Global ETD Search

61	Development of electrochemical sensors containing bimerallic silver and gold nanoparticles Mailu, Stephen Nzioki January 2010 (has links) Magister Scientiae - MSc / Polyaromatic hydrocarbons (PAHs) are ubiquitous environmental pollutants that have been shown to be teratogenic, mutagenic and carcinogenic and pose serious threats to the health of aquatic and human life. Several methods have been developed for their determination such as immunoassay, gas chromatography and high performance liquid chromatography (HPLC) in combination with fluorescence or absorbance detection. However, these methods are known to manifest underlying disadvantages such as complicated pretreatment, high costs and time consuming processes. In this work, a simple, less time consuming electrochemical method in the form of an electrochemical sensor has been developed for the detection of PAHs. The sensor was fabricated by the deposition of silver-gold (1:3) alloy nanoparticles (Ag-AuNPs) on ultrathin overoxidized polypyrrole (PPyox) film which formed a PPyox/Ag-AuNPs composite on glassy carbon electrode (PPyox/Ag-AuNPs/GCE). The silver-gold alloy nanoparticles deposited to form the composite were chemically prepared by simultaneous reduction of silver nitrate (AgNO3) and chloroauric acid (HAuCl4) using sodium citrate and characterized by UV-visible spectroscopy technique which confirmed the homogeneous formation of the alloy nanoparticles. Transmission electron microscopy showed that the synthesized nanoparticles were in the range of 20-50 nm. The properties of the composite formed upon deposition of the nanoparticles on the PPyox film were investigated by electrochemical methods. The PPyox/Ag-AuNPs/GCE sensor showed strong catalytic activity towards the oxidation of anthracene, phenanthrene and pyrene, and was able to simultaneously detect anthracene and phenanthrene in a binary mixture of the two. The catalytic peak currents obtained from square wave voltammetry increased linearly with anthracene, phenanthrene and pyrene concentrations in the range of 3.0 x 10-6 to 3.56 x 10-4 M,3.3 x 10-5 to 2.83 x 10-4 M, 3.3 x 10-5 to 1.66 x 10-4 M and with detection limits of 0.169 μM, 1.59 μM and 2.70 μM, respectively. The PPyox/Ag-AuNPs/GCE sensor is simple, has antifouling properties and is less time consuming with a response time of 4 s. / South Africa Polyaromatic hydrocarbons (PAHs) Electrochemical sensor Polypyrrole polymer (PPy) Anthracene (AN) Pyrene (Py) Phenanthrene (PHE) Cyclic voltammetry (CV) Square wave voltammetry (SWV) Bimetallic nanoparticles
62	ELECTROCHEMICAL DETECTOR WITH ELECTRODES ARRAY AND ROTATING DISK / ELECTROCHEMICAL DETECTOR WITH ELECTRODES ARRAY AND ROTATING DISK SAJDLOVÁ, Zuzana January 2010 (has links) The thesis deals with the testing and optimization of hydrodynamic conditions of the electrochemical detector, which consists of a flow cell containing the electrochemical sensor with an array of electrodes. The flow cell includes a rotating disc-shaped component, which allows radial flow of analytes along the sensor electrodes. This principle imitates the rotating disk electrode, with the difference that here the electrodes are immobile. Hydrodynamic phenomena in this case are similar to RDE. Therefore, the theoretical part of my work deals with hydrodynamics and mass transfer for the well-described case of rotating disk electrode. It was found that in the current set-up under certain conditions, an analyte flowed back from the output cell channel to the sensor, even at the laminar flow. This causes a nonlinear response of the electrodes and their low reproducibility. The solution is to reduce the distance between the rotation component and the electrodes surface and reduce flow speed of analyzed liquid towards the sensor. A novel type of sensor with annular electrodes was designed and tested. It showed four times higher conversion rate of the analyte compared with the originally used AC9 electrochemical sensor having electrodes in the form of full circles lying on a circumference of a common circle. Based on calculations, conversion of the analyte on the plane electrode can be increased up to 100% when using this annular sensor, adjusting flow cell and reducing of the input flow rate. The detector was connected to the liquid chromatograph and its function was tested on two substances - ascorbic acid and dopamine. For the current detector these parameters were set: dynamic range, linearity, noise, detection limit, time constant and the temperature range at which the detector can be operated.
63	Développement de capteurs électrochimiques basés sur de la voltammétrie par échantillonnage de courant sur réseau d'électrodes / Designed of electrochemical sensor based on sampled-current voltammetry performed on an electrode array Mazerie, Isabelle 09 December 2016 (has links) Comme dans beaucoup de domaines, la sécurité dépend du développement de méthodes analytiques très sensibles et fiables pour pouvoir détecter des molécules dangereuses. C'est pourquoi il est important de développer des méthodes simples afin de diagnostiquer rapidement un composé dangereux dans notre environnement. Dans ce contexte, les techniques électrochimiques offrent une alternative intéressante puisqu'elles permettent d'atteindre de grandes sensibilités et une bonne sélectivité, elles sont peu coûteuses et facilement adaptables pour la création de dispositifs portables. Récemment, notre équipe a développé un nouveau concept basé sur de la voltammétrie par échantillonnage de courant sur un réseau d'électrodes (EASCV), lequel est compatible avec la miniaturisation. Ce système permet de renouveler la surface et la solution au voisinage de l'électrode pendant l'analyse. Le projet de cette thèse a été d'étendre l'application de cette technique à des méthodes électrochimiques utilisant une étape de préconcentration. Une première étude, appliquée à la détection du phénol, a permis de montrer que l'EASCV offre une solution intéressante pour diminuer les phénomènes de passivation ayant lieu pendant l'analyse. En effet, une étude expérimentale associée à une étude théorique a montré que si un temps d'échantillonnage court était appliqué, le phénomène de passivation pouvait être évité. Enfin, pour la première fois, il a été possible de coupler la voltammétrie par échantillonnage de courant à la redissolution anodique. Cette étude, appliquée à la détection du plomb, a permis de mettre en place une courbe d'étalonnage et d'obtenir une intensité élevée de courant, 300 fois plus importante qu'avec les techniques classiques de redissolution anodique. Les premiers essais pour adapter ce nouveau concept aux méthodes pulsés se sont également montrés très encourageants. Afin d'améliorer la sensibilité et la sélectivité du capteur, le réseau d'électrodes a été fonctionnalisé. La modification dépend de la nature de l'espèce cible. Ainsi des polymères à empreintes moléculaires (pour des molécules comme la mélamine) ou des ligands (pour des ions comme le plomb) ont été testés. Dans les deux cas, une méthode d'électrogreffage a été mise au point pour fonctionnaliser la surface. Les premiers résultats obtenus sont encourageants puisqu'une courbe courant-potentiel a pu être tracée montrant une sensibilité 10 fois plus grande pour le plomb que celle obtenue avec une préconcentration par électrodépôt. / As in many fields, safety is primarily based on the development of reliable and highly sensitive analytical methods to detect hazardous molecules. Therefore there is a need for developing simple methods for the diagnosis of harmful molecules in our environment. In this context, electrochemical detection systems seems very promising because they are highly sensitive, require short analysis time, are easy to implement and economic to fabricate. Moreover, our team has recently developed a new concept of device based on sampled-current voltammetry performed on an electrode array (EASCV) which is compatible with miniaturization and portability. The system allows the renewal of the electrode surface and of the analytical solution during the analysis. The present project addresses these issues and aims to extend it to methods involving a preconcentration step. A first study, for the detection of phenol, showed that EASCV offers a versatile solution to decrease fouling effect during the analysis. Indeed experimental and theoretical studies show that the renewable of electrode surface and of the solution in the vicinity of the electrode associated with the use of a short sampled time can avoid electrode fouling. For the first time, it was possible to combine sampled-current voltammetry with anodic stripping voltammetry. In this study, we were able to create a calibration curve, for the detection of lead, and we obtained current intensities 300 times higher than with usual linear stripping voltammetry.First attempts to adapt this new concept to pulse methods were promising.. To increase the sensitivity and selectivity of the sensor, the electrode array is chemically modified. The nature of this modification depends on the nature of the analyte. Thus, molecular imprinted polymer (for molecules) or macrocyclic ligands (for ions) are tested In both cases, an electrografting method is achieved to functionalize the surface. The first results are promising since a current-potential curve is obtained with a sensibility ten times higher than with a preconcentration by electrodeposition. Capteur électrochimique Réseau d'électrodes Photolitographie Redissolution anodique Passivation Électrode modifiée Plomb Phénol Electrochemical sensor Electrode array Photolithography Sampled current voltammetry Stripping Electrode fouling Modified electrode Lead Phenol
64	Electrochemical affinity sensors for biomedical, food and environmental applications / Capteurs électrochimiques d'affinité appliqué dans l'analyse biomédicale, sécurité alimentaire et environnementale Florea, Anca Stefana 14 September 2015 (has links) Les capteurs électrochimiques sont des outils pour la détection fiable, peu coûteux, avec une haute sensibilité et sélectivité, pour la détermination des composés biologiques et chimiques dans les domaines du diagnostic clinique, l'environnement et l'industrie alimentaire. Particulièrement, les Immunocapteurs, alliant une très grande spécificité. Également des nouveaux techniques produisent des résultats similaires, par exemple, les capteurs basés sur la technique des Polymères à empreinte moléculaire, la quelle produise des récepteurs artificiels. La technique devient très important dans les sciences bioanalytiques parce qu'il porte des avantages inhérents sur les récepteurs naturels: une grande stabilité dans des diffèrent environnement et conditions, également comptent avec une grande flexibilité dans la conception, une large gamme de molécules peuvent être utilisées. L'objectif du travail présenté ici est de développer des capteurs électrochimiques avec une très grande affinité et spécificité pour une analyte. Les quelles comprennent des applications très divers comme dans la protection de l'environnement, la sécurité alimentaire et le domaine biomédical. La première partie de la thèse présent l'état actuel de la conception et techniques de fabrication des biocapteurs. Ensuite, les aspects généraux des immuno capteurs électrochimiques et capteurs base sur des aptamères sont présentés ici, ainsi que plusieurs exemples rapportés dans la littérature pour la détection de marqueurs biologiques du cancer. Les avantages de l'intégration nanomatériaux dans les dispositifs de détection sont présentés. Ensuite, plusieurs aspects sur la technique des Polymères à empreinte moléculaire sont introduits. La partie personnelle de contribution est structuré en trois chapitres: en premier temps la méthodologie et les résultats obtenus pour le développement de deux essais biologiques pour la détection du marqueur tumoral Mucinl. Le premier chapitre est dédié sur un capteur à base de billes magnétiques, dans le deuxième chapitre une capteur aptamère base sur des nanoparticules d'or sans aucun marquage et finalement un capteur basée sur la technique des Polymères à empreinte moléculaire, cette protocole a été appliqué pour la détection d'explosifs, des médicaments, des hormones et les pesticides / Electrochemical sensors provide reliable and inexpensive tools for the determination of biological and chemical compounds with high sensitivity and selectivity, in the fields of clinical diagnosis, environment protection and food industry. Immunosensors hold particular promise, combining the high specificity of immuno- reactions with the sensitivity of electrochemical methods. Artificial receptors based on molecularly imprinted technique attracted considerable attention in bioanalytical sciences due to inherent advantages over natural receptors, such as high stability in harsh conditions and freedom of molecular design towards a wide range of molecules. The aim of the thesis presented here was to develop electrochemical affinity sensors based on various recognition receptors for environment monitoring, food safety and biomedical field. The first part of the thesis reviews the current state of knowledge in these fields. General aspects of electrochemical immuno- and apta-sensors are presented herein, together with several examples reported in the literature for the detection of cancer biomarkers. The advantages of integrating nanomaterials in sensing devices are then presented. At last, several aspects of the molecularly imprinted polymers are introduced. The personal contribution part is structured in three chapters, that include the methodology and results obtained for the development of biosensors for the detection of Mucinl tumor marker, the first chapter being focused on bioassays based on magnetic beads and second chapter on a label-free aptasensor based on gold nanoparticles, and finally, a third chapter dedicated to the molecularly imprinted-based sensors for the detection of explosives, drugs, hormones and pesticides Capteur électrochimique Immunocapteur Aptamères Polymères à empreinte moléculaire Biomarqueur du cancer Sécurité alimentaire Contrôle de l'environnement Analyses biomédicales Electrochemical sensor Immunosensor Aptasensor Molecularly imprinted polymers Cancer biomarker Food safety Environmental control Biomedical analysis 543.4
65	Multi-dimensional carbonaceous composites for electrode applications Lin, J.-F. (Jhih-Fong) 15 June 2015 (has links) Abstract The objective of this thesis is to demonstrate multi-dimensional carbon nanotube (CNT) structures in combination with various active materials in order to evaluate their performance in electrode applications such as cold emitters, electric double-layer capacitors (EDLC), and electrochemical sensor/catalyst devices. As the host materials for other active materials, the construction of multi-dimensional CNT nanostructures in this thesis is achieved by two different approaches. In the first, direct growth of 3-dimensional carbon nanostructures by catalytic chemical deposition to produce filamentary carbon as well as vertically aligned forests was applied. The second route that was utilized encompassed the immobilization of CNTs from dispersions to form 2-dimensional surface coatings as well as self-supporting porous buckypapers. Carbonaceous nanocomposites of the active materials are obtained by a number of different methods such as (i) growing nanotubes and filamentous structures on porous Ni catalyst structures, (ii) impregnating CNTs with organic receptor molecules or with Pd nanoparticles, (iii) plating and replacing Cu with Pd on the nanotubes by chemical and galvanic reactions, (iv) annealing W evaporated on CNTs to form CNT-WC composites in solid-solid reactions and (v) reacting S vapor with W coated on CNTs to synthesize CNT-WS2 edge-on lamellar structures of the dichalcogenide in the vertically aligned CNT forests. The 3-dimensional carbon-Raney®Ni composite electrodes show reasonable specific capacitance of ~12 F·g-1 in electric double-layer capacitors as well as a low turn-on field (<1.0 V·µm-1) in field emitter devices. CNT-Nafion®-trifluoroacetylazobenzene coatings on glassy carbon electrodes outperform their Nafion®-trifluoroacetylazobenzene counterparts in electrochemical sensing of different amine compounds (e.g. 10 mM cadaverine, putrescine or ammonia). Cu and CuPd/buckypaper composites display catalytic activity in electrocatalytic oxidation of methanol in alkaline media. On the other hand, nanocomposites of WC and WS2 with aligned CNT forest exhibit a promising performance in hydrogen evolution reactions with an overpotential between -0.5 and -0.7 V at pH~1. In addition, these respective CNT forest aligned nanocomposites also demonstrate a novel method to obtain macroscopic 3-dimensional catalytic electrode assemblies. The results in this thesis elucidate the combination of carbon based nanostructures with organic and inorganic materials as a feasible and versatile approach to produce electrodes for several applications. The following studies of each active carbonaceous composite are expected to boost the technological innovation in relevant fields and initiate further development for commercial exploitation. / Tiivistelmä Työn tavoitteena oli demonstroida moniulotteisia hiilinanoputkirakenteita (CNT), joihin yhdistetään erilaisia aktiivisia materiaaleja sekä arvioida niiden suorituskykyä elektrodisovelluksissa, kuten kenttäemitterissä, sähköisissä kaksoiskerroskondensaattoreissa ja sähkökemiallisissa anturi- ja katalyyttikomponenteissa. Moniulotteisten CNT-nanorakenteiden konstruoiminen muiden aktiivisten materiaalien isäntämateriaaliksi toteutettiin kahdella tavalla. Ensimmäisessä toteutuksessa sovellettiin katalyyttis-kemiallista pinnoitusta, jolla kasvatettiin suoraan kolmiulotteisia hiilinanorakenteita sekä kuitumaisena hiilenä että pystysuuntaan orientoituneina hiilinanoputkimetsinä. Toinen päämenetelmä oli hiilinanoputkien immobilisointi dispersioista kaksiulotteisiksi pinnoitteiksi ja itsetukeutuviksi huokoisiksi hiilinanoputkipapereiksi. Hiiltä sisältäviä aktiivisten materiaalien nanokomposiitteja valmistettiin useilla menetelmillä, kuten (i) kasvattamalla nanoputkia ja kuitumaisia rakenteita huokoisiin Ni-katalyyttirakenteisiin, (ii) kyllästämällä hiilinanoputkia orgaanisilla reseptorimolekyyleillä tai Pd-nanopartikkeleilla, (iii) pinnoittamalla ja korvaamalla nanoputkien päällä olevaa kuparia palladiumilla kemiallisten ja galvaanisten reaktioiden avulla, (iv) hehkuttamalla hiilinanoputkien pinnalle höyrystettyä wolframia (W) muodostamaan CNT-WC-komposiitteja kiinteä–kiinteä-reaktiolla sekä (v) antamalla rikkihöyryn reagoida W-pinnoitettujen hiilinanoputkien kanssa lamellaaristen CNT-WS2-kalkogenidirakenteiden syntetisoimiseksi pystysuuntaan orientoituneisiin CNT-metsiin. Kolmiulotteisilla hiili–Raney®Ni-komposiittielektrodeilla saavutetaan kohtuullinen ominaiskapasitanssi (~12 F·g-1) sähköisissä kaksoiskerroskondensaattoreissa ja pieni kytkeytymiskenttä (<1,0 V·μm-1) kenttäemitterikomponenteissa. CNT-Nafion®-trifluoroasetyyliatsobentseeni-pinnoitteet lasimaisilla hiilielektrodeilla ovat selvästi parempia erilaisten amiiniyhdisteiden (esimerkiksi 10 mM kadaveriini, putreskiini tai ammoniakki) sähkökemiallisessa havaitsemisessa kuin vastaavat Nafion®-trifluoroasetyyliatsobentseeni-pinnoitteet. Cu- ja CuPd-hiilinanoputkipaperikomposiitit osoittavat katalyyttistä aktiivisuutta metanolin sähkökatalyyttisessä hapettumisessa emäksisessä väliaineessa. Toisaalta WC- ja WS2-yhdisteiden ja orientoituneiden CNT-metsien muodostamat nanokomposiitit osoittavat lupaavaa suorituskykyä vedynmuodostamisreaktiossa -0,5…-0,7 V ylipotentiaalilla, ja nämä myös demonstroivat uutta menetelmää makroskooppisten kolmiulotteisten katalyyttisten elektrodirakenteiden toteuttamiseksi. Väitöskirjan tulokset osoittavat, että hiilipohjaisten nanorakenteiden ja orgaanisten/epäorgaanisten materiaalien yhdistäminen on toteuttamiskelpoinen ja monipuolinen lähestymistapa elektrodien valmistamiseksi useisiin sovelluksiin. Kunkin työssä esitetyn aktiivista hiiltä sisältävän komposiitin tutkimuksen odotetaan lisäävän kyseisen alan teknisiä innovaatioita ja synnyttävän lisää kehitystyötä tutkimuksen kaupalliseksi soveltamiseksi. carbon nanotube catalyst cold emitter electric double-layer capacitor electrocatalytic hydrogen production electrochemical sensor methanol oxidation nanocomposites hiilinanoputki katalyytti kylmäemitteri metanolin hapetus nanokomposiitit sähköinen kaksoiskerroskondensaattori sähkökatalyyttinen vedyn tuotanto sähkökemiallinen anturi
66	Electrochemical and structural investigations of a layered AU,PT-YSZ mixed potential gas sensing electrode Zhang, Xin 30 December 2019 (has links) In recent developments of mixed potential gas sensors based on Yttrium Stabilized Zirconia (YSZ), the combination of Au/AuPt-admixtures and oxides was found to be promising electrode materials. With this material combination, satisfactory sensing characteristics were achieved, but the role of Au addition, especially its effect on the processes contributing to the mixed potential formation, has not yet been well understood. Deeper insights of the influence of Au on the electrochemical behaviors of this kind of electrodes are necessary for better understanding of the sensing behaviors and for achieving further technological improvements, as for instance, enhancement of the long-term stability. This situation motivated studies of a layered Au,Pt-YSZ mixed potential gas sensing electrode and its dependence on the thickness of the Au-layer and the sintering conditions. In this work, for the first time three variations of this kind of electrode, which generally comprises a thick-film Pt-YSZ electrode and a thin-film Au layer deposited on top, were studied by different kinds of material analytical approaches and electrochemical methods. These studies elucidated the correlation among the electrochemical behaviors of the electrodes, the amount of gold deposition and its non-uniform distribution over the electrode. Based on these structural and electrochemical data, a qualitative model for the first time is proposed to interpret the sensing mechanism of the layered Au,Pt-YSZ electrodes. In the past such a theory was only available for the electrodes at which the Au was homogeneously admixed with the Pt-YSZ composite. From the structural studies including the ESEM, the XRD and the Glow Discharge-Optical Emission Spectroscopy analysis (GD-OES), it was shown that the thin film Au layer at the layered Au,Pt-YSZ electrodes is not uniformly admixed with the Pt-YSZ bulk after firing, but results in a non-uniform lateral distribution on the electrode surface and a concentration gradient of Au from top over the thickness of the electrode. This Au distribution is strongly affected by the sintering temperature. The higher sintering temperature (1050 °C) results in not only a more uniform morphology of the electrode surface without a separate crystalline phase of gold , but also a better alloying of Au and Pt in the inner parts of the electrode during the sintering process, compared to the electrodes sintered at a lower temperature (850 °C). These clear structural differences of the electrodes fired at different temperatures are related to different catalytic activities over the electrode layer, and accordingly affect their open circuit potential (OCP) sensing behaviors and other electrochemical properties. With respect to selectivity and stability of the sensors, the highest sensing response was observed in the H2 containing gases compared to the other gas species like CO, CH4, and C3H6 for both the type II (low temperature sintered) and the type III (high temperature sintered) sensors. However, clear response and potential stability losses were observed at exposure to C3H6. Formation of coking layers on the electrode seems to be correlated with this response decrease. Surprisingly, the response degradation was even observed by aging the sensors at 600 °C in ambient air. Combined OCP, CV and EIS studies revealed that, the aging process results in some minor irreversible but mainly reversible changes at the electrode/electrolyte interface. Both induce the response degradation which is well correlated with an impedance increase and a CV current decrease. The reversible changes are assumed to be attributed to the formation of an oxidation phase of the metallic parts at the TPB, which is well described in literature. Now, for the first time in this work it could be demonstrated that this reversible response degradation can be nearly fully recovered by the application of cathodic polarization sequences. Consequently, due to the strong correlation between the OCP response to CO and the dynamic electrochemical behaviors ((EIS and CV)) at ambient air, both the EIS and the CV method can be used as efficient tools to check the sensitivity of the sensor at ambient air conditions. In case of OCP response degradation, the sensitivity can be almost fully regenerated by application of cathodic polarization at enhanced temperatures (T700°C). This combination of OCP measurements with dynamic electrochemical methods and the application of cathodic polarization procedures is of enormous practical relevance and was filed for a patent. It excited high interest of the sensor chip producer (Lamtec Meß- und Regeltechnik für Feuerungen GmbH, Walldorf) because it allows sensitivity estimation and regeneration of layered Au,Pt-YSZ gas sensing electrodes whenever ambient air conditions are given. For instance, in case of long-term CO/HC-monitoring for improvement of automated combustion process control of firing appliances, this procedure could be carried out in breaks between firing batches without the need of de-installation of the sensor and, indeed, without any exposure to model gases. info:eu-repo/classification/ddc/540 ddc:540
67	Sensitive Electrochemical Detection Platforms for Anthracene and Pyrene Mwazighe, Fredrick 08 October 2020 (has links) Der elektrochemische Nachweis von polycyclischen aromatischen Kohlenwasserstoffen (PAK), zu denen Anthracen und Pyren gehören, bietet eine kostengünstigere, einfachere und schnellere alternative Analysemethode als herkömmliche Methoden wie GC und HPLC. Im Vergleich zu diesen Methoden weist er jedoch nach wie vor eine geringere Empfindlichkeit auf. Einige neuere Bemühungen haben an einem Mangel an Selektivität gelitten, entweder aufgrund der elektrodenmodifizierende Schicht mit hohem Hintergrundstrom oder der Wahl eines Leitelektrolyten, der die Detektion stört. Bei dem vorliegenden Versuch wurden Pt-Pd-Nanopartikel (NPs) und MWCNTs verwendet, um eine Glaskohlenstoffelektrode (GCE) zum empfindlichen Nachweis von Anthracen und Pyren zu modifizieren. Die verwendeten NPs wurden unter Verwendung eines wässrigen Extrakts aus Blättern von E. grandis synthetisiert, einem nachhaltigen und umweltfreundlichen Syntheseweg. Durch einer Optimierung der Mengen an Pt- und Pd-Ionen im Vorläufer wurden NPs mit einer durchschnittlichen Größe von 10 nm erhalten, wobei ein Verhältnis von 1 Pt-Ion zu 3 Pd-Ionen die kleinste Größe ergab. Durch XPS wurde festgestellt, dass die Zusammensetzung der NPs von Pt2+ und Pd0 dominiert wird. Die XRD-Analyse ergab eine kristalline Natur mit einer flächenzentriert-kubischen Struktur. Die Pt-Pd-NPs bewirkten eine Erhöhung des Spitzenstroms um 94 % für Pyren, führten jedoch zu niedrigeren Spitzenströmen für Anthracen. Wenn die NPs weiter mit MWCNTs zum Nachweis von Pyren verwendet wurden, wurde eine Spitzenstromsteigerung von etwa 200 % mit einem Dynamikbereich von 66–130 μM und einer LOD von 23 μM beobachtet. Es wurde auch festgestellt, dass der elektrochemische Prozess gemischt diffusions- und adsorptionskontrolliert ist. Aufgrund des Einflusses der Adsorption musste die Akkumulationszeit im Analyseverfahren berücksichtigt werden. MWCNTs wurden beim Nachweis von Anthracen angewendet, wobei eine Erhöhung des Spitzenstroms um 74 % und eine Verringerung des Überpotentials um 53 mV beobachtet wurde. Ein dynamischer Bereich von 50–146 µM und eine LOD von 42 µM wurden bestimmt. Niedrigere Konzentrationen wurden mit einer Leitungswasserprobe gemessen, die mit Anthracen versetzt war, hauptsächlich wegen der geringen Löslichkeit von PAK in Wasser. Der Einfluss der Säurebehandlung von MWCNTs auf den Nachweis von Anthracen und Pyren wurde ebenfalls untersucht. Die Säurebehandlung ermöglichte das Laden von mehr Material ohne Ablösen der modifizierten Schicht, was zu höheren Spitzenstromverbesserungen für Anthracen (533 %) und Pyren (448 %) führte. Für Anthracen und Pyren wurden LODs von 40 µM bzw. 14 µM bestimmt, die nur geringfügig niedriger sind als die bei MWCNTs/GCE und Pt-PdNPs/MWCNTs/GCE beobachteten Werte. Der Nachweis von Anthracen wurde durch die Anwesenheit von Pyren und gewöhnlichen Ionen gestört, während die LOD für Pyren in Gegenwart von Anthracen 18 µM betrug. Es wurde festgestellt, dass die auf MWCNTs basierende elektrochemische Nachweisplattform eine bessere Reaktion auf Pyren aufweist.:Bibliographische Beschreibung i Referat i Abstract iii Zeitraum, Ort der Durchführung v Acknowledgements vi Dedication vii Table of Contents viii List of Abbreviations and Symbols xii Chapter 1 1 Introduction 1 1.1 Overview 1 1.2 Polycyclic Aromatic Hydrocarbons 2 1.3 Electrochemical Sensors 7 1.3.1 General Response Curve for Chemical Sensors 10 1.4 Carbon Nanotubes 13 1.5 Use of Nanoparticles in Electrochemical Detection 18 1.6 Green Synthesis of Nanoparticles and The Rationale Behind It 21 1.7 Previous Efforts in the Electrochemical Detection of Polycyclic Aromatic Hydrocarbons 24 1.8 Objectives of the Study 26 Chapter 2 28 Experimental 28 2.1 Chemicals 28 2.1.1 Preparation of Anthracene and Pyrene Solutions 28 2.2 Collection and Preparation of Plant Material 29 2.3 Synthesis and Preparation of Materials 29 2.3.1 Synthesis of Metallic Nanoparticles 29 2.3.2 Acid Treatment of Multi-walled Carbon Nanotubes 30 2.4 Characterization of the Nanomaterials 30 2.4.1 UV-Vis Spectrophotometry 30 2.4.2 SEM/EDX and TEM Analysis 30 2.4.3 Powder X-ray Diffractometry 31 2.4.4 XPS Analysis 31 2.5 Electrochemical Measurements 31 2.5.1 Preparation of the Bare and Modified Glassy Carbon Electrode 32 2.5.2 Characterization of the Bare and the Modified Glassy Carbon Electrode 33 2.5.3 Electrocatalytic Oxidation of Anthracene on the Bare and Modified GCEs 33 2.5.4 Electrocatalytic Oxidation of Pyrene on the Bare and Modified GCEs 34 Chapter 3 35 Synthesis, Characterization, and Application of Pt-Pd Nanoparticles in the Electrochemical Detection of Anthracene and Pyrene 35 3.1 Test for Flavonoids and Polyphenols in the E. grandis Leaves’ Extract 35 3.2 Synthesis of Nanoparticles 35 3.3 Characterization of Nanoparticles 37 3.3.1 TEM Analysis 37 3.3.2 SEM Analysis 40 3.3.3 EDX Analysis 41 3.3.4 Powder X-Ray Diffraction Analysis 45 3.3.5 XPS Analysis of Pt-Pd Particles 46 3.4 Impedance Measurements of the Bare and Nanoparticle-modified Glassy Carbon Electrode 49 3.5 Electrochemical Oxidation of Anthracene and Pyrene at the Bare and Nanoparticles-modified Glassy Carbon Electrode 51 3.6 Conclusions 53 Chapter 4 55 Pt-PdNPs/MWCNTs-Modified GCE for the Detection of Pyrene 55 4.1 Impedance Measurement with Pt-PdNPs/MWCNTs/GCE 55 4.2 Electrochemical Oxidation of Pyrene on Pt-PdNPs/MWCNTs/GCE 56 4.3 Analysis of Varying Concentrations of Pyrene on Pt-PdNPs/MWCNTs/GCE 59 4.4 Selectivity 61 4.5 Conclusions 62 Chapter 5 64 Exploring Multi-walled Carbon Nanotubes for the Detection of Anthracene 64 5.1 Impedance Measurement of MWCNT-Modified Glassy Carbon Electrode 64 5.2 Electrochemical Oxidation of Anthracene on MWCNT/GCE 65 5.3 Analysis of Varying Concentrations of Anthracene Using MWCNTs/GCE 68 5.4 Detection of Anthracene in Tap Water 71 5.5 Conclusions 72 Chapter 6 73 Effect of Acid Treatment of Multi-walled Carbon Nanotubes on the Detection of Anthracene and Pyrene 73 6.1 Characterization of fMWCNTs 74 6.2 Electrochemical Oxidation of Anthracene on fMWCNTs/GCE 75 6.2.1 Effect of Change in Scan Rate 76 6.2.2 Effect of Accumulation Time 77 6.2.3 Application of fMWCNTs/GCE in the Analysis of Varying Concentrations of Anthracene 77 6.3 Electrochemical Oxidation of Pyrene on fMWCNTs/GCE 79 6.4 Selectivity 82 6.4.1 Co-detection of Anthracene and Pyrene at fMWCNTs/GCE 83 6.4.2 Interference of Some Common Ions 85 6.5 Detection of Pyrene in Tapwater using fMWCNTs/GCE 86 6.6 Conclusions 87 Chapter 7 88 Summary and Outlook 88 7.1 Summary 88 7.2 Outlook 90 References 92 Selbständigkeitserklärung 101 Curriculum Vitae 102 / Electrochemical detection of polycyclic aromatic hydrocarbons (PAHs), which include anthracene and pyrene, offers a cheaper, simpler, and faster alternative method of analysis than conventional methods like GC and HPLC. However, it still is not as sensitive as these methods. Some recent efforts have suffered from lack of selectivity, either from the electrode modifying layer having high background current or from the choice of supporting electrolyte interfering with the detection. In this work, Pt-Pd nanoparticles (NPs) and MWCNTs were used to modify a glassy carbon electrode (GCE) for sensitive detection of anthracene and pyrene. The NPs used were synthesized using an aqueous extract from E. grandis leaves, a sustainable and environmentally friendly synthetic route. NPs with an average size of 10 nm were obtained by optimizing the amounts of Pt- and Pd-ions in the precursor, with a ratio of 1:3 Pt to Pd-ions producing the smallest size. Through XPS, the composition of the NPs was established to be dominated by Pt2+ and Pd0. XRD analysis revealed a crystalline nature with a face-centered cubic structure. The Pt-Pd NPs produced 94 % enhancement in the peak current for pyrene but resulted in lower peak currents for anthracene. When the NPs were further used with MWCNTs for the detection of pyrene, about 200% peak current enhancement was observed with a dynamic range of 66–130 µM and LOD of 23 µM. The electrochemical process was also established to be mixed diffusion- and adsorption-controlled. The influence of adsorption necessitated the employment of accumulation time in the analysis procedure. MWCNTs were applied in the detection of anthracene and a 74 % peak current enhancement and a reduction in the overpotential by 53 mV were observed. A dynamic range of 50–146 µM and LOD of 42 µM were determined. Lower concentrations were recovered from a tap water sample that was spiked with anthracene, mainly because of the low solubility of PAHs in water. Effect of acid treatment of MWCNTs on the detection of anthracene and pyrene was also investigated. Acid treatment allowed for loading of more material without peeling off of the modified layer which resulted in higher peak current enhancements for anthracene (533%) and pyrene (448%). LODs of 40 µM and 14 µM were determined for anthracene and pyrene respectively, which are only slightly lower than what was observed at MWCNTs/GCE and Pt-PdNPs/MWCNTs/GCE. Detection of anthracene was interfered by the presence of pyrene and common ions, while the LOD for pyrene in the presence of anthracene was 18 µM. The MWCNTs based electrochemical detection platform was found to have a better response towards pyrene.:Bibliographische Beschreibung i Referat i Abstract iii Zeitraum, Ort der Durchführung v Acknowledgements vi Dedication vii Table of Contents viii List of Abbreviations and Symbols xii Chapter 1 1 Introduction 1 1.1 Overview 1 1.2 Polycyclic Aromatic Hydrocarbons 2 1.3 Electrochemical Sensors 7 1.3.1 General Response Curve for Chemical Sensors 10 1.4 Carbon Nanotubes 13 1.5 Use of Nanoparticles in Electrochemical Detection 18 1.6 Green Synthesis of Nanoparticles and The Rationale Behind It 21 1.7 Previous Efforts in the Electrochemical Detection of Polycyclic Aromatic Hydrocarbons 24 1.8 Objectives of the Study 26 Chapter 2 28 Experimental 28 2.1 Chemicals 28 2.1.1 Preparation of Anthracene and Pyrene Solutions 28 2.2 Collection and Preparation of Plant Material 29 2.3 Synthesis and Preparation of Materials 29 2.3.1 Synthesis of Metallic Nanoparticles 29 2.3.2 Acid Treatment of Multi-walled Carbon Nanotubes 30 2.4 Characterization of the Nanomaterials 30 2.4.1 UV-Vis Spectrophotometry 30 2.4.2 SEM/EDX and TEM Analysis 30 2.4.3 Powder X-ray Diffractometry 31 2.4.4 XPS Analysis 31 2.5 Electrochemical Measurements 31 2.5.1 Preparation of the Bare and Modified Glassy Carbon Electrode 32 2.5.2 Characterization of the Bare and the Modified Glassy Carbon Electrode 33 2.5.3 Electrocatalytic Oxidation of Anthracene on the Bare and Modified GCEs 33 2.5.4 Electrocatalytic Oxidation of Pyrene on the Bare and Modified GCEs 34 Chapter 3 35 Synthesis, Characterization, and Application of Pt-Pd Nanoparticles in the Electrochemical Detection of Anthracene and Pyrene 35 3.1 Test for Flavonoids and Polyphenols in the E. grandis Leaves’ Extract 35 3.2 Synthesis of Nanoparticles 35 3.3 Characterization of Nanoparticles 37 3.3.1 TEM Analysis 37 3.3.2 SEM Analysis 40 3.3.3 EDX Analysis 41 3.3.4 Powder X-Ray Diffraction Analysis 45 3.3.5 XPS Analysis of Pt-Pd Particles 46 3.4 Impedance Measurements of the Bare and Nanoparticle-modified Glassy Carbon Electrode 49 3.5 Electrochemical Oxidation of Anthracene and Pyrene at the Bare and Nanoparticles-modified Glassy Carbon Electrode 51 3.6 Conclusions 53 Chapter 4 55 Pt-PdNPs/MWCNTs-Modified GCE for the Detection of Pyrene 55 4.1 Impedance Measurement with Pt-PdNPs/MWCNTs/GCE 55 4.2 Electrochemical Oxidation of Pyrene on Pt-PdNPs/MWCNTs/GCE 56 4.3 Analysis of Varying Concentrations of Pyrene on Pt-PdNPs/MWCNTs/GCE 59 4.4 Selectivity 61 4.5 Conclusions 62 Chapter 5 64 Exploring Multi-walled Carbon Nanotubes for the Detection of Anthracene 64 5.1 Impedance Measurement of MWCNT-Modified Glassy Carbon Electrode 64 5.2 Electrochemical Oxidation of Anthracene on MWCNT/GCE 65 5.3 Analysis of Varying Concentrations of Anthracene Using MWCNTs/GCE 68 5.4 Detection of Anthracene in Tap Water 71 5.5 Conclusions 72 Chapter 6 73 Effect of Acid Treatment of Multi-walled Carbon Nanotubes on the Detection of Anthracene and Pyrene 73 6.1 Characterization of fMWCNTs 74 6.2 Electrochemical Oxidation of Anthracene on fMWCNTs/GCE 75 6.2.1 Effect of Change in Scan Rate 76 6.2.2 Effect of Accumulation Time 77 6.2.3 Application of fMWCNTs/GCE in the Analysis of Varying Concentrations of Anthracene 77 6.3 Electrochemical Oxidation of Pyrene on fMWCNTs/GCE 79 6.4 Selectivity 82 6.4.1 Co-detection of Anthracene and Pyrene at fMWCNTs/GCE 83 6.4.2 Interference of Some Common Ions 85 6.5 Detection of Pyrene in Tapwater using fMWCNTs/GCE 86 6.6 Conclusions 87 Chapter 7 88 Summary and Outlook 88 7.1 Summary 88 7.2 Outlook 90 References 92 Selbständigkeitserklärung 101 Curriculum Vitae 102 info:eu-repo/classification/ddc/540 ddc:540
68	ENGINEERING DESIGN OF NOVEL 3D MICROPHYSIOLOGICAL SYSTEM AND SENSOR FOR FUNCTIONAL ASSESSMENT OF PANCREATIC BETA-CELLS Emma Vanderlaan (15348208) 25 April 2023 (has links) <p> </p> <p>Diabetes, a chronic condition characterized by elevated blood glucose levels, arises when pancreatic β-cells lose capacity to produce a robust, dynamic glucose-stimulated insulin secretion (GSIS) response. Accurate measurement of β-cell health and function <em>ex vivo</em> is thus fundamental to diabetes research, including studies evaluating disease mechanisms, novel drug candidates, and replacement β-cell populations. However, present-day dynamic GSIS assays typically represent end-point measurements, involve expensive commercial perifusion machines, and require time-consuming enzyme-linked immunosorbent assays (ELISA) for insulin detection. Microfluidic devices developed as accessible, low-cost alternatives still rely on secondary ELISAs and suspend islets in liquid medium, limiting their survival <em>in vitro</em>. Here, we present a novel, 3D-printed microphysiological system (MPS) designed to recreate components of <em>in-vivo</em> microenvironments through encapsulation in fibrillar type I collagen and restoration of favorable molecular transport conditions. Following computational-informed design and rapid prototyping, the MPS platform sustained collagen-encapsulated mouse islet viability and cytoarchitecture for 5 days and supported <em>in-situ</em> measurements of dynamic β-cell function. To rapidly detect insulin secretion from β-cells in the MPS, we then developed a highly sensitive electrochemical sensor for zinc (Zn2+), co-released with insulin, based on glassy carbon electrodes modified with bismuth and indium and coated with Nafion. Finally, we validated sensor detection of Zn2+ released from glucose-stimulated INS-1 β-cells and primary mouse islets, finding high correlation with insulin as measured by standard ELISA. Together, the 3D MPS and Zn2+ sensor developed in this dissertation represent novel platforms for evaluating β-cell health and function in a low-cost, user-friendly, and physiologically-relevant manner. </p> Biofabrication Computational physiology Tissue engineering microphysiological system pancreatic beta cells diabetes organ-on-a-chip devices 3D printing computational modeling electrochemical sensor Glucose stimulated insulin secretion zinc (Zn2+) anodic stripping voltammetry
69	Development of a sensitive electrochemical sensor based on carbon dots and graphitic carbon nitride for the detection of 2-chlorophenol and arsenic (III) in water Moundzounga, Theo Herman Gael 02 1900 (has links) M. Tech. (Department of Chemistry, Faculty of Applied and Computer Sciences), Vaal University of Technology. / The presence of organic and inorganic pollutants in aqueous environments is one of the major challenges confronting man. It is therefore important to develop sensitive, versatile and cheap techniques for their detection. Arsenic (III), 2-chlorophenol (2-CP) and sulfamethoxazole (SMX) are priority pollutants that pose health threats to humans and animals. This study was thus aimed at exploring two promising carbon nanomaterials as electrode modifiers for the electrochemical sensing of arsenic (III), 2-CP and SMX in water. Glassy carbon electrode (GCE) was modified with a nanocomposite of carbon dots (CDs) and graphitic carbon nitride (g-C3N4) and used as a sensor for the analytes in aqueous media. The CDs was prepared by a facile one-pot hydrothermal method using pine cone as the carbon source; g-C3N4 and g-C3N4/CDs nanocomposite were prepared via the microwave irradiation heating method. CDs, g-C3N4 and g-C3N4/CDs were dropped-dried on the surface of bare GCE. Transmission electron microscopy (TEM), X-ray diffraction (XRD) and Fourier transform infrared spectroscopy (FTIR) were used to characterize the prepared materials. GCE, g-C3N4/GCE, CDs/GCE and g-C3N4/CDs/GCE electrodes were electrochemically investigated by electrochemical impedance spectroscopy (EIS) and cyclic voltammetry (CV) using a ferrocyanide [Fe (CN) 6]3-/4- redox probe. The current and the reversibility of the redox probes were enhanced in the presence of modifiers. The electrochemical behavior of arsenic (III), 2-CP and SMX on different electrodes (GCE, CDs/GCE, g-C3N4/GCE and g-C3N4/CDs/GCE) were investigated by differential pulse voltammetry (DPV) under optimized conditions in a phosphate buffer solution (pH 7.6, 6 and 5 for 2-CP, As (III) and SMX respectively). The results demonstrated that the g-C3N4/CDs/GCE electrode significantly enhanced the oxidation peak current of all three analytes. The detection sensitivity of the analytes was greatly improved, suggesting that this new modified electrode has great potential in the determination of trace level of arsenic (III), 2-CP and SMX in water. The oxidation peak currents displayed a linear relationship to concentrations for 2-CP (0.5 - 2.5 μM, R2=0.958, n=5), arsenic (III) (2 - 10 μM R2=0.978, n=5) and SMX (0.3 - 1.3 μM R2=0.9906, n=5). The detection limits of 0.62 μM, 1.64 μM and 0.10 μM were obtained for 2-CP, arsenic and SMX, respectively. Phenol and 4-chloro-3-methyl-phenol were found to interfere with the detection of 2-CP, while, Cu2+, Zn2+, Pb2+ and Cd2+ were the only significant ions that interfered with the electrochemical detection of arsenic (III). EDTA was used as a ligand to mask the interference effects of copper, cadmium, lead and zinc on arsenic sensing. The modified electrode (g-C3N4/CDs/GCE) was used to determine arsenic, 2-CP and SMX in spiked tap and effluent water samples by the standard addition method and the results showed percentage recoveries varying from 93-118% for 2-CP, 98-100% for arsenic and 80-105% for SMX. The outcomes of this study established that the nanocomposite material represents an easy and sensitive sensing platform for the monitoring of arsenic (III), 2-CP and SMX in aqueous media. Sensitive electrochemical sensor Carbon dots Graphitic carbon nitride 2-Chlorophenol Arsenic (III) Water contamination Environment contamination Heavy metals removal Dissertations, Academic -- South Africa Water -- Purification Nanocomposites (Materials) Electrochemical sensors

Search results