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Molecular level interactions of large area 2D materialsNa, Seung Ryul 10 August 2015 (has links)
Two-dimensional materials such as self-assembled monolayers (SAMs), graphene, etc. are candidate materials for improving the performance of microelectronics components and MEMS/NEMS devices. In view of their relatively large in-plane dimensions, surface forces are likely to dominate their behavior. The purpose of the current work was to extract not only the adhesion energy (or steady state fracture toughness) but also the traction-separation relation associated with interactions between various two-dimensional materials and substrates. In particular, interactions between SAMs terminated by carboxyl and diamine (COOH/NMe2) groups, hydroxylated silicon surfaces, graphene and silicon, graphene and its seed copper and graphene and epoxy over large areas was considered. Traction-separation relations, which are a continuum description of such molecular interactions, were determined by a direct method, which makes use of measurements of crack tip opening displacements; an inverse approach where the key parameters are extracted by comparing measured global parameters with finite element solutions and a hybrid approach in which the direct method was supplemented by finite element analysis. Furthermore, the surface free energy of graphene was measured by contact angle measurements.
The most striking observation across all the interactions that were considered is that the interaction ranges were much larger than those attributed to van der Waals forces. While van der Waals models might have been at play between graphene and its seed copper foil and graphene and epoxy, the adhesion energies were surprisingly high. This coupled with the long interaction range suggests that roughness effects modulated the basic force field. Interactions between graphene and silicon and hydroxylated silicon surfaces may have been due to capillary and/or electrostatic again possibly modulated by roughness. The interactions between COOH and NMe2 SAMs became stronger under vacuum, which may have induced chemical bonding, and tougher under mixed-mode loading. / text
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Mecanismos redox e aplicações analíticas de L-Cisteína e L-Glutationa ancoradas sobre eletrodos de ouro recobertos com camadas auto-arranjadas de ácido 3-mercaptopropiônico / Redox mechanism and analytical applications of L-cysteine and L-Glutathione binded over gold electrodes modified with 3-mercaptopropionic acid self assembled monolayerOliveira, Fernando Castro Mota de 20 September 2013 (has links)
Moléculas de L-cisteína (CSH) e L-glutationa (GSH) foram ancoradas na superfície de eletrodos de ouro, previamente modificados com uma camada autoarranjada de ácido 3-mercaptopropiônico (MPA). Esta arquitetura molecular foi importante para preservar a atividade redox dos grupos tiólicos da CSH e GSH na interface eletrodo/solução. A identificação do par redox R-S-S-R/R-SH, bem como a determinação do pKa dos grupos -SH superficiais, foram efetuadas usando voltametria cíclica em soluções de eletrólito em diferentes pH contedo ferricianeto de potássio. A presença dos grupos -SH e -S-S- na superfície dos eletrodos modificados foi ainda confirmada por Espectroscopia Raman de Superfície. Determinaram-se as constantes de velocidade de transferência de carga do processo quase reversível R-S-S-R / R-SH. Estes eletrodos modificados apresentaram resposta eletrocatalítica para a redução de espécies reativas de oxigênio (ROS), como peróxido de hidrogênio e para a oxidação de compostos com atividade antioxidante como a quercetina. Demonstrou-se que a presença de íons Cu2+ na superfície destes eletrodos é capaz de deslocar o equilíbrio do par R-SS-R/R-SH, no sentido oxidativo. Métodos de quantificação para estes compostos foram desenvolvidos por amperometria hidrodinâmica e voltametria cíclica. / L-cysteine molecules (CSH) and L-glutathione (GSH) were anchored on the surface of gold electrodes, previously modified with a self assembled monolayer of 3-mercaptopropionic acid (MPA). This molecular architecture was important to preserve the redox properties of the thiol groups of CSH and GSH in the interface electrode / solution. The identification of the redox couple RSSR / R-SH and the determination of the pKa of -SH groups surface were made using cyclic voltammetry in electrolyte solutions at different pH contents potassium ferricyanide. The presence of the -SH and -SS- modified electrode surface was further confirmed by Raman spectroscopy of surface. It was determined the rate constants of direct electron transfer of quasi-reversible coupled R-SS-R/R-SH. The modified electrodes showed electrocatalytic response to the reduction of reactive oxygen species (ROS) such as hydrogen peroxide and the oxidation of compounds with antioxidant activity such as quercetin. It was demonstrated that presence of Cu2+ ions on the electrode surface can shift the equilibrium of the RSSR/R-SH redox coupled into oxidative direction. Hydrogen peroxide and Quercetin were detected at these modified electrodes using amperometry and hydrodynamic cyclic voltammetry.
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Mecanismos redox e aplicações analíticas de L-Cisteína e L-Glutationa ancoradas sobre eletrodos de ouro recobertos com camadas auto-arranjadas de ácido 3-mercaptopropiônico / Redox mechanism and analytical applications of L-cysteine and L-Glutathione binded over gold electrodes modified with 3-mercaptopropionic acid self assembled monolayerFernando Castro Mota de Oliveira 20 September 2013 (has links)
Moléculas de L-cisteína (CSH) e L-glutationa (GSH) foram ancoradas na superfície de eletrodos de ouro, previamente modificados com uma camada autoarranjada de ácido 3-mercaptopropiônico (MPA). Esta arquitetura molecular foi importante para preservar a atividade redox dos grupos tiólicos da CSH e GSH na interface eletrodo/solução. A identificação do par redox R-S-S-R/R-SH, bem como a determinação do pKa dos grupos -SH superficiais, foram efetuadas usando voltametria cíclica em soluções de eletrólito em diferentes pH contedo ferricianeto de potássio. A presença dos grupos -SH e -S-S- na superfície dos eletrodos modificados foi ainda confirmada por Espectroscopia Raman de Superfície. Determinaram-se as constantes de velocidade de transferência de carga do processo quase reversível R-S-S-R / R-SH. Estes eletrodos modificados apresentaram resposta eletrocatalítica para a redução de espécies reativas de oxigênio (ROS), como peróxido de hidrogênio e para a oxidação de compostos com atividade antioxidante como a quercetina. Demonstrou-se que a presença de íons Cu2+ na superfície destes eletrodos é capaz de deslocar o equilíbrio do par R-SS-R/R-SH, no sentido oxidativo. Métodos de quantificação para estes compostos foram desenvolvidos por amperometria hidrodinâmica e voltametria cíclica. / L-cysteine molecules (CSH) and L-glutathione (GSH) were anchored on the surface of gold electrodes, previously modified with a self assembled monolayer of 3-mercaptopropionic acid (MPA). This molecular architecture was important to preserve the redox properties of the thiol groups of CSH and GSH in the interface electrode / solution. The identification of the redox couple RSSR / R-SH and the determination of the pKa of -SH groups surface were made using cyclic voltammetry in electrolyte solutions at different pH contents potassium ferricyanide. The presence of the -SH and -SS- modified electrode surface was further confirmed by Raman spectroscopy of surface. It was determined the rate constants of direct electron transfer of quasi-reversible coupled R-SS-R/R-SH. The modified electrodes showed electrocatalytic response to the reduction of reactive oxygen species (ROS) such as hydrogen peroxide and the oxidation of compounds with antioxidant activity such as quercetin. It was demonstrated that presence of Cu2+ ions on the electrode surface can shift the equilibrium of the RSSR/R-SH redox coupled into oxidative direction. Hydrogen peroxide and Quercetin were detected at these modified electrodes using amperometry and hydrodynamic cyclic voltammetry.
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