AgBr/C3N5复合材料可见光去除无机废水中氨氮

doi:10.3969/j.issn.2097-2806.2024.12.009

摘要/Abstract

摘要：

通过原位沉淀法将AgBr原位沉淀到富氮氮化碳（C₃N₅）表面，制备了AgBr/C₃N₅复合材料，通过X射线衍射（XRD）、傅里叶红外光谱（FTIR）、X射线光电子能谱（XPS）、紫外可见漫反射光谱（UV-vis DRS）和光致发光光谱（PL）等技术手段对复合材料的物相晶型、化学组成、元素组成、光谱吸收和光电子-空穴分离进行了表征分析。AgBr和C₃N₅异质结的构建使得光谱响应范围拓宽，实现了光电子-空穴的高效分离，提升了光催化性能。使用NH₄Cl溶液模拟无机氨氮废水研究复合材料的光催化性能，复合材料投加量为0.10 g，NH₄Cl溶液初始质量浓度100 mg/L，初始pH=10.0，模拟可见光照射60 min复合材料对氨氮的去除率达到了90.27%，循环使用5次后氨氮的去除率仅仅降低了0.12%，复合材料表现出良好的光催化性能和稳定性。Z-scheme机理有效保留了光电子和空穴的还原和氧化活性，将O₂和H₂O分别还原和氧化为超氧自由基（·O₂^-）和羟基自由基（·OH）等活性基团，实现了无机氨氮的高效去除。

关键词: 富氮氮化碳, 复合材料, 可见光, 无机氨氮

Abstract:

AgBr/C₃N₅ composite was prepared by in-situ precipitation of AgBr on the surface of nitrogen-rich carbon nitride （C₃N₅）. The crystal phase, chemical composition, elemental composition, spectral absorption and photoelectron-hole separation of the composite were characterized by X-ray diffraction （XRD）, Fourier transform infrared spectroscopy （FTIR）, X-ray photoelectron spectroscopy （XPS）, ultraviolet-visible diffuse reflectance spectroscopy （UV-vis DRS） and photoluminescence spectroscopy （PL）. The construction of AgBr and C₃N₅ heterojunction could broaden the spectral response range, realize the efficient separation of photoelectrons and holes, and thus improve the photocatalytic performance. The photocatalytic performance of the composite material was studied by simulating inorganic ammonia nitrogen wastewater with NH₄Cl solution. The dosage of the composite material was 0.10 g, the initial mass concentration of NH₄Cl solution was 100 mg/L, and the initial pH was 10.0. The removal rate of ammonia nitrogen by the composite material reached 90.27% after 60 min of simulated visible light irradiation. After 5 cycles, the removal rate of ammonia nitrogen only declined by 0.12%. The composite material showed good photocatalytic performance and stability. The Z-scheme mechanism effectively retained the reduction and oxidation activities of photoelectrons and holes, which could change O₂ and H₂O to active groups such as superoxide radicals （·O₂^-） and hydroxyl radicals （·OH）, respectively, achieving efficient removal of inorganic ammonia nitrogen.

Key words: nitrogen-rich carbon nitride, composite material, visible light, inorganic ammonia nitrogen

中图分类号:

O643.3

朱炳生. AgBr/C₃N₅复合材料可见光去除无机废水中氨氮[J]. 日用化学工业（中英文）, 2024, 54(12): 1473-1480.

Bingsheng Zhu. Removal of ammonia nitrogen from inorganic wastewater by AgBr/C₃N₅ heterojunction under visible light irradiation[J]. China Surfactant Detergent & Cosmetics, 2024, 54(12): 1473-1480.

图/表 10

图1

图2

图3

图4

图5

图6

图7

图8

图9

图10

参考文献 30

[1]	Quan X H, Su B Q, Wang J, et al. A Review: Treatment of coking wastewater by advanced oxidation processes[J]. China Water & Wastewater, 2024, 40 (12) : 41-48.
[2]	Ju P P, Liu H Q, Liu B, et al. Research progress on analysis and control of nitrogen containing pollutants in coking wastewater[J]. Industrial Water Treatment, 2022, 42 (11) : 40-45.
[3]	Zheng P S. Research progress of anaerobic biological treatment technology of coal chemical wastewater[J]. Technology of Water Treatment, 2021, 47 (6) : 24-27, 33.
[4]	Liao W N, Yang Z Q, Wang Y, et al. Novel Z-scheme Nb₂O₅/C₃N₅ photocatalyst for boosted degradation of tetracycline antibiotics by visible light-assisted activation of persulfate system[J]. Chemical Engineering Journal, 2023, 478: 147346.
[5]	Wang X Q, Wang F, Chen B, et al. Promotion of phenol photodecomposition and the corresponding decomposition mechanism over g-C₃N₄/TiO₂ nanocomposites[J]. Applied Surface Science, 2018, 453: 320-329.
[6]	Meng Q, Yang X Y, Wu L Z, et al. Metal-free 2D/2D C₃N₅/GO nanosheets with customized energy-level structure for radioactive nuclear wastewater treatment[J]. Journal of Hazardous Materials, 2022, 422: 126912.
[7]	Zhang J L, Jing B H, Tang Z Y, et al. Experimental and DFT insights into the visible-light driving metal-free C₃N₅ activated persulfate system for efficient water purification[J]. Applied Catalysis B: Environmental, 2021, 289: 120023.
[8]	Yin H F, Yuan C Y, Lv H J, et al. Fabrication of 2D/1D Bi₂WO₆/C₃N₅ heterojunctions for efficient antibiotics removal[J]. Powder Technology, 2023, 413: 118083.
[9]	Long J Q, Wei L, Huang H Z, et al. Facile fabrication of biochar-coupled g-C₃N₅/C and its enhanced photocatalytic properties[J]. Journal of Physics and Chemistry of Solids, 2022, 171: 111029.
[10]	Li S J, Wang C C, Cai M J, et al. Designing oxygen vacancy mediated bismuth molybdate (Bi₂MoO₆)/Nrich carbon nitride (C₃N₅) S-scheme heterojunctions for boosted photocatalytic removal of tetracycline antibiotic and Cr(Ⅵ): Intermediate toxicity and mechanism insight[J]. Journal of Colloid and Interface Science, 2022, 624: 219-232.
[11]	Zhang X W, Li D, Li M Y, et al. Flower-like Co₃O₄/C₃N₅ composite as solid-phase microextraction coating for high-efficiency adsorption and preconcentration of polycyclic aromatic hydrocarbons and polychlorinated biphenyls in water[J]. Chemical Engineering Journal, 2022, 443: 136293.
[12]	Wang L, Chen R J, Zhang Z Q, et al. Constructing direct Z-scheme heterojunction g-C₃N₅/BiOBr for efficient photocatalytic CO₂ reduction with H₂O[J]. Journal of Environmental Chemical Engineering, 2023, 11: 109345.
[13]	Deng Y C, Li L, Zeng H, et al. Unveiling the origin of high-efficiency charge transport effect of C₃N₅/C₃N₄ homojunction for activating peroxymonosulfate to degrade atrazine under visible light[J]. Chemical Engineering Journal, 2023, 457: 141261.
[14]	Yang J, Long J Q, Huang H Z, et al. Synthesis of visible-light driven CeO₂/g-C₃N₅ heterojunction with enhanced photocatalytic performance for organic dyes[J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2023, 660: 130846.
[15]	Zhang Y, Cui T Y, Zhao J B, et al. Fabrication and study of a novel TiO₂/g-C₃N₅ material and photocatalytic properties using methylene blue and tetracycline under visible light[J]. Inorganic Chemistry Communications, 2022, 143: 109815.
[16]	Wang Z R, Li W H, Wu L Z, et al. Nitrogen-rich carbon nitrogen polymers for enhancing the sorption of uranyl[J]. Chinese Chemical Letters, 2022, 33: 3468-3473. doi: 10.1016/j.cclet.2022.03.097
[17]	Chen J F, Zhang Y, Wang Y A, et al. Internal electric field promoted NCDs/BiOBr/AgBr Z-scheme heterojunction with rich oxygen vacancies for efficient photocatalytic degradation of tetracycline and reduction of Cr (Ⅵ)[J]. Journal of Environmental Chemical Engineering, 2024, 12: 112476.
[18]	Bu Y F, Liu S L, Song D D, et al. Preparation of waste polyester-based activated carbon loaded g-C₃N₄ composite and its photocatalytic degradation of methylene blue[J]. Wool Textile Journal, 2023, 51 (2) : 40-48.
[19]	Liu M Y, Wang J Y, Duan L, et al. Nickel oxide modified C₃N₅ photocatalyst for enhanced hydrogen evolution performance[J]. Journal of Fuel Chemistry and Technology, 2022, 50 (2) : 243-249.
[20]	Peng C, Han L X, Huang J M, et al. Comprehensive investigation on robust photocatalytic hydrogen production over C₃N₅[J]. Chinese Journal of Catalysis, 2022, 43: 410-420.
[21]	Ma M X, Yan X, Mao Y L, et al. All-solid-state Z-scheme AgBr/Bi₂CrO₆ heterostructure with metallic Ag as a charge transfer bridge for boosted charge transfer and photocatalytic performances[J]. Applied Surface Science, 2024, 654: 159471.
[22]	Wang L, Tian J. Synthesis and photocatalytic activity of a CaMoO₄ photocatalyst modified with C-O functional groups[J]. China Surfactant Detergent & Cosmetics, 2024, 54 (6) : 669-676.
[23]	He X K, Zhu D C. In situ solvothermal method of C₃N₅@NH₂-MIL-125 composites with enhanced visible-light photocatalytic performance[J]. Journal of Materials Science-Materials in Electronics, 2022, 33: 388-398.
[24]	Cai Z Q, Huang Y N, Ji H D, et al. Type-Ⅱ surface heterojunction of bismuth-rich Bi₄O₅Br₂ on nitrogen-rich g-C₃N₅ nanosheets for efficient photocatalytic degradation of antibiotics[J]. Separation and Purification Technology, 2022, 280: 119772.
[25]	Liu S L, Bu Y F, Cheng S, et al. Preparation of g-C₃N₅/g-C₃N₄ heterojunction for methyl orange photocatalytic degradation: Mechanism analysis[J]. Journal of Water Process Engineering, 2023, 54: 104019.
[26]	Ma R D, Guo X, Shi K X, et al. S-type heterojunction of MOS₂/g-C₃N₄: construction and photocatalysis[J]. Journal of Inorganic Materials, 2023, 38 (10) : 1176-1182.
[27]	Zhang D L, Zhang C, Song H B, et al. Advanced bio-inspired Cu₃P/g-C₃N₅@Cu with highly dispersed Cu₃P nanoclusters for superior visible-light-driven pollutant degradation[J]. Journal of Cleaner Production, 2023, 427: 139273.
[28]	Liu S L, Bu Y F, Cheng S, et al. Synthesis of TiO₂/g-C₃N₅ heterojunction for photocatalytic degradation of methylene blue wastewater under visible light irradiation: Mechanism analysis[J]. Diamond & Related Materials, 2023, 136: 110062.
[29]	Huang G Z, Liu S L, Tian C, et al. Construction of S scheme ZnO/g-C₃N₄ heterojunction for the removal of pyridine from coal chemical wastewater[J]. Optical Materials, 2024, 150: 115288.
[30]	Luo J H, Zhang G, Shi W. AgBr/Ag₃PO₄ composites for photocatalytic removal ammonia nitrogen in inorganic wastewater under visible light irradiation[J]. Journal of South China Normal University (Natural Science Edition), 2023, 55 (5) : 65-71.

AgBr/C₃N₅复合材料可见光去除无机废水中氨氮

Removal of ammonia nitrogen from inorganic wastewater by AgBr/C₃N₅ heterojunction under visible light irradiation

RichHTML

PDF (PC)

赞

可视化

摘要/Abstract

引用本文

使用本文

图/表 10

参考文献 30

相关文章 8

Metrics

本文评价

推荐阅读 0

[1]	常香玲, 柴菲. 氧化锌纳米复合抗菌材料的制备及性能研究[J]. 日用化学工业（中英文）, 2023, 53(9): 1051-1056.
[2]	赵茂军, 白瑞雪, 刘棋, 郭婷, 王盛民, 孟涛. 掺氮TiO₂纳米颗粒稳定的Pickering乳液制备及其触发酶反应[J]. 日用化学工业, 2017, 47(3): 137-141.
[3]	李迎宾, 杨许召, 邹文苑, 徐清杰, 王军. 离子液体表面活性剂的合成与应用(Ⅹ)——在材料制备中的应用[J]. 日用化学工业, 2017, 47(10): 546-549.
[4]	詹舒辉,李娟,刘泽学,徐永霞,李保同,韩春蕊. 无患子皂苷-十二烷基苯磺酸钠复配体系表面活性及在制备氢氧化镍复合材料中的应用[J]. 日用化学工业, 2016, 46(5): 264-266.
[5]	乔仙蓉. 紫外可见光谱分析海娜粉中的指甲花醌[J]. 日用化学工业, 2016, 46(3): 178-182.
[6]	王波,黄超,杨小燕,罗峻,陈新德. 生物基细菌纤维素/膨润土无机凝胶复合材料的制备[J]. 日用化学工业, 2016, 46(1): 39-43.
[7]	孙晶晶, 宋伟明, 孙立, 马帅, 刘鹏, 王斐. Fe₃O₄-ZnO复合材料的可控制备及其性能研究[J]. 日用化学工业, 2015, 45(1): 32-35.
[8]	江琦, 唐泽晴. 锆掺杂氧化锌复合紫外屏蔽材料的制备及表征[J]. 日用化学工业, 2014, 44(2): 90-93.