Global ETD Search

11	Carbon Nanotube Composites Prepared by Ultrasonically Assisted Twin Screw Extrusion Lewis, Todd M. 11 September 2014 (has links) No description available. Polymers Materials Science CNTs CNT PETI-330 PEEK nanocomposites carbon nanotubes mwnts multiwalled carbon nanotubes Twin Screw Extrusion
12	Chemically and Photochemically Crosslinked Networks and Acid-Functionalized Mwcnt Composites Nebipasagil, Ali 21 June 2011 (has links) PTMO-urethane and urea diacrylates (UtDA, UrDA) were synthesized from a two-step reactions of bis (4-isocyanatocyclohexyl) methane (HMDI) with either α,Ï -hydroxy-terminated poly (tetramethylene oxide) (PTMO Mn 250, 1000, 2000 and 2900 g/mol) or α,Ï -aminopropyl-terminated PTMO and 2-hydroxyethyl acrylate (HEA). PTMO-based ester precursors (EtDA) were also synthesized from α,Ï -hydroxy-terminated PTMO (Mn 1000 and 2000 g/mol). Two bis acetoacetates were synthesized from acetoacetylation of 1,4-butanediol and 250 g/mol hydroxy-terminated PTMO with tert-butyl acetoacetate. ¹H NMR spectroscopy confirmed the structure and average molecular weights (Mn)of diacrylates. Mn of these precursors were in the range of 950 to 3670 g/mol by ¹H NMR. The rheological properties of diacrylates were studied and activation energies for flow were calculated. Activation energies increased with increasing Mn and hydrogen-bond segment content. Michael carbon addition was employed to covalently crosslink the precursors resulting in networks with gel fractions better than 90%. DSC and DMA experiments revealed that networks had a broad distribution of glass transition temperatures depending on Mn and degree of hydrogen bonding present in the diacrylates. Their Tg's varied from -61 ºC to 63 ºC depending on the crosslinking density and hydrogen-bonding segment content. TGA revealed that UtDA and UrDA networks had an improved thermal stability compared to their EtDA counterparts. Tensile properties showed a variation depending on the structure and Mn of diacrylate and BisAcAc precursors. The storage moduli of networks precursor change from 25.3 MPa to 2.0 MPa with increasing Mn of the urethane diacrylate Elongation at break increased from 255% to 755 % for the same networks. The Young's moduli increased from 3.27 MPa for EtDA 2000 to 311.1 MPa for UrDA 2000 which was attributed to increasing degree of hydrogen-bonding. Acid functionalization of C70 P Baytubes multiwalled carbon nanotubes (MWCNT) generated acid-functionalized nanotubes (MWCNT-COOH). Suspension of MWCNT-COOH in organic solvents (chloroform, toluene, THF, DMF and 2-propanol) were prepared. DLS indicated average particle diameters of MWCNT-COOH in DMF and in 2-propanol were 139 nm and 162 nm respectively. FESEM of suspensions revealed aggregate free dispersion of MWCNT-COOH in DMF and 2-propanol. MWCNT-COOH containing composite networks were prepared. FESEM images of fracture surfaces of UtDA showed MWCNT-COOH were well-dispersed in the composites. DMA showed an increase in the rubbery plateau modulus which correlated with the MWCNT-COOH content in the networks. Tensile testing also revealed a relationship between MWCNT-COOH content and young's moduli and strain at break of networks. Storage moduli of networks increased from 25 MPa to 211 MPa with increasing MWCNT-COOH content whereas elongation at break decreased from 255 % to 146 %. UtDAs and pentaerythritol tetraacrylate (PETA) were crosslinked under UV radiation (6 passes, 1.42 ± 0.05 W.cm2 for each pass) in the presence of 2,2-dimethoxy-2-phenylacetophenone (DMPA) (1 wt. % of the mixture) UV initiator. DMA demonstrated the presence of broad glass transition regions with a range of Tg's which varied from -60 °C to -30°C. Tensile testing also revealed the relationship between Young's moduli, strain at break and the molecular weight of the diacrylates. The increasing molecular weight of urethane diacrylate precursors caused a drop in the storage moduli of networks from 15.8 MPa to 1.4 MPa and an increase in elongation at break from 76 % to 132 %. / Master of Science Michael carbon addition urethane H-bonding Telechelic multiwalled carbon nanotubes urethane composites UV curing thermo-mechanical property
13	Fabricação, caracterização do comportamento eletroquímico e aproveitamento analítico de eletrodos modificados para a determinação de peróxido de hidrogênio / Fabrication, characterization of the electrochemical behavior and analytical use of modified electrodes for the determination of hydrogen peroxide Roselyn Millaray Castañeda Peña 04 November 2011 (has links) Neste trabalho são apresentados resultados sobre o desenvolvimento de um sensor visando à utilização no monitoramento de peróxido de hidrogênio em amostras de reações Fenton. Superfícies eletródicas modificadas com filmes de poli-azul de metileno (PMB) e óxido de rutênio de hexacianoferrato (RuOHCF) sem e com a incorporação de nanotubos de carbono de paredes múltiplas (MWCNTs) foram utilizadas para a detecção amperométrica de peróxido de hidrogênio. O efeito da ordem de deposição do PMB e MWCNT foi avaliado por voltametria cíclica e espectroscopia de impedância eletroquímica. Estudos realizados por voltametria cíclica indicaram que a superfície modificada com PBM/MWCNTs facilita a redução catódica do peróxido de hidrogênio, processo que ocorre em 0,0 V vs. Ag/AgCl/KCl(sat). O método para a detecção de peróxido de hidrogênio apresentou uma resposta linear de 109 a 3000 µmol L-1, com limite de detecção de 20,7 µmol L-1 e sensibilidade de 108 µA mmol-1 L cm-2. O eletrodo modificado com RuOHCF foi utilizado para a detecção amperométrica de peróxido de hidrogênio por análise em injeção em fluxo (FIA). O método apresentou uma resposta linear de 10 a 5000 µmol L-1 e limite de detecção de 1,7 µmol L-1. Aplicações em amostras comerciais também foram realizadas, e os resultados foram concordantes com os obtidos por método padrão. Estudos sobre o processo eletrocatalítico da reação de peróxido de hidrogênio em filmes de RuOHCF foram investigados utilizando eletrodo rotativo. A incorporação de MWCNTs na superfície eletródica também foi analisada com o filme de RuOHCF. Os resultados indicaram que a presença de MWCNTs melhorou a resposta do sensor para peróxido de hidrogênio em potenciais próximos a 0,0 V vs. Ag/AgCl/KCl(sat). A influência da quantidade de MWCNTs foi avaliada por amperometria em 0,0 V vs. Ag/AgCl/KCl(sat) na presença de peróxido de hidrogênio. O eletrodo modificado com 100 µg de MWCNTs e posterior deposição do filme de RuOHCF apresentou melhores características analíticas. Obteve-se como resultado uma curva analítica em um intervalo de 0,1 a 10 mmol L-1, originando uma reta de acordo com a equação: -I (µA) = 0,26 + 31,2 [H2O2] (mmol L-1), R2= 0,9999. A sensibilidade foi de 1560 µA mmol-1 L cm-2 e os limites de detecção e quantificação foram estimados em 4,7 (S/N = 3) e 15,8 (S/N = 10) µmol L-1, respectivamente. Comparando-se as características analíticas dos filmes de PMB e RuOHCF depositados na superfície dos MWCNTs, aquele que apresentou melhor resultado foi o eletrodo modificado com MWCNTs e RuOHCF por ter melhor limite de detecção e maior sensibilidade. Esse eletrodo modificado com MWCNTs e RuOHCF foi utilizado para monitorar o consumo de peróxido de hidrogênio em amostras de reação Fenton. Também foi avaliado o efeito da presença de Fe3+ contido no próprio processo de degradação. A interferência foi eliminada complexando o Fe3+ com oxalato. Finalmente, o eletrodo foi utilizado para monitorar a concentração de peróxido de hidrogênio na degradação de fenol e os resultados foram concordantes com os obtidos por método espectrofotométrico / This work presents results on the development of a sensor to monitor the hydrogen peroxide content in samples of Fenton reaction. The electrode surface was modified with films of poly-methylene blue (PMB) and ruthenium oxide hexacyanoferrate (RuOHCF). In some cases, multiwalled carbon nanotubes (MWCNT) were also used. The effect of the order of deposition of PMB and MWCNTs was evaluated by cyclic voltammetry and electrochemical impedance spectroscopy. The influence of immobilization of various platforms in the performance of fabricated sensors for hydrogen peroxide was also studied. Cyclic voltammetry experiments indicated that the surface modified with PMB/MWCNTs facilitates the cathodic reduction of hydrogen peroxide, a process that occurred at 0.0 V vs. Ag/AgCl/KCl(sat). The method showed a linear response from 109 to 3000 µmol L-1 hydrogen peroxide. The limit of detection was estimated as 20.7 (S/N = 3) µmol L-1 with a sensitivity of 108 µA mmol-1 L cm-2. Electrodes modified with RuOHCF films were used for the amperometric detection of hydrogen peroxide by flow injection analysis (FIA).The method showed a linear response from 10 to 5000 µmol L-1 and a detection limit of 1.7 µ mol L-1. Analyses of hydrogen peroxide in commercial samples were also performed, and the results agreed with those obtained by a standard method. Studies on the kinetics of the electrocatalytic reduction of hydrogen peroxide in RuOHCF films were carried out using rotating disc voltammetric. The immobilization of MWCNTs on RuOHCF films was also investigated. The results indicated that the presence of MWCNTs facilitated the electrocatalytic reduction of hydrogen peroxide at potential values near to 0.0 V vs. vs. Ag/AgCl/KCl(sat). The influence of the amount of MWCNTs was studied by amperometry at 0.0 V vs. vs. Ag/AgCl/KCl(sat) in the presence of hydrogen peroxide. The electrode modified with 100 µg of MWCNTs and subsequent deposition of the RuOHCF film showed better analytical characteristics. An analytical curve ranging from 0.1 to 10 mmol L-1 hydrogen peroxide was obtained, resulting in a straight line according to the equation: -I (µA) = 0.26 + 31.2 [H2O2] (mmol L-1), R2= 0.9999. The sensitivity was found to be 1560 µA mmol-1 L cm-2 and the detection and quantification limits were estimated at 4.7 (S / N = 3) and 15.8 (S / N = 10) mmol L-1, respectively. Electrodes modified with MWCNTs and RuOHCF films leaded to better detection limit and sensitivity in comparison to those modified with MWCNTs and PMB. This MWCNTs and RuOHCF modified electrode was used to monitor the consumption of hydrogen peroxide in samples of Fenton reaction and the effect of Fe3+ generated in the degradation process was also examined. The interference was minimized by adding oxalate to the samples. Finally, the sensor was used to monitor the concentration of hydrogen peroxide in the degradation of phenol and the results were in agreement with those obtained by using spectrophotometry Amperometria Detecção amperométrica Eletrodos modificados FIA Peróxido de hidrogênio Amperometry FIA amperometric detection Hydrogen peroxide Modified electrodes Multiwalled carbon nanotubes
14	Fabricação, caracterização do comportamento eletroquímico e aproveitamento analítico de eletrodos modificados para a determinação de peróxido de hidrogênio / Fabrication, characterization of the electrochemical behavior and analytical use of modified electrodes for the determination of hydrogen peroxide Peña, Roselyn Millaray Castañeda 04 November 2011 (has links) Neste trabalho são apresentados resultados sobre o desenvolvimento de um sensor visando à utilização no monitoramento de peróxido de hidrogênio em amostras de reações Fenton. Superfícies eletródicas modificadas com filmes de poli-azul de metileno (PMB) e óxido de rutênio de hexacianoferrato (RuOHCF) sem e com a incorporação de nanotubos de carbono de paredes múltiplas (MWCNTs) foram utilizadas para a detecção amperométrica de peróxido de hidrogênio. O efeito da ordem de deposição do PMB e MWCNT foi avaliado por voltametria cíclica e espectroscopia de impedância eletroquímica. Estudos realizados por voltametria cíclica indicaram que a superfície modificada com PBM/MWCNTs facilita a redução catódica do peróxido de hidrogênio, processo que ocorre em 0,0 V vs. Ag/AgCl/KCl(sat). O método para a detecção de peróxido de hidrogênio apresentou uma resposta linear de 109 a 3000 µmol L-1, com limite de detecção de 20,7 µmol L-1 e sensibilidade de 108 µA mmol-1 L cm-2. O eletrodo modificado com RuOHCF foi utilizado para a detecção amperométrica de peróxido de hidrogênio por análise em injeção em fluxo (FIA). O método apresentou uma resposta linear de 10 a 5000 µmol L-1 e limite de detecção de 1,7 µmol L-1. Aplicações em amostras comerciais também foram realizadas, e os resultados foram concordantes com os obtidos por método padrão. Estudos sobre o processo eletrocatalítico da reação de peróxido de hidrogênio em filmes de RuOHCF foram investigados utilizando eletrodo rotativo. A incorporação de MWCNTs na superfície eletródica também foi analisada com o filme de RuOHCF. Os resultados indicaram que a presença de MWCNTs melhorou a resposta do sensor para peróxido de hidrogênio em potenciais próximos a 0,0 V vs. Ag/AgCl/KCl(sat). A influência da quantidade de MWCNTs foi avaliada por amperometria em 0,0 V vs. Ag/AgCl/KCl(sat) na presença de peróxido de hidrogênio. O eletrodo modificado com 100 µg de MWCNTs e posterior deposição do filme de RuOHCF apresentou melhores características analíticas. Obteve-se como resultado uma curva analítica em um intervalo de 0,1 a 10 mmol L-1, originando uma reta de acordo com a equação: -I (µA) = 0,26 + 31,2 [H2O2] (mmol L-1), R2= 0,9999. A sensibilidade foi de 1560 µA mmol-1 L cm-2 e os limites de detecção e quantificação foram estimados em 4,7 (S/N = 3) e 15,8 (S/N = 10) µmol L-1, respectivamente. Comparando-se as características analíticas dos filmes de PMB e RuOHCF depositados na superfície dos MWCNTs, aquele que apresentou melhor resultado foi o eletrodo modificado com MWCNTs e RuOHCF por ter melhor limite de detecção e maior sensibilidade. Esse eletrodo modificado com MWCNTs e RuOHCF foi utilizado para monitorar o consumo de peróxido de hidrogênio em amostras de reação Fenton. Também foi avaliado o efeito da presença de Fe3+ contido no próprio processo de degradação. A interferência foi eliminada complexando o Fe3+ com oxalato. Finalmente, o eletrodo foi utilizado para monitorar a concentração de peróxido de hidrogênio na degradação de fenol e os resultados foram concordantes com os obtidos por método espectrofotométrico / This work presents results on the development of a sensor to monitor the hydrogen peroxide content in samples of Fenton reaction. The electrode surface was modified with films of poly-methylene blue (PMB) and ruthenium oxide hexacyanoferrate (RuOHCF). In some cases, multiwalled carbon nanotubes (MWCNT) were also used. The effect of the order of deposition of PMB and MWCNTs was evaluated by cyclic voltammetry and electrochemical impedance spectroscopy. The influence of immobilization of various platforms in the performance of fabricated sensors for hydrogen peroxide was also studied. Cyclic voltammetry experiments indicated that the surface modified with PMB/MWCNTs facilitates the cathodic reduction of hydrogen peroxide, a process that occurred at 0.0 V vs. Ag/AgCl/KCl(sat). The method showed a linear response from 109 to 3000 µmol L-1 hydrogen peroxide. The limit of detection was estimated as 20.7 (S/N = 3) µmol L-1 with a sensitivity of 108 µA mmol-1 L cm-2. Electrodes modified with RuOHCF films were used for the amperometric detection of hydrogen peroxide by flow injection analysis (FIA).The method showed a linear response from 10 to 5000 µmol L-1 and a detection limit of 1.7 µ mol L-1. Analyses of hydrogen peroxide in commercial samples were also performed, and the results agreed with those obtained by a standard method. Studies on the kinetics of the electrocatalytic reduction of hydrogen peroxide in RuOHCF films were carried out using rotating disc voltammetric. The immobilization of MWCNTs on RuOHCF films was also investigated. The results indicated that the presence of MWCNTs facilitated the electrocatalytic reduction of hydrogen peroxide at potential values near to 0.0 V vs. vs. Ag/AgCl/KCl(sat). The influence of the amount of MWCNTs was studied by amperometry at 0.0 V vs. vs. Ag/AgCl/KCl(sat) in the presence of hydrogen peroxide. The electrode modified with 100 µg of MWCNTs and subsequent deposition of the RuOHCF film showed better analytical characteristics. An analytical curve ranging from 0.1 to 10 mmol L-1 hydrogen peroxide was obtained, resulting in a straight line according to the equation: -I (µA) = 0.26 + 31.2 [H2O2] (mmol L-1), R2= 0.9999. The sensitivity was found to be 1560 µA mmol-1 L cm-2 and the detection and quantification limits were estimated at 4.7 (S / N = 3) and 15.8 (S / N = 10) mmol L-1, respectively. Electrodes modified with MWCNTs and RuOHCF films leaded to better detection limit and sensitivity in comparison to those modified with MWCNTs and PMB. This MWCNTs and RuOHCF modified electrode was used to monitor the consumption of hydrogen peroxide in samples of Fenton reaction and the effect of Fe3+ generated in the degradation process was also examined. The interference was minimized by adding oxalate to the samples. Finally, the sensor was used to monitor the concentration of hydrogen peroxide in the degradation of phenol and the results were in agreement with those obtained by using spectrophotometry Amperometria Amperometry Detecção amperométrica Eletrodos modificados FIA FIA amperometric detection Hydrogen peroxide Modified electrodes Multiwalled carbon nanotubes Peróxido de hidrogênio
15	Synthesis and investigation of nanostructured polymer composites based on heterocyclic esters and carbon nanotubes Bardash, Liubov, Bardash, Liubov 28 September 2011 (has links) (PDF) The thesis relates to synthesis and investigation of nanostructured polymer composites based on oligomers of cyanate esters of bisphenol a (DCBA) or cyclic butylene terephthalate (CBT) and multiwalled carbon nanotubes (MWCNTS). Catalytic effect of mwcnts in process of DCBA polycyclotrimerization as well as in cbt polymerization has been observed. Significant increase in crystallization temperature of nanocomposites based on polybutylene terephthalate (cPBT) with adding of MWCNTS is observed. The effect of processing method of cpbt/mwcnts nanocomposites on its electrical properties has been found. It has been established that the additional heating of the samples (annealing) at temperatures above melting of cPBT leads to reagglomeration of MWCNTS in the system. It is established that reagglomeration of MWCNTS results in increase of conductivity values of nanocomposites due to formation of percolation pathways of MWCNTS through polymer matrix. In the case of polycyanurate matrix (PCN), it is found that addition of small mwcnts contents (0.03-0.06 weight percents) provides increasing tensile strength by 62-94 percents. It has been found that addition of even 0.01 weight percents of MWCNTS provides significant increase in storage modulus of cPBT matrix. This is explained by effective dispersing of small amount of the nanofiller during in situ synthesis of pcn or cpbt matrix that is confirmed by microscopy techniques. It has been established that the properties of the nanocomposites based on heterocyclic esters and MWCNTS can be varied from isolator to conductor and has low percolation thresholds (0.22 and 0.38 weight percents for cPBT and PCN nanocomposites respectively). The conductivity of samples is particularly stable on a very large range of temperature from 300 to 10 degrees Kelvin that make these materials perspective for practical applications in microelectronics, as parts of aircraft and space constructions. [SPI:OTHER] Engineering Sciences/Other Nanocomposite polymer Multiwalled carbon nanotubes Cyanate esters Cyclic butylene terephtalate In situ synthesis Catalytic effect Mechanical properties Electrical properties
16	Analysis Of Multiwalled Carbon Nanotube Agglomerate Dispersion In Polymer Melts Kasaliwal, Gaurav 26 March 2012 (has links) (PDF) For the commercial success of polymer - multiwalled carbon nanotube (MWNT) composites the production of these materials on industrial scale by melt processing is of significant importance. The complete dispersion of primary MWNT agglomerates in a polymer melt is difficult to achieve, making it an important and challenging technological problem. Hence, it is necessary to understand the process of MWNT agglomerate dispersion in a polymer melt. Based on an intensive literature research on mechanisms and influencing factors on dispersion of other agglomerated nanostructured fillers (e.g. carbon black), the main dispersion steps were evaluated and investigated concerning the agglomerated MWNT.Consequently, systematic investigations were performed to study the effect of the melt infiltration on MWNT agglomerate dispersion and to analyse the corresponding main dispersion mechanisms, namely rupture and erosion. The states of MWNT agglomerate dispersion were assessed by quantifying the agglomerate area ratio and particle size distribution using image analysis of optical transmission micrographs. Additionally, the composite’s electrical resistivity was determined. In the prevailing study, polycarbonates (PC) varying in molecular weight were used to produce composites containing 1 wt% MWNT (Baytubes C150HP) as model systems and a discontinuous microcompounder was applied as melt mixing device. The agglomerate structure of the used MWNT material made them especially suitable for the reported investigations. The step of melt infiltration into the primary nanotube agglomerates plays a crucial role for their dispersion in the PC melt. During melt mixing when low shear rates were applied, better state of MWNT dispersion was obtained in high viscosity matrices because applied shear stresses were high. On the contrary, if high shear rates were applied, similar states of MWNT dispersion were obtained in low and high viscosity matrices although significantly lower shear stresses were applied in the low viscosity matrix as compared to the high viscosity matrix. The results indicate that if the applied shear stress values are compared, with increasing matrix viscosity the agglomerate dispersion gets worsen. This is attributed to the fact that low viscosity matrices can infiltrate relatively faster than high viscosity matrices into the agglomerate making them weaker and reducing the agglomerate strength. Thus, at sufficient shear rates MWNT agglomerates disperse relatively faster in low viscosity matrix. This illustrates a balance between the counteracting effects of viscosity on agglomerate infiltration and agglomerate dispersion. Additionally, the effect of matrix molecular weight on the size of un-dispersed MWNT agglomerates was investigated. Under similar conditions of applied shear stress, the composites based on low molecular weight matrix showed smaller sized un-dispersed primary agglomerates as compared to composites with higher molecular weight matrices. This again highlights the role of matrix infiltration as the first step of dispersion. Following the step of melt infiltration, agglomerate size gets reduced due to the dispersion mechanisms. To analyse the corresponding contributions of different dispersion mechanisms (rupture and erosion), the kinetics of MWNT agglomerate dispersion was investigated. If high mixing speeds are employed dispersion is quite fast and needs less time as compared to low mixing speed. A model is proposed to estimate the fractions of rupture and erosion mechanisms during agglomerate dispersion based on the kinetic study in the discontinuous mixer. Under the employed experimental conditions, at high mixing speeds, the dispersion was found to be governed by rupture dominant mechanism, whereas at low mixing speeds the dispersion was controlled by both mechanisms. As far as electrical resistivity is concerned, for a given content of MWNT as the state of dispersion improves, the resistivity values decrease significantly but only up to a plateau value. The composites produced using low viscosity matrices have lower resistivity values as compared to high viscosity matrices. Additionally, composites were prepared using additives, whereas the additives were found to be useful for improving filler dispersion and electrical conductivity. Multiwalled carbon nanotubes CNT kompositen Polymerkompositen Schmelzeverarbeitung Agglomerate dispersion CNT dispersion und verteilung Dispersionsmechanismen Durchlichtmikroskopie Spezifischer Volumenwiederstand Multiwalled carbon nanotubes CNT composites polymer nanocomposites polymer melt compounding agglomerate dispersion CNT dispersion and distribution dispersion mechanisms optical microscopy electrical resistivity ddc:620 rvk:VE 9850
17	Voltametrijske metode zasnovane na ugljeničnim elektrodama modifikovane kompozitima na bazi višezidnih ugljeničnih nanocevi i čestica bizmuta ili antimona za određivanje odabranih ciljnih analita / Voltammetric methods based on carbon electrodes modified with multi walled carbon nanotubes and bismuth and antimony particles based composites for determination of selected target analytes Petrović Sandra 12 September 2019 (has links) <p>Cilj ove doktorske disertacija  bio je razvoj  novih, osetljivih, selektivnih i ekonomski<br />isplativih  voltametrijskih  radnih  elektroda  za  praćenje  odabranih  analita  kako  u<br />laboratorijskim tako i pri terenskim uslovima.  Ispitivana je  mogućnost primene  ovih  radnih  elektroda  primenom  voltametrijskih  metoda  kako  u  model  rastvorima  tako  i  u  pojedinim realnim sistemima. SW-ASV  zasnovana  na  elektrodama  od  staklastog  ugljenika  povr&scaron;inski modifikovanim  Bi-MWCNT  i  BiOCl-MWCNT  je  primenjena  za  određivanje  jona  Pb(II)  i Cd(II)  pri  optimizovanim  uslovima  merenja.  Određivanje  ciljnih  jona  vr&scaron;eno  je  pri  radnom potencijalu  od  -1,2  V  (izmeren  u  odnosu  na  zasićenu  kalomelovu  elektrodu)  i  vremenu<br />elektrodepozicije jona  od 120 s. Sva merenja su izvr&scaron;ena u rastvoru acetatnog pufera čija je pH-vrednost iznosila  4,0. Primenjeni koncentracioni opseg ciljnih analita iznosio je  od 5 do 50  μg  dm <sup>-3</sup> .  Primenom  ovog  tipa  elektrode  dobijene  su  vrednosti  granice  detekcije  za  jone Pb(II) i Cd(II) 0,57  μg dm <sup>-3 </sup>i 1,2 μg dm<sup>-3</sup> , redom. Dobijena RSD iznosila je manje od 10% za oba  jona.  Ova  metoda  je  primenjena  i  za  određivanje  ciljnih  jona  u  realnom  uzorku  porne vode  sedimenta  a  rezultati  dobijeni  optimizovanom  voltametrijskom  metodom  su  u  dobroj saglasnosti sa rezultatima koji su dobijeni primenom komparativne GFAAS metode. Bizmut oksihlorid-vi&scaron;ezidne ugljenične nanocevi kompozitni materijal je primenjen za povr&scaron;insko  modifikovanje  elektrode  od  staklastog  ugljenika  za  brzo  i  jednostavno voltametrijsko  određivanje  tragova  Zn(II)-jona  primenom  SW-ASV  metode.  BiOClMWCNT/GCE je pokazala linearan analitički odgovor u  osegu koncentracija od  2,50 do  80,0 μg  dm <sup>-3 </sup>sa dobijenom vredno&scaron;ću GD 0,75 μg  dm<sup>-3 </sup>pri akumulacionom vremenu od  120 s  i potencijalu  elektrodepozicije  -1,40  V  u  odnosu  na  ZKE.  Merenja  su  vr&scaron;ena  u  acetatnom puferu pH 4,5. Dobijena RSD iznosila je 4,8 %. Upoređene su performanse novodizajnirane BiOCl-MWCNT/GCE elektrode  i  tradicionalne elektrode na bazi bizmut filma (BiF/GCE), MWCNT/GCE,  BiF-MWCNT/GCE  i  nemodifikovane  GC  elektrode.  Novodizajnirana elektroda je primenjena za  detekciju  i određivanje  Zn(II)-jona  u realnim  uzorcima kao &scaron;to su<br />dijetetski  suplement  i  pekarski  kvasac.  Dobijeni  rezultati  su  uporedivi  sa  deklarisanom vredno&scaron;ću  u  slučaju  dijetetskog  suplementa  a  u  slučaju  pekarskog  kvasca  sa  rezultatima dobijenih komparativnom FAAS .<br />Elektroda od ugljenične paste je povr&scaron;inski modifikovana pripremljenim kompozitom<br />koji je  izgrađen od vi&scaron;ezidnih ugljeničnih nanocevi i čestica  Sb<sub>2</sub>O<sub>3.</sub>  Kompozitni  materijal  je okarakterisan  primenom  TEM,  EDS  i  XRD  mernih  tehnika.  Sb<sub>2</sub>O<sub>3</sub>-MWCNT/CPE  je okarakterisana primenom ciklične voltametrije a merenja su vr&scaron;ena u rastvoru hlorovodonične kiseline  (pH  2,0).  Primenom  SW-ASV  metode  ova  radna  elektroda  je  upotrebljena  za određivanje  jona Pb(II) i Cd(II)  u  koncentracionom opsegu 2,0-40,0  μg  dm  <sup>-3 </sup>za  Pb(II)-jon  i 2,0-40,0  μg  dm <sup>-3</sup> za  Cd(II)-jon  pri  čemu  su  dobijene  dobre  linearne  zavisnosti  za  oba  ciljna jona.  Optimalna  procedura  uključuje  primenu  Sb2O3-MWCNT/CPE  u  0,01  mol dm <sup>-3</sup><br />hlorovodoničnoj kiselini uz vreme elektrodepozicije jona iz rastvora od 120  s  na  potencijaluod  -1,2  V,  pri  čemu  su  dobijene  vrednosti  za  GD  1,1  μg  dm <sup>-3</sup> Cd(II)  i  1,6  μg  dm <sup>-3</sup> Pb(II). Optimizovana  metoda  zasnovana  na  ovom  tipu  voltametrijskog  senzora  je  uspe&scaron;no primenjena  za  određivanje  jona  Cd(II)  u  obogaćenom  uzorku  česmenske  vode,  gde  su  se dobijene vrednosti u  saglasnosti sa očekivanom. Elektroda od ugljenične paste povr&scaron;inski je  modifikovana primenom  Sb<sub>2</sub>O<sub>3</sub>-MWCNT nanokompozitnog  materijala  i  primenjena  za  direktno  voltametrijsko  određivanje imidakloprida  u  model  rastvorima.  U  cilju  postizanja  &scaron;to  boljih  analitičkih  performansi optimizovani su eksperimentalni uslovi merenja kao &scaron;to su pH-vrednost rastvora pomoćnog elektrolita  i  kondicioniranje  povr&scaron;ine  voltametrijskog  senzora.  Kao  optimalna  pH-vrednost pomoćnog elektolita (Britton-Robinsonovog pufera) odabrana je pH 7,0, a ponavljanje ciklusa cikliranja najmanje 4 puta povoljno utiče na stabilnost  voltametrijskih signala. Optimizovana metoda primenjena je za SW direktno katodno određivanje imidakloprida u koncentracionom intervalu od 1,41 do 32,77 μg cm <sup>-3</sup> uz dobijeni korelacioni faktor od 0,9995. Na osnovu dobijenih rezultata može se zaključiti da su razvijene analitičke metode pre svega  osetljive,  selektivne,  reproduktivne  i   jednostavne  &scaron;to  omogućava  njihovu  primenu  za veliki broj uzoraka.  Merenjima u model i realnim rastvorima dokazana je mogućnost njihove primene  u   komplikovanim  matriksima,  pri  različitim  pH  vredostima  pri  čemu  su  dobijeni<br />rezultati koji su u saglasnosti sa rezultatima primenjenih komparativnih metoda. Naravno, za dobijanje  reprezentativnih  rezultata  neohodno  je  izvr&scaron;iti  optimizaciju  uslova  merenja  &scaron;to podrazumeva sam odabir supstrat-elektrode, odabir povr&scaron;inskog modifikatora i optimizaciju eksperimentalnih uslova merenja.</p> / <p>The  aim of this  Ph.D. thesis  was the development of new, sensitive, selective and economically  viable  voltametric  working  electrode  for  continuous  monitoring  of  different target  analytes.  The  use  of  these  advantaged  working  electrodes  was  investigated  using voltametric methods both in model solutions and in certain real systems.SW-ASV  based on glassy carbon  electrode surface modified with  Bi- MWCNT and BiOCl-MWCNT  were  applied  for  determination  of  Pb(II)  and  Cd(II)  ions.  Voltametric determination  of  Pb(II)  and  Cd(II)  ions  was  performed  at  working  potential  of  -1.2  V (measured against the saturated calomel electrode) and time of electrodeposition of 120 s. All measurements were performed in acetate buffer solution pH 4.0. Concentration range of targetanalites were  5-50 μg  dm -3 . Using this type of electrode,  obtained  detection limits for  Pb(II) and Cd(II) ions  were  0.57  μg  dm -3 and 1.2  μg  dm -3 , respectively, with RSD lower than 10%.This  method  was  applied  for  target  ions  determination  in  sediment  pore  water  sample,  and obtained results are comparable with those who are obtained using GFAAS method. Bismuth oxychloride-multiwalled carbon nanotubes composite material was applied for  surface  modification  of  the  glass-carbon  electrode  for  quick  and  simple  voltametric determination  of  Zn(II)  ions  using  the  SW-ASV  method.  BiOCl-MWCNT/GCE  showed  a linear  analytical  response  in  a   concentration  from  2.50  to  80.0  μg  dm -3 with  a  value  of detection limit 0.75 μg dm -3 at a acumulation time of 120 s and an electrodeposition potential of  -1.40 V vs. saturated  calomel electrode.  Measurements were carried out in acetate buffer pH 4.5. The obtained  value of the RSD  was  4.8%. The performance of the newly designed BiOCl-MWCNT/GCE  electrode,  traditional  bismuth-based  electrode  (BiF/GCE), MWCNT/GCE,  BiF-MWCNT/GCE  and  unmodified  GC  electrodes  were  compared.  The applied electrode shows very good electroanalytic properties when determining this target ion. Obtained results are in good agreement with declared value in case of dietetic suplement, and in the brewer’s yeast sample results were comparable with FAAS results. Carbon  paste  electrode  surface  modified  with  new  composite  material  based  on multiwalled carbon nanotubes and  Sb2O3  particles. The composite is characterized by TEM, EDS and  XRD measurment. Sb2O3- MWCNT/CPE was characterized by cyclic voltammetry and measurements were carried out in a  hydrochloric acid  solution  (pH 2.0). Using the SWASV  method,  this  working  electrode  was  used  to  determine  Pb(II),  Cd(II)  ions  in  the concentration range  from  2.0  to 40.0  μg dm -3 for Pb(II) and 2.0-40.0  μg dm -3 for Cd(II) ions. Newly  designed  sensor  showed  good  linear  dependences  for  both  target  ions.  The  most optimal  procedure  involving  application  of  Sb2O3-MWCNT/CPE  in   .01  mol  dm -3 hydrochloric  acid,  with  electroposition  time  of  target  ions  120  s  at  a  electrodeposition potential  of  -1.2  V.  Obtained   values  of    LOD  1,1  μg  dm -3 for  Cd(II)  and  for  1,6  μg  dm -3 Pb(II)  ions.  An  optimized  method  based  on  this  type  of  voltametric  sensor  has  been successfully  applied  for  determination  of  Cd(II)  ion  in  a  spiked  tap  water  sample.  Results obtained during this measurment were in tune with expected results. CPE  was  surface  modified  using  Sb2O3-MWCNT  nanocomposite  material  and tested  for  direct  voltametric  determination  of  imidacloprid  in  model  solutions.  In  order  to achieve the best analytical performance, experimental conditions of measurement such as the pH value of the supporting electrolyte and conditioning of the voltametric sensor surface havebeen  optimized.  As  an  optimum  pH  value  of  the  supporting  electrolyte  (Britton-Robinson buffer), a pH 7.0 was selected, and the repeating cycles of the cycling process at least 4 times favorably  influenced  the  stability  of  the  voltametric  signals.  The  optimized  method  was applied for the SW direct cathodic determination  of  imidacloprid in the concentration range from 1.41 to 32.77 μg cm -3  with obtained correlation factor of 0.9995. Based on results it can be concluded that developed analytical methods are sensitive, selective, reproducibile and simple, which can enable their application for various number of samples. Measurements in the model and real solutions have demonstrated the possibility of their  application  in  complicated  matrices,  at  different  pH,  whereby  obtained  results  are  in accordance  with  the  results  of  the  applied  comparative  methods.  For  obtainig  of representative  results  it  is  necessary  to  optimize  conditions  of  measurment  which  include: selection of substrat electrode, surface modifier and optimization of experimental condition.</p>
18	Analysis Of Multiwalled Carbon Nanotube Agglomerate Dispersion In Polymer Melts Kasaliwal, Gaurav 15 July 2011 (has links) For the commercial success of polymer - multiwalled carbon nanotube (MWNT) composites the production of these materials on industrial scale by melt processing is of significant importance. The complete dispersion of primary MWNT agglomerates in a polymer melt is difficult to achieve, making it an important and challenging technological problem. Hence, it is necessary to understand the process of MWNT agglomerate dispersion in a polymer melt. Based on an intensive literature research on mechanisms and influencing factors on dispersion of other agglomerated nanostructured fillers (e.g. carbon black), the main dispersion steps were evaluated and investigated concerning the agglomerated MWNT.Consequently, systematic investigations were performed to study the effect of the melt infiltration on MWNT agglomerate dispersion and to analyse the corresponding main dispersion mechanisms, namely rupture and erosion. The states of MWNT agglomerate dispersion were assessed by quantifying the agglomerate area ratio and particle size distribution using image analysis of optical transmission micrographs. Additionally, the composite’s electrical resistivity was determined. In the prevailing study, polycarbonates (PC) varying in molecular weight were used to produce composites containing 1 wt% MWNT (Baytubes C150HP) as model systems and a discontinuous microcompounder was applied as melt mixing device. The agglomerate structure of the used MWNT material made them especially suitable for the reported investigations. The step of melt infiltration into the primary nanotube agglomerates plays a crucial role for their dispersion in the PC melt. During melt mixing when low shear rates were applied, better state of MWNT dispersion was obtained in high viscosity matrices because applied shear stresses were high. On the contrary, if high shear rates were applied, similar states of MWNT dispersion were obtained in low and high viscosity matrices although significantly lower shear stresses were applied in the low viscosity matrix as compared to the high viscosity matrix. The results indicate that if the applied shear stress values are compared, with increasing matrix viscosity the agglomerate dispersion gets worsen. This is attributed to the fact that low viscosity matrices can infiltrate relatively faster than high viscosity matrices into the agglomerate making them weaker and reducing the agglomerate strength. Thus, at sufficient shear rates MWNT agglomerates disperse relatively faster in low viscosity matrix. This illustrates a balance between the counteracting effects of viscosity on agglomerate infiltration and agglomerate dispersion. Additionally, the effect of matrix molecular weight on the size of un-dispersed MWNT agglomerates was investigated. Under similar conditions of applied shear stress, the composites based on low molecular weight matrix showed smaller sized un-dispersed primary agglomerates as compared to composites with higher molecular weight matrices. This again highlights the role of matrix infiltration as the first step of dispersion. Following the step of melt infiltration, agglomerate size gets reduced due to the dispersion mechanisms. To analyse the corresponding contributions of different dispersion mechanisms (rupture and erosion), the kinetics of MWNT agglomerate dispersion was investigated. If high mixing speeds are employed dispersion is quite fast and needs less time as compared to low mixing speed. A model is proposed to estimate the fractions of rupture and erosion mechanisms during agglomerate dispersion based on the kinetic study in the discontinuous mixer. Under the employed experimental conditions, at high mixing speeds, the dispersion was found to be governed by rupture dominant mechanism, whereas at low mixing speeds the dispersion was controlled by both mechanisms. As far as electrical resistivity is concerned, for a given content of MWNT as the state of dispersion improves, the resistivity values decrease significantly but only up to a plateau value. The composites produced using low viscosity matrices have lower resistivity values as compared to high viscosity matrices. Additionally, composites were prepared using additives, whereas the additives were found to be useful for improving filler dispersion and electrical conductivity. info:eu-repo/classification/ddc/620 ddc:620
19	Study and Development of Nonwovens made of Electrospun Composite Nanofibers / Etude et développement de non-tissés fait en nanofibres composites obtenues par électrofilage Almuhamed, Sliman 14 December 2015 (has links) L’électrofilage est actuellement la méthode la plus utilisée pour la production de nanofibres grâce à sa simplicité, sa reproductibilité et la possibilité d’être industrialisée. Grâce à leurs propriétés particulières telles qu’un grand rapport surface-volume, une porosité inter-fibre élevée et une grande capacité d’adsorption, les nanofibres électrofilées sont de bons candidats pour de nombreuses applications telles que la filtration, les masques respiratoires, les matériaux composites, etc. Cependant, certaines applications particulières, telles que les capteurs, les systèmes d'administration contrôlée de médicaments ou les super condensateurs, exigent que les nanofibres doivent présenter des propriétés complémentaires telles que la conductivité électrique, la porosité de surface de nanofibres, l’hydrophobicité, ou d’autres propriétés particulières. Certains nanomatériaux comme les nanotubes de carbone, la silice mésoporeuse ordonnée, les argiles, ont des propriétés particulières comme la conductivité électriques élevée des nanotubes de carbone, la porosité des matériaux de silice mésoporeuse ordonnée ou de l’argile. Ces propriétés des nanomatériaux peuvent être les fonctions complémentaires cherchées. Dans notre étude, des non-tissés composés de nanofibres de polyacrylonitrile chargées par nanotubes de carbone à multi-parois (MWNT), de la montmorillonite sodique (MMT-Na) ou de la silice mésoporeuse ordonnée (de type SBA-15), sont produits par électrofilage. Les résultats montrent que l’insertion de MWNT rend le non-tissé conducteur en augmentant la conductivité électrique volumique par six ordres de grandeur (de ~ 2×10-12 à ~ 3×10-6 S/m) avec un très faible seuil de percolation de 0.5 % massique. Lorsque le non-tissé est soumis à une compression, la conductivité électrique volumique augmente en augmentant la pression (jusqu’à ~ 2 kPa). Ces non-tissés conducteurs sont très intéressants pour le développement des capteurs à faible amplitude. Les résultats montrent aussi que l’accessibilité des pores des particules inorganiques (c’est-à-dire, les mésopores de SBA-15 et l’espace interfoliaire de MMT-Na) insérées dans la structure nano fibreuse est encore possible. Il a été trouvé que plus de 50% des mésopores de SBA-15 insérées sont encore accessibles quelles que soit les conditions de l’électrofilage et la fraction massique de SBA-15. En outre, l’insertion de ces particules inorganiques apporte plus de stabilité thermique aux nanofibres composites. / Electrospinning is the most common method for the production of nanofibres due to its simplicity, repeatability, and the ability to be scaled up. Owing to their advanced properties like the high surface-to-volume ratio, high interfibrous porosity, high adsorption capacity, etc. electrospun nanofibers are good candidates for many applications such as filtration, respiratory masks, composite materials and others. However, some specific applications including sensors, controlled drug delivery systems, supercapacitors, etc. still require complimentary functions that do not exist in pristine nanofibers in their basic structure like the electrical conductivity, surface porosity of the nanofibers, hydrophobicity, and others.Nanomaterials like carbon nanotubes, ordered mesoporous silica, layered silicate, etc. are characterized by particular properties like the high electrical conductivity of carbon nanotubes, the porosity of ordered mesoporous silica or layered silicate. These particular properties of nanomaterials can fulfill of the targeted functions.In our study, nonwovens made from nanofibers of polyacrylonitrile incorporated with multiwalled carbon nanotubes (MWNT), layered silicate type Na-montmorillonite (Na-MMT) or ordered mesoporous silica type SBA-15 are successfully produced by electrospinning.Results reveal that the incorporation of MWNT altered the electrical state of the nonwoven from insolent to conductor where the volume electrical conductivity increased by six order of magnitude (from ~ 2×10-12 to ~ 3×10-6 S/m) with a very low percolation threshold of about 0.5 wt%. The application of mechanical pressure to the conductive nonwoven causes an increase in the volume electrical conductivity with the increase of the applied pressure (up to ~ 2 kPa). Such conductive nonwoven is very interesting for the development of sensor with low amplitude.Results also show that accessibility of the pores of the inorganic particles (i.e. mesopores of SBA-15 and interlayer space of Na-MMT) incorporated into the nanofibers is still possible. It is found that at least 50% of SBA-15 mesopores are still accessible whatever is the electrospinning conditions and SBA-15 mass fraction. In addition, the incorporation of the studied inorganic particles yields higher thermal stability for the composite nanofibers. Nanofibres Électrofilage Composite Fonctionnalisation Non-tissé Nanotube de carbone multi-voies Montmorillonite sodique (MMT-Na) Nanofibers Electrospinning Composite Functionalization Nonwoven Multiwalled carbon nanotube SBA15 ordered mesoporous silica Na-MMT Layered silicate 620.1
20	Photoacoustic drug delivery using carbon nanoparticles activated by femtosecond and nanosecond laser pulses Chakravarty, Prerona 09 January 2009 (has links) Cellular internalization of large therapeutic agents such as proteins or nucleic acids is a challenging task because of the presence of the plasma membrane. One strategy to facilitate intracellular drug uptake is to induce transient pores in the cell membrane through physical delivery strategies. Physical approaches are attractive as they offer more generic applicability compared with viral or biochemical counterparts. Pulsed laser light can induce the endothermic carbon-steam reaction in carbon-nanoparticle suspensions to produce explosive photoacoustic effects in the surrounding medium. In this study, for the first time, these photoacoustic forces were used to transiently permeabilize the cell membrane to deliver macromolecules into cells. Intracellular delivery using this method was demonstrated in multiple cell types for uptake of small molecules, proteins and DNA. At optimized conditions, uptake was seen in up to 50% of cells with nearly 100% viability and in 90% of cells with ≥90% viability, which compared favorably with other physical methods of drug delivery. Cellular bioeffects were shown to be a consequence of laser-carbon interaction and correlated with properties of the carbon and laser, such as carbon concentration and size, laser pulse duration, wavelength, intensity and exposure time. Similar results were observed using two different lasers, a femtosecond Ti: Sapphire laser and a nanosecond Nd: YAG laser. Uptake was also shown in murine skeletal muscles in vivo with up to 40% efficiency compared to non-irradiated controls. This synergistic use of nanotechnology with advanced laser technology could provide an alternative to viral and chemical-based drug and gene delivery. Ultrashort laser pulses Multiwalled carbon nanotubes Luciferase GFP Dextrans BSA Calcein Gold nanorods Intracellular delivery Physical method Whisker mediated transformation Silicon carbide Tissue culture Ultrasound Loblolly pine Acoustooptical devices Drug delivery systems Femtosecond lasers Nanotechnology Lasers in medicine

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