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| Registros recuperados : 44 | |
| 21. |  | SCATOLINO, M. V.; FONSECA, C. S.; GOMES, M. da S.; ROMPA, V. D.; MARTINS, M. A.; TONOLI, G. H. D.; MENDES, L. M. How the surface wettability and modulus of elasticity of the Amazonian paricá nanofibrils films are affected by the chemical changes of the natural fibers. European Journal of Wood and Wood Products, v. 76, n. 6, 2018. p. 1581-1594| Biblioteca(s): Embrapa Instrumentação. |
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| 22. | | FONSECA, A. S.; PANTHAPULAKKAL, S.; KONAR, S. K.; SAIN, M.; BUFALINOF, L.; RAABE, J.; MIRANDA, I. P. A.; MARTINS, M. A.; TONOLI, G. H. D. Improving cellulose nanofibrillation of non-woodfiber using alkaline andbleaching pre-treatments. Industrial Crops & Products, n. 131, 2019. 203-212| Biblioteca(s): Embrapa Instrumentação. |
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| 23. | | TONOLI, G. H. D.; TEIXEIRA, E. M.; CORRÊA, A. C.; MARCONCINI, J. M.; CAIXETA, L. A.; PEREIRA-DA-SILVA, M. A.; MATTOSO, L. H. C. Cellulose micro/nanofibres from Eucalyptus kraft pulp: preparation and properties. Carbohydrate Polymers, Barking, v. 89, p. 80-88, 2012.| Biblioteca(s): Embrapa Instrumentação. |
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| 24. | | SILVA, L. E.; CLARO, P. I. C.; SANFELICE, R. C.; GUIMARÃES JÚNIOR, M.; OLIVEIRA, J. E.; UGUCIONI, J. C.; CORREA, D. S.; TONOLI, G. H. D. Cellulose nanofibrils modification with polyaniline aiming at enhancing electrical properties for application in flexible electronics. Cellulose Chemistry and Technology, v. 53, n. 7-8, 2019. 775 - 786| Biblioteca(s): Embrapa Instrumentação. |
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| 25. | | MASCARENHAS, A. R. P.; MENDONÇA, M. C.; DIAS, M. C.; MARTINS, M. A.; MELO, R. R. de; DAMASIO, R. A. P.; TONOLI, G. H. D. Production of cellulose micro/nanofbrils with sodium silicate: impact on energy consumption, microstructure, crystallinity and stability of suspensions. Nordic Pulp & Paper Research Journal, v. 37, n. 4, 2022. 686-701| Biblioteca(s): Embrapa Instrumentação. |
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| 26. | | MESQUITA, R. G. A.; CÉSAR, A. A. S.; MENDES, R. F.; MENDES, L. M.; MARCONCINI, J. M.; GLENN, G.; TONOLI, G. H. D. Polyester composites reinforced with corona-treated fibers from pine, eucalyptus and sugarcane bagasse. In: Journal Polymers Environment, New York, n. 25, p. 800-811, 2017.| Biblioteca(s): Embrapa Instrumentação. |
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| 27. | | MASCARENHAS, A. R. P.; SCATOLINO, M. V.; DIAS, M. C.; MARTINS, M. A.; MELO, R. R. de; DAMÁSIO, R. A. P.; MENDONÇA, M. C.; TONOLI, G. H. D. Fibers pre-treatments with sodium silicate afect the properties of suspensions, flms, and quality index of cellulose micro/nanofbrils. Nordic Pulp & Paper Research Journal, v. 37, n. 3, 2022. 534-552| Biblioteca(s): Embrapa Instrumentação. |
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| 28. | | FONSECA, A. de S.; RAABE, J.; DIAS, L. M. S.; BALIZA, A. E. R.; TONOLI, G. H. D.; VASCONCELOS, R.; MARCONCINI, J. M. Avaliação preliminar do potencial de fibras amazônicas para extração de nanocristais de celulose. In: WORKSHOP DA REDE DE NANOTECNOLOGIA APLICADA AO AGRONEGÓCIO, 7.; ESCOLA DE NANOTECNOLOGIA, 3., 2013, São Carlos, SP. Anais... São Carlos, SP: Embrapa Instrumentação, 2013. p. 476-478 Editores: Maria Alice Martins, Odílio Benedito Garrido de Assis, Caue Ribeiro, Luiz Henrique Capparelli Mattoso. CD-ROM. Editores: Maria Alice Martins, Odílio Benedito Garrido de Assis, Caue Ribeiro, Luiz Henrique Capparelli Mattoso.| Biblioteca(s): Embrapa Instrumentação. |
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| 29. | | LEITE, E. R. da S.; PROTÁSIO, T. de P.; ROSADO, S. C. da S.; TRUGILHO, P. F.; TONOLI, G. H. D.; BUFALINO, L. Avaliação da qualidade da madeira de Coffea arabica L. como fonte de bioenergia. Cerne, Lavras, v. 20, n. 4, p. 541-549, 2014.| Biblioteca(s): Embrapa Florestas. |
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| 30. | | RAABE, J.; FONSECA, A. de S.; BUFALINO, L.; RIBEIRO, C.; MARTINS, M. A.; MARCONCINI, J. M.; MENDES, L. M.; TONOLI, G. H. D. Biocomposite of cassava starch reinforced with cellulose pulp fibers modified with deposition of silica (SiO2) nanoparticles. Journal of nanomaterials, [S. l.], v. 2015, p. 1-9, 2015.| Biblioteca(s): Embrapa Instrumentação. |
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| 31. | | GUIMARÃES, B. M. R.; SCATOLINO, M. V.; MARTINS, M. A.; FERREIRA, S. R.; MENDES, L. M.; LIMA, J. T.; GUIMARÃES JUNIOR, M.; TONOLI, G. H. D. Bio-based films/nanopapers from lignocellulosic wastes for production of added-value micro-/nanomaterials. Environmental Science and Pollution Research, v. 29, 2022. 8665-8683| Biblioteca(s): Embrapa Instrumentação. |
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| 32. | | SENA NETO, A. R.; ARAUJO, M. A. M.; BARBOZA, R. M. P.; FONSECA, A. S.; TONOLI, G. H. D.; SOUZA, F. V. D.; MATTOSO, L. H. C.; MARCONCINI, J. M. Comparative study of 12 pineapple leaf fiber varieties for use asmechanical reinforcement in polymer composites. Industrial Crops and Products, v. 64, p. 68-78, 2015.| Biblioteca(s): Embrapa Mandioca e Fruticultura. |
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| 33. | | SENA NETO, A. R.; ARAUJO, M. A. M.; BARBOZA, R. M. P.; FONSECA, A. S.; TONOLI, G. H. D.; SOUZA, F. V. D.; MATTOSO, L. H. C.; MARCONCINI, J. M. Comparative study of 12 pineapple leaf fiber varieties for use as mechanical reinforcement in polymer composites. Industrial Crops and Products, [S. l.], v. 64, p. 68-78, 2015.| Biblioteca(s): Embrapa Instrumentação. |
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| 34. | | DIAS, M. C.; ZIDANES, U. L.; MASCARENHAS, A. R. P.; SETTER, C.; SCATOLINO, M. V.; MARTINS, M. A.; MORI, F. A.; BELGACEM, M. N.; TONOLI, G. H. D.; FERREIRA, S. R. Mandacaru cactus as a source of nanofibrillated cellulose for nanopaper production. International Journal of Biological Macromolecules, v. 235, 123850, 2023. 1-11| Biblioteca(s): Embrapa Instrumentação. |
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| 35. | | FONSECA, A. S.; RAABE, J.; DIAS, L. M.; BALIZA, A. E. R.; COSTA, T. G.; SILVA, L. E.; VASCONCELOS, R. P.; MARCONCINI, J. M.; SAVASTANO JR, H.; MENDES, L. M.; YU, A.; ORTS, W. J.; TONOLI, G. H. D. Main characteristics of underexploited Amazonian palm fibers for using as potential reinforcing materials Waste and Biomass Valorization, v. 9, n. 53, 2018 18 p.| Biblioteca(s): Embrapa Instrumentação. |
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| 36. | | FERREIRA, L. F.; FIGUEIREDO, L. P.; MARTINS, M. A.; LUVIZARO, L. B.; bLARA, B. R. B.; OLIVEIRA, C. R.; GUIMARÃES JUNIOR, M.; TONOLI, G. H. D.; DIAS, M. V. Active coatings of thermoplastic starch and chitosan with alpha-tocopherol/bentonite for special green coffee beans. International Journal of Biological Macromolecules, v. 170, 2021. 810 - 819| Biblioteca(s): Embrapa Instrumentação. |
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| 37. | | SETTER, C.; MASCARENHAS, A. R. P.; DIAS, M. C.; MEIRA, A. C. F. O.; CARVALHO, N. T. S.; LOURENÇO, M. S.; MARTINS, M. A.; TONOLI, G. H. D.; OLIVEIRA, T. J. P. de. Surface modification of cellulosic nanofibrils by spray drying: Drying yield and microstructural, thermal and chemical characterization. Industrial Crops & Products, v. 201, 116899, 2023. 1 - 15| Biblioteca(s): Embrapa Instrumentação. |
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| 38. | | BUFALINO, L.; SENA NETO, A. R. de; TONOLI, G. H. D.; FONSECA, A. de S.; COSTA, T. G.; MARCONCINI, J. M.; COLODETTE, J. L.; LABORY, C. R. G.; MENDES, L. M. How the chemical nature of Brazilian hardwoods affects nanofibrillation of cellulose fibers and film optical quality. Cellulose, [S. l.], v. 22, p. 3657-3672, 2015.| Biblioteca(s): Embrapa Instrumentação. |
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| 39. | | SILVA, D. W.; SCATOLINO, M. V.; PEREIRA, T. G. T.; VILELA, A. P.; EUGENIO, T. M. C.; MARTINS, M. A.; MENDES, R. F.; BUFALINO, L.; TONOLI, G. H. D.; MENDES, L. M. Influence of thermal treatment of eucalyptus fibers on the physical-mechanical properties of extruded fiber-cement composites. Materials Today: Proceedings, v. 31, 2020. S348-S352| Biblioteca(s): Embrapa Instrumentação. |
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| 40. | | FERREIRA, L. F.; OLIVEIRA, A. C. S.; BEGALI, D. O.; SENA NETO, A. R.; MARTINS, M. A.; OLIVEIRA, J. E.; BORGES, S. V.; YOSHIDA, M. I.; TONOLI, G. H. D.; DIAS, M. V. Characterization of cassava starch/soy protein isolate blends obtained by extrusion and thermocompression. Industrial Crops & Products, v. 160, 113092, 2021. 1 - 11| Biblioteca(s): Embrapa Instrumentação. |
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| Registros recuperados : 44 | |
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 | Acesso ao texto completo restrito à biblioteca da Embrapa Mandioca e Fruticultura. Para informações adicionais entre em contato com cnpmf.biblioteca@embrapa.br. |
Registro Completo
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Biblioteca(s): |
Embrapa Mandioca e Fruticultura. |
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Data corrente: |
15/01/2015 |
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Data da última atualização: |
26/05/2023 |
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Tipo da produção científica: |
Artigo em Periódico Indexado |
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Circulação/Nível: |
A - 1 |
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Autoria: |
SENA NETO, A. R.; ARAUJO, M. A. M.; BARBOZA, R. M. P.; FONSECA, A. S.; TONOLI, G. H. D.; SOUZA, F. V. D.; MATTOSO, L. H. C.; MARCONCINI, J. M. |
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Afiliação: |
ALFREDO R. SENA NETO, UFSCar; MARCO A.M. ARAUJO, UFSCar; RAIZA M.P. BARBOZA, UFSCar; ALESSANDRA S. FONSECA, UFLA; GUSTAVO H.D. TONOLI, UFLA; FERNANDA VIDIGAL DUARTE SOUZA, CNPMF; LUIZ HENRIQUE CAPPARELLI MATTOSO, CNPDIA; JOSE MANOEL MARCONCINI, CNPDIA. |
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Título: |
Comparative study of 12 pineapple leaf fiber varieties for use asmechanical reinforcement in polymer composites. |
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Ano de publicação: |
2015 |
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Fonte/Imprenta: |
Industrial Crops and Products, v. 64, p. 68-78, 2015. |
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Idioma: |
Inglês |
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Conteúdo: |
Vegetable fiber reinforced polymer composites have enormous potential to replace materials originatedfrom non-renewable resources. For an adequate use of vegetable fibers as reinforcements, however, therelationships between technological properties and chemical, structural and morphological characteris-tics of the fibers must be fully understood. In this work, fibers from 12 different varieties of pineapple(Ananas genus) were characterized on their morphology, structure, chemical composition, mechanicaland thermal properties. The elastic modulus ranged from 37 to 86 GPa, the tensile strength from 629 to1309 MPa, and the onset oxidation temperature from 240 to 272ºC; indicating the potential of using allselected pineapple fibers as reinforcing fillers (depending on the polymer matrix and processing method).Direct correlations were observed between the thermo-mechanical properties of the fibers and theirchemical features, such as holocellulose and cellulose contents, and also the cellulose crystallinity index.The mechanical properties showed an inversely proportional relation with the lignin content and diam-eter of the fiber bundle. These correlations provided indexes for the direct selection and/or for a geneticimprovement program of the Ananas genus for the development of pineapples whose fibers may beadequate as mechanical reinforcement in polymer composite. An example of methodology is presented,aiming to help with materials selection within the group of vegetable fibers used in composites. MenosVegetable fiber reinforced polymer composites have enormous potential to replace materials originatedfrom non-renewable resources. For an adequate use of vegetable fibers as reinforcements, however, therelationships between technological properties and chemical, structural and morphological characteris-tics of the fibers must be fully understood. In this work, fibers from 12 different varieties of pineapple(Ananas genus) were characterized on their morphology, structure, chemical composition, mechanicaland thermal properties. The elastic modulus ranged from 37 to 86 GPa, the tensile strength from 629 to1309 MPa, and the onset oxidation temperature from 240 to 272ºC; indicating the potential of using allselected pineapple fibers as reinforcing fillers (depending on the polymer matrix and processing method).Direct correlations were observed between the thermo-mechanical properties of the fibers and theirchemical features, such as holocellulose and cellulose contents, and also the cellulose crystallinity index.The mechanical properties showed an inversely proportional relation with the lignin content and diam-eter of the fiber bundle. These correlations provided indexes for the direct selection and/or for a geneticimprovement program of the Ananas genus for the development of pineapples whose fibers may beadequate as mechanical reinforcement in polymer composite. An example of methodology is presented,aiming to help with materials selection within the group of vegetable fibers ... Mostrar Tudo |
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Thesaurus NAL: |
Pineapples. |
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Categoria do assunto: |
-- |
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Marc: |
LEADER 02192naa a2200217 a 4500
001 2005621
005 2023-05-26
008 2015 bl uuuu u00u1 u #d
100 1 $aSENA NETO, A. R.
245 $aComparative study of 12 pineapple leaf fiber varieties for use asmechanical reinforcement in polymer composites.$h[electronic resource]
260 $c2015
520 $aVegetable fiber reinforced polymer composites have enormous potential to replace materials originatedfrom non-renewable resources. For an adequate use of vegetable fibers as reinforcements, however, therelationships between technological properties and chemical, structural and morphological characteris-tics of the fibers must be fully understood. In this work, fibers from 12 different varieties of pineapple(Ananas genus) were characterized on their morphology, structure, chemical composition, mechanicaland thermal properties. The elastic modulus ranged from 37 to 86 GPa, the tensile strength from 629 to1309 MPa, and the onset oxidation temperature from 240 to 272ºC; indicating the potential of using allselected pineapple fibers as reinforcing fillers (depending on the polymer matrix and processing method).Direct correlations were observed between the thermo-mechanical properties of the fibers and theirchemical features, such as holocellulose and cellulose contents, and also the cellulose crystallinity index.The mechanical properties showed an inversely proportional relation with the lignin content and diam-eter of the fiber bundle. These correlations provided indexes for the direct selection and/or for a geneticimprovement program of the Ananas genus for the development of pineapples whose fibers may beadequate as mechanical reinforcement in polymer composite. An example of methodology is presented,aiming to help with materials selection within the group of vegetable fibers used in composites.
650 $aPineapples
700 1 $aARAUJO, M. A. M.
700 1 $aBARBOZA, R. M. P.
700 1 $aFONSECA, A. S.
700 1 $aTONOLI, G. H. D.
700 1 $aSOUZA, F. V. D.
700 1 $aMATTOSO, L. H. C.
700 1 $aMARCONCINI, J. M.
773 $tIndustrial Crops and Products$gv. 64, p. 68-78, 2015.
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