Optofluidic planar reactors for photocatalytic water treatment using solar energy

Lei Lei; Ning Wang; X. M. Zhang; Qidong Tai; Din Ping Tsai; Helen L. W. Chan

doi:10.1063/1.3491471

Optofluidic planar reactors for photocatalytic water treatment using solar energy

Lei Lei
, Ning Wang
, X. M. Zhang^*
, Qidong Tai
, Din Ping Tsai
, Helen L. W. Chan

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

Abstract

Optofluidics may hold the key to greater success of photocatalytic water treatment. This is evidenced by our findings in this paper that the planar microfluidic reactor can overcome the limitations of mass transfer and photon transfer in the previous photocatalytic reactors and improve the photoreaction efficiency by more than 100 times. The microreactor has a planar chamber (5 cm × 1.8 cm × 100 μm) enclosed by two TiO₂-coated glass slides as the top cover and bottom substrate and a microstructured UV-cured NOA81 layer as the sealant and flow input∕output. In experiment, the microreactor achieves 30% degradation of 3 ml 3×10⁻⁵M methylene blue within 5 min and shows a reaction rate constant two orders higher than the bulk reactor. Under optimized conditions, a reaction rate of 8% s⁻¹ is achieved under solar irradiation. The average apparent quantum efficiency is found to be only 0.25%, but the effective apparent quantum efficiency reaches as high as 25%. Optofluidic reactors inherit the merits of microfluidics, such as large surface∕volume ratio, easy flow control, and rapid fabrication and offer a promising prospect for large-volume photocatalytic water treatment.

© 2010 American Institute of Physics.

Original language	English
Article number	043004
Journal	Biomicrofluidics
Volume	4
Issue number	4
Online published	30 Dec 2010
DOIs	https://doi.org/10.1063/1.3491471
Publication status	Published - Dec 2010
Externally published	Yes

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title = "Optofluidic planar reactors for photocatalytic water treatment using solar energy",

abstract = "Optofluidics may hold the key to greater success of photocatalytic water treatment. This is evidenced by our findings in this paper that the planar microfluidic reactor can overcome the limitations of mass transfer and photon transfer in the previous photocatalytic reactors and improve the photoreaction efficiency by more than 100 times. The microreactor has a planar chamber (5 cm × 1.8 cm × 100 μm) enclosed by two TiO2-coated glass slides as the top cover and bottom substrate and a microstructured UV-cured NOA81 layer as the sealant and flow input∕output. In experiment, the microreactor achieves 30\% degradation of 3 ml 3×10−5M methylene blue within 5 min and shows a reaction rate constant two orders higher than the bulk reactor. Under optimized conditions, a reaction rate of 8\% s−1 is achieved under solar irradiation. The average apparent quantum efficiency is found to be only 0.25\%, but the effective apparent quantum efficiency reaches as high as 25\%. Optofluidic reactors inherit the merits of microfluidics, such as large surface∕volume ratio, easy flow control, and rapid fabrication and offer a promising prospect for large-volume photocatalytic water treatment. {\textcopyright} 2010 American Institute of Physics.",

author = "Lei Lei and Ning Wang and Zhang, \{X. M.\} and Qidong Tai and Tsai, \{Din Ping\} and Chan, \{Helen L. W.\}",

year = "2010",

month = dec,

doi = "10.1063/1.3491471",

language = "English",

volume = "4",

journal = "Biomicrofluidics",

issn = "1932-1058",

publisher = "American Institute of Physics",

number = "4",

}

TY - JOUR

T1 - Optofluidic planar reactors for photocatalytic water treatment using solar energy

AU - Lei, Lei

AU - Wang, Ning

AU - Zhang, X. M.

AU - Tai, Qidong

AU - Tsai, Din Ping

AU - Chan, Helen L. W.

PY - 2010/12

Y1 - 2010/12

N2 - Optofluidics may hold the key to greater success of photocatalytic water treatment. This is evidenced by our findings in this paper that the planar microfluidic reactor can overcome the limitations of mass transfer and photon transfer in the previous photocatalytic reactors and improve the photoreaction efficiency by more than 100 times. The microreactor has a planar chamber (5 cm × 1.8 cm × 100 μm) enclosed by two TiO2-coated glass slides as the top cover and bottom substrate and a microstructured UV-cured NOA81 layer as the sealant and flow input∕output. In experiment, the microreactor achieves 30% degradation of 3 ml 3×10−5M methylene blue within 5 min and shows a reaction rate constant two orders higher than the bulk reactor. Under optimized conditions, a reaction rate of 8% s−1 is achieved under solar irradiation. The average apparent quantum efficiency is found to be only 0.25%, but the effective apparent quantum efficiency reaches as high as 25%. Optofluidic reactors inherit the merits of microfluidics, such as large surface∕volume ratio, easy flow control, and rapid fabrication and offer a promising prospect for large-volume photocatalytic water treatment. © 2010 American Institute of Physics.

AB - Optofluidics may hold the key to greater success of photocatalytic water treatment. This is evidenced by our findings in this paper that the planar microfluidic reactor can overcome the limitations of mass transfer and photon transfer in the previous photocatalytic reactors and improve the photoreaction efficiency by more than 100 times. The microreactor has a planar chamber (5 cm × 1.8 cm × 100 μm) enclosed by two TiO2-coated glass slides as the top cover and bottom substrate and a microstructured UV-cured NOA81 layer as the sealant and flow input∕output. In experiment, the microreactor achieves 30% degradation of 3 ml 3×10−5M methylene blue within 5 min and shows a reaction rate constant two orders higher than the bulk reactor. Under optimized conditions, a reaction rate of 8% s−1 is achieved under solar irradiation. The average apparent quantum efficiency is found to be only 0.25%, but the effective apparent quantum efficiency reaches as high as 25%. Optofluidic reactors inherit the merits of microfluidics, such as large surface∕volume ratio, easy flow control, and rapid fabrication and offer a promising prospect for large-volume photocatalytic water treatment. © 2010 American Institute of Physics.

U2 - 10.1063/1.3491471

DO - 10.1063/1.3491471

M3 - RGC 21 - Publication in refereed journal

C2 - 21267436

SN - 1932-1058

VL - 4

JO - Biomicrofluidics

JF - Biomicrofluidics

IS - 4

M1 - 043004

ER -

Optofluidic planar reactors for photocatalytic water treatment using solar energy

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