Morphology regulation of BiOBr and study on its performance of photocatalytic CO2 reduction

doi:10.11949/0438-1157.20241403

Abstract

Abstract:

The use of photocatalytic technology to convert atmospheric CO₂ into high-value-added chemical raw materials is an effective way to alleviate energy and environmental problems. In this work, BiOBr was synthesized via a hydrothermal method, and polyvinylpyrrolidone (PVP) was used to regulate the morphology of BiOBr. The catalyst characterization results show that nano-spherical BiOBr-xP (x represents the amount of PVP introduced) was successfully prepared by introducing PVP. Compared with BiOBr, BiOBr-xP has a larger specific surface area and increases the exposure probability of active sites. Meanwhile, the use of PVP improved the band structure of BiOBr, resulting in a more negative conduction band potential for BiOBr-xP, effectively improving its reduction capacity. Photocatalytic CO₂ reduction tests indicate that BiOBr-2P exhibits optimal photocatalytic activity, achieving a CO generation rate of 2.74 μmol‧g^-1‧h^-1, which is 3.38 times greater than that of BiOBr without PVP (0.81 μmol‧g^-1‧h^-1).

Key words: photocatalysis, carbon dioxide, carbon monoxide, morphology, BiOBr

摘要：

利用光催化技术将大气中的CO₂转化为高附加值的化学原料，是缓解能源和环境问题的有效方法。通过水热法制备了BiOBr，并采用聚乙烯吡咯烷酮（PVP）调控BiOBr的形貌。分析催化剂表征结果可知，引入PVP可成功制备得到纳米球状的BiOBr-xP（x表示引入PVP的量），相比于BiOBr，BiOBr-xP具有更大的比表面积，提高了活性位点的暴露概率。同时，PVP的引入改善了BiOBr的能带结构，BiOBr-xP的导带电势更负，有效提高了BiOBr的还原能力。光催化CO₂还原测试结果表明，BiOBr-2P具有最佳的光催化CO₂还原活性，CO的生成速率为2.74 μmol‧g^-1‧h^-1，是未引入PVP制备的BiOBr（0.81 μmol‧g^-1‧h^-1）的3.38倍。

关键词: 光催化, 二氧化碳, 一氧化碳, 形貌, BiOBr

CLC Number:

TQ 135.3

Lili LU, Chen LI, Liuyun CHEN, Xinling XIE, Xuan LUO, Tongming SU, Zuzeng QIN, Hongbing JI. Morphology regulation of BiOBr and study on its performance of photocatalytic CO₂ reduction[J]. CIESC Journal, 2025, 76(6): 2687-2700.

卢丽丽, 李晨, 陈柳云, 谢新玲, 罗轩, 苏通明, 秦祖赠, 纪红兵. BiOBr的形貌调控及其光催化CO₂还原性能的研究[J]. 化工学报, 2025, 76(6): 2687-2700.

Figures/Tables 11

Fig.1 XRD patterns (a), FTIR spectra (b), N2 adsorption-desorption isotherms (c) and pore size distribution (d) of BiOBr and BiOBr-xP

Table 1 Specific surface area， pore volume， and average pore diameter of BiOBr and BiOBr-xP

样品	比表面积/(m²‧g^-1)	孔容/(cm³‧g^-1)	平均孔径/nm
BiOBr	6.26	0.025	14.31
BiOBr-1P	23.16	0.084	8.59
BiOBr-2P	24.56	0.072	7.84
BiOBr-5P	21.25	0.064	7.08
BiOBr-10P	12.19	0.041	7.78

Fig.2 SEM images of BiOBr (a), BiOBr-1P (b), BiOBr-2P (c), BiOBr-5P (d), and BiOBr-10P (e)

Fig.3 TEM and HRTEM images of BiOBr[(a)—(c)] and BiOBr-2P[(d)—(f)], HAADF-STEM image (g) and the corresponding EDS element mappings [(h)—(j)] of BiOBr-2P

Fig.4 XPS survey spectra of BiOBr and BiOBr-2P (a), high resolution XPS spectra of Bi 4f (b), Br 3d (c), O 1s (d), and C 1s (e) in BiOBr and BiOBr-2P, high resolution XPS spectra of N 1s (f) in BiOBr-2P

Fig.5 UV-Vis diffuse reflectance spectra (a), band gap (b), PL spectra (c) and transient photocurrent response (d) of BiOBr and BiOBr-xP

Fig.6 CO yield (a) and production rate (b) of photocatalytic CO2 reduction over BiOBr and BiOBr-xP, CO yield of photocatalytic CO2 reduction over BiOBr-2P under different reaction conditions (c), stability test of photocatalytic CO2 reduction over BiOBr and BiOBr-2P (d)

Fig.7 SEM images of BiOBr-2P before (a) and after (b) reaction, XRD patterns (c) and FTIR spectra (d) of BiOBr-2P before and after reaction

Fig.8 In-situ DRIFTS spectra of coadsorption of CO2 and H2O on BiOBr (a) and BiOBr-2P (c) in the dark, in-situ DRIFTS spectra of photocatalytic CO2 reduction reaction over BiOBr (b) and BiOBr-2P (d) under light irradiation

Fig.9 Mott-Schottky plots [(a), (b)] and XPS valence band spectra [（c）, (d)] of BiOBr and BiOBr-2P

Fig.10 Energy band structure of BiOBr-2P

References 49

[1]	Jiang W B, Loh H, Low B Q L, et al. Role of oxygen vacancy in metal oxides for photocatalytic CO₂ reduction[J]. Applied Catalysis B: Environmental, 2023, 321: 122079.
[2]	王峰, 张顺鑫, 余方博, 等. 光催化CO₂还原制碳氢燃料系统优化策略研究[J]. 化工学报, 2023, 74(1): 29-44.
	Wang F, Zhang S X, Yu F B, et al. Optimization strategy for producing carbon based fuels by photocatalytic CO₂ reduction[J]. CIESC Journal, 2023, 74(1): 29-44.
[3]	Fujishima A, Honda K. Electrochemical photolysis of water at a semiconductor electrode[J]. Nature, 1972, 238(5358): 37-38.
[4]	Li H, Song Q J, Wan S J, et al. Atomic interface engineering of single-atom Pt/TiO₂-Ti₃C₂ for boosting photocatalytic CO₂ reduction[J]. Small, 2023, 19(34): e2301711.
[5]	Ali S, Razzaq A, Kim H, et al. Activity, selectivity, and stability of earth-abundant CuO/Cu₂O/Cu0-based photocatalysts toward CO₂ reduction[J]. Chemical Engineering Journal, 2022, 429: 131579.
[6]	李腾, 张利君, 李小红, 等. Cu₃P修饰改性CdS光催化析氢性能研究[J]. 聊城大学学报(自然科学版), 2023, 36(2): 25-34, 42.
	Li T, Zhang L J, Li X H, et al. Study on Cu₃P as a cocatalyst to improve the photo-catalytic hydrogen evolution performance of CdS[J]. Journal of Liaocheng University (Natural Science Edition), 2023, 36(2): 25-34, 42.
[7]	Khan B, Raziq F, Bilal Faheem M, et al. Electronic and nanostructure engineering of bifunctional MoS₂ towards exceptional visible-light photocatalytic CO₂ reduction and pollutant degradation[J]. Journal of Hazardous Materials, 2020, 381: 120972.
[8]	Zhao L L, Hou H L, Wang L, et al. Atomic-level surface modification of ultrathin Bi₂WO₆ nanosheets for boosting photocatalytic CO₂ reduction[J]. Chemical Engineering Journal, 2024, 480: 148033.
[9]	薛义松, 郭恩言, 卢启芳. Bi₂MoO₆/Ni₃V₂O₈异质结构纳米纤维的合成及光催化性能研究[J]. 聊城大学学报(自然科学版), 2022, 35(6): 58-67.
	Xue Y S, Guo E Y, Lu Q F. Study on preparation and photocatalytic properties of Bi₂MoO₆/Ni₃V₂O₈ heterostructured nanofibers[J]. Journal of Liaocheng University (Natural Science Edition), 2022, 35(6): 58-67.
[10]	Sun Y, Younis S A, Kim K H, et al. Potential utility of BiOX photocatalysts and their design/modification strategies for the optimum reduction of CO₂ [J]. Science of the Total Environment, 2023, 863: 160923.
[11]	Xu Z D, Chen Y, Wang B H, et al. Highly selective photocatalytic CO₂ reduction and hydrogen evolution facilitated by oxidation induced nitrogen vacancies on g-C₃N₄ [J]. Journal of Colloid and Interface Science, 2023, 651: 645-658.
[12]	Gong Y N, Mei J H, Shi W J, et al. Boosting CO₂ photoreduction to formate or CO with high selectivity over a covalent organic framework covalently anchored on graphene oxide[J]. Angewandte Chemie International Edition, 2024, 63(10): e202318735.
[13]	Chen Z J, Xiong J Y, Cheng G. Recent advances in brookite phase TiO₂-based photocatalysts toward CO₂ reduction[J]. Fuel, 2024, 357: 129806.
[14]	Zhang Z R, Guo R T, Xia C, et al. B-TiO₂/CuInS₂ photocatalyst based on the synergistic effect of oxygen vacancy and Z-scheme heterojunction for improving photocatalyst CO₂ reduction[J]. Separation and Purification Technology, 2023, 323: 124461.
[15]	Fan G D, Hu K W, Li X, et al. Highly efficient S-scheme AgBr/BiOBr with visible light photocatalytic performance for carbamazepine degradation: mechanism insight and toxicity assessment[J]. Journal of Environmental Chemical Engineering, 2023, 11(5): 110918.
[16]	Zhao J L, Miao Z R, Zhang Y F, et al. Oxygen vacancy-rich hierarchical BiOBr hollow microspheres with dramatic CO₂ photoreduction activity[J]. Journal of Colloid and Interface Science, 2021, 593: 231-243.
[17]	Senasu T, Chankhanittha T, Hemavibool K, et al. Solvothermal synthesis of BiOBr photocatalyst with an assistant of PVP for visible-light-driven photocatalytic degradation of fluoroquinolone antibiotics[J]. Catalysis Today, 2022, 384: 209-227.
[18]	Xie F X, Xi Q, Zhang M, et al. Amorphous FeOOH-mediated directional charges transfer in light-switchable oxygen vacancies BiOBr for boosting photocatalytic oxygen evolution[J]. Separation and Purification Technology, 2024, 328: 125082.
[19]	Li X B, Hu Y, Dong F, et al. Non-noble-metallic Ni₂P nanoparticles modified OV-BiOBr with boosting photoelectrochemical hydrogen evolution without sacrificial agent[J]. Applied Catalysis B: Environmental, 2023, 325: 122341.
[20]	Lu L Z, Zhang H Y, Sun Z, et al. Creation of robust oxygen vacancies in 2D ultrathin BiOBr nanosheets by irradiation through photocatalytic memory effect for enhanced CO₂ reduction[J]. Chemical Engineering Journal, 2023, 477: 146892.
[21]	Gao K Y, Zhu H B, Zhang C M, et al. Boosting photocatalytic nitrogen fixation via in situ constructing Bi metal active sites over BiOBr/BiOI heterojunction[J]. Solar RRL, 2022, 6(12): 2200869.
[22]	Talreja N, Ashfaq M, Chauhan D, et al. PVP encapsulated MXene coated on PET surface (PMP)-based photocatalytic materials: a novel photo-responsive assembly for the removal of tetracycline[J]. Environmental Research, 2023, 233: 116439.
[23]	Ribeiro C S, Lansarin M A. Enhanced photocatalytic activity of Bi₂WO₆ with PVP addition for CO₂ reduction into ethanol under visible light[J]. Environmental Science and Pollution Research International, 2021, 28(19): 23667-23674.
[24]	Wang Q L, Jin Y H, Zhang Y F, et al. Polyvinyl pyrrolidone-coordinated ultrathin bismuth oxybromide nanosheets for boosting photoreduction of carbon dioxide via ligand-to-metal charge transfer[J]. Journal of Colloid and Interface Science, 2022, 606: 1087-1100.
[25]	Ni Q Q, Ke X, Qian W J, et al. Insight into tetracycline photocatalytic degradation mechanism in a wide pH range on BiOI/BiOBr: coupling DFT/QSAR simulations with experiments[J]. Applied Catalysis B: Environmental, 2024, 340: 123226.
[26]	Xue X L, Chen R P, Chen H W, et al. Oxygen vacancy engineering promoted photocatalytic ammonia synthesis on ultrathin two-dimensional bismuth oxybromide nanosheets[J]. Nano Letters, 2018, 18(11): 7372-7377.
[27]	Du C W, Nie S Y, Feng W W, et al. Hydroxyl regulating effect on surface structure of BiOBr photocatalyst toward high-efficiency degradation performance[J]. Chemosphere, 2022, 287: 132246.
[28]	Cai M, Shui A Z, Du B. Constructing the ZnO/BiOBr hierarchical heterojunction for efficient pollutant photodegradation driven by visible-light[J]. Surfaces and Interfaces, 2023, 37: 102643.
[29]	Gao Z Y, Yao B H, Yang F, et al. Preparation of BiOBr-Bi heterojunction composites with enhanced photocatalytic properties on BiOBr surface by in situ reduction[J]. Materials Science in Semiconductor Processing, 2020, 108: 104882.
[30]	Tang Q Y, Yang M J, Yang S Y, et al. Enhanced photocatalytic degradation of glyphosate over 2D CoS/BiOBr heterojunctions under visible light irradiation[J]. Journal of Hazardous Materials, 2021, 407: 124798.
[31]	Zhou Y, Zhao H J, Ma F, et al. Synthesis and photocatalytic degradation performance of BiOBr nanoflowers with tunable exposed (001) facet and band gap[J]. Inorganic Chemistry Communications, 2024, 164: 112386.
[32]	Xie J, Lu Z J, Feng Y, et al. A small organic molecule strategy for remedying oxygen vacancies by bismuth defects in BiOBr nanosheet with excellent photocatalytic CO₂ reduction[J]. Nano Research, 2024, 17(1): 297-306.
[33]	Shen M Z, Cai X L, Cao B W, et al. Boron-doped ultrathin BiOBr nanosheet promotion for photocatalytic reduction of CO₂ into CO[J]. Journal of Alloys and Compounds, 2024, 981: 173727.
[34]	Huang H W, Li X W, Wang J J, et al. Anionic group self-doping as a promising strategy: band-gap engineering and multi-functional applications of high-performance C O 3 2 - -doped Bi₂O₂CO₃ [J]. ACS Catalysis, 2015, 5(7): 4094-4103.
[35]	Wang H, Cai X N, Zhang Y J, et al. Double-template-regulated bionic mineralization for the preparation of flower-like BiOBr/carbon foam/PVP composite with enhanced stability and visible-light-driven catalytic activity[J]. Applied Surface Science, 2021, 555: 149708.
[36]	Chen K T, Chong S K, Yuan L L, et al. Conversion-alloying dual mechanism anode: nitrogen-doped carbon-coated Bi₂Se₃ wrapped with graphene for superior potassium-ion storage[J]. Energy Storage Materials, 2021, 39: 239-249.
[37]	Wu Y F, Xu M J, Wang Y Q, et al. BiOCl/BiOBr composites for efficient photocatalytic carbon dioxide reduction[J]. Applied Catalysis A: General, 2024, 677: 119708.
[38]	Sun J J, Zhang Y X, Fan S Y, et al. An efficient Z-type CeO₂/BiOBr heterostructure with enhanced photo-oxidation degradation of o-DCB and CO₂ reduction ability[J]. Applied Catalysis B: Environment and Energy, 2024, 356: 124248.
[39]	Luo Z S, Ye X Y, Zhang S J, et al. Unveiling the charge transfer dynamics steered by built-in electric fields in BiOBr photocatalysts[J]. Nature Communications, 2022, 13(1): 2230.
[40]	Wang L, Liu G P, Wang B, et al. Oxygen vacancies engineering–mediated BiOBr atomic layers for boosting visible light-driven photocatalytic CO₂ reduction[J]. Solar RRL, 2021, 5(6): 2000480.
[41]	Wang B, Zhao J Z, Chen H L, et al. Unique Z-scheme carbonized polymer dots/Bi₄O₅Br₂ hybrids for efficiently boosting photocatalytic CO₂ reduction[J]. Applied Catalysis B: Environmental, 2021, 293: 120182.
[42]	Meng J Z, Duan Y Y, Jing S J, et al. Facet junction of BiOBr nanosheets boosting spatial charge separation for CO₂ photoreduction[J]. Nano Energy, 2022, 92: 106671.
[43]	Xi Y M, Mo W H, Fan Z X, et al. A mesh-like BiOBr/Bi₂S₃ nanoarray heterojunction with hierarchical pores and oxygen vacancies for broadband CO₂ photoreduction[J]. Journal of Materials Chemistry A, 2022, 10(39): 20934-20945.
[44]	Yin S K, Zhao X X, Jiang E H, et al. Boosting water decomposition by sulfur vacancies for efficient CO₂ photoreduction[J]. Energy & Environmental Science, 2022, 15(4): 1556-1562.
[45]	Jin D N, Ma J L, Sun R C. Nitrogen-doped biochar nanosheets facilitate charge separation of a Bi/Bi₂O₃ nanosphere with a Mott–Schottky heterojunction for efficient photocatalytic reforming of biomass[J]. Journal of Materials Chemistry C, 2022, 10(9): 3500-3509.
[46]	Wang S Y, Ding X, Zhang X H, et al. In situ carbon homogeneous doping on ultrathin bismuth molybdate: a dual-purpose strategy for efficient molecular oxygen activation[J]. Advanced Functional Materials, 2017, 27(47): 1703923.
[47]	Yue X Y, Cheng L, Fan J J, et al. 2D/2D BiVO₄/CsPbBr₃ S-scheme heterojunction for photocatalytic CO₂ reduction: insights into structure regulation and Fermi level modulation[J]. Applied Catalysis B: Environmental, 2022, 304: 120979.
[48]	Wu J M, Li K Y, Yang S Y, et al. In-situ construction of BiOBr/Bi₂WO₆ S-scheme heterojunction nanoflowers for highly efficient CO₂ photoreduction: regulation of morphology and surface oxygen vacancy[J]. Chemical Engineering Journal, 2023, 452: 139493.
[49]	Zhao M Y, Qin J Y, Wang N, et al. Reconstruction of surface oxygen vacancy for boosting CO₂ photoreduction mediated by BiOBr/CdS heterojunction[J]. Separation and Purification Technology, 2024, 329: 125179.

Morphology regulation of BiOBr and study on its performance of photocatalytic CO₂ reduction

BiOBr的形貌调控及其光催化CO₂还原性能的研究

RichHTML

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 11

References 49

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	Jichao GUO, Xiaoxiao XU, Yunlong SUN. Airflow simulation and optimization based on $C O 2$ concentration in plant factory [J]. CIESC Journal, 2025, 76(S1): 237-245.
[2]	Fanchen KONG, Shuo ZHANG, Mingsheng TANG, Huiming ZOU, Zhouhang HU, Changqing TIAN. Simulation of gas bearings in carbon dioxide linear compressors [J]. CIESC Journal, 2025, 76(S1): 281-288.
[3]	Ting HE, Kai ZHANG, Wensheng LIN, Liqiong CHEN, Jiafu CHEN. Research on integrated process of cryogenic CO₂ removal under supercritical pressure and liquefaction for biogas [J]. CIESC Journal, 2025, 76(S1): 418-425.
[4]	Fenhong SONG, Wenguang WANG, Liang GUO, Jing FAN. Modulation of TiO₂ by C-element modified g-C₃N₄ and photocatalytic hydrogen production performance of composites [J]. CIESC Journal, 2025, 76(6): 2983-2994.
[5]	Lei TANG, Zhenfei WANG, Congli LI, Jiahui YANG, Hao ZHENG, Qi SHI, Jinxiang DONG. CO working capacity and operating conditions of Co-MOF-74 and Mg-MOF-74 [J]. CIESC Journal, 2025, 76(5): 2279-2293.
[6]	Zhaoxue ZHANG, Zhengyu LI, Wenhui CUI, Qian WANG, Zhiping WANG, Linghui GONG. Research on cascade recovery and utilization of cold energy in liquid hydrogen energy storage based on liquid neon - liquid nitrogen [J]. CIESC Journal, 2025, 76(4): 1731-1741.
[7]	Yichen ZHANG, Wenbiao ZHANG, Haoyang LI, Xiaoyang NING. Flow measurement of gas-liquid two-phase CO₂ using Venturi tube based on dual differential pressure model [J]. CIESC Journal, 2025, 76(4): 1493-1503.
[8]	Wen CHAN, Wan YU, Gang WANG, Huashan SU, Fenxia HUANG, Tao HU. Thermodynamic and economic analyses and dual-objective optimization of Allam cycle with improved regenerator layout [J]. CIESC Journal, 2025, 76(4): 1680-1692.
[9]	Junliang HUO, Zhiguo TANG, Zongjun QIU, Yuhua FENG, Xu JIANG, Leyi WANG, Yu YANG, Fanfan QIAO, Yifan HE, Jianliang YU. Experimental research on risk of freezing and plugging during CO₂ pipeline venting under throttling effect [J]. CIESC Journal, 2025, 76(4): 1898-1908.
[10]	Luochang WU, Zeyu YANG, Jianguo YAN, Xutao ZHU, Yang CHEN, Zichen WANG. Experimental study on convection heat transfer characteristics of supercritical carbon dioxide flowing in mini square channels [J]. CIESC Journal, 2025, 76(4): 1583-1594.
[11]	Yao FU, Yingjuan SHAO, Wenqi ZHONG. Experimental study on cyclic heat storage performance of TiO₂-doped calcium based materials under pressurized carbonation [J]. CIESC Journal, 2025, 76(3): 1180-1190.
[12]	Zheng GONG, Xiulu GAO, Ling ZHAO, Dongdong HU. Preparation and shape memory properties of PBAT/PLA foams by supercritical CO₂ [J]. CIESC Journal, 2025, 76(2): 888-896.
[13]	Xinyu DONG, Longfei BIAN, Yiyi YANG, Yuxuan ZHANG, Lu LIU, Teng WANG. Study on flow and heat transfer mechanism of supercritical CO₂ in inclined upward tube under cooling conditions [J]. CIESC Journal, 2024, 75(S1): 195-205.
[14]	Yanlin CHEN, Aiguo ZHOU, Jiale ZHENG, Chuanruo YANG, Tianshu GE. Effects of support materials on amine-impregnated DAC adsorbents [J]. CIESC Journal, 2024, 75(S1): 217-222.
[15]	Guanyu REN, Yifei ZHANG, Xinze LI, Wenjing DU. Numerical study on flow and heat transfer characteristics of airfoil printed circuit heat exchangers [J]. CIESC Journal, 2024, 75(S1): 108-117.