5 research outputs found
Microfluidics for environmental analysis
2018 Summer.Includes bibliographical references.During my graduate dissertation work I designed and utilized microfluidic devices to study, model, and assess environmental systems. Investigation of environmental systems is important for areas of industry, agriculture, and human health. While effective and well-established, traditional methods to perform environmental assessment typically involve instrumentation that is expensive and has limited portability. Because of this, analysis of environmental systems can have considerable financial burden and be limited to laboratory settings. To overcome the limitations of traditional methods researchers have turned to microfluidic devices to perform environmental analyses. Microfluidics function as a versatile, inexpensive, and rapidly prototyped analytical tool that can achieve analysis in field setting with limited infrastructure; furthermore, microfluidic devices can also be used to study fundamental chemistry or model complex environmental systems. Given the advantages of microfluidic devices, the research presented herein was accomplished using this alternative to traditional instrumentation. The research projects described in this dissertation involve: 1) the study of fundamental chemistry associated with surfactant surface fouling facilitated by divalent metal cations; 2) the creation of a microfluidic device to study fluid interactions within an oil reservoir; and 3) the fabrication of a paper-based microfluidic to selectively quantify K+ in complex samples. The first research topic discussed involves observation of dynamic evidence that supports the hypothesized cation bridging phenomenon. Experimental results were acquired by pairing traditional microfluidics with the current monitoring method to observe relative changes to a charged surface's zeta potential. Divalent metal cations were found to increase surfactant adsorption, and cations of increasing charge density were found to have a greater effect on surface charge. Analysis of the experimental data further supports theoretical cation bridging models and expands on knowledge relating to the mechanism by which surfactant adsorption occurs. This work was published in the ACS journal Langmuir (2018, 34 (4), pp 1550–1556). The second project discussed herein focuses on the development of the microfluidic Flow On Rock Device (FORD) that was designed to study fluid interactions within complex media. The FORD was designed to be an alternative to existing fluid modeling methods and microfluidic devices that test oil recovery strategies. Fabrication of the FORD was accomplished by incorporating real reservoir rock core samples into the device. The novelty of this device is due to the simplicity and accuracy by which the physical and chemical characteristics are represented. This project has been accepted for publication pending minor revisions in Microfluidics and Nanofluidics. The final project discussed the creation of the first non-electrochemical microfluidic paper-based analytical device (µPAD) capable of quantitatively measuring alkali or alkaline earth metals using K+ as a model analyte. This device was fabricated by combining distance-based analytical quantification in µPADs with optode nanosensors. Experimental results were obtained using the naked eye without the requirement of a power source or external hardware. The resulting distance-based µPAD showed high selectivity and the capacity to quantify K+ in real undiluted human serum samples. This work has been published in the ACS journal Analytical Chemistry (2018, 90 (7), pp 4894–4900). The research projects briefly described above and thoroughly discussed later within this dissertation were made possible by the utilization of microfluidic devices. These projects investigated various aspects of environmental chemistry without the use of traditional instrumentation or methods. The experimental results that were obtained further the fundamental understanding of surfactant adsorption, provide an inexpensive and accurate model to observe fluid interactions within reservoir rock material, and allow for the selective quantification of K+ in a paper-based device without the use of a power source. The funding for each of these projects was supplied by BP plc and Global Good, as is mentioned accordingly within this dissertation
Observation of Dynamic Surfactant Adsorption Facilitated by Divalent Cation Bridging
Dynamic
evidence of the mechanism for surfactant adsorption to
surfaces of like charge has been observed. Additionally, removal and
retention of surfactant molecules on the surface were observed as
a function of time. A decrease in surface charge is observed when
metal counterions are introduced and is dependent on charge density
as well as valency of the metal ion. When surfactant species are also
present with the metals, a dramatic increase in surface charge arises.
We observed that the rate and quantity of surfactant adsorption can
be controlled by the presence of divalent Ca<sup>2+</sup>. Under isotonic
conditions the introduction of Ca<sup>2+</sup> is also easily distinguishable
from that of monovalent Na<sup>+</sup> and provides dynamic evidence
of the divalent “cation bridging” phenomenon. Dynamic
changes to surface charge are experimentally determined by utilizing
current monitoring to quantify the zeta potential in a microfluidic
device
Selective Distance-Based K<sup>+</sup> Quantification on Paper-Based Microfluidics
In
this study, paper-based microfluidic devices (μPADs) capable
of K<sup>+</sup> quantification in aqueous samples, as well as in
human serum, using both colorimetric and distance-based methods are
described. A lipophilic phase containing potassium ionophore I (valinomycin)
was utilized to achieve highly selective quantification of K<sup>+</sup> in the presence of Na<sup>+</sup>, Li<sup>+</sup>, and Mg<sup>2+</sup> ions. Successful addition of a suspended lipophilic phase to a wax
printed paper-based device is described and offers a solution to current
approaches that rely on organic solvents, which damage wax barriers.
The approach provides an avenue for future alkali/alkaline quantification
utilizing μPADs. Colorimetric spot tests allowed for K<sup>+</sup> quantification from 0.1–5.0 mM using only 3.00 μL of
sample solution. Selective distance-based quantification required
small sample volumes (6.00 μL) and gave responses sensitive
enough to distinguish between 1.0 and 2.5 mM of sample K<sup>+</sup>. μPADs using distance-based methods were also capable of differentiating
between 4.3 and 6.9 mM K<sup>+</sup> in human serum samples. Distance-based
methods required no digital analysis, electronic hardware, or pumps;
any steps required for quantification could be carried out using the
naked eye