Estudo de encapsulação de nanopartículas magnéticas em nanoporos de alumina.
| Autor(a) principal: | |
|---|---|
| Data de Publicação: | 2010 |
| Tipo de documento: | Dissertação |
| Idioma: | por |
| Título da fonte: | Repositório Institucional da UFG |
| Texto Completo: | http://repositorio.bc.ufg.br/tede/handle/tde/805 |
Resumo: | In this work we investigated the encapsulation of magnetite nanoparticles into the nanopores of anodic alumina membranes using atomic force microscopy (AFM), vibrating sample magnetometer (VSM) and electron magnetic resonance (EMR). Three biocompatible magnetic fluids, with different nanoparticle diameters, stably dispersed in water at physiological conditions, were used. The nanoparticles were obtained through the coprecipitation method and characterized by X-ray diffraction, from which we obtained the nanoparticle size and confirmed the crystal structure. The Scherrer´s relation revealed a nanoparticle diameter of 10.1nm, 12.3nm and 13.8nm. The alumina membrane were prepared through anodization process. The nanopores were arranged on a hexagonal lattice with an alumina thickness of 4 μm, a distance between pores (center to center) of 105 nm, and samples containing nanopores with diameter of 35 nm or 80 nm. The method of encapsulation of nanoparticles consisted of depositing a drop of magnetic fluid into the surface of alumina. The fluid enters the nanopores through capillarity carrying the nanoparticles into it. AFM images prove that we had success in encapsulating nanoparticles only for the alumina samples with nanopores with a size of 80 nm. Magnetization data of the alumina sample containing nanoparticles with a diameter of 13.8nm encapsulated into nanopores of 80 nm, revealed an increase, with respect to the first procedure of encapsulation, of 48 % of the nanoparticles internalized into the nanopore after the second process of encapsulation. Further, different from all the samples investigated, EMR data for the alumina containing nanopores of 80 nm and nanoparticles of 13.8 nm, after the first procedure of encapsulation, had shown perpendicular magnetization with respect to the alumina surface. The EMR spetra were curve fitted using two Gaussian lines, one representing the nanoparticles with magnetization parallel to the surface and the other perpendicular. AFM images suggest, in our sample, that residues on the alumina surface are responsible for the parallel component. The magnetic resonance field data, for the perpendicular contribution, were analyzed taking into account in the energy density terms with uniaxial and cubic symmetry. The uniaxial energy contribution had a term due to magnetic dipolar interaction, between nanoparticles forming a linear chain, a magnetostatic term, due to the nanostructures self-organization, and also a magnetoelastic contribution, which came from the stress generated by the packing of nanoparticles, whose origin were related to the dipolar interaction between nanoparticles forming the linear chain. Indeed, the theoretical analysis allowed us to conclude that the mean size of the chain could vary from 4 to 9.5 nanoparticles. Finally, after heating the alumina, at 300°C for one hour, which contained nanoparticles with a size of 10.1 nm, and dissolving it in NaOH aqueous solution, AFM data were obtained. The AFM images confirmed the existence of nanowires. The diameter distribution, obtained from the AFM images, were curve fitted with a lognormal distribution revealing a modal diameter for the nanowires of 25,8 0, ± 4nm and diameter dispersity of 0,30 ± 0,02nm . |
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BAKUZIS, Andris Figueiroahttp://lattes.cnpq.br/3477269475651042http://lattes.cnpq.br/3534768558295783BRANQUINHO, Luis Cesar2014-07-29T15:07:08Z2011-05-062010-05-26http://repositorio.bc.ufg.br/tede/handle/tde/805In this work we investigated the encapsulation of magnetite nanoparticles into the nanopores of anodic alumina membranes using atomic force microscopy (AFM), vibrating sample magnetometer (VSM) and electron magnetic resonance (EMR). Three biocompatible magnetic fluids, with different nanoparticle diameters, stably dispersed in water at physiological conditions, were used. The nanoparticles were obtained through the coprecipitation method and characterized by X-ray diffraction, from which we obtained the nanoparticle size and confirmed the crystal structure. The Scherrer´s relation revealed a nanoparticle diameter of 10.1nm, 12.3nm and 13.8nm. The alumina membrane were prepared through anodization process. The nanopores were arranged on a hexagonal lattice with an alumina thickness of 4 μm, a distance between pores (center to center) of 105 nm, and samples containing nanopores with diameter of 35 nm or 80 nm. The method of encapsulation of nanoparticles consisted of depositing a drop of magnetic fluid into the surface of alumina. The fluid enters the nanopores through capillarity carrying the nanoparticles into it. AFM images prove that we had success in encapsulating nanoparticles only for the alumina samples with nanopores with a size of 80 nm. Magnetization data of the alumina sample containing nanoparticles with a diameter of 13.8nm encapsulated into nanopores of 80 nm, revealed an increase, with respect to the first procedure of encapsulation, of 48 % of the nanoparticles internalized into the nanopore after the second process of encapsulation. Further, different from all the samples investigated, EMR data for the alumina containing nanopores of 80 nm and nanoparticles of 13.8 nm, after the first procedure of encapsulation, had shown perpendicular magnetization with respect to the alumina surface. The EMR spetra were curve fitted using two Gaussian lines, one representing the nanoparticles with magnetization parallel to the surface and the other perpendicular. AFM images suggest, in our sample, that residues on the alumina surface are responsible for the parallel component. The magnetic resonance field data, for the perpendicular contribution, were analyzed taking into account in the energy density terms with uniaxial and cubic symmetry. The uniaxial energy contribution had a term due to magnetic dipolar interaction, between nanoparticles forming a linear chain, a magnetostatic term, due to the nanostructures self-organization, and also a magnetoelastic contribution, which came from the stress generated by the packing of nanoparticles, whose origin were related to the dipolar interaction between nanoparticles forming the linear chain. Indeed, the theoretical analysis allowed us to conclude that the mean size of the chain could vary from 4 to 9.5 nanoparticles. Finally, after heating the alumina, at 300°C for one hour, which contained nanoparticles with a size of 10.1 nm, and dissolving it in NaOH aqueous solution, AFM data were obtained. The AFM images confirmed the existence of nanowires. The diameter distribution, obtained from the AFM images, were curve fitted with a lognormal distribution revealing a modal diameter for the nanowires of 25,8 0, ± 4nm and diameter dispersity of 0,30 ± 0,02nm .Neste trabalho investigamos o encapsulamento de nanopartículas de magnetita (Fe3O4) em nanoporos de alumina anódica utilizando as técnicas de Microscopia de Força Atômica (AFM), Magnetometria de Amostra Vibrante (VSM) e Ressonância Magnética Eletrônica (RME). Utilizamos três fluidos magnéticos com nanopartículas de diâmetros diferentes dispersas em solução fisiológica. As nanopartículas foram sintetizadas pelo método da coprecipitação e foram caracterizadas por difração de raios-x, de onde confirmamos sua estrutura cristalina e obtivemos o diâmetro. A relação de Scherrer forneceu os seguintes diâmetros: DRX=10,1nm, DRX=12,3nm e DRX=13,8nm. As membranas de alumina foram preparadas pelo método da anodização de um filme de alumínio puro, gerando nanoporos em um arranjo hexagonal, sendo a espessura da alumina de 4μm com distância entre poros centro a centro de 105nm e amostras contendo diâmetros de nanoporos de 35nm ou 80nm. O método de encapsulamento das nanopartículas consistiu em depositar uma gota do fluido magnético sobre a alumina, que penetra nos nanoporos por capilaridade, carreando as nanopartículas. Imagens de AFM mostraram que obtivemos sucesso no encapsulamento das nanopartículas em alumina somente nas amostras com nanoporos de 80nm. Uma comparação entre as curvas de magnetização da amostra com nanopartículas de DRX=13,8nm em nanoporos de 80nm, encapsuladas uma vez e duas vezes, mostrou um acréscimo de 48% no número de nanopartículas encapsuladas do primeiro para o segundo processo de encapsulamento. Além disso, diferentemente de todas as outras amostras estudadas, os dados de RME para alumina com nanoporos de 80 nm e nanopartículas com diâmetro de 13,8 nm, após o primeiro processo de encapsulamento, apresentaram magnetização perpendicular ao plano da membrana de alumina. O espectro de RME foi ajustado por duas gaussianas, uma representando uma componente com magnetização paralela e outra perpendicular. Imagens de AFM sugerem, na nossa amostra, que resíduos na superfície são responsáveis pela componente paralela. A análise dos dados do campo de ressonância para a componente perpendicular foram ajustados considerando termos de simetria uniaxial e cúbica para a densidade de energia. Na contribução uniaxial foi explicitado o termo devido à interação dipolar magnética, entre nanopartículas formando uma cadeia linear, o termo magnetostático, devido à autoorganização das nanoestruturas, e um magnetoelástico, proveniente do stress gerado pelo empacotamento das nanopartículas, cuja origem foi atribuída à interação dipolar entre as nanoestruturas formando a cadeia. A análise teórica permitiu, ainda, concluir que o tamanho médio das cadeias lineares formadas no interior dos nanoporos corresponde a 6,0 nanopartículas, podendo variar entre 4 e 11. Essas cadeias podem existir não somente em nanoporos diferentes, mas também no interior de um mesmo nanoporo. Por fim, após aquecermos a membrana de alumina, a 300°C por 1 hora, que continha nanopartículas com DRX=10,1nm e a dissolvermos em uma solução aquosa de NaOH, obtivemos imagens de AFM dos nanofios. Uma distribuição de tamanho construída a partir das imagens e ajustada por uma lognormal nos forneceu um diâmetro modal para os nanofios de 25,8 0, ± 4nm e uma dispersidade de 0,30 ± 0,02nm.Made available in DSpace on 2014-07-29T15:07:08Z (GMT). No. of bitstreams: 0 Previous issue date: 2010-05-26porUniversidade Federal de GoiásMestrado em FísicaUFGBRCiências Exatas e da TerraNanopartículas magnéticasNanofiosAlumina anódicaRessonância ferromagnética.1. Nanopartículas magnéticas 2. Nanofios 3. Alumina anódica 4. Ressonância ferromagnéticaMagnetic nanoparticlesNanowiresAnodic aluminaFerromagnetic resonanceCNPQ::CIENCIAS EXATAS E DA TERRA::FISICA::FISICA DA MATERIA CONDENSADAEstudo de encapsulação de nanopartículas magnéticas em nanoporos de alumina.Encapsulation study of magnetic nanoparticles in alumina nanopores.info:eu-repo/semantics/publishedVersioninfo:eu-repo/semantics/masterThesisinfo:eu-repo/semantics/openAccessreponame:Repositório Institucional da UFGinstname:Universidade Federal de Goiás (UFG)instacron:UFGtde/8052014-07-29 12:07:08.165metadata.onlyoai:repositorio.bc.ufg.br:tde/805http://repositorio.bc.ufg.br/tedeRepositório InstitucionalPUBhttp://repositorio.bc.ufg.br/oai/requesttasesdissertacoes.bc@ufg.bropendoar:2014-07-29T15:07:08Repositório Institucional da UFG - Universidade Federal de Goiás (UFG)false |
| dc.title.por.fl_str_mv |
Estudo de encapsulação de nanopartículas magnéticas em nanoporos de alumina. |
| dc.title.alternative.eng.fl_str_mv |
Encapsulation study of magnetic nanoparticles in alumina nanopores. |
| title |
Estudo de encapsulação de nanopartículas magnéticas em nanoporos de alumina. |
| spellingShingle |
Estudo de encapsulação de nanopartículas magnéticas em nanoporos de alumina. BRANQUINHO, Luis Cesar Nanopartículas magnéticas Nanofios Alumina anódica Ressonância ferromagnética. 1. Nanopartículas magnéticas 2. Nanofios 3. Alumina anódica 4. Ressonância ferromagnética Magnetic nanoparticles Nanowires Anodic alumina Ferromagnetic resonance CNPQ::CIENCIAS EXATAS E DA TERRA::FISICA::FISICA DA MATERIA CONDENSADA |
| title_short |
Estudo de encapsulação de nanopartículas magnéticas em nanoporos de alumina. |
| title_full |
Estudo de encapsulação de nanopartículas magnéticas em nanoporos de alumina. |
| title_fullStr |
Estudo de encapsulação de nanopartículas magnéticas em nanoporos de alumina. |
| title_full_unstemmed |
Estudo de encapsulação de nanopartículas magnéticas em nanoporos de alumina. |
| title_sort |
Estudo de encapsulação de nanopartículas magnéticas em nanoporos de alumina. |
| author |
BRANQUINHO, Luis Cesar |
| author_facet |
BRANQUINHO, Luis Cesar |
| author_role |
author |
| dc.contributor.advisor1.fl_str_mv |
BAKUZIS, Andris Figueiroa |
| dc.contributor.advisor1Lattes.fl_str_mv |
http://lattes.cnpq.br/3477269475651042 |
| dc.contributor.authorLattes.fl_str_mv |
http://lattes.cnpq.br/3534768558295783 |
| dc.contributor.author.fl_str_mv |
BRANQUINHO, Luis Cesar |
| contributor_str_mv |
BAKUZIS, Andris Figueiroa |
| dc.subject.por.fl_str_mv |
Nanopartículas magnéticas Nanofios Alumina anódica Ressonância ferromagnética. 1. Nanopartículas magnéticas 2. Nanofios 3. Alumina anódica 4. Ressonância ferromagnética |
| topic |
Nanopartículas magnéticas Nanofios Alumina anódica Ressonância ferromagnética. 1. Nanopartículas magnéticas 2. Nanofios 3. Alumina anódica 4. Ressonância ferromagnética Magnetic nanoparticles Nanowires Anodic alumina Ferromagnetic resonance CNPQ::CIENCIAS EXATAS E DA TERRA::FISICA::FISICA DA MATERIA CONDENSADA |
| dc.subject.eng.fl_str_mv |
Magnetic nanoparticles Nanowires Anodic alumina Ferromagnetic resonance |
| dc.subject.cnpq.fl_str_mv |
CNPQ::CIENCIAS EXATAS E DA TERRA::FISICA::FISICA DA MATERIA CONDENSADA |
| description |
In this work we investigated the encapsulation of magnetite nanoparticles into the nanopores of anodic alumina membranes using atomic force microscopy (AFM), vibrating sample magnetometer (VSM) and electron magnetic resonance (EMR). Three biocompatible magnetic fluids, with different nanoparticle diameters, stably dispersed in water at physiological conditions, were used. The nanoparticles were obtained through the coprecipitation method and characterized by X-ray diffraction, from which we obtained the nanoparticle size and confirmed the crystal structure. The Scherrer´s relation revealed a nanoparticle diameter of 10.1nm, 12.3nm and 13.8nm. The alumina membrane were prepared through anodization process. The nanopores were arranged on a hexagonal lattice with an alumina thickness of 4 μm, a distance between pores (center to center) of 105 nm, and samples containing nanopores with diameter of 35 nm or 80 nm. The method of encapsulation of nanoparticles consisted of depositing a drop of magnetic fluid into the surface of alumina. The fluid enters the nanopores through capillarity carrying the nanoparticles into it. AFM images prove that we had success in encapsulating nanoparticles only for the alumina samples with nanopores with a size of 80 nm. Magnetization data of the alumina sample containing nanoparticles with a diameter of 13.8nm encapsulated into nanopores of 80 nm, revealed an increase, with respect to the first procedure of encapsulation, of 48 % of the nanoparticles internalized into the nanopore after the second process of encapsulation. Further, different from all the samples investigated, EMR data for the alumina containing nanopores of 80 nm and nanoparticles of 13.8 nm, after the first procedure of encapsulation, had shown perpendicular magnetization with respect to the alumina surface. The EMR spetra were curve fitted using two Gaussian lines, one representing the nanoparticles with magnetization parallel to the surface and the other perpendicular. AFM images suggest, in our sample, that residues on the alumina surface are responsible for the parallel component. The magnetic resonance field data, for the perpendicular contribution, were analyzed taking into account in the energy density terms with uniaxial and cubic symmetry. The uniaxial energy contribution had a term due to magnetic dipolar interaction, between nanoparticles forming a linear chain, a magnetostatic term, due to the nanostructures self-organization, and also a magnetoelastic contribution, which came from the stress generated by the packing of nanoparticles, whose origin were related to the dipolar interaction between nanoparticles forming the linear chain. Indeed, the theoretical analysis allowed us to conclude that the mean size of the chain could vary from 4 to 9.5 nanoparticles. Finally, after heating the alumina, at 300°C for one hour, which contained nanoparticles with a size of 10.1 nm, and dissolving it in NaOH aqueous solution, AFM data were obtained. The AFM images confirmed the existence of nanowires. The diameter distribution, obtained from the AFM images, were curve fitted with a lognormal distribution revealing a modal diameter for the nanowires of 25,8 0, ± 4nm and diameter dispersity of 0,30 ± 0,02nm . |
| publishDate |
2010 |
| dc.date.issued.fl_str_mv |
2010-05-26 |
| dc.date.available.fl_str_mv |
2011-05-06 |
| dc.date.accessioned.fl_str_mv |
2014-07-29T15:07:08Z |
| dc.type.status.fl_str_mv |
info:eu-repo/semantics/publishedVersion |
| dc.type.driver.fl_str_mv |
info:eu-repo/semantics/masterThesis |
| format |
masterThesis |
| status_str |
publishedVersion |
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http://repositorio.bc.ufg.br/tede/handle/tde/805 |
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http://repositorio.bc.ufg.br/tede/handle/tde/805 |
| dc.language.iso.fl_str_mv |
por |
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por |
| dc.rights.driver.fl_str_mv |
info:eu-repo/semantics/openAccess |
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openAccess |
| dc.publisher.none.fl_str_mv |
Universidade Federal de Goiás |
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Mestrado em Física |
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UFG |
| dc.publisher.country.fl_str_mv |
BR |
| dc.publisher.department.fl_str_mv |
Ciências Exatas e da Terra |
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Universidade Federal de Goiás |
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reponame:Repositório Institucional da UFG instname:Universidade Federal de Goiás (UFG) instacron:UFG |
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Universidade Federal de Goiás (UFG) |
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UFG |
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UFG |
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Repositório Institucional da UFG |
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Repositório Institucional da UFG |
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Repositório Institucional da UFG - Universidade Federal de Goiás (UFG) |
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tasesdissertacoes.bc@ufg.br |
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1798044326520946688 |