Host-Guest Assemblies for Functional Interfaces via Langmuir-Blodgett and Self-Assembly Technique

Shin, Du Hyun

24 January 2014

Various technologies depend on interfacial events that are influenced by various molecular interactions at a solid-liquid interface. The functionality of a surface plays an important role in many applications such as catalysis, sensing, and bio-compatibility, which can benefit from distinctive chemical and physical surface properties. To create tailor-made functional surfaces, surface host-guest assemblies based on Langmuir-Blodgett and self-assembly technique have been employed as a model system as they may offer the potential ability to regenerate surface properties via intercalation of various functional guest molecules. This thesis ranges over the development and characterization of host-guest assemblies and their feasibilities for the regeneration of surface properties via intercalation of functional guests. In our work, 3-dimensional host structures with cavities are constructed on a targeted solid substrate using Langmuir-Blodgett and self-assembly techniques. In particular, by adopting the fundamental concept of host-guest interaction in supramolecular chemistry, we expect that structurally homologous guest molecules where functional groups are anchored can be intercalated into the cavities between hydrophobe arrays at the liquid-solid interface from solution under well-controlled conditions. This approach offers the potential of separating the functional of the monolayer from the inherent structure of the host. The first part of this thesis details two-dimensional host-guest assemblies consisting of guanidinium (G), octadecylsulfonate (S) and various functional alkane guests at the air-aqueous interface and following deposition onto solid substrates via the Langmuir-Blodgett technique. In particular, we evaluated the stability of the host-guest assemblies and the feasibility of exchanging molecular guests under exposure to various organic solvent environments. Analysis of X-ray reflectivity measurements of the thin films showed that good stability of the host-guest assembly could not be achieved due to weak interactions between the host monoalyer and the solid surface. In addition, no evidence of intercalation of guest molecules into guest-free host-cavities was observed. The second part of this thesis discusses the effective methodologies to prepare low-density self-assembled monolayers (LDSAMs) with cavities on silicon substrates. We employed a step-wise reaction based on hydrolytic or silane chemistry: integral spacer molecules such as anthracene-derivatives were anchored to the Si substrate and then long alkane chains were appended to the spacer molecules. The results showed that LDSAMs using an anthryl spacer are attached at the SAM/Si interface via a Si-O-C linkage, and the films do not exhibit a densely packed monolayer quality as would be expected for a non-sterically hindered alkyltrichlorosilane on Si. Thus, the resulting LDSAMs (with cavities) may be capable of accommodating other guest molecules with hydrocarbon chains through intercalation in order to form host-guest assemblies. The third part of this thesis demonstrates the ability of LDSAMs to produce functional surfaces via the intercalation of various functional guest molecules. Self-assembled monolayers of (10-octadecyl)-9-anthracenethiol (host-SAMs) on Au substrates were prepared. Quartz crystal microbalance with dissipation (QCM-D) measurements was used to demonstrate the capacity of LDSAMs to confine guest molecules in the cavities and to probe the structural changes of the host-guest assembly during guest intercalation from ethanol solution. X-ray photoelectron spectroscopy (XPS) measurements were then used to probe host-guest monolayers formed by immersing the host monolayer in solutions in a variety of other solvents. A combined study of QCM-D and XPS showed that guest molecules were intercalated into host-cavities. The reversibility of the intercalation process allows a guest already situated in a host-cavity to be replaced with second guest under well-regulated solvent conditions. / Ph. D.

Functional interfaces

organic molecular monolayer

Langmuir-Blodgett

self-assembly

low-density self-assembled monolayer

host-guest assemblies

Étude de l’oxydoréduction de monocouches électroactives de ferrocénylalcanethiolates par spectroscopie à résonance des plasmons de surface

Chen, Ching-I

08 1900

L’oxydoréduction de monocouches auto-assemblées (SAMs) de ferrocénylalcanethiolates à la surface d’or (FcRSAu) a été étudiée en temps réel par la spectroscopie de résonance de plasmons de surface couplée avec l’électrochimie (E-SPR). La sensibilité de cette technique permet de déterminer des changements d’épaisseur de couche l’ordre de quelques angström résultant d’un changement de structure de la SAM. Plusieurs études antérieures ont proposé que l’oxydation électrochimique d’une SAM de FcRSAu induit une réorientation moléculaire. L’E-SPR est utilisé pour identifier l’origine de ce changement structurel. D’abord, une calibration du réfractomètre SPR utilisé a été effectuée afin de trouver une équation de conversion du signal SPR obtenu en pixel en angle d’incidence pour que l’on puisse calculer le changement d’épaisseur de monocouche à partir du changement d’angle de résonance avec le modèle de Fresnel. Par la suite, une caractérisation approfondie des SAMs de FcCnSAu (où n = 6, 8, 12, 14) en contact avec du NaClO4 acidifié a été réalisée par électrochimie, éllipsométrie, spectroscopie infrarouge et microscopie à force atomique. Les résultats obtenus montrent que l’augmentation de la longueur des chaînes alkyles donne des SAMs de ferrocènes plus épaisses et moins désordonnées. L’analyse par l’E-SPR de ces SAMs pures montre que le changement d’épaisseur induit par l’électro-oxydation dépend linéairement du nombre de méthylènes sur la chaîne alkyle. En appliquant la déconvolution mathématique aux voltampérogrammes cycliques enregistrés pour les SAM mixtes (FcC12SAu/C11SAu) de différentes compositions, on arrive à la conclusion qu’il y a un redressement des chaînes alkyles dans les domaines des ferrocènes agrégés mais la réorientation des têtes de ferrocène dans les domaines de ferrocènes agrégés ou dispersés ne peut pas être exclue. Enfin, l’effet de l’anion électrolytique sur le changement d’épaisseur de la SAM mesuré par l’E-SPR a été étudié. L’analyse électrochimique montre que la capacité de pairage d’anions avec les ferrocéniums décroit comme suit : PF6- > ClO4- > BF4- > NO3-. Tandis que l’épaisseur de la SAM donnée par le changement d’angle de résonance suit la tendance suivante : NO3- ≥ ClO4- > PF6- ≈ BF4-. Des études plus approfondies seront nécessaire pour clarifier cette tendance observée par E-SPR. / The oxidation and reduction of self-assembled ferrocenylalkanethiolate monolayers formed on gold surfaces (FcRSAu) have been followed in real-time by electrochemical surface plasmon resonance (E-SPR) spectroscopy. Film thickness changes on the order of angstroms resulting from SAM structural changes can be detected by SPR. The electrochemically-induced reorientation of the ferrocenylalkanethiolates has been proposed by several spectroelectrochemistry studies. We have used E-SPR to elucidate the nature of the molecular reorientations. The SPR refractometer was first calibrated to find a pixel to angle equation so that Fresnel modeling could be used to calculate SAM thickness changes from the measured resonance angle changes (Δθmin). SAMs of FcCnSAu (where n = 6, 8, 12, 14) were characterized by electrochemistry, infrared spectroscopy and atomic force microscopy. The results obtained show that an increase in the alkyl chain length gives a thicker and less disordered SAM. Oxidation of the surface-bound ferrocenes to ferroceniums and pairing with ClO4- anions produces a similar change in Δθmin for these SAMs, but the variation in the SAM thickness is linearly dependent on the chain length. Mathematical deconvolution of the cyclic voltammograms of binary SAMs (FcC12SAu/C11SAu) of different compositions was used to separate the contributions of the different ferrocene domains (aggregated vs. isolated ferrocenes). We conclude that the aggregated-ferrocenes undergo a change in the orientation of the alkyl chain orientation. We cannot however exclude that the cyclopentadiene rings also reorient themselves. Anion pairing effect was studied by E-SPR. Our electrochemistry results indicate that the ability of the electrolyte anion to pair with the electrogenereted ferrocenium decreases in the following order: PF6- > ClO4- > BF4- > NO3-. On the other hand, the change in Δθmin does not follow the associated trend observed for the anion pairing capacity but rather NO3- ≥ ClO4- > PF6- ≈ BF4-. We hypothesize that the difference in the uptake water molecules by the oxidized SAM may be the reason for this observation. This hypothesis still needs to be verified.

Monocouche auto-assemblée

SAM

Électrochimie

Pairage d’anions

SPR

Self-assembled monolayer

Surface plamon resonance

Electrochemistry

Anion pairing

Étude de la déflexion électrochimique de micro-leviers fonctionnalisés d'une monocouche auto-assemblée électroactive

Castonguay, Catherine

06 1900

No description available.

Micro-levier

Électrochimie

Monocouche auto-assemblée

Ferrocénylalcanethiols

Stress de surface

Microcantilever

Electrochemistry

Self-assembled monolayer

Ferrocenylalkanethiols

Surface stress

Conception de surfaces chimio-structurées pour l'étude de l'adhésion bactérienne et la formation contrôlée des biofilms bactériens / Conception of chemical structured surfaces for the study of the bacterial adhesion and the controlled development of bacterial biofilms

Yunda, Elena

01 October 2019

La formation de biofilms bactériens pathogènes est un problème important, particulièrement dans les secteurs médicaux et agro-alimentaires. La formation contrôlée de biofilms de la bactérie probiotique Lactobacillus rhamnosus GG (LGG) est sélectionnée ici comme méthode potentielle pour prévenir la contamination de surfaces par des bactéries pathogènes. Nous avons étudié le développement de biofilms de LGG ainsi que leur possible contrôle en combinant des approches physico-chimiques et de fonctionnalisation de surface. L’impact des conditions environnementales sur la cinétique de croissance des biofilms et sur leur composition biochimique a été analysé par des mesures in situ et en temps réel par spectroscopie infrarouge à transformée de Fourier en réflexion totale atténuée (ATR-FTIR) sous conditions de flux. Ces données ont été complétées par des images de microscopie en épifluorescence permettant d’obtenir des informations sur la distribution et la forme des cellules bactériennes sur la surface à des étapes clé du développement du biofilm. Compatible avec les mesures ATR-FTIR, un cristal de séléniure de zinc a été choisi comme substrat, nu ou fonctionnalisé avec des monocouches auto-assemblées d’alcane-thiols (SAMs). Différents groupes fonctionnels ont été étudiés : méthyl (-CH3), hydroxyle (-OH) ou amine (-NH2) pour obtenir respectivement des substrats hydrophobe, hydrophile ou chargé positivement. La cinétique d’auto-assemblage des SAMs, leur organisation et l’énergie de surface ont été étudiées en combinant ATR-FTIR, spectroscopie de rétrodiffusion de Rutherford à hautes énergies et mesures d’angles de contact. L’analyse des spectres ATR-FTIR des biofilms de LGG enregistrés in situ et en temps réel pendant 24 heures a montré un rôle important du milieu nutritif sur la composition biochimique et le métabolisme bactériens. Les propriétés du substrat ont un impact faible sur la composition biochimique des biofilms, mais ont un rôle crucial sur leur force d’attachement à la surface. Ce travail pluridisciplinaire a fourni des informations sur l’influence de l’environnement, et particulièrement des caractéristiques du support, sur les propriétés des biofilms aux échelles moléculaire et cellulaire. La méthodologie développée dans ce travail peut notamment être utilisée dans la recherche des conditions les plus favorables à la croissance des biofilms de bactéries probiotiques. / Biofilm formation by pathogenic bacteria brings concerns, particularly in food and medical sectors, and is associated with high sanitary risks and economic losses. Biofilms of probiotic bacteria can potentially be used to prevent the surface contamination by pathogenic species. This work was focused on the investigation of the development of biofilms of probiotic Lactobacillus rhamnosus GG (LGG) and the possible control of their formation by combining surface functionalisation and physico-chemical approaches. The effect of different environmental conditions on the kinetics of the biofilm growth and on its biochemical composition was analysed by in situ and real time measurements with infrared spectroscopy in attenuated total reflection mode (ATR-FTIR) under flow conditions. These data were complemented by epifluorescence images providing information on the surface distribution and the shape of the bacterial cells at specific stages of the biofilm development. Compatible with ATR-FTIR measurements, a zinc selenide (ZnSe) crystal was chosen as a substrate, bare or functionalised with self-assembled monolayers (SAMs). SAMs were formed from alkanethiols terminated by methyl (-CH3), hydroxyl (-OH) or amine (-NH2) groups to obtain hydrophobic, hydrophilic and positively charged substrates, respectively. The kinetics of self-assembly of the alkanethiols onto ZnSe, the organisation of the molecules, their areal density and the surface energy of thus obtained surfaces were studied preliminarily to the biofilm cultivation by means of ATR-FTIR spectroscopy, high energy Rutherford backscattering spectrometry, and contact angle measurements. The analysis of the ATR-FTIR spectra of LGG biofilms recorded in situ and in real time during 24 hours revealed an important role of the nutritive medium in the biosynthesis of nucleic acids, phospholipids, polysaccharides and lactic acid. Substrate properties had low impact on the biochemical composition of LGG biofilms, but had a critical role in the strength of attachment of cultivated biofilms. The findings of this multidisciplinary work provide a fundamental understanding of how the direct environment, including a support surface, influences the properties of bacterial biofilms at the molecular and cellular scales, based on which favourable conditions for the enhancement of probiotic biofilm growth and its mechanical stability can be chosen.

Bactéries

Fonctionalisation de surface

Biofilm

Alcane-thiol

Monocouche auto-assemblée

Spectroscopie infrarouge in situ

Surface functionalisation

Bacteria

Biofilm

Alkanethiol

Self-assembled monolayer

In situ infrared spectroscopy

Towards reliable contacts of molecular electronic devices to gold electrodes

Cafe, Peter F

January 2008

PhD / SYNOPSIS OF THIS THESIS The aim of this thesis is to more fully understand and explain the binding mechanism of organic molecules to the Au(111) surface and to explore the conduction of such molecules. It consists of five discreet chapters connected to each other by the central theme of “The Single Molecule Device: Conductance and Binding”. There is a deliberate concentration on azine linkers, in particular those with a 1,10-phenanthroline-type bidentate configuration at each end. This linker unit is called a “molecular alligator clip” and is investigated as an alternative to the thiol linker unit more commonly used. Chapter 1 places the work in the broad context of Molecular Electronics and establishes the need for this research. In Chapter 2 the multiple break-junction technique (using a Scanning Tunnelling Microscope or similar device) was used to investigate the conductance of various molecules with azine linkers. A major finding of those experiments is that solvent interactions are a key factor in the conductance signal of particular molecules. Some solvents interfere with the molecule’s interaction with and attachment to the gold electrodes. One indicator of the degree of this interference is the extent of the enhancement or otherwise of the gold quantized conduction peak at 1.0 G0. Below 1.0 G0 a broad range for which the molecule enhances conduction indicates that solvent interactions contribute to a variety of structures which could bridge the electrodes, each with their own specific conductance value. The use of histograms with a Log10 scale for conductance proved useful for observing broad range features. vi Another factor which affects the conductance signal is the geometric alignment of the molecule (or the molecule-solvent structure) to the gold electrode, and the molecular alignment is explored in Chapters 3 for 1,10-phenanthroline (PHEN) and Chapter 4 for thiols. In Chapter 3 STM images, electrochemistry, and Density Functional Theory (DFT) are used to determine 1,10-phenanthroline (PHEN) structures on the Au(111) surface. It is established that PHEN binds in two modes, a physisorbed state and a chemisorbed state. The chemisorbed state is more stable and involves the extraction of gold from the bulk to form adatom-PHEN entities which are highly mobile on the gold surface. Surface pitting is viewed as evidential of the formation of the adatom-molecule entities. DFT calculations in this chapter were performed by Ante Bilic and Jeffery Reimers. The conclusions to Chapter 3 implicate the adatom as a binding mode of thiols to gold and this is explored in Chapter 4 by a timely review of nascent research in the field. The adatom motif is identified as the major binding structure for thiol terminated molecules to gold, using the explanation of surface pitting in Chapter 3 as major evidence and substantiated by emergent literature, both experimental and theoretical. Furthermore, the effect of this binding mode on conductance is explored and structures relevant to the break-junction experiment of Chapter 2 are identified and their conductance values compared. Finally, as a result of researching extensive reports of molecular conductance values, and having attempted the same, a simple method for predicting the conductance of single molecules is presented based upon the tunneling conductance formula.

phenanthroline

molecular electronics

break junction

self-assembled monolayer

DPPZ

azine linker

physisorbed

chemisorbed

surface pitting

adatom

thiol binding

gold electrode

porphyrin

molecular conduction

Nanometer Scale Protein Templates for Bionanotechnology Applications

Rundqvist, Jonas

January 2005

Nanofabrication techniques were used to manufacture nanometer scale protein templates. The fabrication approach employs electron beam lithography (EBL) patterning on poly(ethylene glycol) (PEG) thiol (CH3O(CH2CH2O)17NHCO(CH2)2SH) self-assembled monolayers (SAM) on Au. The PEG SAM prevented protein surface adhesion and binding sites for protein were created in the SAM by EBL. Subsequent to EBL, the patterns in the PEG SAM were backfilled with 40-nm NeutrAvidin-coated fluorescent spheres (FluoSpheres). The spontaneous and directed immobilization of the spheres from a solution to the patterns resulted in high resolution protein patterns. The FluoSpheres could be arranged in any arbitrary pattern with ultimately only one or a few FluoSpheres at each binding site. Growth dynamics and SAM morphology of PEG on Au were studied by atomic force microscopy (AFM). PEG SAMs on three types of Au with different microstructure were examined: thermally evaporated granular Au and two types of Au films produced by hydrogen flame annealing of granular Au, Au(111) and "terraced" Au (crystal orientation unknown). The different Au surfaces' substructure affected the morphology and mechanical properties of the PEG SAM. On Au(111), AFM imaging revealed monolayer formation through three distinct steps: island nucleation, island growth, and coalescence. The fine-structure of the SAM revealed dendritic island formation - an observation which can be explained by attractive intermolecular interactions and diffusion-limited aggregation. Island growth was not observed on the "terraced" Au. AFM studies of EBL patterned PEG SAMs on Au(111) revealed two different patterning mechanisms. At low doses, the pattern formation occurs by SAM ablation in a self-developing process where the feature depth is directly dose dependent. At higher doses electron beam induced deposition of material, so-called contamination writing, is seen in the ablated areas of the SAM. The balance between these two mechanisms is shown to depend on the geometry of the pattern. In addition to PEG SAMs, fibronectin monolayers on SiO2 surfaces were patterned by EBL. The areas exposed with EBL lose their functionality and do not bind anti-fibronectin. With this approach we constructed fibronectin templates and used them for cell studies demonstrating pattern dependent cell geometries and cell adhesion. / QC 20101008

nanotechnology

bionanotechnology

nanobiotechnology

electron beam lithography

EBL

poly(ethylene glycol)

PEG

self-assembled monolayer

SAM

self-immobilization

protein pattern

Physics

Fysik

Development of amperometric biosensor with cyclopentadienylruthenium (II) thiolato schiff base self-assembled monolayer (SAM) on gold

Ticha, Lawrence Awa

January 2007

A novel cyclopentadienylruthenium(II) thiolato Schiff base, [Ru(SC6H4NC(H)C6H4OCH2CH2SMe)(&eta / 5-C2H5]2 was synthesized and deposited as a selfassembled monolayer (SAM) on a gold electrode. Effective electronic communication between the Ru(II) centers and the gold electrode was established by electrostatically cycling the Shiff base-doped gold electrode in 0.1 M NaOH from -200 mV to +600 mV. The SAMmodified gold electrode (Au/SAM) exhibited quasi-reversible electrochemistry. The integrity of this electro-catalytic SAM, with respect to its ability to block and electro-catalyze certain Faradaic processes, was interrogated using Cyclic and Osteryoung Square Wave voltammetric experiments. The formal potential, E0', varied with pH to give a slope of about - 34 mV pH-1. The surface concentration, &Gamma / , of the ruthenium redox centers was found to be 1.591 x 10-11 mol cm-2. By electrostatically doping the Au/SAM/Horseradish peroxidase at an applied potential of +700 mV vs Ag/AgCl, a biosensor was produced for the amperometric analysis of hydrogen peroxide, cumene hydroperoxide and tert-butylhydroperoxide. The electrocatalytic-type biosensors displayed typical Michaelis-Menten kinetics with their limits of detection of 6.45 &mu / M, 6.92 &mu / M and 7.01 &mu / M for hydrogen peroxide, cumene hydroperoxide and tert-butylhydroperoxide respectively.

Nanometer Scale Protein Templates for Bionanotechnology Applications

Rundqvist, Jonas

January 2005

<p>Nanofabrication techniques were used to manufacture nanometer scale protein templates. The fabrication approach employs electron beam lithography (EBL) patterning on poly(ethylene glycol) (PEG) thiol (CH3O(CH2CH2O)17NHCO(CH2)2SH) self-assembled monolayers (SAM) on Au. The PEG SAM prevented protein surface adhesion and binding sites for protein were created in the SAM by EBL. Subsequent to EBL, the patterns in the PEG SAM were backfilled with 40-nm NeutrAvidin-coated fluorescent spheres (FluoSpheres). The spontaneous and directed immobilization of the spheres from a solution to the patterns resulted in high resolution protein patterns. The FluoSpheres could be arranged in any arbitrary pattern with ultimately only one or a few FluoSpheres at each binding site.</p><p>Growth dynamics and SAM morphology of PEG on Au were studied by atomic force microscopy (AFM). PEG SAMs on three types of Au with different microstructure were examined: thermally evaporated granular Au and two types of Au films produced by hydrogen flame annealing of granular Au, Au(111) and "terraced" Au (crystal orientation unknown). The different Au surfaces' substructure affected the morphology and mechanical properties of the PEG SAM. On Au(111), AFM imaging revealed monolayer formation through three distinct steps: island nucleation, island growth, and coalescence. The fine-structure of the SAM revealed dendritic island formation - an observation which can be explained by attractive intermolecular interactions and diffusion-limited aggregation. Island growth was not observed on the "terraced" Au.</p><p>AFM studies of EBL patterned PEG SAMs on Au(111) revealed two different patterning mechanisms. At low doses, the pattern formation occurs by SAM ablation in a self-developing process where the feature depth is directly dose dependent. At higher doses electron beam induced deposition of material, so-called contamination writing, is seen in the ablated areas of the SAM. The balance between these two mechanisms is shown to depend on the geometry of the pattern.</p><p>In addition to PEG SAMs, fibronectin monolayers on SiO2 surfaces were patterned by EBL. The areas exposed with EBL lose their functionality and do not bind anti-fibronectin. With this approach we constructed fibronectin templates and used them for cell studies demonstrating pattern dependent cell geometries and cell adhesion.</p>

nanotechnology

bionanotechnology

nanobiotechnology

electron beam lithography

EBL

poly(ethylene glycol)

PEG

self-assembled monolayer

SAM

self-immobilization

protein pattern

Physics

Fysik

Étude de l’oxydoréduction de monocouches électroactives de ferrocénylalcanethiolates par spectroscopie à résonance des plasmons de surface

Chen, Ching-I

08 1900

L’oxydoréduction de monocouches auto-assemblées (SAMs) de ferrocénylalcanethiolates à la surface d’or (FcRSAu) a été étudiée en temps réel par la spectroscopie de résonance de plasmons de surface couplée avec l’électrochimie (E-SPR). La sensibilité de cette technique permet de déterminer des changements d’épaisseur de couche l’ordre de quelques angström résultant d’un changement de structure de la SAM. Plusieurs études antérieures ont proposé que l’oxydation électrochimique d’une SAM de FcRSAu induit une réorientation moléculaire. L’E-SPR est utilisé pour identifier l’origine de ce changement structurel. D’abord, une calibration du réfractomètre SPR utilisé a été effectuée afin de trouver une équation de conversion du signal SPR obtenu en pixel en angle d’incidence pour que l’on puisse calculer le changement d’épaisseur de monocouche à partir du changement d’angle de résonance avec le modèle de Fresnel. Par la suite, une caractérisation approfondie des SAMs de FcCnSAu (où n = 6, 8, 12, 14) en contact avec du NaClO4 acidifié a été réalisée par électrochimie, éllipsométrie, spectroscopie infrarouge et microscopie à force atomique. Les résultats obtenus montrent que l’augmentation de la longueur des chaînes alkyles donne des SAMs de ferrocènes plus épaisses et moins désordonnées. L’analyse par l’E-SPR de ces SAMs pures montre que le changement d’épaisseur induit par l’électro-oxydation dépend linéairement du nombre de méthylènes sur la chaîne alkyle. En appliquant la déconvolution mathématique aux voltampérogrammes cycliques enregistrés pour les SAM mixtes (FcC12SAu/C11SAu) de différentes compositions, on arrive à la conclusion qu’il y a un redressement des chaînes alkyles dans les domaines des ferrocènes agrégés mais la réorientation des têtes de ferrocène dans les domaines de ferrocènes agrégés ou dispersés ne peut pas être exclue. Enfin, l’effet de l’anion électrolytique sur le changement d’épaisseur de la SAM mesuré par l’E-SPR a été étudié. L’analyse électrochimique montre que la capacité de pairage d’anions avec les ferrocéniums décroit comme suit : PF6- > ClO4- > BF4- > NO3-. Tandis que l’épaisseur de la SAM donnée par le changement d’angle de résonance suit la tendance suivante : NO3- ≥ ClO4- > PF6- ≈ BF4-. Des études plus approfondies seront nécessaire pour clarifier cette tendance observée par E-SPR. / The oxidation and reduction of self-assembled ferrocenylalkanethiolate monolayers formed on gold surfaces (FcRSAu) have been followed in real-time by electrochemical surface plasmon resonance (E-SPR) spectroscopy. Film thickness changes on the order of angstroms resulting from SAM structural changes can be detected by SPR. The electrochemically-induced reorientation of the ferrocenylalkanethiolates has been proposed by several spectroelectrochemistry studies. We have used E-SPR to elucidate the nature of the molecular reorientations. The SPR refractometer was first calibrated to find a pixel to angle equation so that Fresnel modeling could be used to calculate SAM thickness changes from the measured resonance angle changes (Δθmin). SAMs of FcCnSAu (where n = 6, 8, 12, 14) were characterized by electrochemistry, infrared spectroscopy and atomic force microscopy. The results obtained show that an increase in the alkyl chain length gives a thicker and less disordered SAM. Oxidation of the surface-bound ferrocenes to ferroceniums and pairing with ClO4- anions produces a similar change in Δθmin for these SAMs, but the variation in the SAM thickness is linearly dependent on the chain length. Mathematical deconvolution of the cyclic voltammograms of binary SAMs (FcC12SAu/C11SAu) of different compositions was used to separate the contributions of the different ferrocene domains (aggregated vs. isolated ferrocenes). We conclude that the aggregated-ferrocenes undergo a change in the orientation of the alkyl chain orientation. We cannot however exclude that the cyclopentadiene rings also reorient themselves. Anion pairing effect was studied by E-SPR. Our electrochemistry results indicate that the ability of the electrolyte anion to pair with the electrogenereted ferrocenium decreases in the following order: PF6- > ClO4- > BF4- > NO3-. On the other hand, the change in Δθmin does not follow the associated trend observed for the anion pairing capacity but rather NO3- ≥ ClO4- > PF6- ≈ BF4-. We hypothesize that the difference in the uptake water molecules by the oxidized SAM may be the reason for this observation. This hypothesis still needs to be verified.

Monocouche auto-assemblée

SAM

Électrochimie

Pairage d’anions

SPR

Self-assembled monolayer

Surface plamon resonance

Electrochemistry

Anion pairing

Development of amperometric biosensor with cyclopentadienylruthenium (II) thiolato schiff base self-assembled monolayer (SAM) on gold

Ticha, Lawrence Awa

January 2007

A novel cyclopentadienylruthenium(II) thiolato Schiff base, [Ru(SC6H4NC(H)C6H4OCH2CH2SMe)(&eta / 5-C2H5]2 was synthesized and deposited as a selfassembled monolayer (SAM) on a gold electrode. Effective electronic communication between the Ru(II) centers and the gold electrode was established by electrostatically cycling the Shiff base-doped gold electrode in 0.1 M NaOH from -200 mV to +600 mV. The SAMmodified gold electrode (Au/SAM) exhibited quasi-reversible electrochemistry. The integrity of this electro-catalytic SAM, with respect to its ability to block and electro-catalyze certain Faradaic processes, was interrogated using Cyclic and Osteryoung Square Wave voltammetric experiments. The formal potential, E0', varied with pH to give a slope of about - 34 mV pH-1. The surface concentration, &Gamma / , of the ruthenium redox centers was found to be 1.591 x 10-11 mol cm-2. By electrostatically doping the Au/SAM/Horseradish peroxidase at an applied potential of +700 mV vs Ag/AgCl, a biosensor was produced for the amperometric analysis of hydrogen peroxide, cumene hydroperoxide and tert-butylhydroperoxide. The electrocatalytic-type biosensors displayed typical Michaelis-Menten kinetics with their limits of detection of 6.45 &mu / M, 6.92 &mu / M and 7.01 &mu / M for hydrogen peroxide, cumene hydroperoxide and tert-butylhydroperoxide respectively.