CO2 Microbubbles in Silicone Oil (Part II: Henry’s Constant and Anomalous Diffusion)

IF 3.7 2区 化学 Q2 CHEMISTRY, MULTIDISCIPLINARY
A. D’Onofrio, V. M. Freytes
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Abstract

This work demonstrates the utility of microfluidic devices for characterizing diffusion mechanisms. We determined Henry’s constant and characterized the diffusion process of gaseous CO2 in silicone oil. Using microfluidic techniques, we analyzed the evolution of the CO2 bubble size in a solvent flowing through a microchannel system. The reduction in bubble size due to the mass transfer of gaseous CO2 into the solvent fluid primarily affects their length. A microfluidic device was used to produce bubbles, consisting of a pressure-driven injection system for the gas and a flow-driven system for the liquid. Additionally, an optical device was coupled for tracking and studying the bubbles in the microchannels, enabling us to study their spatial and temporal evolution using image analysis. From this study, we found two diffusion regimes. The first is a superdiffusive process for short times. In this regime, due to the high concentration gradient values at the gas–liquid interface, we observed a higher rate of carbon dioxide transfer to the silicone oil. At longer times, we see that the gas transfer rate significantly decreases compared to the previous regime, leading to a subdiffusive process. In this latter regime, it was found that if we increase the gas pressure, the system approaches a normal diffusive process that coincides with previously conducted studies by other researchers. It is suggested that the subdiffusion could be due to the high degree of confinement of the bubbles within the microchannel, similar to what occurs in porous media, the high viscosity of the fluid, and the low gas pressure used in the tests. The microfluidic device proved to be a very efficient method for determining the diffusion process and Henry’s constant in this case. Its easy fabrication and low cost make this type of device appropriate for substance characterization.

Abstract Image

硅油中的二氧化碳微气泡(第二部分:亨利常数和反常扩散)
这项工作证明了微流体设备在表征扩散机制方面的实用性。我们测定了亨利常数,并描述了气态二氧化碳在硅油中的扩散过程。利用微流体技术,我们分析了流经微通道系统的溶剂中二氧化碳气泡大小的变化。气态二氧化碳向溶剂流体的传质导致气泡尺寸减小,这主要影响了气泡的长度。产生气泡的微流控装置由气体的压力驱动注入系统和液体的流动驱动系统组成。此外,我们还耦合了一个光学装置,用于跟踪和研究微通道中的气泡,从而能够利用图像分析来研究气泡的空间和时间演变。通过这项研究,我们发现了两种扩散机制。第一种是短时间内的超扩散过程。在这种情况下,由于气液界面的浓度梯度值较高,我们观察到二氧化碳向硅油的转移率较高。在较长的时间内,我们发现气体转移率与前一阶段相比明显下降,从而导致亚扩散过程。在后一种情况下,我们发现如果增加气体压力,系统就会接近正常的扩散过程,这与其他研究人员之前进行的研究不谋而合。据认为,亚扩散可能是由于微通道内气泡的高度封闭(类似于多孔介质中的情况)、流体的高粘度以及试验中使用的低气压造成的。在这种情况下,微流控装置被证明是测定扩散过程和亨利常数的一种非常有效的方法。这种装置易于制造且成本低廉,因此非常适合物质表征。
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来源期刊
Langmuir
Langmuir 化学-材料科学:综合
CiteScore
6.50
自引率
10.30%
发文量
1464
审稿时长
2.1 months
期刊介绍: Langmuir is an interdisciplinary journal publishing articles in the following subject categories: Colloids: surfactants and self-assembly, dispersions, emulsions, foams Interfaces: adsorption, reactions, films, forces Biological Interfaces: biocolloids, biomolecular and biomimetic materials Materials: nano- and mesostructured materials, polymers, gels, liquid crystals Electrochemistry: interfacial charge transfer, charge transport, electrocatalysis, electrokinetic phenomena, bioelectrochemistry Devices and Applications: sensors, fluidics, patterning, catalysis, photonic crystals However, when high-impact, original work is submitted that does not fit within the above categories, decisions to accept or decline such papers will be based on one criteria: What Would Irving Do? Langmuir ranks #2 in citations out of 136 journals in the category of Physical Chemistry with 113,157 total citations. The journal received an Impact Factor of 4.384*. This journal is also indexed in the categories of Materials Science (ranked #1) and Multidisciplinary Chemistry (ranked #5).
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