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On-line Access: 2024-08-27

Received: 2023-10-17

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 ORCID:

Yong GUO

https://orcid.org/0000-0002-4089-4358

Ying GUO

https://orcid.org/0000-0002-3811-5255

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Journal of Zhejiang University SCIENCE A 2024 Vol.25 No.4 P.340-356

http://doi.org/10.1631/jzus.A2300081


N-doping offering higher photodegradation performance of dissolved black carbon for organic pollutants: experimental and theoretical studies


Author(s):  Yong GUO, Mengxia CHEN, Ting CHEN, Ying GUO, Zixuan XU, Guowei XU, Soukthakhane SINSONESACK, Keophoungeun KANMANY

Affiliation(s):  Key Laboratory of Integrated Regulation and Resource Development on Shallow Lakes, Ministry of Education, College of Environment, Hohai University, Nanjing 210093, China; more

Corresponding email(s):   guoyong@hhu.edu.cn, guoyinghhu@163.com

Key Words:  Dissolved black carbon (DBC), N-doping, Organic pollutants, Band gap, Photodegradation


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Yong GUO, Mengxia CHEN, Ting CHEN, Ying GUO, Zixuan XU, Guowei XU, Soukthakhane SINSONESACK, Keophoungeun KANMANY. N-doping offering higher photodegradation performance of dissolved black carbon for organic pollutants: experimental and theoretical studies[J]. Journal of Zhejiang University Science A, 2024, 25(4): 340-356.

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journal="Journal of Zhejiang University Science A",
volume="25",
number="4",
pages="340-356",
year="2024",
publisher="Zhejiang University Press & Springer",
doi="10.1631/jzus.A2300081"
}

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%A Zixuan XU
%A Guowei XU
%A Soukthakhane SINSONESACK
%A Keophoungeun KANMANY
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A1 - Yong GUO
A1 - Mengxia CHEN
A1 - Ting CHEN
A1 - Ying GUO
A1 - Zixuan XU
A1 - Guowei XU
A1 - Soukthakhane SINSONESACK
A1 - Keophoungeun KANMANY
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PB - Zhejiang University Press & Springer
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Abstract: 
We investigated the influence mechanism of n-doping for dissolved black carbon (DBC) photodegradation of organic pollutants. The degradation performance of N-doped dissolved black carbon (NDBC) for tetracycline (TC) (71%) is better than that for methylene blue (MB) (28%) under irradiation. These levels are both better than DBC degradation performances for TC (68%) and MB (18%) under irradiation. Reactive species quenching experiments suggest that h+ and O2- are the main reactive species for NDBC photodegraded TC, while ·OH and h+ are the main reactive species for NDBC photodegraded MB. ·OH is not observed during DBC photodegradation of MB. This is likely because n-doping increases valence-band (VB) energy from 1.55 eV in DBC to 2.04 eV in NDBC; the latter is strong enough to oxidize water to form ·OH. Additionally, n-doping increases the DBC band gap of 2.29 to 2.62 eV in NDBC, resulting in a higher separation efficiency of photo-generated electrons-holes in NDBC than in DBC. All these factors give NDBC stronger photodegradation performance for TC and MB than DBC. High-performance liquid chromatography-mass spectrometry (HPLC-MS) characterization and toxicity evaluation with the quantitative structure-activity relationship (QSAR) method suggest that TC photodegradation intermediates produced by NDBC have less aromatic structure and are less toxic than those produced by DBC. We adopted a theoretical approach to clarify the relationship between the surface groups of NDBC and the photoactive species produced. Our results add to the understanding of the photochemical behavior of NDBC.

掺杂氮元素使溶解性黑碳对有机污染物具有更高的光降解性能:实验和理论研究

作者:郭勇1,3,陈孟霞1,陈婷2,郭颖2,徐子璇1,徐国威1,Soukthakhane SINSONESACK4, Keophoungeun KANMANY4
机构:1河海大学,浅水湖泊综合治理与资源开发教育部重点实验室,中国南京,210093;2江苏省环境科学研究院,江苏省环境工程重点实验室,中国南京,210036;3南京大学,污染控制与资源化研究国家重点实验室,中国南京,210023;4老挝自然资源和环境部,自然资源与环境研究所,中央环境实验室,老挝万象,999012
目的:1.将传统解释可溶性黑炭(DBC)结构的理论与能带结构理论相结合,定量研究DBC的光活性物种与能带结构的关系。2.阐明氮元素掺杂对DBC结构光降解污染物的影响机制。
创新点:通过能带结构理论阐明氮元素掺杂使DBC对有机污染物具有更高的光降解性能的机制。
方法:1.通过实验分析,证明氮元素成功掺入DBC;2.通过光降解实验数据,证明氮掺杂的DBC提高对有机污染物的光降解效率;3.通过活性物种捕获和分子探针实验确定主要的贡献物种,进一步结合能带结构理论阐明两种可溶性的黑碳在光降解过程中产生的贡献物种的不同的原因。
结论:氮掺杂促进了生物炭衍生的DBC对四环素(TC)和亚甲基蓝(MB)的光降解性能。这可能是由于以下原因:(1)氮掺杂使DBC的价带能量从1.55 eV增加到氮掺杂的可溶性黑炭(NDBC)的2.04 eV,这足以使NDBC的水氧化形成·OH。换句话说,NDBC可以产生-OH和,而DBC只能产生。(2)氮掺杂使DBC的带隙从2.29 eV增加到2.62 eV,从而导致光生电子孔的分离效率提高,最终促进光降解效率。(3)氮掺杂降低DBC在光照下的稳定性,使DBC对可见光的反应更加灵敏。

关键词:可溶性黑碳;N-掺杂;有机污染物;带隙;光降解

Darkslateblue:Affiliate; Royal Blue:Author; Turquoise:Article

Reference

[1]AraiW, KameyaH, HashimR, et al., 2022. Reactive oxygen species scavenging capacities of oil palm trunk sap evaluated using the electron spin resonance spin trapping method. Industrial Crops and Products, 182:114887.

[2]Barroso-MartínezJS, RomoAIB, PudarS, et al., 2022. Real-time detection of hydroxyl radical generated at operating electrodes via redox-active adduct formation using scanning electrochemical microscopy. Journal of the American Chemical Society, 144(41):18896-18907.

[3]Ben OuaghremM, de VaugeladeS, BourcierS, et al., 2022. Characterization of photoproducts and global ecotoxicity of chlorphenesin: a preservative used in skin care products. International Journal of Cosmetic Science, 44(1):10-19.

[4]ChenW, YangHP, ChenYQ, et al., 2016. Biomass pyrolysis for nitrogen-containing liquid chemicals and nitrogen-doped carbon materials. Journal of Analytical and Applied Pyrolysis, 120:186-193.

[5]de OliveiraJA, da CruzJC, NascimentoOR, et al., 2022. Selective CH4 reform to methanol through partial oxidation over Bi2O3 at room temperature and pressure. Applied Catalysis B: Environmental, 318:121827.

[6]DengSY, LiZZ, ZhaoTS, et al., 2022. Direct Z-scheme covalent triazine-based framework/Bi2WO6 heterostructure for efficient photocatalytic degradation of tetracycline: kinetics, mechanism and toxicity. Journal of Water Process Engineering, 49:103021.

[7]FangGD, GaoJ, LiuC, et al., 2014. Key role of persistent free radicals in hydrogen peroxide activation by biochar: implications to organic contaminant degradation. Environmental Science & Technology, 48(3):1902-1910.

[8]FangGD, LiuC, GaoJ, et al., 2015. Manipulation of persistent free radicals in biochar to activate persulfate for contaminant degradation. Environmental Science & Technology, 49(9):5645-5653.

[9]FangGD, LiuC, WangYJ, et al., 2017. Photogeneration of reactive oxygen species from biochar suspension for diethyl phthalate degradation. Applied Catalysis B: Environmental, 214:34-45.

[10]FatimahS, BilqisSM, Isnaeni, et al., 2019. Luminescence properties of carbon dots synthesis from sugar for enhancing glows in paints. Materials Research Express, 6(9):095006.

[11]FowlesM, 2007. Black carbon sequestration as an alternative to bioenergy. Biomass and Bioenergy, 31(6):426-432.

[12]FrischMJ, TrucksG, SchlegelHS, et al., 2009. Gaussian 09, Revision A.02. Gaussian Inc., Wallingford, USA.

[13]FuHY, LiuHT, MaoJD, et al., 2016. Photochemistry of dissolved black carbon released from biochar: reactive oxygen species generation and phototransformation. Environmental Science & Technology, 50(3):1218-1226.

[14]GeedSR, SamalK, TagadeA, 2019. Development of adsorption-biodegradation hybrid process for removal of methylene blue from wastewater. Journal of Environmental Chemical Engineering, 7(6):103439.

[15]GolshanM, KakavandiB, AhmadiM, et al., 2018. Photocatalytic activation of peroxymonosulfate by TiO2 anchored on cupper ferrite (TiO2@CuFe2O4) into 2,4-D degradation: process feasibility, mechanism and pathway. Journal of Hazardous Materials, 359:325-337.

[16]GuJM, YanJ, ChenZG, et al., 2017. Construction and preparation of novel 2D metal-free few-layer BN modified graphene-like g-C3N4 with enhanced photocatalytic performance. Dalton Transactions, 46(34):11250-11258.

[17]GuoHH, CuiJ, ChaiX, et al., 2023. Preparation of multilayer strontium-doped TiO2/CDs with enhanced photocatalytic efficiency for enrofloxacin removal. Environmental Science and Pollution Research, 30(26):68403-68416.

[18]GuoMY, YuanBH, SuiY, et al., 2023. Rational design of molybdenum sulfide/tungsten oxide solar absorber with enhanced photocatalytic degradation toward dye wastewater purification. Journal of Colloid and Interface Science, 631:33-43.

[19]GuoY, GuoY, HuaSG, et al., 2022. Coupling band structure and oxidation-reduction potential to expound photodegradation performance difference of biochar-derived dissolved black carbon for organic pollutants under light irradiation. Science of the Total Environment, 820:153300.

[20]GuoYX, WenH, ZhongT, et al., 2022. Edge-rich atomic-layered biobr quantum dots for photocatalytic molecular oxygen activation. Chemical Engineering Journal, 445:136776.

[21]HuSL, TianRX, WuLL, et al., 2013. Chemical regulation of carbon quantum dots from synthesis to photocatalytic activity. Chemistry-An Asian Journal, 8(5):1035-1041.

[22]HuSL, ZhangWY, ChangQ, et al., 2016. A chemical method for identifying the photocatalytic active sites on carbon dots. Carbon, 103:391-393.

[23]ImrichT, KrysovaH, Neumann-SpallartM, et al., 2023. Pseudobrookite (Fe2TiO5) films: synthesis, properties and photoelectrochemical characterization. Catalysis Today, 413-415:113982.

[24]KasinathanM, ThiripuranthaganS, SivakumarA, 2020. Fabrication of sphere-like Bi2MoO6/ZnO composite catalyst with strong photocatalytic behavior for the detoxification of harmful organic dyes. Optical Materials, 109:110218.

[25]KhanMA, AlqadamiAA, WabaidurSM, et al., 2020. Oil industry waste based non-magnetic and magnetic hydrochar to sequester potentially toxic post-transition metal ions from water. Journal of Hazardous Materials, 400:123247.

[26]KöhlerT, ZschornakM, RöderC, et al., 2023. Chemical environment and occupation sites of hydrogen in LiMO3. Journal of Materials Chemistry C, 11(2):520-538.

[27]KumarG, DuttaRK, 2022. Sunlight mediated photo-Fenton degradation of tetracycline antibiotic and methylene blue dye in aqueous medium using FeWO4/Bi2MoO6 nanocomposite. Process Safety and Environmental Protection, 159:862-873.

[28]LarssonDGJ, FlachCF, 2022. Antibiotic resistance in the environment. Nature Reviews Microbiology, 20(5):257-269.

[29]LiHT, LiuRH, LianSY, et al., 2013. Near-infrared light controlled photocatalytic activity of carbon quantum dots for highly selective oxidation reaction. Nanoscale, 5(8):3289-3297.

[30]LiL, ChengM, QinL, et al., 2022. Enhancing hydrogen peroxide activation of Cu‍–‍Co layered double hydroxide by compositing with biochar: performance and mechanism. Science of the Total Environment, 828:154188.

[31]LiRH, WangJJ, ZhouBY, et al., 2017. Simultaneous capture removal of phosphate, ammonium and organic substances by MgO impregnated biochar and its potential use in swine wastewater treatment. Journal of Cleaner Production, 147:96-107.

[32]LinZL, WuYL, JinXY, et al., 2023. Facile synthesis of direct Z-scheme UiO-66-NH2/PhC2Cu heterojunction with ultrahigh redox potential for enhanced photocatalytic Cr(VI) reduction and NOR degradation. Journal of Hazardous Materials, 443:130195.

[33]LiuSH, HuangYY, 2018. Valorization of coffee grounds to biochar-derived adsorbents for Co2 adsorption. Journal of Cleaner Production, 175:354-360.

[34]LiuXJ, LiuJY, ChuHP, et al., 2015. Enhanced photocatalytic activity of Bi2O3-Ag2O hybrid photocatalysts. Applied Surface Science, 347:269-274.

[35]LiuY, GuoHG, ZhangYL, et al., 2019. Fe@C carbonized resin for peroxymonosulfate activation and bisphenol S degradation. Environmental Pollution, 252:1042-1050.

[36]LiuY, LiuXH, LuSY, et al., 2020. Adsorption and biodegradation of sulfamethoxazole and ofloxacin on zeolite: influence of particle diameter and redox potential. Chemical Engineering Journal, 384:123346.

[37]MaWJ, XuXY, AnBY, et al., 2021. Single and ternary competitive adsorption-desorption and degradation of amphenicol antibiotics in three agricultural soils. Journal of Environmental Management, 297:113366.

[38]MeyerS, BrightRM, FischerD, et al., 2012. Albedo impact on the suitability of biochar systems to mitigate global warming. Environmental Science & Technology, 46(22):12726-12734.

[39]OrtizGR, Lartundo-RojasL, Samaniego-BenítezJE, et al., 2021. Photocatalytic behavior for the phenol degradation of ZnAl layered double hydroxide functionalized with SDS. Journal of Environmental Management, 277:111399.

[40]QambraniNA, RahmanMM, WonS, et al., 2017. Biochar properties and eco-friendly applications for climate change mitigation, waste management, and wastewater treatment: a review. Renewable and Sustainable Energy Reviews, 79:255-273.

[41]QinL, ZhouZP, DaiJD, et al., 2016. Novel N-doped hierarchically porous carbons derived from sustainable shrimp shell for high-performance removal of sulfamethazine and chloramphenicol. Journal of the Taiwan Institute of Chemical Engineers, 62:228-238.

[42]QinL, HuangCH, LiuCQ, et al., 2023. Molecular mechanism for the activation of the potent hepatotoxin acetylhydrazine: identification of the initial N-centered radical and the secondary C-centered radical intermediates. Free Radical Biology and Medicine, 204:20-27.

[43]QuXL, FuHY, MaoJD, et al., 2016. Chemical and structural properties of dissolved black carbon released from biochars. Carbon, 96:759-767.

[44]RafiqA, IkramM, AliS, et al., 2021. Photocatalytic degradation of dyes using semiconductor photocatalysts to clean industrial water pollution. Journal of Industrial and Engineering Chemistry, 97:111-128.

[45]ShahidMK, KashifA, FuwadA, et al., 2021. Current advances in treatment technologies for removal of emerging contaminants from water–a critical review. Coordination Chemistry Reviews, 442:213993.

[46]ShaoJG, ZhangJJ, ZhangX, et al., 2018. Enhance SO2 adsorption performance of biochar modified by CO2 activation and amine impregnation. Fuel, 224:138-146.

[47]ShiHH, WangMJ, WangBB, et al., 2020. Insights on photochemical activities of organic components and minerals in dissolved state biochar in the degradation of atorvastatin in aqueous solution. Journal of Hazardous Materials, 392:122277.

[48]SuHS, YiH, GuWY, et al., 2022. Cost of raising discharge standards: a plant-by-plant assessment from wastewater sector in China. Journal of Environmental Management, 308:114642.

[49]SunSM, WangWZ, LiDZ, et al., 2014. Solar light driven pure water splitting on quantum sized BiVO4 without any cocatalyst. ACS Catalysis, 4(10):3498-3503.

[50]TanXF, LiuSB, LiuYG, et al., 2017. Biochar as potential sustainable precursors for activated carbon production: multiple applications in environmental protection and energy storage. Bioresource Technology, 227:359-372.

[51]TangCQ, ZhangYM, HanJG, et al., 2020. Monitoring graphene oxide’s efficiency for removing Re(VII) and Cr(VI) with fluorescent silica hydrogels. Environmental Pollution, 262:114246.

[52]TangSF, WangZT, YuanDL, et al., 2020. Ferrous ion-tartaric acid chelation promoted calcium peroxide fenton-like reactions for simulated organic wastewater treatment. Journal of Cleaner Production, 268:122253.

[53]TianYJ, FengL, WangC, et al., 2019. Dissolved black carbon enhanced the aquatic photo-transformation of chlortetracycline via triplet excited-state species: the role of chemical composition. Environmental Research, 179:108855.

[54]TuYN, LiuHY, LiYJ, et al., 2022. Radical chemistry of dissolved black carbon under sunlight irradiation: quantum yield prediction and effects on sulfadiazine photodegradation. Environmental Science and Pollution Research, 29(15):21517-21527.

[55]WanD, WangJ, ChenT, et al., 2022. Effect of disinfection on the photoreactivity of effluent organic matter and photodegradation of organic contaminants. Water Research, 219:118552.

[56]WanZH, SunYQ, TsangDCW, et al., 2020. Customised fabrication of nitrogen-doped biochar for environmental and energy applications. Chemical Engineering Journal, 401:126136.

[57]WangH, ZhouHX, MaJZ, et al., 2020. Triplet photochemistry of dissolved black carbon and its effects on the photochemical formation of reactive oxygen species. Environmental Science & Technology, 54(8):4903-4911.

[58]WangJT, CaiYL, LiuXJ, et al., 2022. Unveiling the visible-light-driven photodegradation pathway and products toxicity of tetracycline in the system of Pt/BiVO4 nanosheets. Journal of Hazardous Materials, 424:127596.

[59]WangLL, WangL, ShiYW, et al., 2022. Blue TiO2 nanotube electrocatalytic membrane electrode for efficient electrochemical degradation of organic pollutants. Chemosphere, 306:135628.

[60]WengXL, CaiWL, LanRF, et al., 2018. Simultaneous removal of amoxicillin, ampicillin and penicillin by clay supported Fe/Ni bimetallic nanoparticles. Environmental Pollution, 236:562-569.

[61]WoolfD, AmonetteJE, Street-PerrottFA, et al., 2010. Sustainable biochar to mitigate global climate change. Nature Communications, 1:56.

[62]WuZZ, FeiH, WangDZ, 2019. MoS2/Cu2O nanohybrid as a highly efficient catalyst for the photoelectrocatalytic hydrogen generation. Materials Letters, 256:126622.

[63]XiaoCF, ChenXQ, TaoXM, et al., 2023. In situ generation of hydroxyl radicals by B-doped TiO2 for efficient photocatalytic degradation of acetaminophen in wastewater. Environmental Science and Pollution Research, 30(16):46997-47011.

[64]XuXY, CaoXD, ZhaoL, et al., 2014. Interaction of organic and inorganic fractions of biochar with Pb(II) ion: further elucidation of mechanisms for Pb(II) removal by biochar. RSC Advances, 4(85):44930-44937.

[65]YanM, HuaYQ, ZhuFF, et al., 2017. Fabrication of nitrogen doped graphene quantum dots-BiOI/MnNb2O6 p-n junction photocatalysts with enhanced visible light efficiency in photocatalytic degradation of antibiotics. Applied Catalysis B: Environmental, 202:518-527.

[66]YanYB, ChenJ, LiN, et al., 2018. Systematic bandgap engineering of graphene quantum dots and applications for photocatalytic water splitting and CO2 reduction. ACS Nano, 12(4):3523-3532.

[67]YangF, SunLL, XieWL, et al., 2017. Nitrogen-functionalization biochars derived from wheat straws via molten salt synthesis: an efficient adsorbent for atrazine removal. Science of the Total Environment, 607-608:1391-1399.

[68]YaoB, LuoZR, DuSZ, et al., 2022. Magnetic MgFe2O4/biochar derived from pomelo peel as a persulfate activator for levofloxacin degradation: effects and mechanistic consideration. Bioresource Technology, 346:126547.

[69]YaoYJ, ChenH, LianC, et al., 2016. Fe, Co, Ni nanocrystals encapsulated in nitrogen-doped carbon nanotubes as Fenton-like catalysts for organic pollutant removal. Journal of Hazardous Materials, 314:129-139.

[70]YeRQ, PengZW, MetzgerA, et al., 2015. Bandgap engineering of coal-derived graphene quantum dots. ACS Applied Materials & Interfaces, 7(12):7041-7048.

[71]YeWJ, ZhangWW, HuXX, et al., 2020. Efficient electrochemical-catalytic reduction of nitrate using Co/AC0.9-AB0.1 particle electrode. Science of the Total Environment, 732:139245.

[72]YuanH, ShiWL, LuJL, et al., 2023. Dual-channels separated mechanism of photo-generated charges over semiconductor photocatalyst for hydrogen evolution: interfacial charge transfer and transport dynamics insight. Chemical Engineering Journal, 454:140442.

[73]ZhangJ, WangC, HuangNN, et al., 2022. Humic acid promoted activation of peroxymonosulfate by Fe3S4 for degradation of 2,4,6-trichlorophenol: an experimental and theoretical study. Journal of Hazardous Materials, 434:128913.

[74]ZhangJJ, GaoYF, JiaXR, et al., 2018. Oxygen vacancy-rich mesoporous ZrO2 with remarkably enhanced visible-light photocatalytic performance. Solar Energy Materials and Solar Cells, 182:113-120.

[75]ZhangKK, KhanA, SunP, et al., 2020. Simultaneous reduction of Cr(VI) and oxidization of organic pollutants by rice husk derived biochar and the interactive influences of coexisting Cr(VI). Science of the Total Environment, 706:135763.

[76]ZhangZC, WangFX, WangF, et al., 2023. Efficient atrazine degradation via photoactivated SR-AOP over S-BUC-21(Fe): the formation and contribution of different reactive oxygen species. Separation and Purification Technology, 307:122864.

[77]ZhangZF, ZhaoW, ZhaoWW, 2014. Commercialization development of crop straw gasification technologies in China. Sustainability, 6(12):9159-9178.

[78]ZhaoPJ, YangY, PeiY, et al., 2023. TEMPO-oxidized cellulose beads embedded with Au-doped TiO2 nanoparticles for photocatalytic degradation of Tylosin. Cellulose, 30(2):1133-1147.

[79]ZhaoY, TruhlarDG, 2008. The M06 suite of density functionals for main group thermochemistry, thermochemical kinetics, noncovalent interactions, excited states, and transition elements: two new functionals and systematic testing of four M06-class functionals and 12 other functionals. Theoretical Chemistry Accounts, 120(1-3):215-241.

[80]ZhengY, ZhangZS, LiCH, 2017. A comparison of graphitic carbon nitrides synthesized from different precursors through pyrolysis. Journal of Photochemistry and Photobiology A: Chemistry, 332:32-44.

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