Self-floating high-efficient evaporative catalytic seawater hydrogen production system driven by concentrated solar energy based on Cu/TiO2/C-Wood composite

doi:10.11949/0438-1157.20211385

Abstract

Abstract:

Utilizing abundant and readily available solar and seawater resources to provide sustainable and clean energy to mankind is a far-reaching exploration. In this work, we have designed and synthesized the self-floating solar photothermal composite (Cu/TiO₂/C-Wood) that possesses efficiently full-spectrum solar energy capture and photothermic properties for highly targeted interfacial phase transition reactions that are synergistically favorable for both seawater desalination and hydrogen production. Among them, carbonized wood with abundant microchannel and extremely light mass is used as self-floating carrier to rapidly transports liquid water to localized heating interface by capillary and photothermal effects to achieve effective seawater desalination and water steam production. The plasmonic Cu loaded TiO₂ nanoparticles as catalytic active components trigger surface-dominated photothermally catalytic hydrogen evolution of water steam, realizing the dual-function seawater desalination and synergistic hydrogen production. The hydrogen evolution rate of Cu/TiO₂/C-Wood composite is 179 μmol·h^-1·cm^-2 (35.8 mmol·h^-1·g^-1) under 15 kW·m^-2 and remains basically unchanged after being used 5 times. More importantly, the experimental results show that the main component in seawater-sodium chloride can promote the hydrogen production performance by synergistically concentrated irradiation and self-floating phase transfer process, which breaks the bottleneck of seawater hydrogen production technology, confirming the promising application potential of the self-floating two-phase photo-thermo-catalytic system in large-scale, green and sustainable solar hydrogen production from seawater.

Key words: concentrated solar energy, self-floating, evaporation, synergistic photo-thermo-catalysis, seawater hydrogen production

摘要：

利用储量丰富且易获得的太阳能和海水资源为人类提供可持续的清洁能源是一项具有深远影响的探索。在本工作中，设计合成了一种自漂浮复合材料（Cu/TiO₂/C-Wood），该材料具有高效的毛细输液、全光谱太阳能光热转化及光-热协同催化能力，可通过快速的界面相转移过程实现太阳能驱动海水汽化与水蒸气催化分解制氢的一步协同增效反应。其中，具有大量微通道和极轻质量的碳化木（C-Wood）作为漂浮载体，通过毛细作用将液态水快速输送至局部升温的C-Wood表面，借助高效光热转化过程使海水汽化脱盐，同时负载等离子金属Cu的TiO₂纳米粒子作为催化活性组分触发水蒸气光-热协同催化分解制氢反应，从而实现太阳能驱动高效海水汽化催化分解制氢。实验结果表明：该复合材料在15 kW·m^-2的光照条件下，产氢速率达到179 μmol·h^-1·cm^-2（35.8 mmol·h^-1·g^-1），且在循环利用5次后产氢速率仍基本保持不变。更重要的是，通过聚光太阳能和自漂浮毛细输液条件的共同作用，可以获得海水中主要成分氯化钠对产氢性能的显著促进，从而打破了海水制氢技术一直以来面临的氯离子副作用瓶颈问题，证实了聚光太阳能驱动自漂浮高效光热协同催化体系在规模化、绿色、可持续太阳能海水制氢中的应用潜力。

关键词: 聚光太阳能, 自漂浮, 汽化, 光-热协同催化, 海水制氢

CLC Number:

TQ 116.2

Rong MA, Jie SUN, Donghui LI, Jinjia WEI. Self-floating high-efficient evaporative catalytic seawater hydrogen production system driven by concentrated solar energy based on Cu/TiO₂/C-Wood composite[J]. CIESC Journal, 2022, 73(4): 1695-1703.

马荣, 孙杰, 李东辉, 魏进家. 基于Cu/TiO₂/C-Wood复合材料的聚光太阳能驱动自漂浮高效海水汽化催化分解制氢体系[J]. 化工学报, 2022, 73(4): 1695-1703.

Figures/Tables 14

Fig.1 Self-floating high-efficient evaporative catalytic seawater hydrogen production system driven by concentrated solar energy

Fig. 2 XPS spectra of Cu/TiO2 nanoparticles (a); high-resolution spectrum of Cu 2p (b); CuLMM spectrum (c)

Fig.3 XRD patterns of TiO2 (a) and Cu/TiO2 nanoparticles (b)

Fig.4 SEM images of C-Wood (a) and Cu/TiO2/C-Wood (b); Elemental mappings of Cu/TiO2/C-Wood for C, Ti, O and Cu elements [(c)—(f)]

Fig.5 Contact angle images of Cu/TiO2/C-Wood on non-carbonized surface (a) and carbonized surface (b); Photographs of self-floating Cu/TiO2/C-Wood on synthetic seawater (c)

Fig.6 UV-VIS-IR diffuse reflectance spectra of TiO2 (a), Cu/TiO2 (b) and Cu/TiO2/C-Wood (c)

Fig.7 PL spectra of TiO2 and Cu/TiO2

Fig.8 Mass-loading of Cu/TiO2 against hydrogen evolution rate of Cu/TiO2/C-Wood

Fig.9 Cycling tests of proposed solar-driven seawater hydrogen evolution system

Fig.10 Hydrogen evolution rate against irradiance

Fig.11 Surface temperature of Cu/TiO2/C-Wood against irradiance

Fig.12 Hydrogen evolution rate under 15 kW·m-2 irradiation with or without NaCl

Fig.13 Hydrogen evolution against reaction time under 15 kW·m-2 irradiance with/without NaCl

Fig.14 Hydrogen evolution against reaction time under 1 kW·m-2 irradiance with/without NaCl

References 30

1	Zou Z G, Ye J H, Sayama K, et al. Direct splitting of water under visible light irradiation with an oxide semiconductor photocatalyst[J]. Nature, 2001, 414(6864): 625-627.
2	Roeb M, Müller-Steinhagen H. Engineering. Concentrating on solar electricity and fuels[J]. Science, 2010, 329(5993): 773-774.
3	Luo W J, Yang Z S, Li Z S, et al. Solar hydrogen generation from seawater with a modified BiVO₄ photoanode[J]. Energy & Environmental Science, 2011, 4(10): 4046.
4	Turner J A. Sustainable hydrogen production[J]. Science, 2004, 305(5686): 972-974.
5	Kumaravel V, Abdel-Wahab A. A short review on hydrogen, biofuel, and electricity production using seawater as a medium[J]. Energy & Fuels, 2018, 32(6): 6423-6437.
6	Yao Y, Gao X Y, Meng X C. Recent advances on electrocatalytic and photocatalytic seawater splitting for hydrogen evolution[J]. International Journal of Hydrogen Energy, 2021, 46(13): 9087-9100.
7	Dionigi F, Reier T, Pawolek Z, et al. Design criteria, operating conditions, and nickel-iron hydroxide catalyst materials for selective seawater electrolysis[J]. ChemSusChem, 2016, 9(9): 962-972.
8	Ayyub M M, Chhetri M, Gupta U, et al. Photochemical and photoelectrochemical hydrogen generation by splitting seawater[J]. Chemistry A European Journal, 2018, 24(69): 18455-18462.
9	Wang H L, Zhang L S, Chen Z G, et al. Semiconductor heterojunction photocatalysts: design, construction, and photocatalytic performances[J]. Chemical Society Reviews, 2014, 43(15): 5234.
10	Wang Z, Li C, Domen K. Recent developments in heterogeneous photocatalysts for solar-driven overall water splitting[J]. Chemical Society Reviews, 2019, 48(7): 2109-2125.
11	Kudo A, Miseki Y. Heterogeneous photocatalyst materials for water splitting[J]. Chemical Society Reviews, 2009, 38(1): 253-278.
12	Gust D, Moore T A, Moore A L. Solar fuels via artificial photosynthesis[J]. Accounts of Chemical Research, 2009, 42(12): 1890-1898.
13	Ma R, Sun J, Li D H, et al. Review of synergistic photo-thermo-catalysis: mechanisms, materials and applications[J]. International Journal of Hydrogen Energy, 2020, 45(55): 30288-30324.
14	Chen X B, Liu L, Yu P Y, et al. Increasing solar absorption for photocatalysis with black hydrogenated titanium dioxide nanocrystals[J]. Science, 2011, 331(6018): 746-750.
15	Yang X Y, Hu Z C, Yin Q W, et al. Water-soluble conjugated molecule for solar-driven hydrogen evolution from salt water[J]. Advanced Functional Materials, 2019, 29(13): 1808156.
16	Ma R, Sun J, Li D H, et al. Exponentially self-promoted hydrogen evolution by uni-source photo-thermal synergism in concentrating photocatalysis on co-catalyst-free P25 TiO₂ [J]. Journal of Catalysis, 2020, 392: 165-174.
17	Zhang Z Y, Wang Z L, An K, et al. Ti³⁺ tuning the ratio of Cu⁺/Cu⁰ in the ultrafine Cu nanoparticles for boosting the hydrogenation reaction[J]. Small, 2021, 17(23): 2008052.
18	Wang L, Duan S H, Jin P X, et al. Anchored Cu(Ⅱ) tetra(4-carboxylphenyl)porphyrin to P25 (TiO₂) for efficient photocatalytic ability in CO₂ reduction[J]. Applied Catalysis B: Environmental, 2018, 239: 599-608..
19	Zhang P Y, Song T, Wang T T, et al. Plasmonic Cu nanoparticle on reduced graphene oxide nanosheet support: an efficient photocatalyst for improvement of near-infrared photocatalytic H₂ evolution[J]. Applied Catalysis B: Environmental, 2018, 225: 172-179.
20	Sadanandam G, Luo X, Chen X X, et al. Cu oxide quantum dots loaded TiO₂ nanosheet photocatalyst for highly efficient and robust hydrogen generation[J]. Applied Surface Science, 2021, 541: 148687.
21	Li L X, Zhang J P. Highly salt-resistant and all-weather solar-driven interfacial evaporators with photothermal and electrothermal effects based on Janus graphene@silicone sponges[J]. Nano Energy, 2021, 81: 105682.
22	DeSario P A, Pitman C L, Delia D J, et al. Low-temperature CO oxidation at persistent low-valent Cu nanoparticles on TiO₂ aerogels[J]. Applied Catalysis B: Environmental, 2019, 252: 205-213.
23	Linic S, Christopher P, Ingram D B. Plasmonic-metal nanostructures for efficient conversion of solar to chemical energy[J]. Nature Materials, 2011, 10(12): 911-921.
24	Marimuthu A, Zhang J W, Linic S. Tuning selectivity in propylene epoxidation by plasmon mediated photo-switching of Cu oxidation state[J]. Science, 2013, 339(6127): 1590-1593.
25	Kale M J, Avanesian T, Xin H L, et al. Controlling catalytic selectivity on metal nanoparticles by direct photoexcitation of adsorbate-metal bonds[J]. Nano Letters, 2014, 14(9): 5405-5412.
26	Wang M, Zhang L, Huang M R, et al. Morphology-controlled tantalum diselenide structures as self-optimizing hydrogen evolution catalysts[J]. Energy & Environmental Materials, 2020, 3(1): 12-18.
27	Wang J, Sun Y C, Fu L J, et al. A defective g-C₃N₄/RGO/TiO₂ composite from hydrogen treatment for enhanced visible-light photocatalytic H₂ production[J]. Nanoscale, 2020, 12(43): 22030-22035.
28	Bai H Y, Liu N, Hao L, et al. Self-floating efficient solar steam generators constructed using super-hydrophilic N, O dual-doped carbon foams from waste polyester[J]. Energy & Environmental Materials, 2021, 0: 1-10.
29	Christopher P, Xin H L, Marimuthu A, et al. Singular characteristics and unique chemical bond activation mechanisms of photocatalytic reactions on plasmonic nanostructures[J]. Nature Materials, 2012, 11(12): 1044-1050.
30	Guo S H, Li X H, Li J, et al. Boosting photocatalytic hydrogen production from water by photothermally induced biphase systems[J]. Nature Communications, 2021, 12: 1343.

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Self-floating high-efficient evaporative catalytic seawater hydrogen production system driven by concentrated solar energy based on Cu/TiO₂/C-Wood composite

基于Cu/TiO₂/C-Wood复合材料的聚光太阳能驱动自漂浮高效海水汽化催化分解制氢体系

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