PDF(2833 KB)
A hybrid fuel cell for water purification and simultaneously electricity generation
Yujun Zhou, Qinghua Ji, Chengzhi Hu, Huijuan Liu, Jiuhui Qu
PDF(2833 KB)
PDF(2833 KB)
A hybrid fuel cell for water purification and simultaneously electricity generation
● A novel hybrid fuel cell (F-HFC) was fabricated.
● Pollutant degradation and synchronous electricity generation occurred in F-HFC.
● BiOCl-NH4PTA photocatalyst greatly improved electron transfer and charge separation.
● Pollutant could act as substrate directly in ambient conditions without pretreatment.
● The mechanism of the F-HFC was proposed and elucidated.
The development of highly efficient energy conversion technologies to extract energy from wastewater is urgently needed, especially in facing of increasing energy and environment burdens. Here, we successfully fabricated a novel hybrid fuel cell with BiOCl-NH4PTA as photocatalyst. The polyoxometalate (NH4PTA) act as the acceptor of photoelectrons and could retard the recombination of photogenerated electrons and holes, which lead to superior photocatalytic degradation. By utilizing BiOCl-NH4PTA as photocatalysts and Pt/C air-cathode, we successfully constructed an electron and mass transfer enhanced photocatalytic hybrid fuel cell with flow-through field (F-HFC). In this novel fuel cell, dyes and biomass could be directly degraded and stable power output could be obtained. About 87 % of dyes could be degraded in 30 min irradiation and nearly 100 % removed within 90 min. The current density could reach up to ~267.1 μA/cm2; with maximum power density (Pmax) of ~16.2 μW/cm2 with Rhodamine B as organic pollutant in F-HFC. The power densities were 9.0 μW/cm2, 12.2 μW/cm2, and 13.9 μW/cm2 when using methyl orange (MO), glucose and starch as substrates, respectively. This hybrid fuel cell with BiOCl-NH4PTA composite fulfills the purpose of decontamination of aqueous organic pollutants and synchronous electricity generation. Moreover, the novel design cell with separated photodegradation unit and the electricity generation unit could bring potential practical application in water purification and energy recovery from wastewater.
Flow-through field / Hybrid fuel cell / Polyoxometalates / Water purification / Electricity generation
| [1] |
BenM’Barek Y, RosserT, SumJ, BlanchardS, VolatronF, IzzetG, SallesR, FizeJ, KoepfM, Chavarotp-KerlidouM.
CrossRef
Google scholar
|
| [2] |
ChengH, HuangB, DaiY. (2014). Engineering BiOX (X = Cl, Br, I) nanostructures for highly efficient photocatalytic applications. Nanoscale, 6( 4): 2009– 2026
CrossRef
Pubmed
Google scholar
|
| [3] |
CuiW, WangH, LiangY, HanB, LiuL, HuJ. (2013). Microwave-assisted synthesis of Ag@AgBr-intercalated K4Nb6O17 composite and enhanced photocatalytic degradation of Rhodamine B under visible light. Chemical Engineering Journal, 230 : 10– 18
CrossRef
Google scholar
|
| [4] |
DiJ, ChenC, ZhuC, JiM, XiaJ, YanC, HaoW, LiS, LiH, LiuZ. (2018). Bismuth vacancy mediated single unit cell Bi2WO6 nanosheets for boosting photocatalytic oxygen evolution. Applied Catalysis B: Environmental, 238 : 119– 125
CrossRef
Google scholar
|
| [5] |
FriedlJ, Holland-CunzM V, CordingF, PfanschillingF L, WillsC, McFarlaneW, SchrickerB, FleckR, WolfschmidtH, StimmingU. (2018). Asymmetric polyoxometalate electrolytes for advanced redox flow batteries. Energy & Environmental Science, 11( 10): 3010– 3018
CrossRef
Google scholar
|
| [6] |
GuZ A, ZhouJ, AnX Q, ChenQ, HuC Z, LiuH J, QuJ H. (2021). A dual-biomimetic photocatalytic fuel cell for efficient electricity generation from degradation of refractory organic pollutants. Applied Catalysis B: Environmental, 298 : 120501– 120511
CrossRef
Google scholar
|
| [7] |
GuanM, XiaoC, ZhangJ, FanS, AnR, ChengQ, XieJ, ZhouM, YeB, XieY. (2013). Vacancy associates promoting solar-driven photocatalytic activity of ultrathin bismuth oxychloride nanosheets. Journal of the American Chemical Society, 135( 28): 10411– 10417
CrossRef
Pubmed
Google scholar
|
| [8] |
HeY, ChenK D, LeungM K H, ZhangY Z, LiL, LiG S, XuanJ, LiJ F. (2022). Photocatalytic fuel cell: a review. Chemical Engineering Journal, 428 : 131074– 131092
CrossRef
Google scholar
|
| [9] |
ItoT, InumaruK, MisonoM. (2001). Epitaxially self assembled aggregates of polyoxotungstate nanocrystallites, (NH4)3PW12O40: synthesis by homogeneous precipitation using decomposition of urea. Chemistry of Materials, 13( 3): 824– 831
CrossRef
Google scholar
|
| [10] |
JalilP A, FaizM, TabetM, HamdanN M, HussainZ. (2003). A study of the stability of tungstophosphoric acid, H3PW12O40, using synchrotron XPS, XANES, hexane cracking, XRD, and IR spectroscopy. Journal of Catalysis, 217( 2): 292– 297
CrossRef
Google scholar
|
| [11] |
JiQ, ZhangG, LiuH, LiuR, QuJ. (2019). Field-enhanced nanoconvection accelerated electrocatalytic conversion of water contaminants and electricity generation. Environmental Science & Technology, 53( 5): 2713– 2719
CrossRef
Pubmed
Google scholar
|
| [12] |
KatalR, TanhaeiM, HuJ Y. (2021). Photocatalytic degradation of the acetaminophen by nanocrystal-engineered TiO2 thin film in batch and continuous system. Frontiers of Environmental Science & Engineering, 15( 2): 27
CrossRef
Google scholar
|
| [13] |
LiC, FengY, LiangD, ZhangL, TianY, YadavR S, HeW. (2022). Spatial-type skeleton induced Geobacter enrichment and tailored bio-capacitance of electroactive bioanode for efficient electron transfer in microbial fuel cells. Science of the Total Environment, 821 : 153123– 153134
CrossRef
Pubmed
Google scholar
|
| [14] |
LiM, LiuY, DongL, ShenC, LiF, HuangM, MaC, YangB, AnX, SandW. (2019). Recent advances on photocatalytic fuel cell for environmental applications: the marriage of photocatalysis and fuel cells. Science of the Total Environment, 668 : 966– 978
CrossRef
Pubmed
Google scholar
|
| [15] |
LiQ Y, ZhangL, DaiL, TangH, LiQ, XueH G, PangH. (2018). Polyoxometalate-based materials for advanced electrochemical energy conversion and storage. Chemical Engineering Journal, 351 : 441– 461
CrossRef
Google scholar
|
| [16] |
LiW W, YuH Q, RittmannB E. (2015). Chemistry: reuse water pollutants. Nature, 528( 7580): 29– 31
CrossRef
Pubmed
Google scholar
|
| [17] |
LiuM, WangL, ZhaoK, ShiS, ShaoQ, ZhangL, SunX, ZhaoY, ZhangJ. (2019). Atomically dispersed metal catalysts for the oxygen reduction reaction: synthesis, characterization, reaction mechanisms and electrochemical energy applications. Energy & Environmental Science, 12( 10): 2890– 2923
|
| [18] |
LiuW, GongY, TrickerA, WuG, LiuC, ChaoZ, DengY. (2020). Fundamental study toward improving the performance of a high-moisture biomass-fueled redox flow fuel cell. Industrial & Engineering Chemistry Research, 59( 10): 4817– 4828
CrossRef
Google scholar
|
| [19] |
LiuW, MuW, DengY. (2014a). High-performance liquid-catalyst fuel cell for direct biomass-into-electricity conversion. Angewandte Chemie (International ed. in English), 53( 49): 13558– 13562
CrossRef
Pubmed
Google scholar
|
| [20] |
LiuW, MuW, LiuM, ZhangX, CaiH, DengY. (2014b). Solar-induced direct biomass-to-electricity hybrid fuel cell using polyoxometalates as photocatalyst and charge carrier. Nature Communications, 5( 1): 3208
CrossRef
Pubmed
Google scholar
|
| [21] |
LuL, GuestJ S, PetersC A, ZhuX P, RauG H, RenZ Y. (2018). Wastewater treatment for carbon capture and utilization. Nature Sustainability, 1( 12): 750– 758
CrossRef
Google scholar
|
| [22] |
MohamedM, SalamaT, HegazyM, Abou ShahbaR, MohamedS. (2019). Synthesis of hexagonal WO3 nanocrystals with various morphologies and their enhanced electrocatalytic activities toward hydrogen evolution. International Journal of Hydrogen Energy, 44( 10): 4724– 4736
CrossRef
Google scholar
|
| [23] |
Munoz-CupaC, HuY, XuC, BassiA. (2021). An overview of microbial fuel cell usage in wastewater treatment, resource recovery and energy production. Science of the Total Environment, 754 : 142429– 142450
CrossRef
Pubmed
Google scholar
|
| [24] |
NaseriN, YousefzadehS, DaryaeiE, MoshfeghA Z. (2011). Photo response and H2 production of topographically controlled PEG assisted Sol-gel WO3 nanocrystalline thin films. International Journal of Hydrogen Energy, 36( 21): 13461– 13472
CrossRef
Google scholar
|
| [25] |
ParmarJ, JangS, SolerL, KimD P, SánchezS. (2015). Nano-photocatalysts in microfluidics, energy conversion and environmental applications. Lab on a Chip, 15( 11): 2352– 2356
CrossRef
Pubmed
Google scholar
|
| [26] |
Rengifo-HerreraJ A, BlancoM, WistJ, FlorianP, PizzioL R. (2016). TiO2 modified with polyoxotungstates should induce visible-light absorption and high photocatalytic activity through the formation of surface complexes. Applied Catalysis B: Environmental, 189 : 99– 109
CrossRef
Google scholar
|
| [27] |
SadakaneM, SteckhanE. (1998). Electrochemical properties of polyoxometalates as electrocatalysts. Chemical Reviews, 98( 1): 219– 238
CrossRef
Pubmed
Google scholar
|
| [28] |
ShenZ, LiF, LuJ, WangZ, LiR, ZhangX, ZhangC, WangY, WangY, LvZ, LiuJ, FanC. (2021). Enhanced N2 photofixation activity of flower-like BiOCl by in situ Fe(III) doped as an activation center. Journal of Colloid and Interface Science, 584 : 174– 181
CrossRef
Pubmed
Google scholar
|
| [29] |
SongI K, BarteauM A ( 2004). Redox properties of Keggin-type heteropolyacid (HPA) catalysts: effect of counter-cation, heteroatom, and polyatom substitution. Journal of Molecular Catalysis A, Chemical, 212( 1–2): 229– 236
|
| [30] |
SymesM D, CroninL. (2013). Decoupling hydrogen and oxygen evolution during electrolytic water splitting using an electron-coupled-proton buffer. Nature Chemistry, 5( 5): 403– 409
CrossRef
Pubmed
Google scholar
|
| [31] |
VadivelS, NaveenA N, TheerthagiriJ, MadhavanJ, Santhoshini PriyaT, BalasubramanianN. (2016). Solvothermal synthesis of BiPO4 nanorods/MWCNT (1D-1D) composite for photocatalyst and supercapacitor applications. Ceramics International, 42( 12): 14196– 14205
CrossRef
Google scholar
|
| [32] |
WangH, XieW, YuB, QiB, LiuR, ZhuangX, LiuS, LiuP, DuanJ, ZhouJ. (2021). Simultaneous solar steam and electricity generation from synergistic salinity-temperature gradient. Advanced Energy Materials, 11( 18): 2100481– 2100487
CrossRef
Google scholar
|
| [33] |
WangQ, WangW, ZhongL L, LiuD M, CaoX Z, CuiF Y ( 2018). Oxygen vacancy-rich 2D/2D BiOCl-g-C3N4 ultrathin heterostructure nanosheets for enhanced visible-light-driven photocatalytic activity in environmental remediation . Applied Catalysis B, Environmental, 220: 290– 302
|
| [34] |
WangY, PangY, XuH, MartinezA, ChenK. (2022). PEM Fuel cell and electrolysis cell technologies and hydrogen infrastructure development: a review. Energy & Environmental Science, 15( 6): 2288– 2328
CrossRef
Google scholar
|
| [35] |
XuY, Xu S, WangS, ZhangY, LiG ( 2014). Citric acid modulated electrochemical synthesis and photocatalytic behavior of BiOCl nanoplates with exposed 001 facets. Dalton Transactions (Cambridge, England), 43( 2): 479– 485
Pubmed
|
| [36] |
YangW, DuX, LiuW, TrickerA, DaiH, DengY. (2019a). High efficient lignin depolymerization via effective inhibition of condensation during polyoxometalate mediated oxidation. Energy & Fuels, 33( 7): 6483– 6490
CrossRef
Google scholar
|
| [37] |
YangW, DuX, LiuW, WangZ, DaiH, DengY L. (2019b). Direct valorization of lignocellulosic biomass into value-added chemicals by polyoxometalate catalyzed oxidation under mild conditions. Industrial & Engineering Chemistry Research, 58( 51): 22996– 23004
CrossRef
Google scholar
|
| [38] |
ZengQ, ChangS, BeyhaqiA, WangM, HuC. (2020). Efficient electricity production coupled with water treatment via a highly adaptable, successive water-energy synergistic system. Nano Energy, 67 : 104237– 104247
CrossRef
Google scholar
|
| [39] |
ZhangL, WongK, ChenZ, YuJ, Zhao J, HuC, ChanC, WongP ( 2009). AgBr-Ag-Bi2WO6 nanojunction system: A novel and efficient photocatalyst with double visible-light active components . Applied Catalysis A, General, 363( 1–2): 221– 229
|
| [40] |
ZhangX Y, GuoX G, WangQ Y, ZhangR F, XuT, Liang P, HuangX ( 2020). Iron-based clusters embedded in nitrogen doped activeated carbon catalysts with superior cathodic activity in microbial fuel cells. Journal of Materials Chemistry. A, Materials for Energy and Sustainability, 8( 21): 10772– 10778
|
| [41] |
ZhangX, XiaX, HeW, HuangX, LoganB E. (2017). Addition of conductive particles to improve the performance of activated carbon air-cathodes in microbial fuel cells. Environmental Science. Water Research & Technology, 3( 5): 806– 810
CrossRef
Google scholar
|
| [42] |
ZhengQ, DurkinD P, ElenewskiJ E, SunY, BanekN A, HuaL, ChenH, WagnerM J, ZhangW, ShuaiD. (2016). Visible-light-responsive graphitic carbon nitride: rational design and photocatalytic applications for water treatment. Environmental Science & Technology, 50( 23): 12938– 12948
CrossRef
Pubmed
Google scholar
|
| [43] |
ZhouC Y, LaiC, XuP, ZengG M, HuangD L, ZhangC, ChengM, HuL, WanJ, LiuY, XiongW P, DengY C, WenM. (2018a). In Situ Grown AgI/Bi12O17Cl2 heterojunction photocatalysts for visible light degradation of sulfamethazine: efficiency, pathway, and mechanism. ACS Sustainable Chemistry & Engineering, 6( 3): 4174– 4184
|
| [44] |
ZhouY, JiQ, LiuH, QuJ. (2018b). Pore structure-dependent mass transport in flow-through electrodes for water remediation. Environmental Science & Technology, 52( 13): 7477– 7485
CrossRef
Pubmed
Google scholar
|
| [45] |
ZhouY, ZhangG, JiQ, ZhangW, ZhangJ, LiuH, QuJ. (2019). Enhanced stabilization and effective utilization of atomic hydrogen on Pd-In nanoparticles in a flow-through electrode. Environmental Science & Technology, 53( 19): 11383– 11390
CrossRef
Pubmed
Google scholar
|
| [46] |
ZuX H, SunL L, GongJ, LiuX C, LiuY X, DuX, LiuW, ChenL F, YiG B, ZhangW G.
CrossRef
Google scholar
|
/
| 〈 |
|
〉 |
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