A Photothermal-Photocatalytic Textile With Efficient Thermal Management for Boosting Ciprofloxacin Purification

Yuge Wang , Lipei Ren , Yan Zhuang , Dongfang Liu , Zhixun Zhang , Lei Zhuo , Qian Zhang , Xiwei Guo , Xingfang Xiao , He Zhu

Aggregate ›› 2025, Vol. 6 ›› Issue (9) : e70091

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Aggregate ›› 2025, Vol. 6 ›› Issue (9) : e70091 DOI: 10.1002/agt2.70091
RESEARCH ARTICLE

A Photothermal-Photocatalytic Textile With Efficient Thermal Management for Boosting Ciprofloxacin Purification

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Abstract

Photocatalysis is a renewable and eco-friendly process with great potential for the purification of ciprofloxacin (CIP) in water. However, conventional methods tend to focus on the design of photocatalysts, which pays less attention to the photothermal performance, resulting in a limited purification rate. Here, we propose a photothermal-photocatalytic textile based on carbon fiber felts decorated with homogeneous titanium dioxide films to efficiently purify CIP in water. The carbon fiber felts decorated with titanium dioxide films show high solar absorption (∼93 %) for solar water evaporation and simultaneous photocatalytic degradation for CIP purification. Notably, the enhancement of local wettability by titanium dioxide films on carbon fiber felts promotes photothermal efficiency. The carbon fiber felts decorated with titanium dioxide films demonstrate an evaporation rate of 1.19 kg m−2 h−1, achieving an efficiency of 72.5 % under 1 sun. The experimental results reveal that the local thermal effect can effectively enhance catalytic degradation. CIP is almost completely degraded under sunlight, whereas the degradation efficiency under UV light is 55.8%. Specifically, we observe that CIP can be effectively degraded in purified water and condensed water. Moreover, the carbon fiber felts decorated with titanium dioxide films exhibit multidirectional degradation performance and stable physical and chemical properties, maintaining stable photothermal and photocatalytic performance even after prolonged sunlight exposure and repeated use. This work provides a paradigm for harnessing the abundant sunlight for antibiotic degradation.

Keywords

carbon fiber felts / ciprofloxacin degradation / photothermal catalysis / solar-driven purification / titanium dioxide

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Yuge Wang, Lipei Ren, Yan Zhuang, Dongfang Liu, Zhixun Zhang, Lei Zhuo, Qian Zhang, Xiwei Guo, Xingfang Xiao, He Zhu. A Photothermal-Photocatalytic Textile With Efficient Thermal Management for Boosting Ciprofloxacin Purification. Aggregate, 2025, 6(9): e70091 DOI:10.1002/agt2.70091

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

R. Chen, J. Zhang, K. Zhang, et al., “In-Situ Degradation of Organic Pollutants by Bioelectrical-Fenton Reaction With a Metal-Free Polyaniline-Derived Nitrogen-Doped Carbon Nanofibre Electrode,” Journal of Alloys and Compounds 901 (2022): 163710.
[2]

S. Dong, X. Liu, G. Tian, et al., “Surface Oxygen Vacancies Modified Bi2MoO6 Double-Layer Spheres: Enhanced Visible LED Light Photocatalytic Activity for Ciprofloxacin Degradation,” Journal of Alloys and Compounds 892 (2022): 162217.
[3]

C. Du, S. Nie, C. Zhang, et al., “Dual-Functional Z-Scheme CdSe/Se/BiOBr Photocatalyst: Generation of Hydrogen Peroxide and Efficient Degradation Of Ciprofloxacin,” Journal of Colloid & Interface Science 606 (2022): 1715-1728.
[4]

S. Dong, L. Cui, Y. Tian, et al., “A Novel and High-Performance Double Z-Scheme Photocatalyst ZnO-SnO2-Zn2SnO4 for Effective Removal of Biological Toxicity of Antibiotics,” Journal of Hazardous Materials 399 (2020): 123017.
[5]

W. Cai, P. Zhang, X. Xing, L. Lyu, H. Zhang, and C. Hu, “Synergetic Effects of Catalyst-Surface Dual-Electric Centers and Microbes for Efficient Removal of Ciprofloxacin in Water,” Water Research 245 (2023): 120541.
[6]

X. Zhang, M. Kamali, R. Van Beeck, et al., “Degradation of Ciprofloxacin Using Magnetite Nanoparticle-Activated Periodate: Kinetic, Mechanistic and Toxicity Evaluation,” Chemical Engineering Journal 478 (2023): 147323.
[7]

X. Hu, X. Hu, Q. Peng, et al., “Mechanisms Underlying the Photocatalytic Degradation Pathway of Ciprofloxacin With Heterogeneous TiO2,” Chemical Engineering Journal 380 (2020): 122366.
[8]

Y. Yang, Z. Zhong, J. Li, H. Du, and Z. Li, “Efficient With Low-Cost Removal and Adsorption Mechanisms of Norfloxacin, Ciprofloxacin and Ofloxacin on Modified Thermal Kaolin: Experimental and Theoretical Studies,” Journal of Hazardous Materials 430 (2022): 128500.
[9]

T. Zhang, Y. Hu, L. Jiang, et al., “Removal of Antibiotic Resistance Genes and Control of Horizontal Transfer Risk by UV, Chlorination and UV/Chlorination Treatments of Drinking Water,” Chemical Engineering Journal 358 (2019): 589-597.
[10]

L. Leng, L. Wei, Q. Xiong, et al., “Use of Microalgae Based Technology for the Removal of Antibiotics From Wastewater: A Review,” Chemosphere 238 (2020): 124680.
[11]

W. Jin, C.-Y. Yang, and R. Pau, et al., “Photocatalytic Doping of Organic Semiconductors,” Nature 630 (2024): 96-101.
[12]

L. Hao, H. Huang, Y. Zhang, and T. Ma, “Oxygen Vacant Semiconductor Photocatalysts,” Advanced Functional Materials 31 (2021): 2100919.
[13]

H. Yu, R. Shi, Y. Zhao, et al., “Smart Utilization of Carbon Dots in Semiconductor Photocatalysis,” Advanced Materials 28 (2016): 9454-9477.
[14]

Y. Chen, C. Yan, J. Dong, et al., “Structure/Property Control in Photocatalytic Organic Semiconductor Nanocrystals,” Advanced Functional Materials 31 (2021): 2104099.
[15]

X. Xiao, S. Tu, M. Lu, et al., “Discussion on the Reaction Mechanism of the Photocatalytic Degradation of Organic Contaminants From a Viewpoint of Semiconductor Photo-Induced Electrocatalysis,” Applied Catalysis B: Environmental 198 (2016): 124-132.
[16]

S.-Q. Liu, “Magnetic Semiconductor Nano-Photocatalysts for the Degradation of Organic Pollutants,” Environmental Chemistry Letters 10 (2012): 209-216.
[17]

C. Zhou, C. Lai, C. Zhang, et al., “Semiconductor/Boron Nitride Composites: Synthesis, Properties, and Photocatalysis Applications,” Applied Catalysis B: Environmental 238 (2018): 6-18.
[18]

L. Cui, C. Ma, P. Wang, H. Che, H. Xu, and Y. Ao, “Rationally Constructing a 3D Bifunctional Solar Evaporator for High-Performance Water Evaporation Coupled With Pollutants Degradation,” Applied Catalysis B: Environmental 337 (2023): 122988.
[19]

F. Guo, H. Zhang, H. Li, and Z. Shen, “Modulating the Oxidative Active Species by Regulating the Valence of Palladium Cocatalyst in Photocatalytic Degradation of Ciprofloxacin,” Applied Catalysis B: Environmental 306 (2022): 121092.
[20]

S. Sezer, P. Demircivi, N. Erdol Aydin, and G. Nasun Saygili, “Photocatalytic Degradation of Ciprofloxacin by Using Tannin-Doped BaTiO3 Catalyst,” Journal of Photochemistry and Photobiology A: Chemistry 451 (2024): 115468.
[21]

N. T. T. Hai, V. V. Tu, P. H. Long, et al., “Improvement of Photocatalytic Degradation and Adsorption of Ciprofloxacin by Bismuth Oxyiodide,” Chemical Engineering and Technology 46 (2023): 2404-2411.
[22]

H. Wang, Z. Wang, Z. Zhang, Y. Fan, X. Fu, and W. Dai, “Enhanced Photocatalytic Hydrogen Production From Formic Acid With Reversible Electron Transfers in PdO/TiO2,” Fuel 362 (2024): 130865.
[23]

Y. Liu, Q. Li, J. Zhang, W. Sun, S. Gao, and J. K. Shang, “PdO Loaded TiO2 Hollow Sphere Composite Photocatalyst With a High Photocatalytic Disinfection Efficiency on Bacteria,” Chemical Engineering Journal 249 (2014): 63-71.
[24]

X. Yu, J. Zhang, J. Zhang, et al., “Photocatalytic Degradation of Ciprofloxacin Using Zn-Doped Cu2O Particles: Analysis of Degradation Pathways and Intermediates,” Chemical Engineering Journal 374 (2019): 316-327.
[25]

K. Xu, J. Shen, S. Zhang, D. Xu, and X. Chen, “Efficient Interfacial Charge Transfer of BiOCl-In2O3 Step-Scheme Heterojunction for Boosted Photocatalytic Degradation of Ciprofloxacin,” Journal of Materials Science and Technology 121 (2022): 236-244.
[26]

G. Liu, L. Han, J. Wang, et al., “Continuous Near-Complete Photocatalytic Degradation of Toluene by V/N-Doped TiO2 Loaded on Honeycomb Ceramics Under UV Irradiation,” Journal of Materials Science and Technology 174 (2024): 188-194.
[27]

A. Singh, J. Dhau, R. Kumar, et al., “Tailored Carbon Materials (TCM) for Enhancing Photocatalytic Degradation of Polyaromatic Hydrocarbons,” Progress in Materials Science 144 (2024): 101289.
[28]

D. Mateo, J. L. Cerrillo, S. Durini, and J. Gascon, “Fundamentals and Applications of Photo-Thermal Catalysis,” Chemical Society Reviews 50 (2021): 2173-2210.
[29]

Z. Yang, Z.-Y. Wu, Z. Lin, et al., “Optically Selective Catalyst Design with Minimized Thermal Emission for Facilitating Photothermal Catalysis,” Nature Communications 15 (2024): 7599.
[30]

X. Xiao, L. Pan, B. Chen, et al., “A Janus and Superhydrophilic Design for Stable and Efficient High-Salinity Brine Solar Interfacial Desalination,” Chemical Engineering Journal 455 (2023): 140777.
[31]

Q. Jiang, L. Tian, K. K. Liu, et al., “Bilayered Biofoam for Highly Efficient Solar Steam Generation,” Advanced Materials 28 (2016): 9400-9407.
[32]

M. Wang, Y. Wei, X. Wang, et al., “An Integrated System With Functions of Solar Desalination, Power Generation and Crop Irrigation,” Nature Water 1 (2023): 716-724.
[33]

P. Tao, G. Ni, C. Song, et al., “Solar-Driven Interfacial Evaporation,” Nature Energy 3 (2018): 1031-1041.
[34]

J. Wang, F. Lin, J. Chen, M. Wang, and X. Ge, “The Preparation, Drug Loading and In Vitro NIR Photothermal-Controlled Release Behavior of Raspberry-Like Hollow Polypyrrole Microspheres,” Journal of Materials Chemistry B 3 (2015): 9186-9193.
[35]

H. Xu, “Taking Solar Evaporation Technologies to a New Era,” Nature Water 3 (2025): 125-126.
[36]

J. Zhang, H. Chen, X. Duan, H. Sun, and S. Wang, “Photothermal Catalysis: From Fundamentals to Practical Applications,” Materials Today 68 (2023): 234-253.
[37]

J.-D. Xiao and H.-L. Jiang, “Metal-Organic Frameworks for Photocatalysis and Photothermal Catalysis,” Accounts of Chemical Research 52 (2019): 356-366.
[38]

Y. Lu, H. Zhang, Y. Wang, et al., “Solar-Driven Interfacial Evaporation Accelerated Electrocatalytic Water Splitting on 2D Perovskite Oxide/MXene Heterostructure,” Advanced Functional Materials 33 (2023): 2215061.
[39]

Y. Luo, Y. Zhang, T. Xing, et al., “Full-Color Tunable and Highly Fire-Retardant Colored Carbon Fibers,” Advanced Functional Materials 5 (2023): 1618-1631.
[40]

L. Cao, D. Chen, W.-Q. Wu, J. Z. Y. Tan, and R. A. Caruso, “Monodisperse Anatase Titania Microspheres With High-Thermal Stability and Large Pore Size (∼80 nm) as Efficient Photocatalysts,” Journal of Materials Chemistry A 5 (2017): 3645-3654.
[41]

Z. Hu, X. Xu, H. Shao, et al., “Catalytically Ultrathin Titania Coating to Enhance Energy Storage and Release of Aluminum Hydride via Atomic Layer Deposition,” Chemical Engineering Journal 499 (2024): 155809.
[42]

M. Li, M. Zu, J. Yu, H. Cheng, Q. Li, and B. Li, “Controllable Synthesis of Core-Sheath Structured Aligned Carbon Nanotube/Titanium Dioxide Hybrid Fibers by Atomic Layer Deposition,” Carbon 123 (2017): 151-157.
[43]

Z. Wei, L. Wu, X. Yue, et al., “Titania Nanoengineering Towards Efficient Plasmonic Photocatalysis: Mono- and Bi-Metal-Modified Mesoporous Microballs Built of Faceted Anatase,” Applied Catalysis B: Environment and Energy 345 (2024): 123654.
[44]

Y. Qing, C. Yang, N. Yu, et al., “Superhydrophobic TiO2/Polyvinylidene Fluoride Composite Surface With Reversible Wettability Switching and Corrosion Resistance,” Chemical Engineering Journal 290 (2016): 37-44.
[45]

J.-M. Kim, K. Vikrant, T. Kim, K.-H. Kim, and F. Dong, “Thermocatalytic Oxidation of Gaseous Benzene by a Titanium Dioxide Supported Platinum Catalyst,” Chemical Engineering Journal 428 (2022): 131090.
[46]

C. Liu, H. Niu, D. Wang, et al., “S-Scheme Bi-oxide/Ti-Oxide Molecular Hybrid for Photocatalytic Cycloaddition of Carbon Dioxide to Epoxides,” ACS Catalysis 12 (2022): 8202-8213.
[47]

J. Liu, Q. Zhang, X. Tian, et al., “Highly Efficient Photocatalytic Degradation of Oil Pollutants by Oxygen Deficient SnO2 Quantum Dots for Water Remediation,” Chemical Engineering Journal 404 (2021): 127146.
[48]

C. Li, L. Ren, C. Zhang, W. Xu, and X. Liu, “TiO2 Coated Polypropylene Membrane by Atomic Layer Deposition for Oil-Water Mixture Separation,” Advanced Fiber Materials 3 (2021): 138-146.
[49]

Q. Meng, Q. Wang, H. Liu, and L. Jiang, “A Bio-Inspired Flexible Fiber Array With an Open Radial Geometry for Highly Efficient Liquid Transfer,” NPG Asia Mater 6 (2014): e125-e125.
[50]

Y. Fu, C. A. Tippets, E. U. Donev, and R. Lopez, “Structural Colors: From Natural to Artificial Systems,” Wiley Interdisciplinary Reviews: Nanomedicine and Nanobiotechnology 8 (2016): 758-775.
[51]

M. Szindler, M. M. Szindler, P. Boryło, and T. Jung, “Structure and Optical Properties of TiO 2 Thin Films Deposited by ALD Method,” Open Physics 15 (2017): 1067-1071.
[52]

Y. Zhou, Z. Qin, Z. Liang, et al., “Ultra-Broadband Metamaterial Absorbers From Long to Very Long Infrared Regime,” Light: Science & Applications 10 (2021): 138.
[53]

L. Zhu, M. Gao, C. K. N. Peh, and G. W. Ho, “Solar-Driven Photothermal Nanostructured Materials Designs and Prerequisites for Evaporation and Catalysis Applications,” Materials Horizons 5 (2018): 323-343.
[54]

S. Wang, B. Zhu, M. Liu, L. Zhang, J. Yu, and M. Zhou, “Direct Z-Scheme ZnO/CdS Hierarchical Photocatalyst for Enhanced Photocatalytic H2-Production Activity,” Applied Catalysis B: Environmental 243 (2019): 19-26.
[55]

Z. Fan, P. He, H. Bai, et al., “Green Recycling of Waste Poly(ethylene terephthalate) Into Ni-MOF Nanorod for Simultaneous Interfacial Solar Evaporation and Photocatalytic Degradation of Organic Pollutants,” EcoMat 6 (2024): e12422.
[56]

L. Wang, G. Zhou, Y. Tian, et al., “Hydroxyl Decorated g-C3N4 Nanoparticles With Narrowed Bandgap for High Efficient Photocatalyst Design,” Applied Catalysis B: Environmental 244 (2019): 262-271.
[57]

J. Xiao, Q. Han, H. Cao, et al., “Number of Reactive Charge Carriers—A Hidden Linker Between Band Structure and Catalytic Performance in Photocatalysts,” ACS Catalysis 9 (2019): 8852-8861.
[58]

L. Liu, J. Liu, K. Sun, J. Wan, F. Fu, and J. Fan, “Novel Phosphorus-Doped Bi2WO6 Monolayer With Oxygen Vacancies for Superior Photocatalytic Water Detoxication and Nitrogen Fixation Performance,” Chemical Engineering Journal 411 (2021): 128629.
[59]

Y. Liu, P. Yan, X. Li, et al., “Selective Recycling of Mixed Polyesters via Heterogeneous Photothermal Catalysis,” Advanced Materials 37 (2025): 2412740.
[60]

N. Xu, X. Hu, W. Xu, et al., “Mushrooms as Efficient Solar Steam-Generation Devices,” Advanced Materials 29 (2017): 1606762.
[61]

Q. Zhang, X. Yin, C. Zhang, et al., “Self-Assembled Supercrystals Enhance the Photothermal Conversion for Solar Evaporation and Water Purification,” Small 18 (2022): 2202867.
[62]

C. Dai, Z. Li, K. Zheng, et al., “Strategic Design of Porous Interfacial Evaporators: A Comprehensive Review Unveiling the Significant Role of Pore Engineering,” Nano Energy 131 (2024): 110244.
[63]

J. Chen, Y. Bai, J. Feng, et al., “Anisotropic Seeded Growth of Ag Nanoplates Confined in Shape-Deformable Spaces,” Angewandte Chemie International Edition 60 (2021): 4117-4124.
[64]

S. Dong, Y. Gong, Z. Zeng, et al., “Dissolved Organic Matter Promotes Photocatalytic Degradation of Refractory Organic Pollutants in Water by Forming Hydrogen Bonding With Photocatalyst,” Water Research 242 (2023): 120297.
[65]

T. Xu, H. Zhao, H. Zheng, and P. Zhang, “Atomically Pt Implanted Nanoporous TiO2 Film for Photocatalytic Degradation of Trace Organic Pollutants in Water,” Chemical Engineering Journal 385 (2020): 123832.
[66]

L. Wei, C. Yu, K. Yang, Q. Fan, and H. Ji, “Recent Advances in VOCs and CO Removal via Photothermal Synergistic Catalysis,” Chinese Journal of Catalysis 42 (2021): 1078-1095.
[67]

Y. Zhou, Y. Feng, H. Xie, J. Lu, D. Ding, and S. Rong, “Cryptomelane Nanowires for Highly Selective Self-Heating Photothermal Synergistic Catalytic Oxidation of Gaseous Ammonia,” Applied Catalysis B: Environmental 331 (2023): 122668.
[68]

Y. Liu, X. Wang, X. Li, et al., “Universal and Scalable Synthesis of Photochromic Single-Atom Catalysts for Plastic Recycling,” Nature Communications 15 (2024): 9357.
[69]

M. Shi and X. Meng, “Photothermal Catalysis: From Principles to Applications,” International Journal of Hydrogen Energy 48 (2023): 34659-34676.
[70]

X. Li, R. Yang, L. Zou, et al., “Reassessing the Role of Thermal Convection in Simultaneous Water Production and Pollutant Degradation in Interfacial Photothermal-Photocatalytic Systems,” Advanced Materials 37 (2025): 2416283.
[71]

Z. Yu, Y. Li, Y. Zhang, et al., “Microplastic Detection and Remediation Through Efficient Interfacial Solar Evaporation for Immaculate Water Production,” Nature Communications 15 (2024): 6081.
[72]

H. Wang, Z. Wang, T. Wang, et al., “Shooting Three Birds With One Stone: Device Construction and Thermal Management for Simultaneous Photothermal Conversion Water Evaporation, Thermoelectric Generation and Photocatalytic Degradation,” Advanced Functional Materials 34 (2024): 2315211.
[73]

F.-Z. Jiao, J. Wu, T. Zhang, et al., “Simultaneous Solar-Thermal Desalination and Catalytic Degradation of Wastewater Containing Both Salt Ions and Organic Contaminants,” ACS Applied Materials and Interfaces 15 (2023): 41007-41018.
[74]

L. Wang, Y. Luo, Y. Song, X. He, T. Xu, and X. Zhang, “Hydrogel-Functionalized Bandages With Janus Wettability for Efficient Unidirectional Drug Delivery and Wound Care,” ACS Nano 18 (2024): 3468-3479.

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