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Preparation And Characterization Of Silver Sers NanotagsKibar, Seda 01 December 2010 (has links) (PDF)
ABSTRACT
PREPARATION AND CHARACTERIZATION OF SILVER SERS NANOTAGS
Kibar, Seda
M.S., Department of Chemistry
Supervisor: Prof. Dr. Mü / rvet Volkan
December 2010, 88 pages
Tags are materials used for labeling substances and so make possible the qualitative and quantitative analysis both in macroscopic and microscopic world. Nowadays, surface enhanced Raman spectroscopy became the favored one among the optical based-tag detection systems. Progress in surface enhanced Raman detection and imaging technologies depends on the availability of Raman labels with strong light scattering characteristics.
In this study various SERS nanotags were prepared. An ideal SERS nanotag consists of three parts, core nanoparticle for enhancement, Raman active molecule for signature and a shell for protection and further functionalization.
As a core material, silver nanoparticles were prepared using the chemical reduction method with sodium citrate as reductant. SERS enhancement provided by Ag particles prepared was examined. For colloidal stabilization and further surface modifications, silica with a controlled thickness was deposited on Ag nanoparticles.
Three single-dye doped nanotags, Ag-BCB@SiO2 Ag-CFV@SiO2 and Ag-CV@SiO2 were prepared using positively charged dyes, brilliant cresyl blue (BCB), cresyl fast violet (CFV) and cresyl violet (CV). The effects of silica thickness and dye concentration in the reaction medium were examined. Stability of prepared nanotags and repeatability of the method were investigated.
Multi-dye doped nanotags were prepared using BCB and CFV solutions mixed at various concentration ratios. Resulting Raman spectra Ag-BCB-CFV@SiO2 nanotags successfully exhibited characteristic peaks of each dye with a good resolution. In addition, the molar ratio between dyes BCB and CFV was reflected on the related spectra. A linear correlation was observed between the molar ratio of the dyes and their Raman intensity ratio.
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Patterned nanoarray sers substrates for pathogen detectionMarotta, Nicole Ella 25 August 2010 (has links)
The objectives of the work presented were to 1) fabricate reproducible nanorod array SERS substrates, 2) detection of bacteria using nanorod substrates, 3) detection of DNA hybridization using nanorod substrates and 4) critically evaluate the sensing method.
Important findings from this work are as follows. A novel method for batch fabrication of substrates for surface enhanced Raman scattering (SERS) has been developed using a modified platen machined to fit in a commercial electron beam evaporator. The use of this holder enables simultaneous deposition of silver nanorod (AgNR) arrays onto six microscope slide substrates utilizing glancing angle deposition. In addition to multiple substrate fabrication, patterning of the AgNR substrates with 36 wells allows for physical isolation of low volume samples. The well-to-well, slide-to-slide, and batch-to-batch variability in both physical characteristics and SERS response of substrates prepared via this method was nominal. A critical issue in the continued development of AgNR substrates is their stability over time, and the potential impact on the SERS response. The thermal stability of the arrays was investigated and changes in surface morphology were evaluated using scanning electron microscopy and x-ray diffraction and correlated with changes in SERS enhancement. The findings suggest that the shelf-life of AgNR arrays is limited by migration of silver on the surface. Continued characterization of the AgNR arrays was carried out using fluorescent polystyrene microspheres of two different sizes. Theory suggests that enhancement between nanorods would be significantly greater than at the tops due to contributing electromagnetic fields from each nanostructure. In contrast to the theory, SERS response of microspheres confined to the tops of the AgNR array was significantly greater than that for beads located within the array. The location of the microspheres was established using optical fluorescence and scanning electron microscopy.
The application of SERS to characterizing pathogens such as bacteria and viruses is an active area of investigation. AgNR array-based SERS substrates have enabled detection of pathogens present in biofluids. Specifically, several publications have focused on determining the spectral bands characteristic of bacteria from different species and cell lines. Studies were carried out on three strains of bacteria as well as the medium in which the bacteria were grown. The spectra of the bacteria and medium were surprisingly similar, so additional spectra were acquired for commonly used bacterial growth media. In many instances, these spectra were similar to published spectra purportedly characteristic of specific bacterial species.
In addition to bacterial samples, nucleic acid hybridization assays were investigated. Oligonucleotide pairs specifically designed to detect respiratory syncytial virus (RSV) in nasal fluids were prepared and evaluated. SERS spectra acquired on oligos, alone or in combination, contain the known spectral signatures of the nucleosides that comprise the oligo. However, spectra acquired on an oligo with a 5'- or 3' thiol were distinctly different from that acquired on the identical oligo without a thiol pendant group suggesting some control over the orientation of the oligo on the nanorod surface. The signal enhancement in SERS depends markedly upon the location of the probe relative to the substrate surface. By systematic placement of nucleotide markers along the oligo chain, the point at which the nucleotide disappears from the spectrum was identified.
The overall findings for AgNR SERS substrates suggest that the applicability of SERS for detecting nucleic acid hybridization is limited. The strong distance dependence coupled with the lack of substrate stability at temperatures required for annealing oligos during hybridization suggest that AgNRs are not the platform to use for hybridization assays.
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Enhancement of Raman signals : coherent Raman scattering and surface enhanced Raman spectroscopyChou, He-Chun 06 July 2012 (has links)
Raman spectroscopy is a promising technique because it contains abundant vibrational chemical information. However, Raman spectroscopy is restricted by its small scattering cross section, and many techniques have been developed to amplify Raman scattering intensity. In this dissertation, I study two of these techniques, coherent Raman scattering and surface enhanced Raman scattering and discuss their properties. In the first part of my dissertation, I investigate two coherent Raman processes, coherent anti-Stokes Raman scattering (CARS) and stimulated Raman scattering (SRS). In CARS project, I mainly focus on the molecular resonance effect on detection sensitivity, and I find the detection sensitivity can be pushed into 10 [micromolar] with the assistance of molecular resonance. Also, I am able to retrieve background-free Raman spectra from nonresonant signals. For SRS, we develop a new SRS system by applying spectral focusing mechanism technique. We examine the feasibility and sensitivity of our SRS system. The SRS spectra of standards obtained from our system is consistent with literature, and the sensitivity of our system can achieve 10 times above shot-noise limit. In second part of this dissertation, I study surface enhanced Raman scattering (SERS) and related plasmonic effects. I synthesize different shapes of nanoparticles, including nanorod, nanodimer structure with gap and pyramids by template method, and study how electric field enhancement effects correlate to SERS by two photon luminescence (TPL). Also, I build an optical system to study optical image, spectra and particle morphology together. I find that SERS intensity distribution is inhomogeneous and closely related to nanoparticle shape and polarization direction. However, TPL and SERS are not completely correlated, and I believe different relaxation pathways of TPL and SERS and coupling of LSPR and local fields at different frequencies cause unclear correlation between them. / text
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Markierungsfreie Proteinanalytik mit oberflächenverstärkter Ramanspektroskopie / Label-free protein analytics with surface-enhanced Raman spectroscopyChristou, Konstantin 25 August 2009 (has links)
No description available.
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Χρησιμοποίηση της μεθόδου SERS στην ελεγχόμενη αποδέσμευση μικρού μοριακού βάρους χημικών ενώσεων από πολυμερικές μήτρεςΑναστασόπουλος, Ιωάννης 27 March 2012 (has links)
Η χρήση των πολυμερών στον τομέα της ιατρικής βιομηχανίας κερδίζει ολοένα και μεγαλύτερο έδαφος τα τελευταία χρόνια έχοντας ήδη κάνει ισχυρή την παρουσία τους σε ένα ευρύ πεδίο κλάδων της βιοϊατρικής όπως στη μηχανική ιστών, στην εμφύτευση ιατρικών συσκευών και τεχνητών οργάνων, στην προσθετική και την οφθαλμολογία, στην οδοντιατρική και την αποκατάσταση οστών, στη χημειοθεραπεία και σε ποικιλία άλλων ιατρικών εφαρμογών. Με τη χρήση πολυμερικών συστημάτων μεταφοράς δραστικών ουσιών καθίσταται ικανή η ελεγχόμενη αργή αποδέσμευση φαρμάκων στο σώμα καθώς και η στοχευμένη απελευθέρωσή τους σε σημεία όπου υπάρχουν φλεγμονές ή όγκοι. Τοιουτοτρόπως, χημειοθεραπείες με χρήση βιοπολυμερών ως διαμεσολαβητές, προβάλλουν ως δυνητικές υποψήφιοι στην αντιμετώπιση του καρκίνου του εγκεφάλου με ενθαρρυντικά αποτελέσματα. Συγκρινόμενη με την τυπική συστημική χημειοθεραπεία, η ενδοογκική απελευθέρωση φαρμάκου με τη χρήση βιοπολυμερών θεωρητικώς παρουσιάζει αρκετά πλεονεκτήματα: τα βιοπολυμερή μπορούν να μεταφέρουν το φάρμακο απευθείας στον όγκο-στόχο αυξάνοντας τη συγκέντρωση τοπικά και παράλληλα μειώνοντας τη συστημική τοξικότητα· μπορούν έτσι να χρησιμοποιούνται στη θεραπεία ανοσοκατασταλμένων ασθενών που δεν μπορούν να υποβληθούν σε συστημική χημειοθεραπεία. Από τη στιγμή που είναι απαραίτητη η ποσοτικοποίηση των φαρμάκων για τον χαρακτηρισμό των συστημάτων αποδέσμευσης και για μελέτες φαρμακοκινητικής, θα πρέπει να επιλέγεται η καταλληλότερη μέθοδος ποσοτικοποίησης παρέχοντας υψηλή ευαισθησία και ακρίβεια, εξασφαλίζοντας μεγάλη ανιχνευτική ικανότητα ακόμη και για πολύ χαμηλές συγκεντρώσεις. Στην παρούσα εργασία δύο αναλυτικές τεχνικές, η απορρόφηση υπεριώδους-ορατού και η επιφανειακή ενίσχυση της σκέδασης Raman (Surface Enhanced Raman Scattering, SERS), χρησιμοποιήθηκαν για την ποσοτική εκτίμηση του αντινεοπλασματικού φαρμάκου Mitoxantrone και του αντιμυκητιακού παράγοντα Ambisome (Αμφοτερισίνη Β) που αποδεσμεύτηκαν από βιοσυμβατές πολυμερικές μήτρες συμπολυμερούς αιθυλενίου-οξικού βινυλεστέρα, συμπολυμερούς γλυκολικού-γαλακτικού οξέος και πολυπροπυλενίου. Το SERS είναι ένα νέο, εναλλακτικό, ταχύ και μη καταστροφικό εργαλείο που μπορεί να βρεί εφαρμογή και στην ποσοτική εκτίμηση ουσιών πάρα πολύ χαμηλών συγκεντρώσεων. Χάρις στην ενίσχυση που παρέχεται στο σήμα Raman από τα νανο-εκτραχυμένα υποστρώματα ευγενών μετάλλων ή τα νανο-συσσωματώματα κολλοειδών διαλυμάτων ευγενών μετάλλων, έχει αναφερθεί ακόμη και συλλογή φάσματος SERS από ένα μόνο μόριο. Συνεπώς, η εφαρμογή του SERS σε μελέτες ουσιών εξαιρετικά χαμηλών συγκεντρώσεων φαίνεται να είναι πολύ ενδιαφέρουσα. Κατασκευάστηκαν πολυμερικά υμένια με εγκλωβισμένες τις δραστικές ουσίες και η μελέτη αποδέσμευσης πραγματοποιήθηκε σε νερό. Ποσοτικές μετρήσεις με τη χρήση του SERS σε πολύ μικρές συγκεντρώσεις έδειξαν μεγαλύτερη ανιχνευτική ευαισθησία σε σχέση με αυτές που πραγματοποιήθηκαν με την απορρόφηση UV-Vis. Συμπερασματικά, το SERS δείχνει ικανό στον ποσοτικό προσδιορισμό ενεργών ουσιών που αποδεσμεύονται από βιοσυμβατά πολυμερικά συστήματα μεταφοράς δραστικών ουσιών σε πολύ μικρές συγκεντρώσεις. / The application of polymeric materials for medical purposes is growing very fast. Polymers have found applications in such diverse biomedical fields as tissue engineering, implantation of medical devices and artificial organs, prosthesis, ophthalmology, dentistry, bone repair, chemotherapy and many other medical fields. Polymer-based delivery systems enable controlled slow release of drugs into the body and also they make possible targeting of drugs into sites of inflammation or tumors. Thus, biopolymer-mediated chemotherapy has shown promising results in the treatment of brain tumors. When compared to conventional systemic chemotherapy, intratumoral biopolymer-mediated drug delivery has several theoretical advantages: Biopolymers can deliver drugs into the tumor bed, thus maximizing local concentration while minimizing systemic toxicity. They may therefore be employed in the treatment of immunodepressed patients etc. Since drugs need to be quantified for drug delivery system characterization, intracellular distribution studies, free or vehicular, and for pharmacokinetic assays, the most suitable quantification method must be chosen. It should have a high sensitivity, specificity and reproducibility and should be capable of measuring at very low concentration range, as well. In the present study, two analytical techniques are utilized to quantitatively evaluate the antineoplastic drug Mitoxantrone and the antifungal agent Ambisome (Amphotericin b) released from active agents-loaded biocompatible polymer matrices poly(propylene), poly(ethylene-co-vinyl acetate), poly(lactic-co-glycolic acid); the UV-Vis absorption and the Surface Enhance Raman Scattering (SERS). SERS is a new, versatile, fast and non destructive tool for the estimation of extremely small amounts of substances. Due to the enhancement provided to the Raman signal by the nano-rough noble-metal substrates or the nano-structured colloidal clusters of noble metals, even single molecule detection has been reported. Therefore, applying SERS to extremely low concentration measurements proves to be challenging. Drug loaded polymer specimens were prepared and the in vitro drug release was determined in water. Fast SERS quantitative measurements showed enhanced sensitivity compared to the UV-Vis absorption; SERS may enable low concentration quantitative assessment of controlled release of drugs from biopolymer-based delivery systems.
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Advanced multimodal methods in biomedicine : Raman spectroscopy and digital holographic microscopyMcReynolds, Naomi January 2017 (has links)
Moving towards label-free technologies is essential for many clinical and research applications. Raman spectroscopy is a powerful tool in the field of biomedicine for label-free cell characterisation and disease diagnosis, owing to its high chemical specificity. However, Raman scattering is a relatively weak process and can require long acquisition times, thus hampering its integration to clinical technologies. Multimodal analysis is currently pushing the boundaries in biomedicine, obtaining more information than would be possible using a single mode and overcoming any limitations specific to a single technique. Digital holographic microscopy (DHM) is a rapid and label-free quantitative phase imaging modality, providing complementary information to Raman spectroscopy, and is thus an ideal candidate for combination in a multimodal system. Firstly, this thesis explores the use of wavelength modulated Raman spectroscopy (WMRS), for the classification of immune cell subsets. Following this a multimodal approach, combining Raman spectroscopy and DHM, is demonstrated, where each technique is considered individually and in combination. The complementary modalities provide a wealth of information (both chemical and morphological) for cell characterisation, which is a step towards achieving a label-free technology for the identification of human immune cells. The suitability of WMRS to discriminate between closely related neuronal cell types is also explored. Furthermore optical spectroscopic techniques are useful for the analysis of food and beverages. The use of Raman and fluorescence spectroscopy to successfully discriminate between various whisky and extra-virgin olive oil brands is demonstrated, which may aid the detection of counterfeit or adulterated samples. The use of a compact Raman device is utilised, demonstrating the potential for in-field analysis. Finally, monodisperse and highly spherical nanoparticles are synthesised. A short study demonstrates the potential for these nanoparticles to benefit the techniques of surface enhanced Raman spectroscopy and optical trapping, by way of minimising variability.
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Plasmonic, electrical and catalytic properties of one-dimensional copper nanowires:effect of native oxidesHajimammadov, R. (Rashad) 24 April 2018 (has links)
Abstract
Recent advances in materials synthesis resulted in a rediscovery of the low cost copper in its one and two-dimensional forms and project newer applications of this metal in fields not considered before. In this thesis, one-dimensional copper, i.e. nanowires are synthesized by a hydrothermal route and explored for their chemical, electrical, catalytic and plasmonic properties with highlighted advantages, benefited from their size and shape compared to thin film and bulk copper. Characterization of copper nanowires and their native oxides were performed using a number of analytical techniques such as X-ray photoelectron and Auger spectroscopy, Raman spectroscopy, X-ray diffraction as well as scanning probe and electron microscopy techniques to elucidate the oxidation mechanism and to assess the feasibility of the oxidized materials for various applications. A few atomic layers of cuprous oxide seem to form on the surface of the nanowires instantly, maybe already during synthesis, which then slowly grows further when exposing the nanowires to ambient air leading to the appearance of cupric oxide as well. Because of the surface oxides, individual nanowires and their bundled networks exhibit semiconducting behavior, which complicates the direct use of such materials for interconnections in electronics. However, even with the presence of native oxides, copper nanowires hold promise in many other applications such as the ones explored here for plasmonics and heterogeneous catalysis. As demonstrated in this work, surface plasmon absorption properties of the nanowires can be exploited for chemical sensing of surface adsorbed molecules (model compound Rhodamine 6G) by efficiently amplifying its Raman spectrum without using any lithographically defined sensor template. Further, it is shown that phenol contamination in water may be efficiently eliminated by converting it to nontoxic polyphenol as well as to CO2 owing to the highly efficient catalytic property of the mixed oxide phases on the surface of the nanowires. The results published in this thesis contribute to the understanding of the chemical and physical behavior of copper nanowires and other low dimensional copper nanostructures that undergo rapid surface oxidation. / Tiivistelmä
Jatkuva elektronisten laitteiden ja anturien pienentäminen on hyvin linjassa teknologian kehittymisen kanssa. Pyrkimys monitoimisiin ja tehokkaisiin materiaaleihin on muuttanut tavanomaisten materiaalien käsitystä. Viimeisimmät edistysaskeleet materiaalisynteesissä ovat johtaneet edullisen kuparin uudelleenlöytämiseen sen yksi- ja kaksidimensionaalisissa muodoissa ennustaen metallille uusia sovellutuksia alueilla, joissa sitä ei ole aiemmin hyödynnetty. Tässä väitöstyössä on tutkittu hydrotermisesti syntetisoitujen yksiulotteisten kuparinanojohtimien kemiallisia, sähköisiä, katalyyttisiä ja plasmonisia ominaisuuksia sekä näiden pieneen kokoon ja muotoon perustuvia etuoja ohutkalvo- ja bulkkikupariin verrattuna. Kuparinanojohtimia ja niiden luonnollisia oksideja karakterisoitiin useilla analyysitekniikoilla kuten röntgenelektroni- ja Auger-eletronispektroskopialla, Raman-spektroskopialla, röntgendiffraktiolla sekä pyyhkäisykärki- ja elektronimikroskopialla selvittäen hapettumismekanismeja ja oksidien soveltuvuutta eri käyttötarkoituksiin.
Muutaman atomikerroksen paksuinen kupari(I)oksidikerros havaittiin muodostuvan välittömästi, luultavasti jo materiaalisynteesin aikana nanojohtimien pinnalle. Nanojohtimien altistuessa ympäröivälle ilmalle oksidikerros kehittyi hitaasti johtaen kupari(II)oksidin muodostumiseen. Pintaoksidien johdosta yksittäiset nanojohtimet ja niistä yhteenkasautuneet verkostot käyttäytyvät puolijohdemaisesti mikä monimutkaistaa näiden materiaalien käyttöä sellaisenaan elektroniikan johtimissa. Luonnollisista oksideista huolimatta kuparinanojohtimet ovat lupaavia monissa muissa sovelluksissa, kuten tässä työssä tutkituissa plasmonisessa ja heterogeenisessä katalyysissä. Väitöstyössä osoitetaan, että nanojohtimen pintaplasmonisia absorptio-ominaisuuksia voidaan hyödyntää pintaan absorboituneiden molekyylien kemiallisessa havainnoinnissa (mallinnettu yhdiste rodamiini 6G) vahvistamalla Raman–spektriä käyttämättä lainkaan litografiapohjaista anturisapluunaa. Myöskin vesien fenolikontaminaatio voidaan tehokkaasti muuntaa myrkyttömiksi polyfenoleiksi ja hiiidioksidiksi hyödyntämällä nanojohtimien pinnalla olevia oksideja tehokkaana katalyyttinä (jopa parempi kuin kaupallisten kupariin pohjautuvat katalyytit). Tässä väitöstyössä julkaistut tulokset edistävät kuparinanojohtimien sekä muiden pienikokoisten ja nopeasti hapettuvien kuparinanorakenteiden kemiallisen ja fyysisen käytöksen ymmärtämistä. Tieteellisten kehitysaskeleiden lisäksi tämä väitöstyö voi myös toimia lähteenä pienirakenteisten yleisten metallien sovelluksille.
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Nanomembranas tensionadas : ilhas de InAs em substratos complacentes de Si e microtubos metálicos enrolados como um sensor SERS para monocamadas auto organizadas / Straining nanomembranes : InAs islands on compliant Si substrates and rolled-up metal microtubes for a SERS sensor with self-assembled monolayersMerces, Leandro, 1989- 25 August 2018 (has links)
Orientadores: Christoph Friedrich Deneke, Eduardo Granado Monteiro da Silva / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Física Gleb Wataghin / Made available in DSpace on 2018-08-25T16:50:29Z (GMT). No. of bitstreams: 1
MercesSilva_Leandrodas_M.pdf: 8926273 bytes, checksum: 010f49f410852b0ba0278adfc3e091fa (MD5)
Previous issue date: 2014 / Resumo: Nanomembranas livres são definidas como filmes ultrafinos constituídos por metais, óxidos ou semicondutores, com espessuras nanométricas e vastas áreas superficiais. São obtidas em geral por um processo de subcorrosão seletiva de uma camada de sacrifício, cujo papel é liberá-las gradualmente, permitindo que o relaxamento da energia elástica nelas armazenada aconteça de maneira controlada, garantindo a integridade final das estruturas. Neste trabalho, nanomembranas livres de Si suportadas por um substrato de SOI foram utilizadas como substratos complacentes para o crescimento de ilhas de InAs em uma câmara de MBE. Além disso, nanomembranas metálicas tensionadas (Ag/Ti/Cr/Ag) foram utilizadas na obtenção de microtubos metálicos enrolados. Análises detalhadas da morfologia das amostras, das estruturas das ilhas e dos microtubos, do strain em ambos os sistemas e de suas possíveis aplicações foram realizadas. A microscopia eletrônica de varredura mostrou que as estruturas permaneceram íntegras após as deformações. A microscopia de força atômica revelou uma baixa densidade de ilhas no topo das nanomembranas de Si. Ademais, possibilitou o aperfeiçoamento de parâmetros superficiais das nanomembranas metálicas e o enrolamento de microtubos com diâmetros pré definidos, garantindo convergência com o modelo analítico. Técnicas de difração de raios X e modelagem por elementos finitos foram utilizadas para elucidar os estados de strain observados em ambas as estruturas. As simulações das curvaturas do substrato complacente de Si e do microtubo metálico sugeriram, respectivamente, um gradiente de strain dependente da posição lateral de cada ilha na nanomembrana e coeficientes de strain constantes nas nanomembranas de Ti e Cr. Finalmente, cálculos envolvendo elasticidade contínua sugeriram que para uma nanomembrana de Si com espessura adequada, o InAs pode transferir strain suficiente para possibilitar o crescimento epitaxial coerente. Ainda, medidas de espectroscopia Raman em moléculas auto organizadas de 1-octadecanethiol, adsorvidas em Ag e aprisionadas entre as paredes dos microtubos metálicos, sugeriram que tal sistema pode ser utilizado como um dispositivo SERS para self-assembled monolayers / Abstract: Freestanding nanomembranes (NMs) are defined as metallic, semiconductor or oxide ultrathin films with nanometer thickness and macroscopic surface areas. In general, they are obtained by a process of selective underetching of a sacrificial layer, whose role is gradually release them, allowing relaxation of their stored elastic energy in a controlled way, ensuring integrity of the final structure. In this work, freestanding edge-supported Si nanomembranes are used as compliant substrate to the InAs growth on a SOI substrate in a MBE chamber. Furthermore, strained metallic nanomembranes (Ag / Ti / Cr / Ag) are used to obtain rolled-up metallic microtubes. A detailed analysis of sample morphology, InAs island and metallic microtube structure, strain on both systems and their possible applications is carried out. Scanning electron microscopy shows the structures stay intact during and after deformation. Atomic force microscopy reveals a lower island density on the top of the freestanding membranes. Moreover, it allowed optimizing the surface parameters of the strained metallic membranes, rolling-up tubes with pre-defined diameters and ensuring convergence with the proposed analytical model. X-ray diffraction and finite element modeling is used to elucidate the observed strain states in both structures. The bending simulations of compliant Si substrate and rolled up metallic microtube suggest, respectively, a lateral strain distribution depending on the island position on the freestanding membrane and a constant strain distribution on the Ti/Cr strained NMs. Finally, continuous elasticity calculations suggest that for a Si nanomembrane with adequate thickness, the InAs can transfer enough strain to enable coherent epitaxial growth. In addition, Raman spectroscopy measurements of 1-octadecanethiol self-assembled molecules adsorbed on an Ag nanomembrane and trapped between the microtube Ag walls suggest the system could be used as a SERS sensor for self-assembled monolayers / Mestrado / Física / Mestre em Física
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DEVELOPMENT OF HEADSPACE ANALYSIS OF LIVING AND POSTHARVEST FRESH PRODUCE USING SURFACE-ENHANCED RAMAN SPECTROSCOPY (SERS)Du, Xinyi 15 July 2020 (has links)
The increasing market demand for fresh produce promotes a keen interest in developing a rapid, sensitive and reliable method for monitoring plant health and determining the shelf-life of postharvest produce. The objective of this study is to explore the capability of Surface-enhanced Raman spectroscopy (SERS) in these applications. SERS integrates Raman spectroscopy which measures molecular vibrations and nanotechnology which enhances the weak Raman signals. Herein, we developed two SERS methods based on a surface detection approach using nanoparticles solution and a headspace detection approach using gold nanoparticles (AuNPs) fibers, to detect biochemical changes during postharvest storage of arugula leaves. Compared with surface detection, the headspace detection revealed significant spectral changes during the storage, particularly in the shifts around 500, 950 and 1030 cm-1. These changes analyzed using principal component analysis (PCA) to establish a prediction model for shelf-life determination. Through analyzing reference standard compounds, we identified the dimethyl disulfide (DMDS), 1-propanethiol and methanethiol (MT) were most likely to account for the signature spectra of headspace arugula at the late storage period due to the activities of spoilage bacteria. The headspace detection method was also applied to monitor the stress responses of living basil to abiotic stresses (pesticide/salinity). However, the volatile analysis of the basil plants response to abiotic stresses (pesticide/salinity) showed indistinctive results. In conclusion, the headspace detection based on SERS provides a new strategy for quality monitoring of fresh produce in the food industry.
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Single-molecule interfacial electron transfer dynamics in solar energy conversionDhital, Bharat 17 November 2016 (has links)
No description available.
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