Literature DB >> 18405911

The terminal rise velocity of 10-100 microm diameter bubbles in water.

Luke Parkinson1, Rossen Sedev, Daniel Fornasiero, John Ralston.   

Abstract

Single bubbles of very pure N2, He, air and CO2 were formed in a quiescent environment in ultra-clean water, with diameters ranging from 10 to 100 mum. Their terminal rise velocities were measured by high-speed video microscopy. For N2, He and air, excellent agreement with the Hadamard-Rybczynski (H-R) equation was observed, indicating that slip was occurring at the liquid-vapor interface. For CO2 bubbles with diameters less than 60 microm, the terminal rise velocities exceeded those predicted by the H-R equation. This effect was ascribed to the enhanced solubility of CO2 compared with the other gases examined. The presence of a diffusion boundary layer may be responsible for the increased terminal velocity of very small CO2 bubbles.

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Year:  2008        PMID: 18405911     DOI: 10.1016/j.jcis.2008.02.072

Source DB:  PubMed          Journal:  J Colloid Interface Sci        ISSN: 0021-9797            Impact factor:   8.128


  9 in total

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Journal:  Proc Natl Acad Sci U S A       Date:  2010-06-07       Impact factor: 11.205

2.  A stepwise mechanism for aqueous two-phase system formation in concentrated antibody solutions.

Authors:  Bradley A Rogers; Kelvin B Rembert; Matthew F Poyton; Halil I Okur; Amanda R Kale; Tinglu Yang; Jifeng Zhang; Paul S Cremer
Journal:  Proc Natl Acad Sci U S A       Date:  2019-07-23       Impact factor: 11.205

3.  The bubble-induced population dynamics of fermenting yeasts.

Authors:  Atul Srivastava; Kenji Kikuchi; Takuji Ishikawa
Journal:  J R Soc Interface       Date:  2020-11-18       Impact factor: 4.118

4.  Effect of disjoining pressure on terminal velocity of a bubble sliding along an inclined wall.

Authors:  Lorena A Del Castillo; Satomi Ohnishi; Lee R White; Steven L Carnie; Roger G Horn
Journal:  J Colloid Interface Sci       Date:  2011-08-26       Impact factor: 8.128

5.  Generation and Stability of Size-Adjustable Bulk Nanobubbles Based on Periodic Pressure Change.

Authors:  Qiaozhi Wang; Hui Zhao; Na Qi; Yan Qin; Xuejie Zhang; Ying Li
Journal:  Sci Rep       Date:  2019-02-04       Impact factor: 4.379

6.  Mobile-surface bubbles and droplets coalesce faster but bounce stronger.

Authors:  Ivan U Vakarelski; Fan Yang; Yuan Si Tian; Er Qiang Li; Derek Y C Chan; Sigurdur T Thoroddsen
Journal:  Sci Adv       Date:  2019-10-25       Impact factor: 14.136

7.  Toward Precisely Controllable Acoustic Response of Shell-Stabilized Nanobubbles: High Yield and Narrow Dispersity.

Authors:  Amin Jafari Sojahrood; Al C de Leon; Richard Lee; Michaela Cooley; Eric C Abenojar; Michael C Kolios; Agata A Exner
Journal:  ACS Nano       Date:  2021-03-08       Impact factor: 15.881

8.  Microbubble enhanced mass transfer efficiency of CO2 capture utilizing aqueous triethanolamine for enzymatic resorcinol carboxylation.

Authors:  Daniel Ohde; Benjamin Thomas; Simon Matthes; Shunya Tanaka; Paul Bubenheim; Koichi Terasaka; Michael Schlüter; Andreas Liese
Journal:  RSC Adv       Date:  2021-01-20       Impact factor: 3.361

9.  Magnetic phase separation in microgravity.

Authors:  Álvaro Romero-Calvo; Ömer Akay; Hanspeter Schaub; Katharina Brinkert
Journal:  NPJ Microgravity       Date:  2022-08-08       Impact factor: 4.970
  9 in total

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