Final published version, 32.6 MB, PDF document
Available under license: CC BY-NC-ND: Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License
Research output: Thesis › Doctoral Thesis
Research output: Thesis › Doctoral Thesis
}
TY - BOOK
T1 - Optimised self-calibrating microfluidic systems towards design optimisation
AU - Quane, Nile
PY - 2022/4/24
Y1 - 2022/4/24
N2 - Clean water is a finite resource, and the quality of such is best monitored by colorimetric in-situ sensors, which allow frequent, non-labour intensive sampling, and are low-cost and simple to manufacture. There are multiple types of sensors that exist in the literature, however, many are cost-prohibitive for wide deployment, or the literature does not not fully elaborate on their operation. The aim of this research was to extend the lifetime and improve the performance of a colorimetric in-situ sensor, Aquamonitrix colorimetric sensor, that was produced by T.E. Laboratories, in addition to characterising sensor behaviour. Its operation was focused on the Griess reaction, in which a vivid azo dye is produced in the presence of nitrite, that can be linearly calibrated to the absorbance by the dye from a photodectector placed at the opposite end of a microfluidic detector channelto a monochromatic light source. Using multiobjective optimisation on a numerical model of a Y-junction micromixer, it was found that both sensitivity could be increased and reagent could be conserved, by limiting the proportion of reagent used during testing to 5% to 7.5% of testing solution, as opposed to the 50% originally used by the system.The conservation of the reagent allowed for an increased sensor deployment lifetimeof up to tenfold. To better understand how the parameters of analyte concentration, reagentproportion of test solution, and mean flow velocity of the solution affect sensoroutput, both mechanistic and data-based modelling of the continuous and stopped flowstages of the sensor were undertaken. Third-order and second-order models were identifiedfor the continuous and stopped flow data respectively. The second-order model isanalagous to the two-step Griess reaction, of which there is a first, faster step. Furthercharacterisation of the zeroes, poles and transfer function coefficients of the third ordermodels showed that parameterisation was possible and, using principal componentanalysis, reduction of parameters. Other testing on the effects of order of cycles, turbidityand heavy metals was also conducted to measure their impact on sensor output.Carryover between sensor cycles was found to be the most interfering factor on sensoroutput, due to the microfluidic connector components, which was eliminated after eightcycles. Overall, the performance and efficiency of the existing sensor was improved,iiiand the methodologies in this dissertation can be used for other continuous-flow colorimetricsensors and reactions, or even other microreactor applications, such as in greenchemistry.
AB - Clean water is a finite resource, and the quality of such is best monitored by colorimetric in-situ sensors, which allow frequent, non-labour intensive sampling, and are low-cost and simple to manufacture. There are multiple types of sensors that exist in the literature, however, many are cost-prohibitive for wide deployment, or the literature does not not fully elaborate on their operation. The aim of this research was to extend the lifetime and improve the performance of a colorimetric in-situ sensor, Aquamonitrix colorimetric sensor, that was produced by T.E. Laboratories, in addition to characterising sensor behaviour. Its operation was focused on the Griess reaction, in which a vivid azo dye is produced in the presence of nitrite, that can be linearly calibrated to the absorbance by the dye from a photodectector placed at the opposite end of a microfluidic detector channelto a monochromatic light source. Using multiobjective optimisation on a numerical model of a Y-junction micromixer, it was found that both sensitivity could be increased and reagent could be conserved, by limiting the proportion of reagent used during testing to 5% to 7.5% of testing solution, as opposed to the 50% originally used by the system.The conservation of the reagent allowed for an increased sensor deployment lifetimeof up to tenfold. To better understand how the parameters of analyte concentration, reagentproportion of test solution, and mean flow velocity of the solution affect sensoroutput, both mechanistic and data-based modelling of the continuous and stopped flowstages of the sensor were undertaken. Third-order and second-order models were identifiedfor the continuous and stopped flow data respectively. The second-order model isanalagous to the two-step Griess reaction, of which there is a first, faster step. Furthercharacterisation of the zeroes, poles and transfer function coefficients of the third ordermodels showed that parameterisation was possible and, using principal componentanalysis, reduction of parameters. Other testing on the effects of order of cycles, turbidityand heavy metals was also conducted to measure their impact on sensor output.Carryover between sensor cycles was found to be the most interfering factor on sensoroutput, due to the microfluidic connector components, which was eliminated after eightcycles. Overall, the performance and efficiency of the existing sensor was improved,iiiand the methodologies in this dissertation can be used for other continuous-flow colorimetricsensors and reactions, or even other microreactor applications, such as in greenchemistry.
U2 - 10.17635/lancaster/thesis/1615
DO - 10.17635/lancaster/thesis/1615
M3 - Doctoral Thesis
PB - Lancaster University
ER -