The bioelectrochemistry of enzymes and their cofactors at carbon nanotube and nitrogen-doped carbon nanotube electrodes

Goran, Jacob Michael

01 September 2015

This dissertation explores the electrochemical behavior of enzymes and their cofactors at carbon nanotube (CNT) and nitrogen-doped carbon nanotube (N-CNT) electrodes. Two common types of oxidoreductases are considered: flavin adenine dinucleotide (FAD)-dependent oxidases and nicotinamide adenine dinucleotide-dependent (NAD⁺)-dehydrogenases. Chapter 1 presents the oxygen reduction reaction (ORR) at N-CNT electrodes as a way to electrochemically measure enzymatic turnover at the electrode surface. The unique peroxide pathway at N-CNT electrodes, which catalytically disproportionates hydrogen peroxide (H₂O₂) back into oxygen, provides an increased ORR current directly proportional to the rate of enzymatic turnover for H₂O₂ producing enzymes, even in an oxygen saturated solution. Biosensing of L-lactate using the increased ORR current is demonstrated using L-lactate oxidase. Chapter 2 explores the surface bound electrochemical signal of FAD when FAD-dependent enzyme or free FAD is allowed to spontaneously adsorb onto the CNT/N-CNT surface. Specifically, the origin of the enzymatically generated FAD signal and the rate constant of the electron transfer are elucidated. Chapter 3 continues the discussion of the cofactor FAD by demonstrating its use as an informative surface specific redox probe for graphitic carbon surfaces. Primarily, FAD can be used to determine the electroactive surface area and the relative hydrophobicity/hydrophilicity of graphitic surfaces. Chapter 4 changes gears to NAD⁺-dependent dehydrogenases by investigating the electrocatalytic oxidation of NADH at N-CNTs in comparison with conventional carbon electrodes or nondoped CNTs. Biosensing of glucose through the oxidation of NADH is demonstrated using glucose dehydrogenase adsorbed onto the N-CNT surface. Chapter 5 continues the discussion of NAD⁺-dependent dehydrogenases by addressing the reaction kinetics of NADH oxidation at N-CNTs as a tool to measure the enzymatic reduction of NAD⁺.

Enzymes

Electrochemistry

Bioelectrochemistry

Cofactors

Carbon nanotubes

Nitrogen-doped carbon nanotubes

Synthèse de nanotubes de carbonne dopés à l'azote et leur application catalytique / Synthesis of nitrogen doped carbon nanotubes and their application in catalysis

Benyounes, Anas

24 March 2016

L'objectif de ce travail est la synthèse et l'étude des propriétés acido-basiques de nanotubes de carbone (CNT) dopés à l’azote pour les utiliser comme catalyseurs ou supports de catalyseurs. Pour ce faire, trois types de nanotubes de carbone dopés à l'azote ont été synthétisés, caractérisés et testés dans la conversion de l'alcool isopropylique. Les nanotubes de carbone dopés diffèrent par le taux d’azote et la présence ou non d'une section non dopée dans leur structure. Pour les matériaux à faible teneur en azote, la réaction conduit à la formation d'acétone indiquant la présence de sites basiques. À plus forte teneur en azote, les catalyseurs dopés conduisent à la formation d'acétone et de propène, mettant en évidence la présence de sites basiques et acides. La caractérisation par XPS nous a permis de proposer que les sites basiques sont constitués de groupes de surface pyridiniques et les sites acides sont des groupements sulfoniques formés au cours de la purification de ces matériaux avec de l'acide sulfurique. Des catalyseurs au ruthénium et au palladium supportés (2%) sur des nanotubes de carbone non dopés et dopés à l'azote (N-CNT), ont été préparés et évalués dans la réaction de décomposition de l'alcool isopropylique comme réaction test. La présence de fonctionnalités azotées (azote pyridinique, pyrrolique et quaternaire) sur le support dopé à l'azote induit une plus grande dispersion du métal. En ce qui concerne les catalyseurs supportés, ceux de palladium étaient plus actifs et plus sélectifs que ceux au ruthénium. De plus, les catalyseurs au Pd sont sélectifs en acétone, tandis que les catalyseurs au Ru conduisent à la déshydratation et la déshydrogénation. Le dopage des nanotubes de carbone par l’azote conduit aussi à l'apparition de propriétés d'oxydo-réduction. Enfin, nous avons montré que des nanotubes de carbone, constitués de deux sections différentes : une partie non dopée hydrophobe reliée à un segment hydrophile, sont amphiphiles. Nous les avons utilisés comme supports tensioactif de catalyseur au palladium. Ces nouveaux catalyseurs à base de Pd supporté ont été testés dans la réaction d'oxydation de plusieurs alcools en utilisant l'oxygène moléculaire en phase liquide. L'oxydation du 2- heptanol produit sélectivement la cétone correspondante, alors que l'oxydation de l'alcool benzylique est très sélective vis-à-vis de l'aldéhyde. Par ailleurs, l'oxydation de l'éthanol produit de l'acide acétique de manière sélective. / The objective of this work is the synthesis and the investigation of the acid and basicproperties of nitrogen doped carbon nanotubes (CNTs) able to be used as catalysts or catalystsupports. For this, three types of purified nitrogen doped CNTs were synthesized,characterized and tested for isopropyl alcohol conversion under nitrogen or air atmosphere,and compared to undoped CNTs. The N-doped CNTs differ from their nitrogen content andfrom the presence or not of undoped section in their structure. The reaction lead to theformation of acetone as the sole product on catalysts presenting no nitrogen or low nitrogencontent (< 2.8% w/w), pointing to the presence of basic sites. At higher nitrogen content, Ndopedcatalysts lead to the formation of acetone and propene, highlighting the presence ofboth basic and acids sites on such material. XPS characterization allow us to propose that thebasic sites consist in pyridinic surface groups and the acidic sites in sulfonic surface groupsformed during the purification of these material with sulfuric acid. Ruthenium and palladiumsupported catalysts (2% w/w) were prepared on nitrogen-doped and non-doped carbonnanotubes (N-CNT), and evaluated for the reaction of decomposition of isopropyl alcohol asprobe reaction. The presence of nitrogen functionalities (pyridinic, pyrrolic and quaternarynitrogen) on the nitrogen doped support induces a higher metal dispersion: 1.8 nm (Pd/NCNT)< 4.9 nm (Pd/CNT), and 2.4 nm (Ru/N-CNT) < 3.0 nm (Ru/CNT). As far as thesupported catalysts are concerned, the palladium ones were more active and more selectivethan the ruthenium ones. The Pd catalysts were selective towards acetone, whereas Rucatalysts lead to dehydration and dehydrogenation products. The nitrogen doping induces theappearance of redox properties, which appear when oxygen is present in the reaction mixture.Finally, we have shown that unique amphiphilic magnetic hybrid carbon nanotubes thatcontain on the same nanotube two different sections: a hydrophobic undoped part connectedto a hydrophilic N-doped segment are synthesized and used as tensioactive supports forpalladium catalysts. These new Pd-supported catalysts have been used in the alcoholoxidation reaction using molecular oxygen in the liquid phase. The oxidation of 2-heptanolproduces selectively the ketone, the oxidation of benzyl alcohol is very selective towards thealdehyde, and ethanol oxidation produces selectively acetic acid.

Catalyse

Nanotubes de carbonne dopés à l'azote

Oxydation

Alcool

Paladium

Catalysis

Nitrogen doped carbon nanotubes

Oxidation

Alcohol

Palladium

Síntese de estruturas 3D de nanotubos de carbono verticalmente alinhados, dopados e não-dopados, decorados com nanopartículas de óxido de titânio, sua caracterização microestrutural e de propriedades fotocatalíticas e elétricas

Acauan, Luiz Henrique

January 2015

Neste trabalho foi desenvolvido um procedimento experimental para a fabricação de estruturas 3D de nanotubos de carbono crescidos sobre substrato de cobre e decorados com partículas de óxido de titânio. Foram relacionados os três tipos diferentes de NTCs nesta estrutura (simples, dopados com nitrogênio e tratados com plasma) com a deposição do TiO2 por ALD. Foram igualmente propostas três aplicações para esta estrutura. A síntese dos NTCs verticalmente orientados, dopados e não dopados, foi otimizada dentre alguns parâmetros de síntese como temperatura, agente oxidante e principalmente, o filme catalisador. A introdução de defeitos nos NTCP através do tratamento a plasma oxidativo foi avaliada frente a variáveis como pressão, potência e tempo de exposição. A relação entre os defeitos destes três tipos de NTCs e a deposição de TiO2 por ALD foi avaliada por microscopia eletrônica de transmissão, Raman, XPS e TGA. O procedimento experimental para confecção da estrutura 3D foi desenvolvido etapa por etapa via diversas técnicas experimentais, desde caracterização química, imagem, até testes empíricos. Na estrutura final, foram avaliadas as propriedades fotocatalíticas pela decomposição de corante orgânico em meio aquoso, propriedades capacitivas por voltametria cíclica e propriedades de emissão por campo através de curvas de campo elétrico por corrente de emissão e diagramas F-N. Foram obtidas florestas de NTCs de boa qualidade com até 0.5mm de altura, de diâmetros e número de paredes regulares. Nestes foi possível introduzir defeitos de maneira controlável, mantendo o arranjo da floresta. As florestas de NTCNx alcançam uma altura de até 0,3mm com concentração de nitrogênio de 2% tendo os nanotubos uma estrutura típica “bamboo-like”. Os resultados mostram a relação entre o tipo de defeito e a deposição de TiO2 por ALD, obtendo-se partículas cristalinas para os NTCP e NTCNx, sendo neste ultimo as partículas homogeneamente distribuídas e com tamanho uniforme, enquanto nos NTCOx forma-se uma densa camada de TiO2 composta por grandes grãos monocristalinos A partir de processo como tratamentos térmicos e transferência dos NTC de substrato foi possível obter uma estrutura 3D composta de uma camada carbono grafítico e NTC-VAs sobre um substrato de cobre, sem alterar o arranjo inicial das florestas. As amostras mostraram efeito de emissão de elétrons por campo elétrico, porém estas requerem uma análise mais quantitativa. Os ensaios de fotocatálise mostraram que a imobilização do TiO2 em um suporte denso inviabiliza a degradação do corante em meio aquoso. Os NTCNx apresentaram maior capacitância que as mostras de NTCP, e o TiO2 foi aparentemente ineficaz para a melhoria desta propriedade. / In this work, we propose an experimental procedure for fabrication of 3D carbon nanotubes structures anchored with titanium oxide particles, on a copper substrate. We correlate three different types of CNTs from this structure (pristine, doped with nitrogen and treated with plasma) with the deposition of TiO2 by ALD. It was yet suggested, three applications for this structure. The synthesis of vertically aligned CNTs, doped and undoped, was optimized among several synthesis parameters such as temperature, oxidizing agent and specially, the catalyst film. The introduction of defects in NTCP by oxidative plasma treatment was evaluated against variables such as pressure, power and exposure time. The association between the defects from these three types of CNTs and the deposition of TiO2 by ALD was assessed by transmission microscopy, Raman, XPS and TGA. The experimental procedure for assembling the 3D structure had been studied step by step by various techniques, from chemical and imaging, up to empirical testing. In the final structure, the photocatalytic properties were evaluated by the organic dye decomposition in an aqueous medium, capacitive properties by cyclic voltammetry and field emission properties through electric field versus emission current curves and F-N diagram. Was obtained high quality NTCs with a height up to 0.5mm with regular diameters and number of walls. On these, it was introduced, in a controllable way, a high amount of defects without jeopardizing the forest structure. The NTCNx forest reach a 0,3nm height with a 2% nitrogen concentration in its typical structure “bamboo-like”. The results show the relation between the type of defect and the deposition of TiO2 by ALD, forming crystalline particles over the NTCP and NTCNx, in this last evenly distributed with uniform size, while on the NTCOx is is formed a dense TiO2 layer shaped by large monocrystalline grains. By process such as heat treatments and CNT transferring was achieved a 3d structure composed by a graphitic carbon layer and VACNTs over a cupper substrate, without disturb the forest assembly. The samples showed electron field emission effect, but its assessment for quantitative analysis was limited to technical issues. The photocatalysis tests showed that immobilization of TiO2 on a dense support prevents the dye degradation in an aqueous medium. The NTCNx shown higher capacitance than NTCP, and the TiO2 was apparently ineffective for improvement of this property.

Nanotubos de carbono

Nanoparticulas

Óxido de titânio

Fotocatálise

Carbon nanotubes

Nitrogen doped carbon nanotubes

Plasma-treated carbon nanotubes

TiO2

ALD

3D carbon structures

Photocatalyst

Supercapacitance

Field emission

From Synthesis To Applications Of Pristine And Nitrogen-Doped Carbon Nanotubes

Goswami, Gopal Krishna

07 1900

Carbon nanotubes (CNTs) are well known as excellent electrical conductors. However, their transport properties are limited by electrical breakdown in ambient. Moreover, the electronic properties can further be modulated by doping. Devices such as Schottky diodes, transistors and logic gates based on un-doped and doped CNT junctions have been realized. Recently, nitrogen doped CNTs show potential application in replacing platinum cathode catalyst in fuel cell technology. We synthesize pristine, nitrogen-doped and nitrogen-doped:pristine CNT intratubular junctions by one-step co-pyrolysis and explore them for different applications. We show that the position of electrical breakdown can be predicted which is essential to know for high current applications. Among other applications, we show that individual CNT intratubular junction exhibits rectifying characteristics. Further investigation indicates the intratubular junction behaves like Schottky diode. Lastly, the potential replacement of platinum by nitrogen doped CNTs in direct methanol fuel cell has been explored.

Carbon Nanotubes (CNTs)

Nitrogen Doped Carbon Nanotubes (NCNTs)

Carbon Nanotubes - Synthesis

Nitrogen-doped:pristine

Single Multi-walled Carbon Nanotubes

Pristine Carbon Nanotubes

Nanowires

Nanoparticles

Nanowire Arrays

Nantechnology

Síntese de estruturas 3D de nanotubos de carbono verticalmente alinhados, dopados e não-dopados, decorados com nanopartículas de óxido de titânio, sua caracterização microestrutural e de propriedades fotocatalíticas e elétricas

Acauan, Luiz Henrique

January 2015

Neste trabalho foi desenvolvido um procedimento experimental para a fabricação de estruturas 3D de nanotubos de carbono crescidos sobre substrato de cobre e decorados com partículas de óxido de titânio. Foram relacionados os três tipos diferentes de NTCs nesta estrutura (simples, dopados com nitrogênio e tratados com plasma) com a deposição do TiO2 por ALD. Foram igualmente propostas três aplicações para esta estrutura. A síntese dos NTCs verticalmente orientados, dopados e não dopados, foi otimizada dentre alguns parâmetros de síntese como temperatura, agente oxidante e principalmente, o filme catalisador. A introdução de defeitos nos NTCP através do tratamento a plasma oxidativo foi avaliada frente a variáveis como pressão, potência e tempo de exposição. A relação entre os defeitos destes três tipos de NTCs e a deposição de TiO2 por ALD foi avaliada por microscopia eletrônica de transmissão, Raman, XPS e TGA. O procedimento experimental para confecção da estrutura 3D foi desenvolvido etapa por etapa via diversas técnicas experimentais, desde caracterização química, imagem, até testes empíricos. Na estrutura final, foram avaliadas as propriedades fotocatalíticas pela decomposição de corante orgânico em meio aquoso, propriedades capacitivas por voltametria cíclica e propriedades de emissão por campo através de curvas de campo elétrico por corrente de emissão e diagramas F-N. Foram obtidas florestas de NTCs de boa qualidade com até 0.5mm de altura, de diâmetros e número de paredes regulares. Nestes foi possível introduzir defeitos de maneira controlável, mantendo o arranjo da floresta. As florestas de NTCNx alcançam uma altura de até 0,3mm com concentração de nitrogênio de 2% tendo os nanotubos uma estrutura típica “bamboo-like”. Os resultados mostram a relação entre o tipo de defeito e a deposição de TiO2 por ALD, obtendo-se partículas cristalinas para os NTCP e NTCNx, sendo neste ultimo as partículas homogeneamente distribuídas e com tamanho uniforme, enquanto nos NTCOx forma-se uma densa camada de TiO2 composta por grandes grãos monocristalinos A partir de processo como tratamentos térmicos e transferência dos NTC de substrato foi possível obter uma estrutura 3D composta de uma camada carbono grafítico e NTC-VAs sobre um substrato de cobre, sem alterar o arranjo inicial das florestas. As amostras mostraram efeito de emissão de elétrons por campo elétrico, porém estas requerem uma análise mais quantitativa. Os ensaios de fotocatálise mostraram que a imobilização do TiO2 em um suporte denso inviabiliza a degradação do corante em meio aquoso. Os NTCNx apresentaram maior capacitância que as mostras de NTCP, e o TiO2 foi aparentemente ineficaz para a melhoria desta propriedade. / In this work, we propose an experimental procedure for fabrication of 3D carbon nanotubes structures anchored with titanium oxide particles, on a copper substrate. We correlate three different types of CNTs from this structure (pristine, doped with nitrogen and treated with plasma) with the deposition of TiO2 by ALD. It was yet suggested, three applications for this structure. The synthesis of vertically aligned CNTs, doped and undoped, was optimized among several synthesis parameters such as temperature, oxidizing agent and specially, the catalyst film. The introduction of defects in NTCP by oxidative plasma treatment was evaluated against variables such as pressure, power and exposure time. The association between the defects from these three types of CNTs and the deposition of TiO2 by ALD was assessed by transmission microscopy, Raman, XPS and TGA. The experimental procedure for assembling the 3D structure had been studied step by step by various techniques, from chemical and imaging, up to empirical testing. In the final structure, the photocatalytic properties were evaluated by the organic dye decomposition in an aqueous medium, capacitive properties by cyclic voltammetry and field emission properties through electric field versus emission current curves and F-N diagram. Was obtained high quality NTCs with a height up to 0.5mm with regular diameters and number of walls. On these, it was introduced, in a controllable way, a high amount of defects without jeopardizing the forest structure. The NTCNx forest reach a 0,3nm height with a 2% nitrogen concentration in its typical structure “bamboo-like”. The results show the relation between the type of defect and the deposition of TiO2 by ALD, forming crystalline particles over the NTCP and NTCNx, in this last evenly distributed with uniform size, while on the NTCOx is is formed a dense TiO2 layer shaped by large monocrystalline grains. By process such as heat treatments and CNT transferring was achieved a 3d structure composed by a graphitic carbon layer and VACNTs over a cupper substrate, without disturb the forest assembly. The samples showed electron field emission effect, but its assessment for quantitative analysis was limited to technical issues. The photocatalysis tests showed that immobilization of TiO2 on a dense support prevents the dye degradation in an aqueous medium. The NTCNx shown higher capacitance than NTCP, and the TiO2 was apparently ineffective for improvement of this property.

Nanotubos de carbono

Nanoparticulas

Óxido de titânio

Fotocatálise

Carbon nanotubes

Nitrogen doped carbon nanotubes

Plasma-treated carbon nanotubes

TiO2

ALD

3D carbon structures

Photocatalyst

Supercapacitance

Field emission

Síntese de estruturas 3D de nanotubos de carbono verticalmente alinhados, dopados e não-dopados, decorados com nanopartículas de óxido de titânio, sua caracterização microestrutural e de propriedades fotocatalíticas e elétricas

Acauan, Luiz Henrique

January 2015

Neste trabalho foi desenvolvido um procedimento experimental para a fabricação de estruturas 3D de nanotubos de carbono crescidos sobre substrato de cobre e decorados com partículas de óxido de titânio. Foram relacionados os três tipos diferentes de NTCs nesta estrutura (simples, dopados com nitrogênio e tratados com plasma) com a deposição do TiO2 por ALD. Foram igualmente propostas três aplicações para esta estrutura. A síntese dos NTCs verticalmente orientados, dopados e não dopados, foi otimizada dentre alguns parâmetros de síntese como temperatura, agente oxidante e principalmente, o filme catalisador. A introdução de defeitos nos NTCP através do tratamento a plasma oxidativo foi avaliada frente a variáveis como pressão, potência e tempo de exposição. A relação entre os defeitos destes três tipos de NTCs e a deposição de TiO2 por ALD foi avaliada por microscopia eletrônica de transmissão, Raman, XPS e TGA. O procedimento experimental para confecção da estrutura 3D foi desenvolvido etapa por etapa via diversas técnicas experimentais, desde caracterização química, imagem, até testes empíricos. Na estrutura final, foram avaliadas as propriedades fotocatalíticas pela decomposição de corante orgânico em meio aquoso, propriedades capacitivas por voltametria cíclica e propriedades de emissão por campo através de curvas de campo elétrico por corrente de emissão e diagramas F-N. Foram obtidas florestas de NTCs de boa qualidade com até 0.5mm de altura, de diâmetros e número de paredes regulares. Nestes foi possível introduzir defeitos de maneira controlável, mantendo o arranjo da floresta. As florestas de NTCNx alcançam uma altura de até 0,3mm com concentração de nitrogênio de 2% tendo os nanotubos uma estrutura típica “bamboo-like”. Os resultados mostram a relação entre o tipo de defeito e a deposição de TiO2 por ALD, obtendo-se partículas cristalinas para os NTCP e NTCNx, sendo neste ultimo as partículas homogeneamente distribuídas e com tamanho uniforme, enquanto nos NTCOx forma-se uma densa camada de TiO2 composta por grandes grãos monocristalinos A partir de processo como tratamentos térmicos e transferência dos NTC de substrato foi possível obter uma estrutura 3D composta de uma camada carbono grafítico e NTC-VAs sobre um substrato de cobre, sem alterar o arranjo inicial das florestas. As amostras mostraram efeito de emissão de elétrons por campo elétrico, porém estas requerem uma análise mais quantitativa. Os ensaios de fotocatálise mostraram que a imobilização do TiO2 em um suporte denso inviabiliza a degradação do corante em meio aquoso. Os NTCNx apresentaram maior capacitância que as mostras de NTCP, e o TiO2 foi aparentemente ineficaz para a melhoria desta propriedade. / In this work, we propose an experimental procedure for fabrication of 3D carbon nanotubes structures anchored with titanium oxide particles, on a copper substrate. We correlate three different types of CNTs from this structure (pristine, doped with nitrogen and treated with plasma) with the deposition of TiO2 by ALD. It was yet suggested, three applications for this structure. The synthesis of vertically aligned CNTs, doped and undoped, was optimized among several synthesis parameters such as temperature, oxidizing agent and specially, the catalyst film. The introduction of defects in NTCP by oxidative plasma treatment was evaluated against variables such as pressure, power and exposure time. The association between the defects from these three types of CNTs and the deposition of TiO2 by ALD was assessed by transmission microscopy, Raman, XPS and TGA. The experimental procedure for assembling the 3D structure had been studied step by step by various techniques, from chemical and imaging, up to empirical testing. In the final structure, the photocatalytic properties were evaluated by the organic dye decomposition in an aqueous medium, capacitive properties by cyclic voltammetry and field emission properties through electric field versus emission current curves and F-N diagram. Was obtained high quality NTCs with a height up to 0.5mm with regular diameters and number of walls. On these, it was introduced, in a controllable way, a high amount of defects without jeopardizing the forest structure. The NTCNx forest reach a 0,3nm height with a 2% nitrogen concentration in its typical structure “bamboo-like”. The results show the relation between the type of defect and the deposition of TiO2 by ALD, forming crystalline particles over the NTCP and NTCNx, in this last evenly distributed with uniform size, while on the NTCOx is is formed a dense TiO2 layer shaped by large monocrystalline grains. By process such as heat treatments and CNT transferring was achieved a 3d structure composed by a graphitic carbon layer and VACNTs over a cupper substrate, without disturb the forest assembly. The samples showed electron field emission effect, but its assessment for quantitative analysis was limited to technical issues. The photocatalysis tests showed that immobilization of TiO2 on a dense support prevents the dye degradation in an aqueous medium. The NTCNx shown higher capacitance than NTCP, and the TiO2 was apparently ineffective for improvement of this property.

Nanotubos de carbono

Nanoparticulas

Óxido de titânio

Fotocatálise

Carbon nanotubes

Nitrogen doped carbon nanotubes

Plasma-treated carbon nanotubes

TiO2

ALD

3D carbon structures

Photocatalyst

Supercapacitance

Field emission