[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.4491/eer.2016.028

Extent and persistence of dissolved oxygen enhancement using nanobubbles

Tekile, Andinet (Construction Environment Engineering Department, University of Science and Technology)
Kim, Ilho (Construction Environment Engineering Department, University of Science and Technology)
Lee, Jai-Yeop (Korea Institute of Civil Engineering and Building Technology)

Publication Information

Environmental Engineering Research / v.21, no.4, 2016 , pp. 427-435 More about this Journal

Abstract

In this study, change in water-dissolved oxygen (DO) was analyzed under various synthetic water qualities and nanobubbles (NBs) application conditions, such as gas type, initial DO as well as water dissolved, suspended and organic matters contents. When oxygen, rather than air, was introduced into nitrogen-desorbed ultra-pure water, the stagnation time was significantly increased. It took ten days for DO concentration to drop back to saturation. The higher the initial DO concentration, the longer particles were observed above saturation due to particle stability improvement. The oxygen mass transfer rate of 0.0482 mg/L/min was found to reach a maximum at an electrolytic concentration of 0.75 g/L, beyond which the transfer rate decreased due to adsorption of negative ions of the electrolyte at the interface. High levels of turbidity caused by suspended solids have become a barrier to dissolution of NBs oxygen into the water solution, and thus affected the transfer performance. On the other hand, by applying NBs for just an hour, up to 7.2% degradation of glucose as representative organic matter was achieved. Thus, NBs technology would maintain a high DO extent for an extended duration, and thus can improve water quality provided that water chemistry is closely monitored during its application.

Keywords

Application conditions; Dissolved oxygen; Nanobubbles; Water quality;

Citations & Related Records

Reference

1	Michioku K, Sakatani Y, Matsuo K, Oda T, Hara Y. Reservoir purification by using micro-bubble aerator. In: 7th International Conference on Hydroscience and Engineering (ICHE); 10-13 September 2006; Philadelphia, USA.
2	Srithongouthai S, Endo A, Inoue A, et al. Control of dissolved oxygen levels of water in net pens for fish farming by a microscopic bubble generating system. Fisheries Sci. 2006;72:485-493. DOI
3	Li P, Takahashi M, Chiba K. Degradation of phenol by the collapse of microbubbles. Chemosphere 2009;75:1371-1375. DOI
4	Kim KH, Lee KH, Adachi Y, Pyun CK. Field investigation of water purification technique in the lagoon. In: 6th International Conference on Offshore and Polar Engineering; 28 May-2 June 2006; California, USA.
5	Burns SE, Yiacoumi S, Tsouris C. Microbubble generation for environmental and industrial separations. Sep. Purif. Technol. 1997;11:221-232. DOI
6	Takahashi M. Nanobubbles: An introduction. In: Tsuge H, ed. Micro- and nanobubbles: Fundamentals and applications. Singapore: Pan Stanford Publishing; 2014. p. 307-315.
7	Calgaroto S, Wilberg KQ, Rubio J. On the nanobubbles interfacial properties and future applications in flotation. Miner. Eng. 2014;60:33-40. DOI
8	Agarwal A, Ng WJ, Liu Y. Principle and applications of microbubble and nanobubble technology for water treatment. Chemosphere 2011;84:1175-1180. DOI
9	Cho SH, Kim JY, Chun JH, Kim JD. Ultrasonic formation of nanobubbles and their zeta-potentials in aqueous electrolyte and surfactant solutions. Colloid. Surface. A. 2005;269:28-34. DOI
10	Kikuchi K, Ioka A, Oku T, Tanaka Y, Saihara Y, Ogumi Z. Concentration determination of oxygen nanobubbles in electrolyzed water. J. Colloid Interf. Sci. 2009;329:306-309. DOI
11	Yount, DE. On the elastic properties of the interfaces that stabilize gas cavitation nuclei. J. Colloid Interf. Sci. 1997;193:50-59. DOI
12	Ushikubo FY, Furukawa T, Nakagawa R, et al. Evidence of the existence and the stability of nano-bubbles in water. Colloid. Surface. A. 2010;361:31-37. DOI
13	Wu C, Nesset N, Masliyah J, Xu Z. Generation and characterization of submicron size bubbles. Adv. Colloid Interf. Sci. 2012;179-182:123-132. DOI
14	Najafi AS, Drelich J, Yeung A, Xu Z, Masliyah J. A novel method of measuring electrophoretic mobility of gas bubbles. J. Colloid Interf. Sci. 2007;308:344-350. DOI
15	Hampton MA, Nguyen AV. Nanobubbles and the nanobubble bridging capillary force. Adv. Colloid Interf. Sci. 2010;154:30-55. DOI
16	Jiang P. Gas transfer parameter estimation: Applications and implications of classical assumptions [dissertation]. USA: Univ. of California; 2010.
17	Uchida T, Oshita S, Ohmori M, et al. Transmission electron microscopic observations of nanobubbles and their capture of impurities in wastewater. Nanoscale Res. Lett. 2011;6:295. DOI
18	Muroyama K., Imai K, Oka Y, Hayashi J. Mass transfer properties in a bubble column associated with micro-bubble dispersions. Chem. Eng. Sci. 2013;100:464-473. DOI
19	Sadatomi M, Kawahara A, Matsuura H, Shikatani S. Micro-bubble generation rate and bubble dissolution rate into water by a simple multi-fluid mixer with orifice and porous tube. Exp. Therm. Fluid Sci. 2012;41:23-30. DOI
20	He Y. An alternative mathematical model for oxygen transfer evaluation in clean water. Case Study; c2014 [cited 20 June 2014]. Available from: http://www.wateronline.com/doc/an-alternative-mathematical-model-for-oxygen-transfer.
21	Leu HG, Lin SH, Shyu CC, Lin CM. Effects of surfactants and suspended solids on oxygen transfer under various operating conditions. Environ. Technol. 1998;19:299-306. DOI
22	Kawahara A, Sadatomi M, Matsuyama F, Matsuura H, Tominaga M, Noguchi M. Prediction of micro-bubble dissolution characteristics in water and seawater. Exp. Therm. Fluid Sci. 2009;33: 883-894. DOI
23	Li H, Hu L, Song D, Al-Tabbaa A. Subsurface transport behavior of micro-nano bubbles and potential applications for groundwater remediation. Int. J. Environ. Res. Public Health 2014;11: 473-486.
24	Ljunggren S, Eriksson JC. The lifetime of a colloid-sized gas bubble in water and the cause of hydrophobic attraction. Colloid. Surface. A. 1997;129-130:151-155. DOI
25	Takahashi M, Li P. Base and technological application of micro-bubble and nanobubble. J. Phys. Chem. 2009;22:2-19.
26	Ghadimkhani A, Zhang W, Marhaba T. Ceramic membrane defouling (cleaning) by air nano bubbles. Chemosphere 2016;146:379-384. DOI
27	Riser-Roberts E. Remediation of petroleum contaminated soils; biological, physical and chemical processes. USA: Lewis publishers; 1998.
28	Li H, Hu L, Xia Z. Impact of groundwater salinity on bioremediation enhanced by micro-nano bubbles. Materials 2013;6:3676-3687. DOI

Reference

2	(2020) Environmental engineering research Simultaneous nitrification and denitrification by using ejector type microbubble generator in a single reactor / 25 (2) , 251
11	(2016) Analytical sciences : The International Journal of the Japan Society for Analytical Chemistry Optimization of Procedure for Determining Dissolved Oxygen in Surface Water and Seawater Exploiting the UV-vis Absorption of Mn(III) Species / 37 (11) , 1517
1	(2016) Ingeniería Study of the Influence of Clays on the Transfer of Dissolved Oxygen in Water / 26 (1) , 5
no.pb	(2016) Journal of environmental management Using oxygen/ozone nanobubbles for in situ oxidation of dissolved hydrogen sulfide at a residential tunnel-construction site / 302 (no.pb) , 114068
None	(2022) The Science of the total environment Enhancing sulfide mitigation via the sustainable supply of oxygen from air-nanobubbles in gravity sewers / 808 (None) , 152203
None	(2016) Journal of colloid and interface science Aeration and dissolution behavior of oxygen nanobubbles in water / 609 (None) , 584