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11	Controle estatístico multivariado de processo aplicado à produção de biodiesel por transesterificação SALES, Rafaella de Figueiredo 19 February 2016 (has links) Submitted by Fabio Sobreira Campos da Costa (fabio.sobreira@ufpe.br) on 2016-09-02T14:13:49Z No. of bitstreams: 2 license_rdf: 1232 bytes, checksum: 66e71c371cc565284e70f40736c94386 (MD5) Dissertação_Rafaella de Figueiredo Sales.pdf: 2788155 bytes, checksum: 95e4d0c2ca7494069abdc945b186152e (MD5) / Made available in DSpace on 2016-09-02T14:13:49Z (GMT). No. of bitstreams: 2 license_rdf: 1232 bytes, checksum: 66e71c371cc565284e70f40736c94386 (MD5) Dissertação_Rafaella de Figueiredo Sales.pdf: 2788155 bytes, checksum: 95e4d0c2ca7494069abdc945b186152e (MD5) Previous issue date: 2016-02-19 / PETROBRAS/ PRH 28 / O biodiesel é considerado um potencial substituto para os combustíveis de origem fóssil. Geralmente, esse biocombustível é produzido através da transesterificação de óleos vegetais ou gordura animal utilizando um álcool de cadeia curta. A vasta aplicação industrial da transesterificação para produção de biodiesel requer um cuidadoso monitoramento do processo e modelagem dessa reação, orientados para um melhor entendimento e para a otimização do processo. Além disso, o controle do processo é de fundamental importância para garantir a qualidade do biodiesel de forma constante, uniforme e atendendo às especificações necessárias para a sua comercialização. Dentre as técnicas existentes para o monitoramento de reações, a espectroscopia no infravermelho próximo permite uma análise rápida e não destrutiva, podendo ser utilizada para o monitoramento in-line de processos. Nesse contexto, o presente trabalho descreve o monitoramento in-line da produção de biodiesel por transesterificação de óleo de soja com metanol utilizando a espectroscopia na região do infravermelho próximo. As reações foram conduzidas em batelada com controle de temperatura e velocidade de agitação. Dois estudos diferentes foram então realizados a partir dos dados espectroscópicos coletados ao longo das reações. A primeira abordagem consistiu na implementação de estratégias de controle estatístico multivariado e de qualidade, baseadas em métodos de projeção multivariada. Nesse estudo, modelos de referência baseados em dois métodos diferentes (tempo real e após o término da batelada) foram desenvolvidos usando bateladas sob condições normais de operação (concentração de catalisador NaOH de 0,75% em massa em relação à massa de óleo de soja, temperatura de 55°C e velocidade de agitação de 500 rpm). Foram avaliadas diferentes técnicas de pré-processamento espectral, bem como estratégias para desdobramento da matriz de dados espectrais. Posteriormente, bateladas submetidas a diferentes perturbações (relacionadas à adição de água e a mudanças na temperatura, na velocidade de agitação, na concentração de catalisador e na matéria prima utilizada) foram produzidas para avaliar o desempenho dos diferentes modelos em relação às suas capacidades de detectar falhas de operação. De um modo geral, as cartas de controle desenvolvidas foram capazes de detectar a maioria das falhas intencionalmente produzidas ao longo do processo. Apenas pequenas perturbações na velocidade de agitação não foram identificadas. A segunda abordagem baseou-se no estudo do comportamento cinético da metanólise do óleo de soja em diferentes condições de temperatura (20, 45 e 55°C) e de concentração de catalisador (0,75 e 1,0% m/m de NaOH). Nesse estudo, a modelagem cinética foi realizada a partir dos perfis de concentração do éster metílico estimados utilizando o método de Resolução multivariada de curvas com mínimos quadrados alternantes com restrição de correlação. Os perfis de concentração obtidos permitiram o desenvolvimento de um estudo cinético simplificado da reação, a qual foi considerada como seguindo uma cinética de pseudo-primeira ordem baseada na concentração do éster metílico para a reação global de transesterificação. O modelo cinético incluiu apenas o regime pseudo-homogêneo, em que é observada uma rápida taxa de reação e a cinética está controlada pela reação química. Para esse regime, obteve-se uma energia de ativação de 32,29 kJ.mol-1, com base na equação de Arrhenius. / Biodiesel is considered a potential substitute for fossil fuels. In general, this biofuel is produced by transesterification of vegetable oils or animal fats using a short-chained alcohol. The wide industrial application of transesterification for biodiesel production requires a thorough process monitoring and modeling of this reaction, oriented to a better understanding and optimization of the process. Moreover, process control is of utmost importance to ensure in a constant and uniform way the biodiesel quality in order to meet commercialization requirements. Among the existing techniques applied for reaction monitoring, near infrared spectroscopy allows a fast and non-destructive analysis, being able to be used for in-line process monitoring. In this context, the present work describes the in-line monitoring of biodiesel production by transesterification of soybean oil with methanol using near infrared spectroscopy. Reactions were carried out in batch reactors with temperature and agitation speed control. Two different studies were then carried out from spectroscopic data collected throughout the reactions. The first approach consisted of the implementation of multivariate statistic and quality control strategies, based on multivariate projection methods. In this study, reference models based on two different methods (real time and end of batch) were developed using batches under normal operating condition (0.75 w/w% of catalyst NaOH with respect to the amount of oil, temperature of 55ºC and stirring speed of 500 rpm). Different techniques for pre-processing and unfolding the spectral data were evaluated. Afterwards, batches subjected to different disturbances (related with water addition and changes in the temperature, agitation speed, catalyst content and raw material used) were manufactured to assess the performance of the different models in terms of their capability for fault detection. In general, the control charts developed were able to detect most of the failures intentionally produced during the batch runs. Only small variations in the stirring spend were not detected. The second approach was based on the study of the kinetic behavior of the soybean oil methanolysiscarried out with different temperatures (20, 44 and 55°C) and catalyst (NaOH) concentrations (0.75 and 1.0 w/w% based onoil weight). In this study, the kinetic modelling was developed from methyl ester concentration profiles estimated by Multivariate curve resolution alternating least squares with correlation constraint. The obtained concentration profiles allowed the development of a simplified kinetic model of the reaction, which was considered to follow a pseudo-first order overall kinetics based on methyl ester concentration for global transesterification reaction. The kinetic model included only the pseudo-homogeneous regime where the overall process kinetics is under chemical reaction control and a fast methanolysis rate is observed. For this regime, the activation energy was 32.29 kJ.mol-1, based on Arrhenius equation. Biodiesel Transesterificação Espectroscopia NIR Controle estatístico multivariado Biodiesel Transesterification NIR spectroscopy Multivariate statistical control
12	Applications of Chemometric Algorithms to Ion Mobility Spectrometry and Matrix Assisted Laser Desorption/Ionization Time-of-Flight Mass Spectrometry Chen, Ping 18 July 2008 (has links) No description available. Analytical Chemistry Bioinformatics Chemistry Experiments Chemometrics Ion Mobility Spectrometry MALDI-MS Bacteria Multivariate Curve Resolution SIMPLISMA ALS TCCCN Toxic Industrial Chemicals
13	Water-Mediated Interactions Through the Lens of Raman Multivariate Curve Resolution Denilson Mendes de Oliveira (10708623) 06 May 2021 (has links) Raman multivariate curve resolution (Raman-MCR) spectroscopy is used to study water-mediated interactions by decomposing Raman spectra of aqueous solutions into bulk water and solute-correlated (SC) spectral components. The SC spectra are minimum-area difference spectra that reveal solute-induced perturbations of water structure, including changes in water hydrogen-bonding strength, tetrahedral structure, and formation of dangling (non-hydrogen-bonded) OH defects in a solute's hydration shell. Additionally, Raman-active intramolecular vibrational modes of the solute may be used to uncover complementary information regarding solute--solute interactions. Herein, Raman-MCR is applied to address fundamental questions related to: (1) confined cavity water and its connection to host-guest binding, (2) hydrophobic hydration of fluorinated solutes, (3) specific ion effects on nonionic micelle formation, and (4) ion pairing in aqueous solutions. Solution Chemistry Structural Chemistry and Spectroscopy Raman spectroscopy Multivariate curve resolution Ion pairing Water structure Hydrophobic hydration Host-guest binding Fluorination
14	Chemometric analysis of full scan direct mass spectrometry data for the discrimination and source apportionment of atmospheric volatile organic compounds measured from a moving vehicle. Richards, Larissa Christine 30 August 2021 (has links) Anthropogenic emissions into the troposphere can impact air quality, leading to poorer health outcomes in the affected areas. Volatile organic compounds (VOCs) are a group of chemical compounds, including some which are toxic, that are precursors in the formation of ground-level ozone and secondary organic aerosols. VOCs have a variety of sources, and the distribution of atmospheric VOCs differs significantly over time and space. Historically, the large number of chemical species present at low concentrations (parts-per-trillion to parts-per-billion by volume) have made VOCs difficult to measure in ambient air. However, with improvements in analytical instrumentation, these measurements are becoming more common place. Direct mass spectrometry (MS), such as membrane introduction mass spectrometry (MIMS) and proton-transfer reaction time-of-flight mass spectrometry (PTR-ToF-MS) facilitate real-time, continuous measurements of VOCs in air, with full scan mass spectral data capturing changes in chemical composition with high temporal resolution. Operated on-road, mobilized direct MS has been used for quantitative mapping of VOCs at the neighborhood scale, but identifying VOC sources based on the observed mixture of molecules in the full scan MS dataset has yet to be explored. This dissertation describes the use of chemometric techniques to interrogate full scan MS data, and the progression from discriminating VOC samples of known chemical composition based on full scan MIMS data through to the apportionment of VOC sources measured continuously with a PTR-ToF-MS system operating in a moving vehicle. Lab‐constructed VOC samples of known chemical composition and concentration demonstrated the use of principal component analysis (PCA) to discriminate, and k-nearest neighbours to classify, samples based on normalized full scan MIMS data. Furthermore, multivariate curve resolution-alternating least squares (MCR-ALS) was used to resolve mixtures into molecular component contributions. PCA was also used to discriminate ‘real-world’ VOC mixtures (e.g., woodsmoke VOCs, headspace above aqueous hydrocarbon samples) of unknown chemical composition measured by MIMS. Using vehicle mounted MIMS and PTR-ToF-MS systems, full scan MS data of ambient atmospheric VOCs were collected and PCA was applied to the normalized full scan MS data. A supervised analysis performed PCA on samples collected near known VOC sources, while an unsupervised analysis using PCA followed by cluster analysis was used to identify groups in a continuous, time series PTR-ToF-MS dataset measured between Nanaimo and Crofton, British Columbia (BC). In both the supervised and unsupervised analysis, samples impacted by emissions from different sources (e.g., internal combustion engines, sawmills, composting facilities, pulp mills) were discriminated. With PCA, samples were discriminated based on differences in the observed full scan MS data, however real-world samples are often impacted by multiple VOC sources. MCR-weighted ALS (MCR-WALS) was applied to the continuous, time series PTR-ToF-MS data from three field campaigns on Vancouver Island, BC for source apportionment. Variable selection based on signal-to-noise ratios was used to reduce the mass list while retaining the observed m/z that capture changes in the mixture of VOCs measured, improving model results, and reducing computation time. Both point (e.g., anthropogenic hydrocarbon emissions, pulp mill emissions) and diffuse (e.g., VOCs from forest fire smoke) VOC sources were identified in the data, and were apportioned to determine their contributions to the measured samples. The data analyzed captured fine scale changes in the ambient VOCs present in the air, and geospatial maps of each individual source, and of the source apportionment were used to visualize the distribution of VOC sources across the sampling area. This work represents the first use of MCR-WALS to identify and apportion ambient VOC sources based on continuous PTR-ToF-MS data measured from a moving vehicle. The methods described can be applied to larger scale field campaigns for the source apportionment of VOCs across multiple days to capture diurnal and seasonal variations. Identifying spatial and temporal trends in the sources of VOCs at the regional scale can help to identify pollution ‘hot spots’ and inform evidence-based public policy for improving air quality. / Graduate / 2022-08-17 Chemometrics Membrane introduction mass spectrometry Volatile organic compounds Air quality Principal component analysis Receptor modelling Tropospheric chemistry Geospatial mapping of VOC sources Air quality Mobile mass spectrometry Real-time, continuous, VOC measurements Direct mass spectrometry Source apportionment Source discrimination Direct mass spectrometry Environmental chemistry Mobile lab Mobile air quality measurements Cluster analysis Multivariate curve resolution
15	Multivariate spectroscopic methods for the analysis of solutions Wiberg, Kent January 2004 (has links) <p>In this thesis some multivariate spectroscopic methods for the analysis of solutions are proposed. Spectroscopy and multivariate data analysis form a powerful combination for obtaining both quantitative and qualitative information and it is shown how spectroscopic techniques in combination with chemometric data evaluation can be used to obtain rapid, simple and efficient analytical methods. These spectroscopic methods consisting of spectroscopic analysis, a high level of automation and chemometric data evaluation can lead to analytical methods with a high analytical capacity, and for these methods, the term high-capacity analysis (HCA) is suggested. It is further shown how chemometric evaluation of the multivariate data in chromatographic analyses decreases the need for baseline separation. </p><p>The thesis is based on six papers and the chemometric tools used are experimental design, principal component analysis (PCA), soft independent modelling of class analogy (SIMCA), partial least squares regression (PLS) and parallel factor analysis (PARAFAC). The analytical techniques utilised are scanning ultraviolet-visible (UV-Vis) spectroscopy, diode array detection (DAD) used in non-column chromatographic diode array UV spectroscopy, high-performance liquid chromatography with diode array detection (HPLC-DAD) and fluorescence spectroscopy. The methods proposed are exemplified in the analysis of pharmaceutical solutions and serum proteins.</p><p>In Paper I a method is proposed for the determination of the content and identity of the active compound in pharmaceutical solutions by means of UV-Vis spectroscopy, orthogonal signal correction and multivariate calibration with PLS and SIMCA classification. Paper II proposes a new method for the rapid determination of pharmaceutical solutions by the use of non-column chromatographic diode array UV spectroscopy, i.e. a conventional HPLC-DAD system without any chromatographic column connected. In Paper III an investigation is made of the ability of a control sample, of known content and identity to diagnose and correct errors in multivariate predictions something that together with use of multivariate residuals can make it possible to use the same calibration model over time. In Paper IV a method is proposed for simultaneous determination of serum proteins with fluorescence spectroscopy and multivariate calibration. Paper V proposes a method for the determination of chromatographic peak purity by means of PCA of HPLC-DAD data. In Paper VI PARAFAC is applied for the decomposition of DAD data of some partially separated peaks into the pure chromatographic, spectral and concentration profiles. </p> Chemometrics UV-Vis spectroscopy Multivariate calibration Lidocaine Identity Content PLS SIMCA Non-column Diode array UV spectroscopy DAD Control sample High Capacity Analysis (HCA) Fluorescence spectroscopy Albumin Immunoglobulin G HPLC-DAD Prilocaine Peak purity determination PCA PARAFAC Partial separation Curve resolution Analytical chemistry Analytisk kemi
16	Multivariate spectroscopic methods for the analysis of solutions Wiberg, Kent January 2004 (has links) In this thesis some multivariate spectroscopic methods for the analysis of solutions are proposed. Spectroscopy and multivariate data analysis form a powerful combination for obtaining both quantitative and qualitative information and it is shown how spectroscopic techniques in combination with chemometric data evaluation can be used to obtain rapid, simple and efficient analytical methods. These spectroscopic methods consisting of spectroscopic analysis, a high level of automation and chemometric data evaluation can lead to analytical methods with a high analytical capacity, and for these methods, the term high-capacity analysis (HCA) is suggested. It is further shown how chemometric evaluation of the multivariate data in chromatographic analyses decreases the need for baseline separation. The thesis is based on six papers and the chemometric tools used are experimental design, principal component analysis (PCA), soft independent modelling of class analogy (SIMCA), partial least squares regression (PLS) and parallel factor analysis (PARAFAC). The analytical techniques utilised are scanning ultraviolet-visible (UV-Vis) spectroscopy, diode array detection (DAD) used in non-column chromatographic diode array UV spectroscopy, high-performance liquid chromatography with diode array detection (HPLC-DAD) and fluorescence spectroscopy. The methods proposed are exemplified in the analysis of pharmaceutical solutions and serum proteins. In Paper I a method is proposed for the determination of the content and identity of the active compound in pharmaceutical solutions by means of UV-Vis spectroscopy, orthogonal signal correction and multivariate calibration with PLS and SIMCA classification. Paper II proposes a new method for the rapid determination of pharmaceutical solutions by the use of non-column chromatographic diode array UV spectroscopy, i.e. a conventional HPLC-DAD system without any chromatographic column connected. In Paper III an investigation is made of the ability of a control sample, of known content and identity to diagnose and correct errors in multivariate predictions something that together with use of multivariate residuals can make it possible to use the same calibration model over time. In Paper IV a method is proposed for simultaneous determination of serum proteins with fluorescence spectroscopy and multivariate calibration. Paper V proposes a method for the determination of chromatographic peak purity by means of PCA of HPLC-DAD data. In Paper VI PARAFAC is applied for the decomposition of DAD data of some partially separated peaks into the pure chromatographic, spectral and concentration profiles. Chemometrics UV-Vis spectroscopy Multivariate calibration Lidocaine Identity Content PLS SIMCA Non-column Diode array UV spectroscopy DAD Control sample High Capacity Analysis (HCA) Fluorescence spectroscopy Albumin Immunoglobulin G HPLC-DAD Prilocaine Peak purity determination PCA PARAFAC Partial separation Curve resolution Analytical chemistry Analytisk kemi
17	Atomic Layer Deposition and High Sensitivity-Low Energy Ion Scattering for the Determination of the Surface Silanol Density on Glass and Unsupervised Exploratory Data Analysis with Summary Statistics and Other Methods Gholian Avval, Tahereh 18 July 2022 (has links) With the increasing importance of hand-held devices with touch displays, the need for flat panel displays (FPDs) will likely increase in the future. Glass is the most important substrate for FPD manufacturing, where both its bulk and surface properties are critical for its performance. Many properties of the glass used in FPDs are controlled by its surface chemistry. Surface hydroxyls are the most important functional groups on a glass surface, which control processes that occurs on oxide surfaces, including wetting, adhesion, electrostatic charging and discharge, and the rate of contamination. In this dissertation, I present a new approach for determining surface silanol densities on planar surfaces. This methodology consists of tagging surface silanols using atomic layer deposition (ALD) followed by low energy ion scattering (LEIS) analysis of the tags. The LEIS signal is limited to the outermost atomic layer, i.e., LEIS is an extremely surface sensitive technique. Quantification in LEIS is straightforward in the presence of suitable reference materials. An essential part of any LEIS measurement is the preparation and characterization of the sample and appropriate reference materials that best represent the samples. My tag-and-count method was applied to chemically and thermally treated fused silica. In this work, I determined the silanol density of a fully hydroxylated fused silica surface to be 4.67 OH/nm2. This value agrees with the literature value for high surface area silica powder. My methodology should be important in future glass studies. Surface Science Spectra (SSS) is an important, peer-reviewed database of spectra from surfaces. Recently, SSS has been expanding to accept spectra from new surface techniques. I created the first SSS submission form for LEIS spectra (see appendix 5), and used it to create the first SSS LEIS paper (on CaF2 and Au reference materials, see chapter 3). I also show LEIS reference spectra for ZnO, and copper in the appendix 1. The rest of my dissertation focuses on my chemometrics/informatics and data analysis work. For example, I showed the performance and capabilities of a series of summary statistics as new tools for unsupervised exploratory data analysis (EDA) (see chapter 4). Unsupervised EDA is often the first step in understanding complex data sets because it can group, and even classify, samples according to their spectral similarities and differences. Pattern recognition entropy (PRE) and other summary statistics are direct methods for analyzing data - they are not factor-based approaches like principal component analysis (PCA) or multivariate curve resolution (MCR). I show that, in general, PRE outperforms the other summary statistics, especially in image analysis, although I recommend a suite of summary statistics be used in exploring complex data sets. In addition, I introduce the concept of divided spectrum-PRE (DS-PRE) as a new EDA method and use it to analyze multiple data sets. DS-PRE increases the discrimination power of PRE. I have also prepared a guide that discusses the vital aspects and considerations for chemometrics/informatics analyses of XPS data along with specific EDA tools that can be used to probe XPS data sets, including PRE, PCA, MCR, and cluster analysis (see chapter 5). I emphasize the importance of an initial evaluation/plotting of raw data, data preprocessing, returning to the original data after a chemometrics/informatics analysis, and determining the number of abstract factors to keep in an analysis, including reconstructing the data using PCA. In my thesis, I also show the analysis of commercial automotive lubricant oils (ALOs) with various chemometrics techniques (see chapter 6). Using these methods, the ALO samples were readily differentiated according to their American Petroleum Institute (API) classification and base oil types: mineral, semi-synthetic, and synthetic. surface hydroxyls silanols (SiOH) fused silica glass atomic layer deposition ALD ZnO HS-LEIS LEIS CaF2 Au X-ray photoelectron spectroscopy XPS spectroscopic ellipsometry SE summary statistics pattern recognition entropy PRE divided-spectrum-PRE DS-PRE principal component analysis PCA multivariate curve resolution MCR hierarchical cluster analysis HCA. Physical Sciences and Mathematics

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