The use of scanning electrochemical microscopy for the detection and quantification of adsorbed intermediates at electrodes

Rodriguez Lopez, Joaquin, 1983-

07 December 2010

Scanning electrochemical microscopy (SECM) was used for the study and characterization of catalytic and electrocatalytic processes occurring at electrodes. The Surface Interrogation mode (SI-SECM) was introduced for the detection and quantification of adsorbed intermediates and products of catalyzed chemical and electrochemical reactions at noble metals (Pt, Au). In SI-SECM two micro electrodes (i.e. an SECM tip and a substrate of the desired material) are aligned concentrically at a micrometric distance where SECM feedback effects operate. A contrast mechanism based on feedback effects allows for the detection of reactive adsorbed intermediates at the substrate: the SECM tip generates a reactive homogeneous species that “micro-titrates” the substrate adsorbates to yield an electrochemical signal that contains information about the amount of intermediate and about its kinetics of reaction with the redox mediator. The technique was used for the study of the reactivity of three model small adsorbates: 1) the reactivity of adsorbed oxygen on Au and Pt with a reducing mediator was explored and suggested the detection of “incipient oxides” at these surfaces; kinetic parameters of the reactivity of Pt oxides with mediators were obtained, fit to theory and used to explain observations about the electrocatalytic behavior of Pt under anodizing conditions; 2) the reactivity of oxidizing mediators with adsorbed hydrogen on Pt was studied and showed the cation of N,N,N,N-tetramethyl-p-phenylenediamine (TMPD) to be a successful interrogation agent, the detection of hydrogen generated by the decomposition of formic acid on Pt at open circuit was investigated; 3) electrogenerated bromine was used to catalytically interrogate carbon monoxide at Pt, this reaction was previously unreported. The mentioned applications of SECM were validated through the use of digital simulations of diffusion in the complex SECM geometry through flexible commercial finite element method software. / text

Electrocatalysis

Reaction intermediates

Titration

Electrode surface analysis

Electroanalytical techniques

SECM

Surface interrogation

ELECTROANALYTICAL PAPER-BASED SENSORS FOR IN-FIELD DETECTION OF CHLORATE-BASED EXPLOSIVES AND QUANTIFICATION OF OXYANIONS

Carolina Guimaraes Vega (15339037)

18 May 2023

<p> </p> <p><em>Improvised explosive devices (IEDs) are a global threat due to their destructive potential, the easy access to raw materials, and online instructions to manufacture them. These circumstances have led to an increase in the number of IEDs using potassium chlorate as an oxidizer. The standard methods to detect chlorate are mainly designed for laboratory-only testing. Thus, field instrumentation capable of detecting oxidizers from explosives fuel-oxidizers is critical for crime scene investigation and counterterrorism efforts (described in Chapter 1). We developed a paper-based sensor for the in-field detection of chlorate (described in Chapter 2). The sensor is low-cost, disposable, portable, and inexpensive to fabricate, and its flexibility features allow for surface sampling without sample destruction. The sensor has an electrodeposited molybdate sensing layer, as chlorate was reported to have a catalytic effect on the molybdate reduction. The chlorate detection relies on monitoring the change in redox activity of the molybdate sensing layer using different electroanalytical techniques. We effectively demonstrated the analytical performance of the sensor (Chapter 3), obtaining a limit of detection of 1.2 mM and a limit of quantification of 4.10 mM. We evaluated the selectivity of the sensor by testing other oxidizers, such as perchlorate and nitrate, which did not present any electrochemical activity with the molybdate sensing layer.</em></p> <p><em>Additionally, we performed an interferent study with sugar, commonly used as fuel in IEDs, and other common white household powders such as baking soda, flour, and corn starch and neither a false positive nor a false negative result was observed (Chapter 3). As bromate has been reported to have a stronger catalytic effect than chlorate on the redox activity of molybdate, the quantification of bromate was also explored, and a bromate sensor was developed using the findings of the chlorate sensor (Chapter 4). The reaction mechanism involved in the molybdate</em></p> <p><em>reduction was explored and discussed in Chapter 5. The capability of the sensor in detecting chlorate from combusted samples and post-blast samples was successfully demonstrated in Chapter 6, as well as the design of encased prototypes to allow for an in-field presumptive test, storage, and transport for in-laboratory confirmatory tests and compared the performance of the sensor to the available commercial tests.</em></p>

Electroanalytical chemistry

Electrochemical paper-based devices

Explosives

sensor

oxyanions

chlorate-based explosives

Electrochemical Characterization of Common Cutting Agents Found in Illicit Drugs

George G Hedlund (16618584)

30 August 2023

<p>  </p> <p>Nationwide use of illicit drugs has continued to rise over the last few decades, with more than a two-fold increase in global seizures from 2016 and 2020. Most seized drug samples are complex mixtures of drugs and cutting agents, which can complicate the detection and quantification of the illicit drugs in the sample. The presence of these cutting agents can however be beneficial for source tracing purposes, as the majority of cutting agents are selected based on availability in the area where the bulk drug was prepared. The goal of this work was to conduct a systematic study of the electrochemical characteristics of the most common cutting agents found in illicit drugs using unmodified, commercially available glassy carbon electrodes. The long-term goal is to establish an extensive database of electrochemical characterizations of cutting agents and illicit drugs encountered by law enforcement using unmodified, commercially available electrodes to help expand the developing field of forensic electrochemical analyses. This database could then be referenced for the identification of unknown samples to determine the presence of possible illicit drugs and cutting agents that are present to help guide the analyst in further testing.</p> <p>The standard methods for drug detection include a combination of laboratory testing and field-deployable assays ranging from colorimetric tests to gas chromatography-mass spectrometry instrumentation. These detection methods, as well as relevant literature were investigated in Chapter 1. The most used screening methods for illicit drugs are colorimetric tests; however, these assays are prone to false positives. Chapter 1 introduces the existing applications and current research efforts in forensic electrochemistry by describing relevant electrochemical sensors and methods and examining in particular their performance regarding accuracy, sensitivity, and low-cost claims. This overview highlights the broad possibilities of electrochemical analysis in forensics as well as the opportunities when applied to detection and quantification of illicit drugs, demonstrating the current needs for more systematic and consistent characterizations of cutting agents found in seized-drug samples. Chapter 2 details the material, reagents, and experimental conditions, showing their simplicity, and the standard electrochemical and preparative equipment used geared towards an easy implementation in any analytical laboratory. Chapter 3 describes the systematic voltametric characterizations performed on thirteen common cutting agents: phenacetin hydrochloride, levamisole hydrochloride, diphenhydramine hydrochloride, quinine, acetaminophen, ascorbic acid, caffeine, lactose, inositol, mannitol, glucose, sodium bicarbonate and calcium carbonate. In addition to the common, information-rich cyclic voltammetry (CV), differential pulse voltammetry (DPV) and square wave voltammetry (SWV) were used as these pulsed electroanalytical methods are typically considered more sensitive than CV and often employed for quantitative analyses of species present at low concentrations (Chapter 3). Overall, DPV resulted in voltammograms with peaks shaped closer to the ideal redox peaks, also referred to as ‘better defined’, thus enhancing the analytical performance of the assay. For example, In the analysis of diphenhydramine hydrochloride, DPV permitted the measurement of an oxidation with a peak displayed at 1.0 V vs Ag/AgCl, which was not observable when performing CV or SWV. On the other hand, SWV provided noticeably greater intensities of peak current, which allowed for a better detection of the difficult-to-observe redox reactions of quinine occurring at -0.4, 0.0 and 0.4 V vs Ag/AgCl.</p> <p>Some chemical species when present in seized drugs can alter the pH of the tested samples, such as ascorbic acid. Changes in pH will impact the redox activity of the pH-dependent electroactive species present in a sample, thus we investigated how pH of the solvent affected the observation of the redox peaks of those susceptible cutting agents, namely ascorbic acid, quinine, diphenhydramine hydrochloride, and levamisole hydrochloride (Chapter 4). Of particular interest was a significant change in the electrochemical characterization of these species when the pH was varied around their pKa values. Additionally, the composition of the solvent, or supporting electrolyte (SE) solution, can in some cases result in interactions with the analytes in the sample; the study of caffeine with different SE in Chapter 4 illustrates this situation. Specifically, sulfuric acid was the most suited SE of those tested for caffeine analysis.</p> <p>The impact of successive voltametric scans, on the analysis of chemical species were also investigated, using acetaminophen and quinine, demonstrating the development of additional redox peaks in some situations that could provide additional elements towards a more individualized electrochemical profile for cutting agents (Chapter 4). </p> <p>The influence of the material of the working electrode on the electrochemical characterization of cutting agents was explored. Solutions of ascorbic acid, acetaminophen, quinine, and diphenhydramine hydrochloride were electrochemically characterized using a glassy carbon and a platinum working electrode, while ascorbic acid was also characterized on gold and silver electrodes. These examples demonstrate the adaptability of this electroanalytical method with various commonly used electrodes. (Chapter 4). In Chapter 5, we applied similar electrochemical method to the identification of cutting agents and illicit drugs in two-component mixtures. Specifically, these trials included mixtures of fentanyl with a cutting agent at a relative ratio of 1 : 100, using as cutting agents ascorbic acid, diphenhydramine hydrochloride, or glucose, demonstrating the ability of this simple electrochemical method using common commercial electrodes to simultaneously detect illicit drugs and cutting agents. </p>

Electroanalytical chemistry

Forensic chemistry

cutting agents

voltammetry,

forensic Chemistry

drug screening

<b>Confined Multiphase Electrochemistry</b>

Kathryn J Vannoy (18115249)

06 March 2024

<p dir="ltr">Scientists across many disciplines have observed a striking phenomenon: chemical reactions that do not appreciably occur in large volumes often proceed readily in microdroplets. At the core of suggested mechanisms is the influence of interfacial chemistry on the overall reaction; when the interfacial area dominates the reactor volume, the measured reaction rate is often accelerated. For instance, microdroplets with a high surface area-to-volume ratio (generally with radii smaller than 10 µm) provide a unique reaction environment and have been observed to accelerate a wide variety of chemical reactions. This is likely surprising to most readers, as much of our chemical intuition comes from experiments performed on benchtops in beakers (large, single-phase systems). However, microdroplets are regularly exploited by nature, from multiphase atmospheric aerosols to biomolecular condensates in cells. Thus, it is vital to have measurement tools capable of studying multiphase, nanoscale reactors. An electrochemical perspective on measuring multiphase chemistry under nanoconfinement is given in Chapters 2-4. To my knowledge, there were no reports of accelerated reactivity in microdroplets from electrochemical studies until the 2021 observation that enzyme turnover rates are inversely-related to the size of the containing nanodroplet (given in Chapter 6). In this dissertation work, we developed new electroanalytical tools to probe chemical transformations/reactions at micro- and nano-interfaces and made use of new reaction schemes that capitalize on multiphase microenvironments.</p><p dir="ltr">Much of the method development was built on the foundation of stochastic nanoelectrochemistry, a technique that is reviewed thoroughly in Chapters 2, 4, and 5. Briefly, stochastic nanoelectrochemistry is the measurement of single nano-entities, one-at-a-time, as the collide with a micron-sized electrode. The nano-entities studied in this dissertation were aqueous droplets, either suspended in an immiscible oil continuous phase or propelled through air. We dove deeply into these studies, from using correlated microscopy to watch how these micro- and nanodroplets collide with other interfaces to building simulations to quantify changes to the chemistry inside. We showed how the surface environment directs water nanodroplet collisions (Chapter 10) and measured the sub-diffraction-limited nanometer contact area that forms between a microdroplet and a metal surface (Chapter 11). Using the nanodroplets as tiny reactors, we measured accelerated rate constants and promoted unfavorable nucleation events in attoliter-femtoliter aqueous droplets (see Chapter 6-7 and Chapter 12, respectively) and in microliter aqueous droplets (see Chapter 8 and Chapter 9, respectively).</p><p dir="ltr">As mentioned above, microdroplets are ubiquitous in air (<i>e.g.,</i> aerosols). However, electrochemistry is not an obvious choice for the measurement of intact aerosols because electrochemistry is traditionally performed in a conductive solution, and electrochemistry in air is difficult. In this dissertation we laid the groundwork for a path forward that allows electrochemical access the air|microdroplet interface. We designed and characterized a novel electrochemical cell, where the working electrode is a microwire traversing a suspended liquid film (Chapters 13-15). The early results were born from pure curiosity: Can we do electrochemistry in a soap bubble wall? Chapter 13 shows that the answer is “Yes!”, and that electrochemistry can report on aerosol contents that are collected from the air into this thin film. However, the soap bubble wall was severely limited by the lifetime of the bubble wall (bubbles pop), so in Chapters 14 and 15, we introduce a suspended ionic liquid film that does not pop from evaporation. With the more robust system, we realized the ability to probe intact single microdroplets, one-at-a-time (Chapter 14), giving electrochemical access to the air|water interface.</p><p dir="ltr">As detection of illicit substances from aerosols has the potential for immediate impact on first responder, user, and bystander safety, we employed the new technology to electroanalyze aerosolized methamphetamine (Chapter 13) and fentanyl (Chapter 15). Electrochemistry is small, simple, and affordable, making it a realistic candidate for an in-field sensor. We overcame selectivity challenges by using our understanding of interfacial microenvironments to leverage local pH changes, as demonstrated by the reliable detection of low purity cocaine in mixed powders (Chapter 16). This patented method provides a highly selective technique for cocaine identification in the presence of adulterants without the need to bring any chemicals to the scene (water is our only reagent!).</p><p dir="ltr">In sum, this body of work contributes to the electrochemical studies in nano- and microdroplets, extending the reach to account for droplet size on measured rates and to include microdroplets with a water|air boundary. Applications of the work were focused on in-field detection of illicit substances.</p>

Electroanalytical chemistry

microdroplet

stochastic electrochemistry

reaction acceleration

forensic chemistry

point-of-care sensor

enzyme catalysis

MINIATURIZABLE POTENTIOMETRIC BIOSENSING TOOLS

Nicole Leigh Walker (15847931)

30 May 2023

<p>  </p> <p>As our ability to make more sensitive measurements increases, we begin to reach for the ultimate measurement sensitivity: a single entity. Mass spectrometry and fluorescence-based methods exist for single entity studies, and through these the intriguing effects of confinement begin to be observed. These mass spectrometry and fluorescence-based techniques are however, often destructive, which precludes measurements over time. The advent of nanoelectrochemical methods, however, allows for the creation of tools that can make measurements inside of confined volumes—a droplet, a cell, <em>etc</em>.—over extended periods of time. While most nanoelectrochemical methods are based on amperometry or voltammetry, potentiometry allows for minimal perturbation of the system’s homeostasis by passing negligible current.</p> <p>To overcome many of the issues involved in these other methods, we design potentiometric tools that can be easily miniaturized to fit within single entities, particularly within single cells. These tools include enzymatic biosensors designed to be minimally influenced by the cell’s O2 or NAD+ levels, as well as a novel reference electrode that can be made to be very low leakage or completely leakless to avoid contamination of the cell by the reference electrode’s internal filling solution. Both of these tools are designed such that they are easily modified to suit a number of different applications, including for use inside non-aqueous solutions.</p>

Analytical spectrometry

Electroanalytical chemistry

reference electrode

Biosensor design

miniaturizable electrodes

Uso de eletrodos de cobre e eletrodos modificados como sensores eletroquímicos / Use of copper and modified electrodes as electrochemical sensors

Dantas, Luiza Maria Ferreira

28 November 2014

Este trabalho foi dividido em quatro etapas, além da introdução. A primeira parte consiste no estudo comparativo do comportamento eletroquímico de eletrodos de cobre em soluções tampão fosfato 0,10 mol L-1 com valores de pH 4,5 e 7,8, e em solução de NaOH com valores de pH 13,0 e 14,0. Mostrou-se que as espécies formadas eletroquimicamente sobre a superfície do eletrodo são dependentes do valor de pH e do potencial aplicado. Os resultados experimentais obtidos estão de acordo com aqueles reportados na literatura. A segunda parte da tese corresponde ao desenvolvimento de um sensor eletroquímico fabricado com microeletrodos de cobre para a determinação de peróxido de hidrogênio (H2O2) em amostras comerciais de antissépticos bucais e clareadores dentais. Nas condições experimentais otimizadas (solução tampão fosfato 0,10 mol L-1 (pH 7,0) e potencial de redução de -0,20 V), microeletrodos de cobre foram utilizados para a determinação de H2O2 sem a necessidade de etapas de extração, obtendo-se faixa linear de 0,015 a 6,4 mmol L-1 e limite de detecção de 2,8 &#181;mol L-1. O método proposto mostrou-se reprodutível e a presença de interferentes na matriz da amostra analisada não alterou a resposta do sensor para H2O2. Na terceira parte, a reação de eletro-oxidação de glicerol em superfícies de cobre em soluções de NaOH foi investigada utilizando a microscopia eletroquímica de varredura (SECM) no modo de geração pelo substrato de cobre / coleta no microeletrodo de platina (tip) (SG/TC). Os experimentos com a SECM mostraram a dependência da corrente com a distância entre o gerador e a tip, assim como a dependência com a concentração da solução de NaOH. Além disso, a corrente monitorada no microeletrodo diminuiu significativamente após a adição de glicerol. A atividade eletrocatalítica de eletrodos de cobre, no que diz respeito à oxidação de glicerol em meio alcalino, permitiu o desenvolvimento de um sensor amperométrico para a determinação de glicerol em amostra de biodiesel, com um intervalo linear de 0,05 a 1,33 mmol L-1 e limite de detecção de 20 &#181;mol L-1. A metodologia proposta foi aplicada para a determinação do analito em uma amostra de biodiesel de mamona. A quarta parte descreve a síntese, caracterização eletroquímica e utilização de nanotubos de carbono de paredes múltiplas (NCPM) decorados com nanopartículas de paládio (Pd) para a modificação da superfície de eletrodo de carbono vítreo (CV) para a oxidação de metanol, etanol e glicerol em solução de KOH 1,0 mol L-1. Os resultados mostraram que o NCPM/Pd é um bom catalisador para a eletro-oxidação de álcoois em meio alcalino e que maior atividade eletrocatalítica foi obtida para o glicerol. Em condições otimizadas, experimentos amperométricos foram realizados para o desenvolvimento do método analítico para a determinação de glicerol em biodiesel, obtendo-se um intervalo linear de 0,06 a 24 mmol L-1 e limite de detecção 30 &#181;mol L-1. Amostras de biodiesel foram analisadas com sucesso por meio de curvas de adição de padrão utilizando o eletrodo CV/NCPM/Pd. / This thesis is divided into four parts, apart from a general introduction. Part 1 is concerned with a critical comparison of the electrochemical behaviour of copper electrodes, in 0.10 mol L-1 phosphate buffer solution (pH 4.5 and 7.8), and in NaOH solution (pH 13.0 and 14.0). The electrochemical study showed that the species formed on the surface depends on both pH and the applied potential. The experimental results are in good agreement with those reported in the literature. A second goal of the thesis was the development of an electrochemical sensor for hydrogen peroxide (H2O2) determination in commercial oral antiseptic and dental whitening samples using copper microelectrodes. With optimized experimental conditions (working potential applied = -0.20 V in 0.10 mol L-1 phosphate buffer solution pH= 7.0), copper microelectrodes can be used to detect H2O2 without any previous extraction steps, in the range of 0.015 to 6.4 mmol L-1 with a lower detection limit of 2.8 &#181;mol L-1. In addition, the electrode exhibited an excellent reproducibility and long-term stability as well as negligible interference from sorbitol, ethanol, glycerin and saccharin. In the third part, the electrooxidation reaction of glycerol at copper surfaces in NaOH solutions was investigated using Scanning Electrochemical Microscopy (SECM) in a copper substrate generation / platinum microelectrode (tip) collection mode (SG/TC). The results showed the dependence of the current measured at the tip with respect to the distance between generator and the tip, as well as on the concentration of the NaOH solution. Other studies led to the conclusion that the current measured at the tip decreased significantly after addition of glycerol in the solution. The electrocatalytic activity of copper electrodes for the oxidation of glycerol in alkaline medium allowed the development of an amperometric method to determine glycerol in biodiesel samples in the range 0.05 to 1.33 mmol L-1 with a detection limit of 20 &#181;mol L-1. The determination of the analyte in a castor biodiesel sample employing a single copper microelectrode was carried out. The four part of this thesis shows results on the synthesis, electrochemical characterization and use of a glassy carbon (GC) electrode modified with multi-wall carbon nanotubes (MWCNT) decorated with palladium (Pd) for the electrochemical oxidation of methanol, ethanol and glycerol in 1.0 mol L-1 KOH solution. The results showed that MWCNT/Pd is a good electrocatalyst for methanol, ethanol and glycerol oxidation in alkaline medium, with highest activity toward glycerol oxidation. With optimized experimental conditions, an amperometric method was developed for the determination of glycerol in biodiesel samples, in the range of 0.06 to 24 mmol L-1 and detection limit of 30 &#181;mol L-1. Biodiesel samples were successfully analyzed by the standard addition method using the GC/MWCNT/Pd film electrode.

Carbon nanotube

Copper microelectrode

Electroanalytical methods

Glicerol

Glycerol

Hydrogen peroxide

Métodos eletroanalíticos

Microeletrodos de cobre

Nanotubos de carbono

Paládio

Palladium

Peróxido de hidrogênio

\"Aplicação de eletrodos compósitos a base de poliuretana-grafite\" / \"Application of composite electrodes from polyurethane-graphite\"

Cervini, Priscila

10 October 2006

Eletrodos compósitos a base de grafite e resina poliuretana de origem vegetal foram preparados e avaliados quanto ao seu desempenho em relação à determinação voltamétrica e amperométrica de hidroquinona, paracetamol e atenolol. Os eletrodos foram preparados sob pressões diferentes em prensa hidráulica, demonstrando que quanto maior a pressão, maior a corrente medida para uma mesma solução, até um valor limite. O ferricianeto de potássio foi usado como sonda eletroquímica para testes de desempenho do eletrodo em voltametria de onda quadrada (SWV) e por análise em fluxo (FIA), com detecção amperométrica com o eletrodo compósito 60% (grafite, m/m) como eletrodo de trabalho. A hidroquinona (HQ) foi determinada em SWV e FIA, com limites de detecção (LD) da ordem de 283 nmol L-1 e 100 &#61549;mol L-1, respectivamente. A determinação de HQ em reveladores fotográficos forneceu resultados que concordam com o método de comparação em cromatografia líquida de alta eficiência (HPLC) com 95% de confiança. Determinação de paracetamol (APAP) em voltametria de pulso diferencial (DPV), eletrodo de disco rotatório (RDE), FIA e cronoamperometria levaram a limites de detecção de 3,9; 2,6; 18,9 e 6,7 &#61549;mol L-1, respectivamente, usando o eletrodo compósito 60% (grafite, m/m). O APAP foi determinado em formulações farmacêuticas comerciais, com o compósito, em DPV e FIA, com resultados concordantes com HPLC, com 95% de confiança. Estudos também foram feitos na determinação de atenolol (ATN) em DPV e FIA, com limites de detecção de 3,2 e 18,1 &#61549;mol L-1, respectivamente, usando o eletrodo compósito 60% (grafite, m/m). Em formulações farmacêuticas foi possível determinar o ATN em concordância com resultados de HPLC. Houve interferência de ácido ascórbico no APAP e furosemida e propanolol no caso do ATN. Entretanto, os concomitantes presentes em formulações farmacêuticas não interferiram e procedimentos de adição de padrão permitiram obter resultados satisfatórios em DPV. Em FIA não foi necessário fazer adição de padrão. Apenas o ATN se adsorve na superfície do eletrodo, usando DPV, mas foi possível determiná-lo sem necessidade de renovação de superfície entre medidas sucessivas, inclusive em fluxo. Em todos os casos o compósito foi mais sensível que o carbono vítreo, talvez pela presença de grupos funcionais no polímero. / Composite electrodes from graphite and vegetal polyurethane resin were prepared and evaluated in relation to their performance in voltammetric and amperometric determination of hydroquinone (HQ), acetaminophen (APAP) and atenolol (ATN). The electrodes were cured under different pressures in an hydraulic press showing that as higher the pressure, higher the current measured for a same solution, until a limiting value. Potassium ferricyanide was used as an electrochemical probe to test the performance of the electrode in square wave voltammetry (SWV) and as a rotating disc electrode (RDE). The HQ was determined using SWV and FIA, with amperometric detection at the composite electrode as a working electrode. Limits of detection (LD) of 283 nmol L-1 and 100 &#61549;mol L-1 were obtained in SWV and FIA, respectively. The determination of HQ in photographic developers showed results that agreed a comparison method based on of high performance liquid chromatography (HPLC) with 95% of confidence. The APAP was determined in differential pulse voltammetry (DPV), RDE, FIA and chronoamperommetry, with LD 3.9, 2.6, 18.9 and 6.7 &#61549;mol L-1, respectively, using the graphite-PU 60 % (graphite, w/w) composite electrode. The procedure was applied in the determination of APAP in commercial pharmaceutical formulations, at the composite in DPV and FIA with results that agreed with HPLC at 95% confidence level. The ATN was also determined using DPV and FIA, with LD of 3.2 and 18.1 &#61549;mol L-1, respectively. In pharmaceutical formulations it was possible to determine the ATN in agreement with results of HPLC. Interference of ascorbic acid in the APAP and furosemide and propanolol using ATN determinations were observed. However, the concomitants present in pharmaceutical formulation did not interfere and standard addition procedures permitted to obtain satisfactory results in DPV. In FIA, standard addition was not necessary, being the analytes determined on the bases of analytical curves. Only ATN adsorved in the surface of the electrode using DPV, but it was possible to determine it without necessity of surface renovation between successive measurements, including in FIA. In all cases, the composite was more sensitive than glassy carbon (GC), probably due to the presence of functional groups in the polymer and/ or because of the active area of the composite.

electroanalytical techniques

formulações farmacêuticas

pharmaceutical formulations

técnicas eletroanalíticas

Avaliação voltamétrica da conversão do óleo de babaçu (orbignya phalerata) em biodiesel / Voltammetric evaluation of the conversion of babassu oil (orbignya phalerata) into biodiesel

SILVA, Leila Maria Santos da

22 June 2017

Submitted by Daniella Santos (daniella.santos@ufma.br) on 2017-11-17T19:21:39Z No. of bitstreams: 1 LeilaSilva.pdf: 1492880 bytes, checksum: c148829492dd872495deb962291e5381 (MD5) / Made available in DSpace on 2017-11-17T19:21:39Z (GMT). No. of bitstreams: 1 LeilaSilva.pdf: 1492880 bytes, checksum: c148829492dd872495deb962291e5381 (MD5) Previous issue date: 2017-06-22 / PRH 39-ANP/UFMA / The present work proposes the evaluation of electrochemical procedures for the monitoring of the conversion of babassu oil to biodiesel through glycerol analysis. Firstly, a study was carried out to evaluate the best biodiesel / water ratio for the extraction of glycerol in order to verify if the variation in biodiesel and water ratios directly influence the voltammetric response of glycerol. Subsequently, a study on the oxidation of glycerol was carried out. The electrochemical measurements were performed in a potentiostat/Autolab PGSTAT12 galvanostat coupled to a three electrode electrochemical cell: platinum disk (working electrode), a platinum wire (auxiliary electrode) and Ag/AgClSat (reference electrode). The electrochemical behavior of the glycerol oxidation was evaluated in different electrolytes by means of cyclic voltammetry, with the best conditions being established for analysis in 0.1 mol L-1 BR buffer medium (pH 12). In this medium, the glycerol had an oxidation peak around -200 mV. The analytical feasibility of the determination of glycerol in biodiesel samples was studied by means of differential pulse voltammetry and in this technique some operational parameters were optimized: deposition time (30s), deposition potential (-500 mV) and pulse amplitude (150 mV), whose values provided good electroanalytical results. After 20 minutes of reaction (time chosen as sufficient for the formation of glycerol), the analyte was extracted into the aqueous phase, as determined by the optimized voltammetric procedure. An analytical and statistical evaluation showed good linearity (r = 0.996), sensitivity (3.03 μA/mol L-1), precision (1.02% to 3.16%), detection limit (0.01 mmol L-1) and quantification limit (0.04 mmol L-1). The accuracy of the procedure was evaluated by the percentage recovery of glycerol, whose recovery values varied between 99 and 113% and indicate that the proposed method is accurate and suitable for glycerol analysis during the transesterification process. / O presente trabalho propõe a avaliação de procedimentos eletroquímicos para o monitoramento da conversão do óleo de babaçu em biodiesel através da análise de glicerol. Primeiramente, foi realizado um estudo para avaliar a melhor proporção biodiesel/água para extração do glicerol com intuito de verificar se a variação na proporção de biodiesel e água influenciam diretamente na resposta voltamétrica do glicerol. Posteriormente, realizou-se um estudo sobre a oxidação do glicerol. As medidas eletroquímicas foram realizadas em um potenciostato/galvanostato Autolab PGSTAT12 acoplado a uma célula eletroquímica de três eletrodos: disco de platina (eletrodo de trabalho), um fio de platina (eletrodo auxiliar) e Ag/AgClSat (eletrodo de referência). O comportamento eletroquímico da oxidação do glicerol foi avaliado em diferentes eletrólitos por meio da voltametria cíclica, sendo as melhores condições estabelecidas para análise em meio de tampão BR 0,1 mol L-1 (pH 12). Nesse meio, o glicerol apresentou um pico de oxidação em torno de – 200 mV. A viabilidade analítica da determinação do glicerol em amostras de biodiesel foi estudada por meio da voltametria de pulso diferencial e nesta técnica foram otimizados alguns parâmetros operacionais: tempo de deposição (30s), potencial de deposição (-500 mV) e amplitude de pulso (150 mV), cujos valores proporcionaram bons resultados eletroanalíticos. Após 20 minutos de reação (tempo escolhido como suficiente para a formação do glicerol), o analito foi extraído para a fase aquosa, sendo o mesmo determinado pelo procedimento voltamétrico otimizado. Uma avaliação analítica e estatística mostrou bons resultados de linearidade (r = 0,996), sensibilidade (3,03 μA/mol L-1), precisão (1,02% a 3,16%,), limite de detecção (0,01 mmol L-1) e limite de quantificação (0,04 mmol L-1). A exatidão do procedimento foi avaliada através da porcentagem de recuperação do glicerol, cujos valores de recuperação variaram entre 99 e 113% e indicam que o método proposto é exato e adequado para análise de glicerol durante o processo de transesterificação.

Óleo de Babaçu;

Reação de Transesterificação;

Biodiesel;

Glicerol;

Método Eletroanalítico

Babassu Oil;

Transesterification Reaction;

Biodiesel;

Glycerol;

Electroanalytical Methods.

Bioquímica

Uso de eletrodos de cobre e eletrodos modificados como sensores eletroquímicos / Use of copper and modified electrodes as electrochemical sensors

Luiza Maria Ferreira Dantas

28 November 2014

Este trabalho foi dividido em quatro etapas, além da introdução. A primeira parte consiste no estudo comparativo do comportamento eletroquímico de eletrodos de cobre em soluções tampão fosfato 0,10 mol L-1 com valores de pH 4,5 e 7,8, e em solução de NaOH com valores de pH 13,0 e 14,0. Mostrou-se que as espécies formadas eletroquimicamente sobre a superfície do eletrodo são dependentes do valor de pH e do potencial aplicado. Os resultados experimentais obtidos estão de acordo com aqueles reportados na literatura. A segunda parte da tese corresponde ao desenvolvimento de um sensor eletroquímico fabricado com microeletrodos de cobre para a determinação de peróxido de hidrogênio (H2O2) em amostras comerciais de antissépticos bucais e clareadores dentais. Nas condições experimentais otimizadas (solução tampão fosfato 0,10 mol L-1 (pH 7,0) e potencial de redução de -0,20 V), microeletrodos de cobre foram utilizados para a determinação de H2O2 sem a necessidade de etapas de extração, obtendo-se faixa linear de 0,015 a 6,4 mmol L-1 e limite de detecção de 2,8 &#181;mol L-1. O método proposto mostrou-se reprodutível e a presença de interferentes na matriz da amostra analisada não alterou a resposta do sensor para H2O2. Na terceira parte, a reação de eletro-oxidação de glicerol em superfícies de cobre em soluções de NaOH foi investigada utilizando a microscopia eletroquímica de varredura (SECM) no modo de geração pelo substrato de cobre / coleta no microeletrodo de platina (tip) (SG/TC). Os experimentos com a SECM mostraram a dependência da corrente com a distância entre o gerador e a tip, assim como a dependência com a concentração da solução de NaOH. Além disso, a corrente monitorada no microeletrodo diminuiu significativamente após a adição de glicerol. A atividade eletrocatalítica de eletrodos de cobre, no que diz respeito à oxidação de glicerol em meio alcalino, permitiu o desenvolvimento de um sensor amperométrico para a determinação de glicerol em amostra de biodiesel, com um intervalo linear de 0,05 a 1,33 mmol L-1 e limite de detecção de 20 &#181;mol L-1. A metodologia proposta foi aplicada para a determinação do analito em uma amostra de biodiesel de mamona. A quarta parte descreve a síntese, caracterização eletroquímica e utilização de nanotubos de carbono de paredes múltiplas (NCPM) decorados com nanopartículas de paládio (Pd) para a modificação da superfície de eletrodo de carbono vítreo (CV) para a oxidação de metanol, etanol e glicerol em solução de KOH 1,0 mol L-1. Os resultados mostraram que o NCPM/Pd é um bom catalisador para a eletro-oxidação de álcoois em meio alcalino e que maior atividade eletrocatalítica foi obtida para o glicerol. Em condições otimizadas, experimentos amperométricos foram realizados para o desenvolvimento do método analítico para a determinação de glicerol em biodiesel, obtendo-se um intervalo linear de 0,06 a 24 mmol L-1 e limite de detecção 30 &#181;mol L-1. Amostras de biodiesel foram analisadas com sucesso por meio de curvas de adição de padrão utilizando o eletrodo CV/NCPM/Pd. / This thesis is divided into four parts, apart from a general introduction. Part 1 is concerned with a critical comparison of the electrochemical behaviour of copper electrodes, in 0.10 mol L-1 phosphate buffer solution (pH 4.5 and 7.8), and in NaOH solution (pH 13.0 and 14.0). The electrochemical study showed that the species formed on the surface depends on both pH and the applied potential. The experimental results are in good agreement with those reported in the literature. A second goal of the thesis was the development of an electrochemical sensor for hydrogen peroxide (H2O2) determination in commercial oral antiseptic and dental whitening samples using copper microelectrodes. With optimized experimental conditions (working potential applied = -0.20 V in 0.10 mol L-1 phosphate buffer solution pH= 7.0), copper microelectrodes can be used to detect H2O2 without any previous extraction steps, in the range of 0.015 to 6.4 mmol L-1 with a lower detection limit of 2.8 &#181;mol L-1. In addition, the electrode exhibited an excellent reproducibility and long-term stability as well as negligible interference from sorbitol, ethanol, glycerin and saccharin. In the third part, the electrooxidation reaction of glycerol at copper surfaces in NaOH solutions was investigated using Scanning Electrochemical Microscopy (SECM) in a copper substrate generation / platinum microelectrode (tip) collection mode (SG/TC). The results showed the dependence of the current measured at the tip with respect to the distance between generator and the tip, as well as on the concentration of the NaOH solution. Other studies led to the conclusion that the current measured at the tip decreased significantly after addition of glycerol in the solution. The electrocatalytic activity of copper electrodes for the oxidation of glycerol in alkaline medium allowed the development of an amperometric method to determine glycerol in biodiesel samples in the range 0.05 to 1.33 mmol L-1 with a detection limit of 20 &#181;mol L-1. The determination of the analyte in a castor biodiesel sample employing a single copper microelectrode was carried out. The four part of this thesis shows results on the synthesis, electrochemical characterization and use of a glassy carbon (GC) electrode modified with multi-wall carbon nanotubes (MWCNT) decorated with palladium (Pd) for the electrochemical oxidation of methanol, ethanol and glycerol in 1.0 mol L-1 KOH solution. The results showed that MWCNT/Pd is a good electrocatalyst for methanol, ethanol and glycerol oxidation in alkaline medium, with highest activity toward glycerol oxidation. With optimized experimental conditions, an amperometric method was developed for the determination of glycerol in biodiesel samples, in the range of 0.06 to 24 mmol L-1 and detection limit of 30 &#181;mol L-1. Biodiesel samples were successfully analyzed by the standard addition method using the GC/MWCNT/Pd film electrode.

Glicerol

Métodos eletroanalíticos

Microeletrodos de cobre

Nanotubos de carbono

Paládio

Peróxido de hidrogênio

Carbon nanotube

Copper microelectrode

Electroanalytical methods

Glycerol

Hydrogen peroxide

Palladium

\"Aplicação de eletrodos compósitos a base de poliuretana-grafite\" / \"Application of composite electrodes from polyurethane-graphite\"

Priscila Cervini

10 October 2006

Eletrodos compósitos a base de grafite e resina poliuretana de origem vegetal foram preparados e avaliados quanto ao seu desempenho em relação à determinação voltamétrica e amperométrica de hidroquinona, paracetamol e atenolol. Os eletrodos foram preparados sob pressões diferentes em prensa hidráulica, demonstrando que quanto maior a pressão, maior a corrente medida para uma mesma solução, até um valor limite. O ferricianeto de potássio foi usado como sonda eletroquímica para testes de desempenho do eletrodo em voltametria de onda quadrada (SWV) e por análise em fluxo (FIA), com detecção amperométrica com o eletrodo compósito 60% (grafite, m/m) como eletrodo de trabalho. A hidroquinona (HQ) foi determinada em SWV e FIA, com limites de detecção (LD) da ordem de 283 nmol L-1 e 100 &#61549;mol L-1, respectivamente. A determinação de HQ em reveladores fotográficos forneceu resultados que concordam com o método de comparação em cromatografia líquida de alta eficiência (HPLC) com 95% de confiança. Determinação de paracetamol (APAP) em voltametria de pulso diferencial (DPV), eletrodo de disco rotatório (RDE), FIA e cronoamperometria levaram a limites de detecção de 3,9; 2,6; 18,9 e 6,7 &#61549;mol L-1, respectivamente, usando o eletrodo compósito 60% (grafite, m/m). O APAP foi determinado em formulações farmacêuticas comerciais, com o compósito, em DPV e FIA, com resultados concordantes com HPLC, com 95% de confiança. Estudos também foram feitos na determinação de atenolol (ATN) em DPV e FIA, com limites de detecção de 3,2 e 18,1 &#61549;mol L-1, respectivamente, usando o eletrodo compósito 60% (grafite, m/m). Em formulações farmacêuticas foi possível determinar o ATN em concordância com resultados de HPLC. Houve interferência de ácido ascórbico no APAP e furosemida e propanolol no caso do ATN. Entretanto, os concomitantes presentes em formulações farmacêuticas não interferiram e procedimentos de adição de padrão permitiram obter resultados satisfatórios em DPV. Em FIA não foi necessário fazer adição de padrão. Apenas o ATN se adsorve na superfície do eletrodo, usando DPV, mas foi possível determiná-lo sem necessidade de renovação de superfície entre medidas sucessivas, inclusive em fluxo. Em todos os casos o compósito foi mais sensível que o carbono vítreo, talvez pela presença de grupos funcionais no polímero. / Composite electrodes from graphite and vegetal polyurethane resin were prepared and evaluated in relation to their performance in voltammetric and amperometric determination of hydroquinone (HQ), acetaminophen (APAP) and atenolol (ATN). The electrodes were cured under different pressures in an hydraulic press showing that as higher the pressure, higher the current measured for a same solution, until a limiting value. Potassium ferricyanide was used as an electrochemical probe to test the performance of the electrode in square wave voltammetry (SWV) and as a rotating disc electrode (RDE). The HQ was determined using SWV and FIA, with amperometric detection at the composite electrode as a working electrode. Limits of detection (LD) of 283 nmol L-1 and 100 &#61549;mol L-1 were obtained in SWV and FIA, respectively. The determination of HQ in photographic developers showed results that agreed a comparison method based on of high performance liquid chromatography (HPLC) with 95% of confidence. The APAP was determined in differential pulse voltammetry (DPV), RDE, FIA and chronoamperommetry, with LD 3.9, 2.6, 18.9 and 6.7 &#61549;mol L-1, respectively, using the graphite-PU 60 % (graphite, w/w) composite electrode. The procedure was applied in the determination of APAP in commercial pharmaceutical formulations, at the composite in DPV and FIA with results that agreed with HPLC at 95% confidence level. The ATN was also determined using DPV and FIA, with LD of 3.2 and 18.1 &#61549;mol L-1, respectively. In pharmaceutical formulations it was possible to determine the ATN in agreement with results of HPLC. Interference of ascorbic acid in the APAP and furosemide and propanolol using ATN determinations were observed. However, the concomitants present in pharmaceutical formulation did not interfere and standard addition procedures permitted to obtain satisfactory results in DPV. In FIA, standard addition was not necessary, being the analytes determined on the bases of analytical curves. Only ATN adsorved in the surface of the electrode using DPV, but it was possible to determine it without necessity of surface renovation between successive measurements, including in FIA. In all cases, the composite was more sensitive than glassy carbon (GC), probably due to the presence of functional groups in the polymer and/ or because of the active area of the composite.

formulações farmacêuticas

técnicas eletroanalíticas

electroanalytical techniques

pharmaceutical formulations