Ultramicroeletrodo de irídio com filme de mercúrio eletrodepositado para medidas in situ de íons metálicos e pesticidas em solos e águas naturais / Iridium based ultramicroelectrodes with an electro-platted mercury film for in situ determination of metallic ions and pesticides in soil and natural waters

Silva Júnior, Paulo Roberto Vieira da

19 June 2009

Neste trabalho foram desenvolvidas metodologias para a determinação de substâncias de interesse, como metais pesados (micronutrientes e contaminantes), macronutrientes e pesticidas em solo e águas naturais com ultramicroeletrodo de irídio recoberto com filme de Hg eletrodepositado (UME Ir-Hg) e técnicas voltamétricas, utilizando uma cápsula porosa de cerâmica como cela eletroquímica. As metodologias de medidas com os ultramicroeletrodos foram desenvolvidas inicialmente em condições controladas e posteriormente aplicadas a medidas in-situ, com experimentos com águas naturais e solos, conduzidos em laboratório e também com posteriores medidas em amostras reais. Segundo os resultados obtidos foi possível explorar as metodologias voltamétricas, principalmente as de pulso e redissolução anódica, como ferramentas para estudos in-situ dos metais Cd(II), Pb(II) e Cu(II) e do inseticida organofosforado paration metílico, substâncias de grande interesse, obtendo-se um bom nível de repetibilidade e sensibilidade, com limites de detecção em amostras reais de centenas de ppb\'s. / In this work a methodology for determination of metallic ions (micronutrients and contaminants), macronutrients and pesticides in soil and natural waters was developed using an Hg plated iridium based ultramicroelectrode and voltammetric techniques, using a ceramic capsule as an electrochemical cell. The measurement procedures were developed initially in controlled conditions and therefore applied to in-situ measurements, in soil and natural waters, performed in lab and with real field samples. Regarding the obtained results it was possible do explore the voltammetric techniques, mainly the pulsed and stripping ones, as tools for in-situ determination of Cd(II), Pb(II), Cu(II) and the insecticide methyl parathion, with good reproducibility and sensibility, with detection limits in the order of hundreds of parts per billion.

águas naturais

in situ measurements

insecticides

inseticidas

íons metálicos

medidas in-situ

metallic ions

natural waters

soil

solos

ultramicroelectrodes

ultramicroeletrodos

Ultramicroeletrodo de irídio com filme de mercúrio eletrodepositado para medidas in situ de íons metálicos e pesticidas em solos e águas naturais / Iridium based ultramicroelectrodes with an electro-platted mercury film for in situ determination of metallic ions and pesticides in soil and natural waters

Paulo Roberto Vieira da Silva Júnior

19 June 2009

Neste trabalho foram desenvolvidas metodologias para a determinação de substâncias de interesse, como metais pesados (micronutrientes e contaminantes), macronutrientes e pesticidas em solo e águas naturais com ultramicroeletrodo de irídio recoberto com filme de Hg eletrodepositado (UME Ir-Hg) e técnicas voltamétricas, utilizando uma cápsula porosa de cerâmica como cela eletroquímica. As metodologias de medidas com os ultramicroeletrodos foram desenvolvidas inicialmente em condições controladas e posteriormente aplicadas a medidas in-situ, com experimentos com águas naturais e solos, conduzidos em laboratório e também com posteriores medidas em amostras reais. Segundo os resultados obtidos foi possível explorar as metodologias voltamétricas, principalmente as de pulso e redissolução anódica, como ferramentas para estudos in-situ dos metais Cd(II), Pb(II) e Cu(II) e do inseticida organofosforado paration metílico, substâncias de grande interesse, obtendo-se um bom nível de repetibilidade e sensibilidade, com limites de detecção em amostras reais de centenas de ppb\'s. / In this work a methodology for determination of metallic ions (micronutrients and contaminants), macronutrients and pesticides in soil and natural waters was developed using an Hg plated iridium based ultramicroelectrode and voltammetric techniques, using a ceramic capsule as an electrochemical cell. The measurement procedures were developed initially in controlled conditions and therefore applied to in-situ measurements, in soil and natural waters, performed in lab and with real field samples. Regarding the obtained results it was possible do explore the voltammetric techniques, mainly the pulsed and stripping ones, as tools for in-situ determination of Cd(II), Pb(II), Cu(II) and the insecticide methyl parathion, with good reproducibility and sensibility, with detection limits in the order of hundreds of parts per billion.

águas naturais

inseticidas

íons metálicos

medidas in-situ

solos

ultramicroeletrodos

in situ measurements

insecticides

metallic ions

natural waters

soil

ultramicroelectrodes

Electrochemical Investigation of the Reaction Mechanism in Lithium-Oxygen Batteries

Lindberg, Jonas

January 2017

Lithium-oxygen batteries, also known as Lithium-air batteries, could possibly revolutionize energy storage as we know. By letting lithium react with ambient oxygen gas very large theoretical energy densities are possible. However, there are several challenges remaining to be solved, such as finding suitable materials and understanding the reaction, before the lithium-oxygen battery could be commercialized. The scope of this thesis is focusing on the latter of these challenges. Efficient ion transport between the electrodes is imperative for all batteries that need high power density and energy efficiency. Here the mass transport properties of lithium ions in several different solvents was evaluated. The results showed that the lithium  mass transport in electrolytes based on the commonly used lithium-oxygen battery solvent dimethyl sulfoxide (DMSO) was very similar to that of conventional lithium-ion battery electrolytes. However, when room temperature ionic liquids were used the performance severely decreased. Addition of Li salt will effect the oxygen concentration in DMSO-based electrolytes. The choice of lithium salt influenced whether the oxygen concentration increased or decreased. At one molar salt concentration the highest oxygen solubility was 68 % larger than the lowest one. Two model systems was used to study the electrochemical reaction: A quartz crystal microbalance and a cylindrical ultramicroelectrode. The combined usage of these systems showed that during discharge soluble lithium superoxide was produced. A consequence of this was that not all discharge product ended up on the electrode surface. During discharge the cylindrical ultramicroelectrodes displayed signs of passivation that previous theory could not adequately describe. Here the passivation was explained in terms of depletion of active sites. A mechanism was also proposed. The O2 and Li+ concentration dependencies of the discharge process were evaluated by determining the reactant reaction order under kinetic and mass transport control. Under kinetic control the system showed non-integer reaction orders with that of oxygen close to 0.5 suggesting that the current determining step involves adsorption of oxygen. At higher overpotentials, at mass transport control, the reaction order of lithium and oxygen was zero and one, respectively. These results suggest that changes in oxygen concentration will influence the current more than that of lithium. During charging not all of the reaction product was removed. This caused an accumulation when several cycles was examined. The charge reaction pathway involved de-lithiation and bulk oxidation, it also showed an oxygen concentration dependence. / Litiumsyrebatteriet, även känt som litiumluftbatteriet, kan potentiellt revolutionera vårt förhållande till energilagring. Genom att låta litium reagera med syrgas från luften kan teoretiskt höga energitätheter uppnås. Dock så behöver många problem lösas, så som att hitta lämpliga elektrod- och elektrolytmaterial samt att få en ökad förståelse för reaktionsmekanismen, innan litiumsyrebatteriet kan kommersialiseras. Den här avhandlingen behandlar de sistnämnda av dessa problem. För att ett batteri ska kunna leverera hög effekttäthet och energieffektivitet krävs en effektiv jontransport mellan elektroderna. Här utvärderades masstransporten hos flera olika elektrolyter. Resultatet visade att masstransporten av litium i en litiumsyrebatterielektrolyt (baserad på dimetylsulfoxid (DMSO)) är likvärdig med en konventionell litiumjonbatterielektrolyt. När elektrolyter baserade på jonvätskor användes uppvisades väldigt stora energiförluster. När litiumsalt tillsattes påverkades lösligheten av syre i DMSO-baserade elektrolyter. Vilken sorts litiumsalt som användes påverkade om lösligheten av syre ökade eller minskade. Vid en saltkoncentration på en molar var den högsta syrelösligheten 68 \% större än den lägsta. Två olika modellsystem används för att studera den elektrokemiska reaktionen: En elektrokemisk kvartskristallmikrovåg och en cylindrisk ultramikroelektrod. Vid kombinerad användning av dessa system påvisades att löslig litiumsuperoxid bildades vid urladdningen. Följden av detta blev att endast delar av urladdningsprodukten hamnade på elektroden. Vid urladdning visade ultramikroelektroderna tecken på passivering som inte kunde beskrivas av tidigare teori. Här föreslås att passiveringen uppstår på grund av en blockering av de aktiva säten där reaktionen fortskrider. För denna process föreslås även en detaljerad mekanism. Urladdningsprocessens koncentrationsberoende utvärderades genom att bestämma reaktionsordningen för syre och litium under kinetisk- och masstransport kontroll. Under kinetisk kontroll fanns inga heltalsreaktionsordningar, för syre var reaktionsordningen nära 0.5 vilket föreslår att det reaktionssteg som bestämmer strömstorleken innefattar en adsorption av syre. Vid högre överpotentialer, då systemet var under masstransportkontroll, var reaktionsordningarna för litium och syre noll respektive ett. Detta föreslår att ändringar i syrekoncentration påverkar strömmen betydligt mer än vad det gör för litium. Under uppladdning kunde inte all reaktionsprodukt avlägsnas från elektroden. Detta ledde till en ackumulation då flera cykler studerades. Uppladdningens delsteg innefattade en delitiering följt av en oxidation av reaktionsproduktbulken. Denna process uppvisade även ett syrekoncentrationsberoende. / <p>QC 20171114</p>

Lithium-Oxygen Batteries

Lithium Mass Transport

Oxygen Solubility

Reaction Rate Law

Reaction Mechanism

Electrode Passivation

Ultramicroelectrodes

EQCM

Other Chemical Engineering

Annan kemiteknik

Kinetics of Ion Transport in Conducting Polymers

Venugopal, Vinithra

07 September 2016

No description available.

Mechanical Engineering

conducting polymers

ion transport

polypyrrole

PPyDBS

cation concentration sensors

ultramicroelectrodes

scanning elecrochemical microscopy

shear force imaging

constitutive model

saturation kinetics

Isolated Graphene Edge Nanoelectrodes: Fabrication, Selective Functionalization, and Electrochemical Sensing

Yadav, Anur

03 August 2021

Diese Arbeit präsentiert eine einfache eine einfache, auf Photolithographie basierende Methode zur Darstellung einer isolierten Graphenkante (oder GrEdge) einer Monolage als Nanoelektrode auf einem isolierenden Substrat vorgestellt. Trotz ihrer Millimeter-Länge verhält sich die nur einen Nanometer breite GrEdge-Elektrode wie ein Nanodraht mit einem hohen Seitenverhältnis von 1000000 zu 1. Des Weiteren wird der Einsatz von elektrochemischer Modifikation (ECM) demonstriert, um die GrEdge selektiv mit Metall-Nanopartikeln und organischen Schichten nicht-kovalente oder kovalente zu funktionalisieren, wodurch die Chemie der Kante verändert werden kann. Durch die Anbringung von Metall-Nanopartikeln kann zusätzlich oberflächenverstärkte Raman-Spektroskopie (SERS) genutzt werden, um die chemische Beschaffenheit sowohl der unberührten als auch der funktionalisierten GrEdge zu charakterisieren. Die GrEdge weist sehr hohe Mass-entransportraten auf, was charakteristisch für Nanoelektroden ist. Dementsprechend wird die voltammetrische Antwort von der Kinetik des heterogenen Elektrontransfers (HET) diktiert. An der GrEdge-Elektrode werden hohe HET-Raten beobachtet: mindestens 14 cm/s für Außensphäre sonde Ferrocenmethanol (FcMeOH) mit einem quasi-Nernst'schen Verhalten und 0,06 cm/s oder höher für innere Sphäre sonde Ferricyanide ([Fe(CN)6]3-) mit einer kinetisch kontrollierten Reaktion. Nach der selektiven Modifikation der Kante mit Goldnanopartikeln erweist sich der HET als reversibel, mit einer massentransportbegrenztes Nernst‘sches Verhalten aufweisen für beide Redoxmoleküle. Darüber hinaus ermöglicht die schnelle HET-Kinetik die Detektion der reduzierten Form von Nicotinamid-Adenin-Dinukleotid (NADH) und Flavin-Adenin-Dinukleotid (FAD) mit niedrigen Ansatzpotentialen und hinunter bis zu niedrigen mikromolaren Konzentrationen. Entsprechend verbessert die vorliegende Arbeit das Verständnis der Kante von Graphen und deren Chemie. / This thesis presents a simple photolithography-based method to realize the isolated monolayer graphene edge (or GrEdge) nanoelectrode on an insulating substrate. The millimeter-long and a nanometer-wide GrEdge is found to behave like a nanowire with a high aspect ratio of 1000000-to-1. Further, the use of electrochemical modification (ECM) is demonstrated to selectively functionalize the GrEdge with metal nanoparticles and organic moieties in a non-covalent/ covalent manner to tune the chemistry of the edge. The attachment of metal nanoparticles was used to exploit surface-enhanced Raman scattering (SERS) to characterize the chemistry of both the pristine and the functionalized GrEdge. The GrEdge electrodes were found to exhibit very high mass transport rates, characteristic of nanoelectrodes. Accordingly, the voltammetric response is found to be dictated by the kinetics of heterogeneous electron transfer (HET), attributed to the nanoscale geometry and a unique diffusional profile at such electrodes. At the GrEdge electrode, high HET rates are observed: at least 14 cm/s for outer-sphere probe, ferrocenemethanol (FcMeOH) with a quasi-Nernstian behavior; and 0.06 cm/s or higher for inner-sphere probe, ferricyanide ([Fe(CN)6]3-) with a kinetically controlled response. Upon selective modification of the edge with gold nanoparticles, the HET is found to be reversible, with a mass-transport-limited Nernstian response for both probes. Furthermore, the fast HET kinetics enables the sensing of the reduced form of nicotinamide adenine dinucleotide (NADH) and flavin adenine dinucleotide (FAD) with low onset potentials and down to low micromolar concentrations. Hence, this thesis improves the understanding of the edges of graphene and their chemistry. It also realizes isolated GrEdge as a new class of nanoelectrode which forms an important basis within the fields of fundamental electrochemistry and analytical sciences.

Graphen

Graphenkante

chemische Funktionalisierung

Elektrochemie

elektrochemischer Modifikation (ECM)

Nanoelektroden

Ultramikroelektroden (UME)

heterogener Elektronentransfer (HET)

HET-Kinetik

elektrochemischer Sensorik

graphene

graphene edge

chemical functionalization

electrochemistry

electrochemical modification (ECM)

nanoelectrodes

ultramicroelectrodes (UME)

heterogeneous electron transfer (HET)

HET kinetics

electrochemical sensing

543 Analytische Chemie

541 Physikalische Chemie

VK 7720

VG 9307

UP 3150

VE 6307

VG 6847

ddc:543

ddc:541