Dispersão de nanotubos de carbono e nanocristais de celulose em diferentes quitosanas: estudo das suspensões e propriedades de nanocompósitos poliméricos
| Ano de defesa: | 2015 |
|---|---|
| Autor(a) principal: | |
| Orientador(a): | |
| Banca de defesa: | |
| Tipo de documento: | Dissertação |
| Tipo de acesso: | Acesso aberto |
| Idioma: | por |
| Instituição de defesa: |
Universidade Federal de Minas Gerais
|
| Programa de Pós-Graduação: |
Não Informado pela instituição
|
| Departamento: |
Não Informado pela instituição
|
| País: |
Não Informado pela instituição
|
| Palavras-chave em Português: | |
| Link de acesso: | https://hdl.handle.net/1843/SFSA-9WHV3D |
Resumo: | In this study different suspensions were prepared by dispersing functionalized carbon nanotubes (MWCNT) and/or cellulose nanocrystals (NCC) in acidic solutions of low ( = 3,3x104 g/mol and = 25%) and high molar mass ( = 3,7x105 g/mol and = 31%) chitosans andglycerol (10% by weight) with the use of a tip ultrasound. The dispersions were characterized in order to find what concentration of each nanofiller would be possible to disperse with those chitosans without the use of further centrifugation steps. It was found that concentrations of NCC ofabout 10wt% and 1w% and nanotubes in the order of 2wt% and 0.5wt% were effectively dispersed in such matrices (high and low molecular weights, respectively) and the suspensions remain stableeven after 3 months or more (at rest), indicating the filler stabilization by the chitosan with the preparation of thermodynamic dispersions. From these suspensions, binary (CHI /MWCNT or NCC) and ternary (CHI/MWCNT/NCC) polymer nanocomposites were prepared by casting technique. The addition of MWCNTs and NCCs affects the thermal stability of the chitosan (as measured by thermogravimetry), indicating possible interaction between the filler and matrix. Infrared spectroscopy data of the composite films showed the interaction filler/chitosan, which was corroborated by the scanning and transmission electronic microscopies images. These images showed good adhesion of the fillers to the polymer matrix as a result of MWCNT/CHI, NCC/CHI and CHI/MWCNT/NCC interactions. Furthermore, another evidence of this interaction (obtained in the fracture images) is the fact that no nanotube was pulled out from the matrix with the fracture, as well the observation of curved nanotubes connecting "points"of the fractured surface. This morphology is essential to the transfer of tension between the fillers and matrix when the material is subjected to mechanical stress. In fact, the mechanical tests showed that both the nanotubes (in a smaller scale) and NCC are excellent reinforcement for chitosan. Increases were observed in properties such as modulus, tensile strength, elongation at break and toughness. Moreover, in the ternary composite, the synergy between the matrix, nanocrystals and nanotubes allowed the preparation of nanocomposites with superior properties to those found in the binary systems using low concentrations of the nanofiller, especially in the high molecular weight chitosan matrix. |
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2019-08-10T14:20:52Z2025-09-09T01:14:43Z2019-08-10T14:20:52Z2015-02-25https://hdl.handle.net/1843/SFSA-9WHV3DIn this study different suspensions were prepared by dispersing functionalized carbon nanotubes (MWCNT) and/or cellulose nanocrystals (NCC) in acidic solutions of low ( = 3,3x104 g/mol and = 25%) and high molar mass ( = 3,7x105 g/mol and = 31%) chitosans andglycerol (10% by weight) with the use of a tip ultrasound. The dispersions were characterized in order to find what concentration of each nanofiller would be possible to disperse with those chitosans without the use of further centrifugation steps. It was found that concentrations of NCC ofabout 10wt% and 1w% and nanotubes in the order of 2wt% and 0.5wt% were effectively dispersed in such matrices (high and low molecular weights, respectively) and the suspensions remain stableeven after 3 months or more (at rest), indicating the filler stabilization by the chitosan with the preparation of thermodynamic dispersions. From these suspensions, binary (CHI /MWCNT or NCC) and ternary (CHI/MWCNT/NCC) polymer nanocomposites were prepared by casting technique. The addition of MWCNTs and NCCs affects the thermal stability of the chitosan (as measured by thermogravimetry), indicating possible interaction between the filler and matrix. Infrared spectroscopy data of the composite films showed the interaction filler/chitosan, which was corroborated by the scanning and transmission electronic microscopies images. These images showed good adhesion of the fillers to the polymer matrix as a result of MWCNT/CHI, NCC/CHI and CHI/MWCNT/NCC interactions. Furthermore, another evidence of this interaction (obtained in the fracture images) is the fact that no nanotube was pulled out from the matrix with the fracture, as well the observation of curved nanotubes connecting "points"of the fractured surface. This morphology is essential to the transfer of tension between the fillers and matrix when the material is subjected to mechanical stress. In fact, the mechanical tests showed that both the nanotubes (in a smaller scale) and NCC are excellent reinforcement for chitosan. Increases were observed in properties such as modulus, tensile strength, elongation at break and toughness. Moreover, in the ternary composite, the synergy between the matrix, nanocrystals and nanotubes allowed the preparation of nanocomposites with superior properties to those found in the binary systems using low concentrations of the nanofiller, especially in the high molecular weight chitosan matrix.Universidade Federal de Minas GeraisQuitosanaNanocristais de celuloseNanocompósitosNanotubos de carbonoQuitosanaCeluloseFísico-químicaCompósitos poliméricosNanotubos de carbonoCristaisNanotecnologia Dispersão de nanotubos de carbono e nanocristais de celulose em diferentes quitosanas: estudo das suspensões e propriedades de nanocompósitos poliméricosinfo:eu-repo/semantics/publishedVersioninfo:eu-repo/semantics/masterThesisSandra Aparecida Alexandreinfo:eu-repo/semantics/openAccessporreponame:Repositório Institucional da UFMGinstname:Universidade Federal de Minas Gerais (UFMG)instacron:UFMGRodrigo Lassarote LavalFabiano Vargas PereiraRosana Zacarias DominguesNelcy Della Santina MohallemNo presente trabalho foram preparadas diferentes suspensões pela dispersão de nanotubos de carbono funcionalizados (MWCNT-COOH) e/ou nanocristais de celulose (NCC) em soluções ácidas de quitosana de baixa massa molar (Mv=3,3x104 g/mol e GA= 25%) e de alta massa molar (Mv= 3,7x105 g/mol e GA= 31%) e glicerol (10% (m/m)) com o emprego de ultrassom de ponta. As dispersões foram caracterizadas de forma a verificar qual a concentração de cada nanocarga seria possível dispersar nessas quitosanas sem a utilização de etapas posteriores de centrifugação. Foi verificado que concentrações de nanotubos da ordem de 2% (m/m) e de 0,5% (m/m) são efetivamente dispersas nessas matrizes (de baixa e alta massas molares, respectivamente) e que as mesmas permanecem estáveis mesmo após 3 meses ou mais de repouso, evidenciando a estabilização das cargas pela quitosana e a obtenção de dispersões termodinâmicas. A partir dessas suspensões, foram preparados nanocompósitos poliméricos binários (QUI/ MWCNT-COOH ou NCC) e ternários (QUI/MWCNT-COOH/NCC) por evaporação do solvente e transvasamento (casting). A adição de MWCNT-COOHs e NCCs influencia a estabilidade térmica das matrizes de quitosana (avaliada por termogravimetria), indicando possível interação entre as cargas e a matriz. Dados de espectroscopia vibracional na região do infravermelho dos filmes dos compósitos evidenciaram a interação carga/matriz o que foi corroborado pelas imagens de microscopias eletrônicas de varredura e transmissão. Essas imagens mostraram uma boa adesão das cargas à matriz polimérica como resultado da interação MWCNT-COOH/QUI e NCC/QUI e QUI/MWCNT-COOH/NCC. Além disso, outro indício dessa interação é que nas imagens (obtidas na superfície de fratura) não foram observadas regiões que indicassem que o nanotubo foi puxado para fora da matriz no momento da fratura, além de nanotubos curvados e entrelaçados na matriz polimérica, ligando "pontos" da superfície fraturada. Essa morfologia é essencial para a transferência de tensão entre nanotubo e matriz quando o material é sujeito a uma solicitação mecânica. De fato, os ensaios mecânicos mostraram que tanto os nanotubos (em menor escala) e os NCC são excelentes agentes de reforço para a quitosana. Foram verificados aumentos nas propriedades como módulo de elasticidade, resistência a tração, alongamento na ruptura e tenacidade. Além disso, nos compósitos ternários, a sinergia entre matriz, nanotubos e nanocristal permitiu o preparo de nanocompósitos com propriedades superiores às verificadas nos compósitos binários empregando baixas concentrações das nanocargas, especialmente na matriz de quitosana de alta massa molar.UFMGORIGINALdissert.sandra.pdfapplication/pdf10925449https://repositorio.ufmg.br//bitstreams/2c26711b-916a-4064-96c1-9610f25cfa86/download7e3b100fa840db48b1bee7e7b3a0713fMD51trueAnonymousREADTEXTdissert.sandra.pdf.txttext/plain211549https://repositorio.ufmg.br//bitstreams/41296f24-ae81-4c60-86b6-235cec63ed61/download6dfcf7cf7dfad20f72144e7521b2ebe7MD52falseAnonymousREAD1843/SFSA-9WHV3D2025-09-08 22:14:43.661open.accessoai:repositorio.ufmg.br:1843/SFSA-9WHV3Dhttps://repositorio.ufmg.br/Repositório InstitucionalPUBhttps://repositorio.ufmg.br/oairepositorio@ufmg.bropendoar:2025-09-09T01:14:43Repositório Institucional da UFMG - Universidade Federal de Minas Gerais (UFMG)false |
| dc.title.none.fl_str_mv |
Dispersão de nanotubos de carbono e nanocristais de celulose em diferentes quitosanas: estudo das suspensões e propriedades de nanocompósitos poliméricos |
| title |
Dispersão de nanotubos de carbono e nanocristais de celulose em diferentes quitosanas: estudo das suspensões e propriedades de nanocompósitos poliméricos |
| spellingShingle |
Dispersão de nanotubos de carbono e nanocristais de celulose em diferentes quitosanas: estudo das suspensões e propriedades de nanocompósitos poliméricos Sandra Aparecida Alexandre Quitosana Celulose Físico-química Compósitos poliméricos Nanotubos de carbono Cristais Nanotecnologia Quitosana Nanocristais de celulose Nanocompósitos Nanotubos de carbono |
| title_short |
Dispersão de nanotubos de carbono e nanocristais de celulose em diferentes quitosanas: estudo das suspensões e propriedades de nanocompósitos poliméricos |
| title_full |
Dispersão de nanotubos de carbono e nanocristais de celulose em diferentes quitosanas: estudo das suspensões e propriedades de nanocompósitos poliméricos |
| title_fullStr |
Dispersão de nanotubos de carbono e nanocristais de celulose em diferentes quitosanas: estudo das suspensões e propriedades de nanocompósitos poliméricos |
| title_full_unstemmed |
Dispersão de nanotubos de carbono e nanocristais de celulose em diferentes quitosanas: estudo das suspensões e propriedades de nanocompósitos poliméricos |
| title_sort |
Dispersão de nanotubos de carbono e nanocristais de celulose em diferentes quitosanas: estudo das suspensões e propriedades de nanocompósitos poliméricos |
| author |
Sandra Aparecida Alexandre |
| author_facet |
Sandra Aparecida Alexandre |
| author_role |
author |
| dc.contributor.author.fl_str_mv |
Sandra Aparecida Alexandre |
| dc.subject.por.fl_str_mv |
Quitosana Celulose Físico-química Compósitos poliméricos Nanotubos de carbono Cristais Nanotecnologia |
| topic |
Quitosana Celulose Físico-química Compósitos poliméricos Nanotubos de carbono Cristais Nanotecnologia Quitosana Nanocristais de celulose Nanocompósitos Nanotubos de carbono |
| dc.subject.other.none.fl_str_mv |
Quitosana Nanocristais de celulose Nanocompósitos Nanotubos de carbono |
| description |
In this study different suspensions were prepared by dispersing functionalized carbon nanotubes (MWCNT) and/or cellulose nanocrystals (NCC) in acidic solutions of low ( = 3,3x104 g/mol and = 25%) and high molar mass ( = 3,7x105 g/mol and = 31%) chitosans andglycerol (10% by weight) with the use of a tip ultrasound. The dispersions were characterized in order to find what concentration of each nanofiller would be possible to disperse with those chitosans without the use of further centrifugation steps. It was found that concentrations of NCC ofabout 10wt% and 1w% and nanotubes in the order of 2wt% and 0.5wt% were effectively dispersed in such matrices (high and low molecular weights, respectively) and the suspensions remain stableeven after 3 months or more (at rest), indicating the filler stabilization by the chitosan with the preparation of thermodynamic dispersions. From these suspensions, binary (CHI /MWCNT or NCC) and ternary (CHI/MWCNT/NCC) polymer nanocomposites were prepared by casting technique. The addition of MWCNTs and NCCs affects the thermal stability of the chitosan (as measured by thermogravimetry), indicating possible interaction between the filler and matrix. Infrared spectroscopy data of the composite films showed the interaction filler/chitosan, which was corroborated by the scanning and transmission electronic microscopies images. These images showed good adhesion of the fillers to the polymer matrix as a result of MWCNT/CHI, NCC/CHI and CHI/MWCNT/NCC interactions. Furthermore, another evidence of this interaction (obtained in the fracture images) is the fact that no nanotube was pulled out from the matrix with the fracture, as well the observation of curved nanotubes connecting "points"of the fractured surface. This morphology is essential to the transfer of tension between the fillers and matrix when the material is subjected to mechanical stress. In fact, the mechanical tests showed that both the nanotubes (in a smaller scale) and NCC are excellent reinforcement for chitosan. Increases were observed in properties such as modulus, tensile strength, elongation at break and toughness. Moreover, in the ternary composite, the synergy between the matrix, nanocrystals and nanotubes allowed the preparation of nanocomposites with superior properties to those found in the binary systems using low concentrations of the nanofiller, especially in the high molecular weight chitosan matrix. |
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2015 |
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2015-02-25 |
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2019-08-10T14:20:52Z 2025-09-09T01:14:43Z |
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2019-08-10T14:20:52Z |
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info:eu-repo/semantics/publishedVersion |
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Universidade Federal de Minas Gerais |
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Universidade Federal de Minas Gerais |
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