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Macroscale Modeling of the Piezoresistive Effect in Nanofiller-Modified Fiber-Reinforced CompositesSultan Mohammedali Ghazzawi (18369387) 16 April 2024 (has links)
<p dir="ltr">The demand and utilization of fiber-reinforced composites are increasing in various sectors, including aerospace, civil engineering, and automotive industries. Non-destructive methods are necessary for monitoring fiber-reinforced composites due to their complex and often visually undetectable failure modes. An emerging method for monitoring composite structures is through the integration of self-sensing capabilities. Self-sensing in nanocomposites can be achieved through nanofiller modifications, which involve introducing an adequate amount of nanofillers into the matrix, such as carbon nanotubes (CNTs) and carbon nanofillers (CNFs). These fillers form an electrically well-connected network that allows the electrical current to travel through conductive pathways. The disruption of connectivity of these pathways, caused by mechanical deformations or damages, results in a change in the overall conductivity of the material, thereby enabling intrinsic self-sensing.</p><p dir="ltr">Currently, the majority of predictive modeling attempts in the field of self-sensing nanocomposites have been dedicated to microscale piezoresistivity. There has been a lack of research conducted on the modeling of strain-induced resistivity changes in macroscale fiber-matrix material systems. As a matter of fact, no analytical macroscale model that addresses the impact of continuous fiber reinforcement in nanocomposites has been presented in the literature. This gap is significant because it is impossible to make meaningful structural condition predictions without models relating observed resistivity changes to the mechanical condition of the composite. Accordingly, this dissertation presents a set of three research contributions. The overall objective of these contributions is to address this knowledge gap by developing and validating an analytical model. In addition to advancing our theoretical understanding, this model provides a practical methodology for predicting the piezoresistive properties of continuous fiber-reinforced composites with integrated nanofillers.</p><p dir="ltr">To bridge the above-mentioned research gap, three scholarly contributions are presented in this dissertation. The first contribution proposes an analytical model that aims to predict the variations in resistivity within a material system comprising a nanofiller-modified polymer and continuous fiber reinforcement, specifically in response to axial strain. The fundamental principle underlying our methodology involves the novel use of the concentric cylindrical assembly (CCA) homogenization technique to model piezoresistivity. The initial step involves the establishment of a domain consisting of concentric cylinders that represent a continuous reinforcing fiber phase wrapped around by a nanofiller-modified matrix phase. Subsequently, the system undergoes homogenization to facilitate the prediction of changes in the axial and transverse resistivity of the concentric cylinder as a consequence of longitudinal deformations. The second contribution investigates the effect of radial deformations on piezoresistivity. Here, we demonstrate yet another novel application of the CCA homogenization technique to determine piezoresistivity. This contribution concludes by presenting closed-form analytical relations that describe changes in axial and transverse resistivity as functions of externally applied radial strain. The third contribution involves computationally analyzing piezoresistivity in fiber-reinforced laminae by using three-dimensional representative volume elements (RVE) with a CNF/epoxy matrix. By comparing the single-fiber-based analytical model with the computational model, we can investigate the impact of interactions between multiple adjacent fibers on the piezoresistive properties of the material. The study revealed that the differences between the single-fiber CCA analytical model and the computational model are quite small, particularly for composites with low- to moderate-fiber volume fractions that undergo relatively minor deformations. This means that the analytical methods herein derived can be used to make accurate predictions without resorting to much more laborious computational methods.</p><p dir="ltr">In summary, the impact of this dissertation work lies in the development of novel analytical closed-form nonlinear piezoresistive relations. These relations relate the electrical conductivity/resistivity changes induced by axial or lateral mechanical deformations in directions parallel and perpendicular to the reinforcing continuous fibers within fiber-reinforced nanocomposites and are validated against in-depth computational analyses. Therefore, these models provide an important and first-ever bridge between simply observing electrical changes in a self-sensing fiber-reinforced composite and relating such observations to the mechanical state of the material.</p>
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DEVELOPMENT OF ELECTROCHEMICAL AND COLORIMETRIC SENSING PLATFORMS FOR AGRICULTURE AND HEALTHCARE APPLICATIONSAna Maria NA Ulloa Gomez (14209715) 04 December 2022 (has links)
<p>Fully portable, rapid, and user-friendly sensors can successfully lead to the continuous monitoring of toxins present in the ecosystem as well as the detection of biomarkers to prevent diseases. Towards this goal, we explore electrochemical and colorimetric methods to develop platforms for the on-site detection of pesticides, heavy metals, and inflammation biomarkers. </p>
<p>This thesis presents work with the primary aim of developing non-biological and biological-based platforms. Chapter 2 describes a fully roll-to-roll electrochemical sensor with high sensing and manufacturing reproducibility for detecting nitroaromatic organophosphorus pesticides (NOPPs). This sensor is based on a flexible, screen-printed silver electrode modified with a graphene nanoplatelets coating and a zirconia coating. This chapter outlines the evaluation of the electrocatalytic activity of zirconia towards the reduction of NOPPs, using methyl parathion as a pesticide sample. Furthermore, it describes the fundamentals of electrochemistry focused on voltammetry techniques used for surface characterization and quantification. The topics reviewed serve as the first step to further manufacturing sensors through large-scale methods (e.g., roll-to-roll). Chapter 3 describes the development of a dual-modality sensing system for the detection of mercury in river waters with high accuracy and precision. The objective of this project was to incorporate colorimetric platforms into the electrochemical methods to create a dual detection design and avert false positives and negatives. Here, novel bio-functional aptamers were incorporated in a sensor containing a paper test that detects mercury by a color change and an electrochemical test that measures charge transfer resistance changes upon aptamer-target interaction. For this platform, the colorimetric test demonstrates the utilization of two systems that consist of silver and gold citrate-capped nanoparticles bio-functionalized with highly specific aptamers. The mechanism of detection of these two systems is through Ps-AgNPs and Ps-AuNPs aggregation as a result of ssDNA-Hg2+ interaction. Using Ps-AuNPs microparticles, Chapter 4 describes a fully colorimetric and smartphone-based biosensor for detecting cardiac troponin T, a biomarker for diagnosing acute myocardial infarction. Here, a comparison in detection performance between Whatman grade 1 and high-flow filter paper is reviewed. Finally, Chapter 5 evaluates the colorimetric detection performance of Ps-AuNPs microparticles towards imidacloprid and carbendazim, two of the pesticides most found in imported produce in the United States. The chapter compares gold-based microparticles in which different aptamers were immobilized, and image acquisition approaches.</p>
<p>All sensors reported in this thesis are especially suitable for environmental contaminants monitoring or point-of-care diagnosis applications. The materials selection, use or synthesis, and platforms’ performance optimization, development, and feasibility for scale-up manufacturing are expected to advance on-site biosensing technologies and their commercialization.</p>
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NOVEL HIGH-RATE MANUFACTURING PROCESS FOR MULTIFUNCTIONAL THERMOPLASTIC COMPOSITESJessica Lavorata Anderson (17593293) 11 December 2023 (has links)
<p dir="ltr">In pursuit of enhanced fuel economy, the automotive industry is exploring the substitution of metal components with lightweight polymer composites. These components must withstand elevated static loading and crash performance, while ideally offering added functionalities and reduced weight. To tackle these challenges, this research presents an innovative manufacturing method aimed at reducing costs and cycle times associated with continuous fiber polymer composites. This method involves producing a linear thermoplastic composite rod known as M-TOW (Multi-tow), which can be molded into intricate shapes to serve as tailored structural reinforcement in hybrid-molded parts. The research encompasses the processing of M-TOW, with a focus on predicting consolidation using Darcy’s law, integrating functional components for thermal and electrical conductivity using overbraided metallic wire or sensing using optical fibers, and its application in real-world scenarios. These advancements showcase the versatility and potential of M-TOW in high-rate continuous fiber manufacturing, paving the way for multifunctional hybrid molded structures.<br><br></p>
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Making Temperature Measurements Inside An Ammonium Perchlorate Crystal Using Encapsulated ThermophosphorsChase William Wernex (17551410) 05 December 2023 (has links)
<p dir="ltr">Phosphor thermography is an effective technique for making spatially resolved temperature measurements on surfaces, however little consideration has been given to incorporating the phosphors inside crystalline materials to make internal measurements. Doing so would grant optical access to the phosphors through the crystal. In this work, we prepared a thermographic energetic composite via fast crash encapsulation of BaMgAl<sub>10</sub>O<sub>17</sub>:Eu (BAM) in ammonium perchlorate (AP) crystals, which enabled the use of phosphor thermography to spatially resolve the temperature of the energetic composite. We demonstrate that the temperature measurements show good agreement with thermocouple measurements. The ability to calibrate the material was also demonstrated and compared to the response in dynamic thermal environments. Usability limits as well as thermal stability issues of the composite were also investigated and discussed. The successful encapsulation of BAM within AP and demonstration of thermographic behavior in the composite, indicate the viability of using encapsulation as a method to produce thermographic energetic composites.</p>
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CHARACTERIZATION AND SIMULATED ANALYSIS OF CARBON FIBER WITH NANOMATERIALS AND ADDITIVE MANUFACTURINGOluwaseun Peter Omole (17002056) 03 January 2024 (has links)
<p dir="ltr">Due to the vast increase and versatility of Additive Manufacturing and 3D-printing, in this study, the mechanical behavior of implementing both continuous and short carbon fiber within Nylon and investigated for its effectiveness within additively manufactured prints. Here, 0.1wt% of pure nylon was combined with carbon nanotubes through both dry and heat mixing to determine the best method and used to create printable filaments. Compression, tensile and short beam shear (SBS) samples were created and tested to determine maximum deformation and were simulated using ANSYS and its ACP Pre tool. SEM imaging was used to analyze CNT integration within the nylon filament, as well as the fractography of tested samples. Experimental testing shows that compressive strength increased by 28%, and the average SBS samples increased by 8% with minimal impacts on the tensile strength. The simulated results for Nylon/CF tensile samples were compared to experimental results and showed that lower amounts of carbon fiber samples tend to have lower errors.</p>
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Integrated Sinc Method for Composite and Hybrid StructuresSlemp, Wesley Campbell Hop 07 July 2010 (has links)
Composite materials and hybrid materials such as fiber-metal laminates, and functionally graded materials are increasingly common in application in aerospace structures. However, adhesive bonding of dissimilar materials makes these materials susceptible to delamination. The use of integrated Sinc methods for predicting interlaminar failure in laminated composites and hybrid material systems was examined. Because the Sinc methods first approximate the highest-order derivative in the governing equation, the in-plane derivatives of in-plane strain needed to obtain interlaminar stresses by integration of the equilibrium equations of 3D elasticity are known without post-processing. Interlaminar stresses obtained with the Sinc method based on Interpolation of Highest derivative were compared for the first-order and third-order shear deformable theories, the refined zigzag beam theory and the higher-order shear and normal deformable beam theory. The results indicate that the interlaminar stresses by the zigzag theory compare well with those obtained by a 3D finite element analysis, while the traditional equivalent single layer theories perform well for some laminates.
The philosophy of the Sinc method based on Interpolation of Highest Derivative was extended to create a novel weak form based approach called the Integrated Local Petrov-Galerkin Sinc Method. The Integrated Local Petrov-Galerkin Sinc Method is easily utilized for boundary-value problem on non-rectangular domains as demonstrated for analysis of elastic and elastic-plastic plane-stress panels with elliptical notches. The numerical results showed excellent accuracy compared to similar results obtained with the finite element method.
The Integrated Local Petrov-Galerkin Sinc Method was used to analyze interlaminar debonding of composite and fiber-metal laminated beams. A double-cantilever beam and a fixed-ratio mixed mode beam were analyzed using the Integrated Local Petrov-Galerkin Sinc Method and the results were shown to correlate well with those by the finite element method. An adaptive Sinc point distribution technique was implemented for the delamination analysis which significantly improved the methods accuracy for the present problem. Delamination of a GLARE, plane-strain specimen was also analyzed using the Integrated Local Petrov-Galerkin Sinc Method. The results correlate well with 2D, plane-strain analysis by the finite element method, including interlaminar stresses obtained by through-the-thickness integration of the equilibrium equations of 3D elasticity. / Ph. D.
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<b>Effect of Film Thickness on CeO</b><sub><strong>2</strong></sub><b>/Au Vertically Aligned Nanocomposite Morphology and Properties</b>Matteo T Moceri (18431868) 26 April 2024 (has links)
<p dir="ltr">The primary goal of this work is to gain a fundamental understanding on how growth conditions affect the morphology and crystallography orientation of CeO<sub>2</sub>/Au vertically aligned nanocomposite (VAN) thin films. Focus has been placed on how the changes in morphology and crystallography translate to tunable optical properties. The morphological effects have been observed and analyzed via two main approaches: the change in morphology was observed at multiple points along the film thickness, and the morphology at the film/substrate interface has been analyzed with respect to total film thickness. The changes in Au crystallography orientations have been observed by measuring peak shift in XRD patterns and determining the resulting in- and out-of-plane strain. To observe additional effects of this morphology change, optical measurements have been taken for films at the bottom, middle, and top of the thickness range. Strong trends in transmittance, plasmonic absorption peak shifts and hyperbolic permittivity behavior are correlated with the film thickness. This tunability of optical properties likely arises from changes in both Au pillar phase morphology and crystal orientation. These findings demonstrate that changing film thickness may be a desirable method to easily tune the morphology and optical properties of VAN thin films.</p>
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Functional silica materials for controlled release, sensing and elimination of target moleculesCandel Busquets, Inmaculada 29 July 2014 (has links)
La presente tesis doctoral titulada “Materiales de sílice funcionales para la
liberación controlada, detección y eliminación de moléculas de interés” se centra
en el diseño y desarrollo de materiales híbridos orgánico-inorgánicos mediante la
aplicación de los conceptos de Química Supramolecular. Durante el desarrollo de
la presente tesis doctoral se han preparado y caracterizado diferentes materiales
de base silícea para distintas aplicaciones.
La primera parte de la tesis se centra en el desarrollo de materiales de base silícea
capaces de variar su comportamiento fluorescente en función de la presencia o
ausencia de un cierto analito en el medio. Estos materiales emplean como soporte
nanopartículas de sílice que se funcionalizan superficialmente con dos unidades
diferentes, una coordinante y una indicadora (un fluoróforo). La interacción del
analito de interés (en nuestro caso aniones) con la unidad coordinante modificará
las propiedades emisivas del fluoróforo. Así, se han preparado dos materiales en
los cuales el grupo fluorescente es rodamina mientras que el grupo coordinante
es un imidazolato o una sal de guanidinio respectivamente. Una vez
caracterizados ambos materiales se estudió su comportamiento frente a
diferentes especies aniónicas a diferentes concentraciones resultando selectivos a
la presencia de benzoato (el material funcionalizado con imidazolatos),
dihidrógeno fosfato e hidrógeno sulfato (el material funcionalizado con sales de
guanidinio).
El tercer capítulo de la tesis se centra en la aplicación de materiales híbridos
orgánico-inorgánicos para la detección y eliminación de especies altamente
tóxicas como son los agentes neurotóxicos. Estos son compuestos
organofosforados capaces de causar graves lesiones en el sistema nervioso
central. En una primera aproximación se emplea el concepto de puerta molecular
para la detección de agentes neurotóxicos. Para ello, se utiliza como soporte
inorgánico un material mesoporoso de sílice (MCM-41) cuyos poros se cargan con
un colorante que actúa de indicador mientras que la superficie externa del mismo se funcionaliza con una molécula capaz de reaccionar con dichos agentes
neurotóxicos. Dicha molécula es capaz de interaccionar entre sí (mediante enlaces
de hidrógeno) formando una red que mantiene bloqueada la salida de los poros.
En presencia de DCP (dietilclorofosfato, un simulante de agente neurotóxico), y
después de que este reaccione con dicha molécula, se produce una reorganización
espacial que permite la liberación del colorante. De este modo, la presencia de los
agentes neurotóxicos está señalizada mediante un cambio de color. En una
segunda aproximación se aborda el uso de soportes inorgánicos de tipo MCM-41
como materiales para la eliminación de agentes neurotóxicos. Para ello se
modificaron químicamente las superficies de estos materiales silíceos mediante
tratamiento con distintas bases. Como consecuencia de este tratamiento básico
los silanoles de la superficie se desprotonan dando lugar a los correspondientes
silanolatos (nucleófilos fuertes). Estos silanolatos son capaces de reaccionar con
los agentes neurotóxicos descomponiéndolos y favoreciendo su eliminación de un
medio contaminado.
Por último, se estudia la aplicación de materiales híbridos orgánico-inorgánicos
funcionalizados con puertas moleculares en aplicaciones de liberación controlada,
concretamente, en liberación controlada intracelular de fármacos de interés. El
material híbrido consta de un soporte de sílice mesoporosa cuyos poros se cargan
con un compuesto citotóxico (camptotecina) y su superficie externa se
funcionaliza con una gluconamida. La presencia de una monocapa densa de
gluconamidas por el exterior del material inhibe la liberación del compuesto
citotóxico. Al añadir enzimas con capacidad para hidrolizar enlaces amida
(amidasa y pronasa) se produce la liberación de la camptotecina. El correcto
funcionamiento del material se comprobó in vitro e in vivo (en células HeLa). / Candel Busquets, I. (2014). Functional silica materials for controlled release, sensing and elimination of target molecules [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/39101
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Optical detection of chemical species of environmental and biological relevance using molecular sensors and hybrid materialsLo Presti, Maria 02 September 2021 (has links)
[ES] La presente tesis doctoral titulada "Detección óptica de especies químicas de importancia ambiental y biológica utilizando sensores moleculares y materiales híbridos" se centra en el diseño, preparación, caracterización y evaluación de sensores químicos moleculares. El trabajo realizado se puede dividir en dos partes: (i) síntesis de sensores de cationes metálicos en disolución y (ii) síntesis y caracterización de nanopartículas híbridas orgánico-inorgánicas para el reconocimiento de especies químicas y biológicas.
En el primer capítulo se introduce el marco en el que se engloban los fundamentos teóricos de la química supramolecular en que se basan los estudios prácticos realizados durante la presente tesis doctoral. A continuación, en el capítulo dos, se presentan los objetivos generales de la tesis.
En el tercer capítulo se presenta un quimiodosímetro cromo-fluorogénico, capaz de detectar selectivamente cationes trivalentes entre cationes y aniones monovalentes y divalentes mediante una reacción de deshidratación en agua.
En el cuarto capítulo se presenta una unidad (BODIPY) conectada electrónicamente con un macrociclo dithia-dioxa-aza. Las soluciones de acetonitrilo y agua-acetonitrilo 95: 5 v / v de la sonda mostraron una banda ICT en la zona visible y son casi no emisivas. Cuando se utilizó acetonitrilo como disolvente, la adición de Hg (II) y cationes metálicos trivalentes indujo un cambio hipsocrómico de la banda de absorción y mejoras moderadas de la emisión. Se obtuvo una respuesta altamente selectiva al utilizar medios competitivos como agua-acetonitrilo 95:5 v/v. En este caso, sólo el Hg (II) indujo un cambio hipsocrómico de la banda de absorción y una mejora marcada de la emisión.
El quinto capítulo explora el desarrollo de sensores para berberina y amantadina. Dos moléculas de interés biológico por su uso como fármacos. Se han preparado tres sistemas de sensores basados en la aproximación de puertas moleculares. En concreto, sobre nanopartículas MCM-41 cargadas con rodamina B como unidad de señalización, se ha llevado a cabo la funcionalización con diversas aminas y el bloqueo de poros con cucurbituril CB7. Las aminas utilizadas son
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ciclohexilamina, bencilamina y amantadina. Los materiales obtenidos se han caracterizado por técnicas de difracción de rayos X y microscopía electrónica de transmisión confirmando la estructura mesoporosa de las nanopartículas. Los materiales preparados muestran una respuesta a la berberina y la adamantina, quitando el tapón y liberando el tinte fluorescente al medio. La respuesta de los materiales a las dos sustancias de interés (berberina y amantadina) depende de la estructura química de cada uno de los materiales en función de las constantes de afinidad entre el analito y CB7. Los resultados obtenidos abren el camino al uso de puertas moleculares como sensores de berberina y amantadina. / [CA] La present tesi doctoral titulada "Detecció òptica d'espècies químiques d'importància ambiental i biològica utilitzant sensors moleculars i materials híbrids" se centra en el disseny, preparació, caracterització i avaluació de sensors químics moleculars. El treball realitzat es pot dividir en dues parts: (i) síntesi de sensors de cations metàl·lics en dissolució i (ii) síntesi i caracterització de nanopartícules híbrides orgànic-inorgànics per al reconeixement d'espècies químiques i biològiques.
En el primer capítol s'introdueix el marc en el qual s'engloben els fonaments teòrics de la química supramolecular en què es basen els estudis pràctics realitzats durant la present tesi doctoral. A continuació, en el capítol dos, es presenten els objectius generals de la tesi.
En el tercer capítol es presenta un quimiodosímetro crom-fluorogénic, capaç de detectar selectivament cations trivalents entre cations i anions monovalents i divalents mitjançant una reacció de deshidratació en aigua.
En el quart capítol es presenta una unitat (BODIPY) connectada electrònicament amb un macrocicle dithia-dioxa-aza. Les solucions de acetonitril i aigua-acetonitril 95:5 v/v de la sonda van mostrar una banda ICT a la zona visible i són gairebé no emisivas. Quan es va utilitzar acetonitril com a dissolvent, l'addició de Hg (II) i cations metàl·lics trivalents va induir un canvi hipsocròmic de la banda d'absorció i millores moderades de l'emissió. Es va obtenir una resposta altament selectiva a l'utilitzar mitjans competitius com aigua-acetonitril 95:5 v/v. En aquest cas, només el Hg (II) va induir un canvi hipsocròmic de la banda d'absorció i una millora marcada de l'emissió.
El cinquè capítol explora el desenvolupament de sensors per berberina i amantadina. Dues molècules d'interès biològic pel seu ús com a fàrmacs. S'han preparat tres sistemes de sensors basats en l'aproximació de portes moleculars. En concret, sobre nanopartícules MCM-41 carregades amb rodamina B com a unitat de senyalització, s'ha dut a terme la funcionalització amb diverses amines i el bloqueig de porus amb cucurbituril CB7. Les amines utilitzades són ciclohexilamina, bencilamina i amantadina. Els materials obtinguts s'han caracteritzat per tècniques
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de difracció de raigs X i microscòpia electrònica de transmissió confirmant l'estructura mesoporosa de les nanopartícules. Els materials preparats mostren una resposta a la berberina i la adamantina, llevant el tap i alliberant el tint fluorescent a l'mig. La resposta dels materials a les dues substàncies d'interès (berberina i amantadina) depèn de l'estructura química de cada un dels materials en funció de les constants d'afinitat entre l'anàlit i CB7. Els resultats obtinguts obren el camí a l'ús de portes moleculars com a sensors de berberina i amantadina. / [EN] The present doctoral thesis entitled "Optical detection of chemical species of environmental and biological importance using molecular sensors and hybrid materials" focuses on the design, preparation, characterization and evaluation of molecular chemical sensors. The work carried out can be divided into two parts: (i) synthesis of metal cation sensors in solution and (ii) synthesis and characterization of hybrid organic-inorganic nanoparticles for the recognition of chemical and biological species.
The first chapter introduces the framework that encompasses the theoretical foundations of supramolecular chemistry on which the practical studies carried out during this doctoral thesis are based. Next, in chapter two, the general objectives of the thesis are presented.
In the third chapter, a chromium-fluorogenic chemodosimeter is presented, capable of selectively detecting trivalent cations by means of a dehydration reaction in water.
The fourth chapter presents a new compound containing a BODIPY unit electronically connected with a dithia-dioxa-aza macrocycle. Acetonitrile and water-acetonitrile 95:5 v/v solutions of the probe showed an ICT band in the visible zone and were nearly non-emissive. When acetonitrile was used as a solvent, addition of Hg(II) and trivalent metal cations induced an hypsochromic shift of the absorption band and moderate emission enhancements. A highly selective response was obtained when using competitive media such as water- acetonitrile 95:5 v/v. In this case only Hg(II) induced a hypsochromic shift of the absorption band and a marked emission enhancement.
The fifth chapter explores the development of sensors for berberine and amantadine; two molecules of biological interest due to their use as drugs. Three sensing systems based on a "molecular gate" approximation have been prepared. Specifically, MCM-41 nanoparticles were loaded with Rhodamine B as a signalling unit, functionalized with various amines and capped with cucurbituril CB7. The amines used are cyclohexylamine, benzylamine and amantadine., The materials obtained were characterized by X-ray diffraction techniques and transmission
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electron microscopy, confirming the mesoporous structure of the nanoparticles. The prepared materials showed a response to berberine and adamantine, which induced release of the fluorescent dye to the medium. The response of the materials to the two substances of interest (berberine and amantadine) depends on the chemical structure of the capping ensemble and it is a function of the affinity constants between the analyte and CB7. The results obtained open the way to the use of gated materials as berberine and amantadine probes. / We thank the Spanish Government (MAT2015-64139-C4-1-R) and Generalitat
Valenciana (PROMETEOII/2014/047). M. L. P. thanks Generalitat Valenciana for her
Grisolia fellowship. Thanks are also due to Fundação para a Ciência e Tecnologia
(Portugal) for financial support to the Portuguese NMR network (PTNMR, Bruker
Avance III 400-Univ. Minho), FCT and FEDER (European Fund for Regional
Development)-COMPETEQREN- EU for financial support to the research centre
CQ/UM [PEst-C/ QUI/UI0686/2013 (FCOMP-01-0124-FEDER-037302)], and a post-
doctoral grant to R. M. F. Batista (SFRH/BPD/79333/2011). / Lo Presti, M. (2021). Optical detection of chemical species of environmental and biological relevance using molecular sensors and hybrid materials [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/172664
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Enzyme-functionalized hybrid mesoporous nanodevices for sensing, controlled release and molecular communicationLlopis Lorente, Antoni 04 March 2019 (has links)
Tesis por compendio / [ES] La presente tesis doctoral titulada "Nanodispositivos mesoporosos híbridos funcionalizados con enzimas para detección, liberación controlada y comunicación molecular" se centra en el diseño, preparación, caracterización y evaluación de distintos nanodispositivos híbridos orgánico-inorgánicos utilizando como soporte nanopartículas tipo Janus de oro y sílice mesoporosa, que se equipan con enzimas, especies fluorescentes y puertas moleculares.
Como conclusión general, los estudios realizados muestran que la incorporación de enzimas sobre nanopartículas permite introducir funciones de reconocimiento con alta especificidad y diseñar nanodispositivos avanzados para distintas finalidades. La combinación de nanopartículas híbridas con grupos orgánicos como puertas moleculares, efectores enzimáticos y especies cromo- fluorogénicas o fármacos puede resultar muy versátil; y se espera que los resultados obtenidos puedan inspirar el desarrollo de nuevos materiales inteligentes con aplicación en distintas áreas como la nanomedicina y la detección de moléculas de interés. / [CA] La present tesi doctoral titulada "Nanodispositius mesoporosos híbrids funcionalitzats amb enzims per a detecció, alliberació controlada i comunicació molecular" es centra en el disseny, preparació, caracterització i avaluació de distints nanodispositius híbrids orgànic-inorgànics utilitzant com a suport nanopartícules tipus Janus d'or i sílice mesoporosa, que s'equipen amb enzims, espècies fluorescents i portes moleculars.
Com a conclusió general, els estudis realitzats mostren que la incorporació d'enzims sobre nanopartícules permeten introduir funcions de reconeixement amb alta especificitat i dissenyar nanodispositius avançats per a distintes finalitats. La combinació de nanopartícules híbrides amb grups orgànics com portes moleculars, efectors enzimàtics i espècies cromo-fluorogèniques o fàrmacs pot resultar molt versàtil; i s'espera que els resultats obsessos inspiren el desenvolupament de nous materials intel·ligents amb aplicació en distintes àrees com la nanomedicina i la detecció de molècules d'interés. / [EN] This PhD thesis entitled "Enzyme-functionalized hybrid mesoporous nanodevices for sensing, controlled release and molecular communication" is focused on the design, synthesis, characterization and evaluation of several hybrid organic-inorganic nanodevices using Janus gold-mesoporous silica nanoparticles as scaffolds, equipped with enzymes, fluorescent species and molecular gates.
In conclusion, these studies show that the incorporation of enzymes on nanoparticles allows to introduce recognition capabilities with high specificity and to design advanced nanodevices for different purposes. The combination of hybrid nanoparticles with organic groups such as molecular gates, enzymatic effectors and chromo-fluorogenic species or drugs can be very versatile; and we hope that the obtained results inspire the development of new smart materials with application in different areas such as nanomedice and sensing. / Llopis Lorente, A. (2019). Enzyme-functionalized hybrid mesoporous nanodevices for sensing, controlled release and molecular communication [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/117612 / Compendio
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