Fe2O3/g-C3N5光催化剂的制备及对煤矿瓦斯中甲烷的去除

doi:10.3969/j.issn.2097-2806.2025.09.007

摘要/Abstract

摘要： 通过溶剂热法制备了Fe₂O₃/g-C₃N₅光催化剂，研究了光催化剂对煤矿瓦斯中甲烷的去除性能。通过X射线衍射（XRD）、傅里叶红外光谱（FTIR）、紫外可见漫反射光谱（UV-vis DRS）、光致发光光谱（PL）、瞬态光电流谱（TPC）、交流阻抗谱（EIS）和顺磁共振波谱（ESR）对光催化剂的物相晶型、特征基团、光谱吸收、光电子-空穴重组、光电化学性能和活性基团等进行了表征分析。结果表明：模拟太阳光照射180 min，Fe₂O₃/g-C₃N₅光催化剂对初始体积分数18%的CH₄的去除率为96.8%，循环使用5次后CH₄的去除率为95.8%，表现出良好的光催化活性和稳定性，这得益于Fe₂O₃和g-C₃N₅之间Z型异质结的构建，有效促进了光电子-空穴的分离，拓宽了光谱吸收范围，促进了电荷的转移。CH₄被h⁺攻击生成·CH₃，进一步被·O₂^-和·OH氧化从而实现降解去除，为光催化去除煤矿瓦斯中CH₄提供了理论依据。

关键词: 富氮氮化碳, 光催化剂, 异质结, 瓦斯, 甲烷

Abstract:

Fe₂O₃/g-C₃N₅ photocatalyst was prepared by solvothermal method, and its performance in methane removal from coal mine gas was studied. X-ray diffraction （XRD）, Fourier transform infrared spectroscopy （FTIR）, ultraviolet-visible diffuse reflectance spectroscopy （UV-vis DRS）, photoluminescence （PL）, transient photocurrent spectroscopy （TPC）, electrochemical impedance spectroscopy （EIS） and electron spin resonance spectroscopy （ESR） were used to characterize the crystal structure, characteristic absorption bands, spectral absorption, photoelectron-hole recombination, photoelectrochemical properties and active groups of the photocatalyst. The results showed that, under simulated sunlight irradiation for 180 min, the Fe₂O₃/g-C₃N₅ photocatalyst had removed 96.8% of CH₄ （the initial volume fraction of CH₄ was 18%）, and the removal efficiency of CH₄ could still reach 95.8% after 5 cycles, indicative of good photocatalytic activity and stability. That was due to the construction of Z-scheme heterojunction between Fe₂O₃ and g-C₃N₅, which effectively promoted the photoelectron-hole separation, broadened the spectral absorption range, and promoted charge transfer. CH₄ was attacked by h⁺ to generate ·CH₃, which was further oxidized by ·O₂^- and ·OH to achieve degradation and removal. This work could provide a theoretical basis for photocatalytic removal of CH₄ in coal mine gas.

Key words: nitrogen-rich carbon nitride, photocatalyst, heterojunction, gas, methane

中图分类号:

O643.3

李燕萍. Fe₂O₃/g-C₃N₅光催化剂的制备及对煤矿瓦斯中甲烷的去除[J]. 日用化学工业（中英文）, 2025, 55(9): 1137-1144.

Yanping Li. Preparation of Fe₂O₃/g-C₃N₅ photocatalyst and its application in removal of methane from coal mine gas[J]. China Surfactant Detergent & Cosmetics, 2025, 55(9): 1137-1144.

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参考文献 26

[1]	吴烨, 张智慧, 赵紫薇, 等. 能源结构、绿色科技创新对碳减排的影响机制研究[J]. 中国商论, 2024, 33 (16) : 140-144.
[2]	汪宝发, 胡祖祥. 煤矿瓦斯爆炸事故现状统计及规律分析[J]. 煤炭技术, 2022, 41 (9) : 148-151.
[3]	刘业娇, 崔梦圆, 段泽宇, 等. 2011—2022年煤矿热动力灾害事故特征及发生规律分析[J]. 矿业安全与环保, 2024, 51 (4) : 96-102, 109.
[4]	张磊, 徐虎, 刘朋, 等. 黄河北煤田高瓦斯掘进工作面瓦斯治理技术研究与应用[J]. 科学技术创新, 2024 (20) : 72-75.
[5]	刘慧婷, 杜隆达, 覃礼堂. SrWO₄光催化剂的制备及其光催化降解盐酸金霉素的研究[J]. 日用化学工业(中英文), 2023, 53 (12) : 1377-1384.
[6]	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.
[7]	Meng Q, Yang X Y, 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.
[8]	卜义夫, 刘思乐, 宋丹丹, 等. 废旧涤纶基活性炭负载g-C₃N₄光催化剂的制备及其对亚甲基蓝的光催化降解[J]. 毛纺科技, 2023, 51 (2) : 40-48.
[9]	Liu S L, 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.
[10]	胡佳伟, 夏楷, 杨奥, 等. 超薄2D/2D NiPS₃/C₃N₅异质结的界面工程促进光催化产氢[J]. 物理化学学报, 2024, 40 (5) : 48-51.
[11]	Liu S C, Liu S T, Wang W Z, et al. Mn-periodate complex in situ formed at Mn-N coordinate site in Mn-doped g-C₃N₅ for efficient and rapid water purification[J]. Chemical Engineering Journal, 2024, 498: 155546.
[12]	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.
[13]	Harpreet S G, Gurwinder S, Jae H Y, et al. Mesoporous titanium carbonitride derived from mesoporous C₃N₅ for highly efficient hydrogen evolution reaction[J]. Carbon, 2022, 195: 9-18.
[14]	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.
[15]	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.
[16]	Seguel M, Bustamante M, Fernandez L, et al. Effect of Fe₂O₃ on CeO₂ films in the photocatalytic evaluation towards the degradation of brilliant green and oxytetracycline[J]. Materials Research Bulletin, 2024, 180: 113058.
[17]	Akalın A S, Yavaş A, Güler S, et al. Photocatalytic activities of Fe₂O₃ coated ZnO nanowires grown by electrochemical anodization method[J]. Ceramics International, 2024, 50: 39278-39284.
[18]	Wang H Y, Luo J H, et al. Photoelectrochemical determination of cardiac troponin I based on rod-like g-C₃N₅@MnO₂ heterostructure[J]. Microchimica Acta, 2023, 190: 19-29.
[19]	Rahman H, Zhang B, Kubuki S, et al. Catalytic activity of Nb-doped α-Fe₂O₃-Heterojunction structure, ferrimagnet-like character, and high activity[J]. Inorganic Chemistry Communications, 2024, 169: 113077.
[20]	Yao J, Liu D, Zhao B, et al. Insight into the effect of B-doping on electronic structure and photocatalytic H₂ evolution performance of C₃N₅ nanosheets[J]. Journal of Photochemistry and Photobiology, A: Chemistry, 2023, 436: 114359.
[21]	Fu C, Wu T, Sun J W, et al. Dual-defect enhanced piezocatalytic performance of C₃N₅ for multifunctional applications[J]. Applied Catalysis B: Environmental, 2023, 323: 122196.
[22]	Ulfa M, Nina, Pangestuti I, et al. Enhancing photocatalytic activity of Fe₂O₃/TiO₂ with gelatin: A fuzzy logic analysis of mesoporosity and iron loading[J]. South African Journal of Chemical Engineering, 2024, 50: 245-260.
[23]	唐贝. ZnO/g-C₃N₄异质结光催化材料的制备及对吡啶的降解[J]. 无机盐工业, 2024, 56 (4) : 133-142.
[24]	Annamalai K, Sasirekha N, Balakumar S. Optimizing junction interface integrity between 3D/2D defect pyrochlore Bi_1.8Fe_0.2WO₆ and g-C₃N₄ nanostructures: A novel multifunctional nanocomposite for enhanced photocatalytic and photo-electrocatalytic water splitting and water remediation applications[J]. Surfaces and Interfaces, 2024, 53: 105071.
[25]	Priyadharsan A, Kamaraj C, Ranjith R, et al. Synthesis of multifunctional rGO/g-C₃N₄/FeTiO₃ ternary nanocomposites for photocatalyst, antibacterial, and ecotoxicity assessment of zebrafish embryo model[J]. Journal of Alloys and Compounds, 2024, 1007: 176256.
[26]	杨娟, 郝静怡, 魏建平, 等. 吸附型复合催化剂光催化消除煤矿瓦斯的机理[J]. 煤炭学报, 2018, 43 (8) : 2250-2255.

Fe₂O₃/g-C₃N₅光催化剂的制备及对煤矿瓦斯中甲烷的去除

Preparation of Fe₂O₃/g-C₃N₅ photocatalyst and its application in removal of methane from coal mine gas

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