. [49] HUANG X J, MO W L, MA Y Y, et al. Pyrolysis kinetic analysis of sequential extract residues from Hefeng subbituminous coal based on the Coats-Redfern method [J]. ACS omega, 2022, 7(25): 21397-21406. [50] 薛靖文, 傅敬强, 唐盛伟, 等. 羰基硫脱除反应机理与动力学研究进展 [C]. 第33届全国天然气学术年会, 中国广西南宁, 2023, 10. XUE Jingwen, FU Jingqiang, TANG Shengwei, et al. Research progress in reaction mechanism and kinetics of carbonyl sulfide removal [C]. The 33 rd National Natural Gas Academic Annual Conference, Nanning Guangxi China, 2023, 10. [51] 姚宏哲，黄飞宇，杨松，等. 重质油高温快速热解自动反应网络的动力学建模 [J]. 化工学报, 2024, 75 (07): 2644-2655. YAO Hongzhe, HUANG Feiyu, YANG Song, et al. Kinetic modeling of the high-temperature rapid pyrolysis auto-reaction network of heavy oil [J]. CIESC Journal, 2024, 75(07): 2644-2655. [52] SAGGESE Chiara, FRASSOLDATI Alessio, CUOCI Alberto, et al. A wide range kinetic modeling study of pyrolysis and oxidation of benzene [J]. Combustion and Flame, 2013, 160(7): 1168-1190. [53] KASMAEI Azadeh Shamsi, ROFOUEI Kazem, OLYA M E, et al. Kinetic and thermodynamic studies on the reactivity of hydroxyl radicals in wastewater treatment by advanced oxidation processes [J]. Progress in Color, Colorants and Coatings, 2020, 13(1): 1-10.