New insights into the physics of inertial microfluidics in curved microchannels. I. Relaxing the fixed inflection point assumption
Rafeie M., Hosseinzadeh S., Taylor R. A., Ibragimi V. M. M.
Biomicrofluidics
Vol.13, Issue3, Num.034117
Опубликовано: 2019
Тип ресурса: Статья
Аннотация:
Inertial microfluidics represents a powerful new tool for accurately positioning cells and microparticles within fluids for a variety of biomedical, clinical, and industrial applications. In spite of enormous advancements in the science and design of these devices, particularly in curved microfluidic channels, contradictory experimental results have confounded researchers and limited progress. Thus, at present, a complete theory which describes the underlying physics is lacking. We propose that this bottleneck is due to one simple mistaken assumption - the locations of inflection points of the Dean velocity profile in curved microchannels are not fixed, but can actually shift with the flow rate. Herein, we propose that the dynamic distance (δ) between the real equilibrium positions and their nearest inflection points can clearly explain several (previously) unexplained phenomena in inertial microfluidic systems. More interestingly, we found that this parameter, δ, is a function of seve
Ключевые слова:
Fluidic devices; Microchannels; Curved microchannel; Equilibrium positions; Inertial microfluidics; Inflection points; Micro-particles; Microfluidic channel; Operational parameters; Velocity profiles; Microfluidics
Язык текста: Английский
ISSN: 1932-1058
Rafeie M.
Hosseinzadeh S.
Taylor R. A.
Ibragimi V. M. M. Varkiani Madzhid Modzhtaba 1983-
Рафеие М.
Хоссеинзадех С.
Тайлор Р. А.
Ибрагими В. М. М. Варкиани Маджид Моджтаба 1983-
New insights into the physics of inertial microfluidics in curved microchannels. I. Relaxing the fixed inflection point assumption
Текст визуальный непосредственный
Biomicrofluidics
American Institute of Physics
Vol.13, Issue3 Num.034117
2019
Статья
Fluidic devices Microchannels Curved microchannel Equilibrium positions Inertial microfluidics Inflection points Micro-particles Microfluidic channel Operational parameters Velocity profiles Microfluidics
Inertial microfluidics represents a powerful new tool for accurately positioning cells and microparticles within fluids for a variety of biomedical, clinical, and industrial applications. In spite of enormous advancements in the science and design of these devices, particularly in curved microfluidic channels, contradictory experimental results have confounded researchers and limited progress. Thus, at present, a complete theory which describes the underlying physics is lacking. We propose that this bottleneck is due to one simple mistaken assumption - the locations of inflection points of the Dean velocity profile in curved microchannels are not fixed, but can actually shift with the flow rate. Herein, we propose that the dynamic distance (δ) between the real equilibrium positions and their nearest inflection points can clearly explain several (previously) unexplained phenomena in inertial microfluidic systems. More interestingly, we found that this parameter, δ, is a function of seve