Studies on lignocellulosic fibers of Brazil. Part I: Source, production, morphology, properties and applications

Kozlowski R, Rawluk M, Barriga J. State of the art-production, processing and applications of fibrous plants. In: Sivam RL, Araújo RC, editors. 2nd international conference on textile engineering (SINTEX-2004) Proceedings, September 7–11; 2004, Natal, in CD-ROM, Paper No.TIP-1-007.

Satyanaryana, 2005, Studies on natural fibers of Brazil and green composites, Met Mater Proc, 17, 183

http://www.ibge.gov.br (accessed 20 March 2007).

http://www.worldbank.org/data/countrydata/aag/bra_aag.pdf (accessed February 2005).

First international conference on natural polymers and composites (ISNaPol-1996) lignocellulosics-plastics & composites, Eds. Leão A, Carvalho F. X. and Frollini E, DOP Publishers, Sao Paulo, Brasil, March 13–16; 1996 [Published in 1997].

Mattoso LHC, Leão A, Frollini E, editors. Second international symposium on natural polymers and composites (ISNaPol 1998), Atibaia, Brasil, May 10–13; 1998.

Mattoso LHC, Leão A, Frollini E, editors. Third international symposium on natural polymers and composites (ISNaPol 2000), Atibaia, Brasil, May 14–17; 2000.

Mattoso LHC, Leão A, Frollini E, editors. Fourth international symposium on “natural polymers and composites (ISNaPol 2002), São Pedro, Brasil, September 1–4; 2002.

Mei LHI, Mattoso LHC, Curvelo AAS, editors. Fifth international symposium on natural polymers and composites (ISNaPol 2004), São Pedro, Brasil, September 12–15; 2004.

Kandachar PV. Overview and advances on science, technology and application of composite materials based on natural resources. In: Materials design and production processes for low cost housing conference, 25–29 November, Bangalore (India), organized by UNIDO, ICS (Italy), ICAMT and BMTPC (India); 2002 [without page number].

Netravali, 2003, Composites get greener, Mater Today, 6, 22, 10.1016/S1369-7021(03)00427-9

Nickel, 2003, Activities in biocomposites, Mater Today, 6, 44, 10.1016/S1369-7021(03)00430-9

Marsh, 2003, Next step for automotive materials, Mater Today, 6, 36, 10.1016/S1369-7021(03)00429-2

Satyanarayana KG, Arizaga GGC, Wypych F. Ecofriendly composites – a new vista for textile engineers. In: International conference SINTEX-2004, in CD-ROM, Paper No.TIC-E-001.pdf.

Satyanarayana KG, Wypych F, Ramos LP, Amico CS, Sydenstricker THD. Perspectives for plant fibers and natural polymers of Brazil through composite technology. In: International conference ISNaPol 2004, September 12–15, Sao Pedro, SP, Brasil; 2004 [Paper No.90].

Bledzki, 1999, Composites reinforced with cellulose based fibers, Prog Polym Sci, 221, 10.1016/S0079-6700(98)00018-5

Wambua, 2003, Natural fibers: can they replace glass in fiber-reinforced plastics?, Compos Sci Technol, 63, 1259, 10.1016/S0266-3538(03)00096-4

Joshi, 2004, Are natural fiber composites environmentally superior to glass fiber reinforced composites?, Composites A, 35, 371, 10.1016/j.compositesa.2003.09.016

Suddell BC, Evans WJ, Isaac DH, Crosky A. A survey into the application of natural fiber composites in the automotive industry. In: Conference (ISNaPol 2002). p. 455–60.

Kedari, 2003, New insulating particle boards from durial peel and coconut coir, Build Environ, 38, 435, 10.1016/S0360-1323(02)00030-6

Demir, 2006, Effect of surface treatments on the tensile and water sorption properties of polypropylene-Luff cylindrica composites, Composites A, 37, 447, 10.1016/j.compositesa.2005.05.036

Peijis, 2003, Composites for recyclability, Mater Today, 6, 30, 10.1016/S1369-7021(03)00428-0

Rajesh A, Kozlowski R, editors. Proceedings of international conference on textiles for sustainable developments. FAO/ESCORENA, Port Elizabeth, South Africa, 23–27 October; 2005. p. 1–632 [in CD].

IGBE – Produção agrícola municipal e levantamento sistemático da produção agrícola (accessed 20 March 2007).

Homma AKO.O Desenvolvimento da agroindústria no estado do Pará, http://www.captu.embrapa.br/pup_outros/rev20011213_08.pdf (accessed February 2005).

http://www.cpatu.embrapa.br/online/Circ.tec.27.pdf (accessed February 2005).

Nolasco AM, Soffner MLAP, Nolasco AC. Physical-mechanical characterization of banana fiber, Musa cavendish – nanicão variety. In: 2nd International symposium on natural polymers and composites in international conference ISNaPol; 1998. p. 191–93.

Satyanarayana, 1981, Potential of natural fibres as a resource for industrial material in Kerala, J Sci Ind Res, 40, 222

Kulkarni, 1983, Mechanical properties of banana fibers, J Mater Sci, 18, 2290, 10.1007/BF00541832

Ferreira LC, Trindade WG, Frollini E, Kawano Y. Raman and infrared spectra of natural fibers. In: Mattoso LHC, Leão A, Frollini E, editors. Conference ISNaPol 2004, São Pedro, Brasil, 12–15 September; 2004. p. 269–71.

Rosa MF. Sustainable development by recycling coconut husks. In: Development marketplace 2003, Washington. Summary of Finalist Proposals; 2003. p. 23.

Filho NOL, Ladchumananandasivam R, Veríssimo SA, Medeiros JI. The importance of cotton fibre in the Brazilian market and its perspectives. In: Conference SINTEX II, September 2004-Paper No.TTN-A-015.pdf.

Homma AKO, A civilização da junta na Amazônia: expansão e declínio. Amazônia: meio ambiente e desenvolvimento agrícola. Brasília: EMBRAPA/SPI; 1998. p. 13–67.

Alexandre MEO, Ladchumananandasivam R, Veríssimo SA, Menezes PL, Batista JH, Araújo RC. Pine apple leaf fiber (PALF) as an economic resource for the state of Rio Grande do Norte and to Brazil. In: International conference SINTEX-2004 proceedings – in CD-ROM, Paper No.TTN-H-001.pdf.

Alexandre MEO, Ladchumananandasivam R, Veríssimo SA, Menezes PL, Batista JH, Araújo RC. Thermal analysis of the pineapple leaf fiber. In: International conference SINTEX-2004 proceedings – in CD-ROM, Paper Nos.TTN-A-008.pdf.

Ladchumananandasivam R, Alexandre MEO, Carvalho LH, Cavalcanti WS, Tavares MM. Tensile properties of composites made of pineapple leaf fibre (Palf) and polyester. In: SriBandopdhyay, Zeng Q, Berndt CC, Rizkalla S, Gowripalan N, Matisons J, editors. International conference on developments in composites: advanced, infrastructural, natural and nano-composites (ACUN-5), 10–14 July, UNSW, Sydney, Australia. p. 494–500.

Martins MA, Joekes I, Ferriera FC, Job AE, Mattoso LHC. Thermal behaviour of raw and chemically treated sisal fibers. In: International conference ISNaPol; 2004. p. 13–15.

Mattoso LHC, Ferreira CF, Curvelo AAS. Sisal fiber: Morphology and applications in polymer composite. In: International conference ISNaPol; 1996. p. 241–66.

Oksman K, Wallstrom L, Berglund L, Filho RDT. Mechanical properties and morphology of sisal fiber-epoxy composites. In: International conference ISNaPol; 2000. p. 355–61.

Satyanarayana KG. Agrobased fibers of Brazil and their composites – An overview’. In: International conference on textiles for sustainable developments. FAO/ ESCORENA, Port Elizabeth, South Africa, 23–27 October; 2005. p. 312–24 [in CD].

http://www.revistaagroamazonia.com.br/13-fibras.htm (accessed February 2005).

Toro Ind. e Com. Ltd., Natural fibers, Internal Publication, 1994.

Caraschi JC, Leão AL, Characterization of curaua fiber. Mol Cryst & Liq Cryst: 2000;353:149–152; Mechanical properties of curauá fibers. In: Conference ISNaPol; 2000. p. 450–53.

Leão AL, Rowell RM, Tavares N. Applications of natural fibers in the Brazilian Automotive industry – Thermoforming and injection moulding processes. In: 4th international conference on wood fiber-plastic composites conference proceeding; 1997. Forest Product Society, Madison (WI). p. 20.

Leão AL, Tan IH, Caraschi JC. Curaua fiber – A tropical natural fiber from Amazons-potentials and applications in composites. In: Yasser Gowayed, Faissal Abdel, editors. Haydy international conference on advanced composites (ICAC98) proceedings, Hurghada, Egypt, 15–18 December; 1998. p. 557–64; Frollini E, Leão AL, Mattoso LHC, editors. Natural polymers and agro fibers based composites, São Carlos; 2000. p. 257–71.

Leão, 1998, Applications of natural fibers in automotive industry in Brazil, 755

Giacomini NP, Leão AL, Neis AM. Unsaturated polyester based composites reinforced with curauá fibers-preliminary studies. In: Conference ISNaPol; 2000. p. 386–92.

Trindade, 2004, Phenolic thermoset matrix reinforced with sugar cane bagasse fibers: attempt to develop a new fiber surface chemical modification involving formation of quinines followed by reaction with furfuryl alcohol, Macromolec Mater Eng, 289, 728, 10.1002/mame.200300320

Trindade WG, Hoareau W, Razera IAT, Ruggeiro R, Frollini E, Castelan A. Chemically modified sugarcane bagasse and curaúa fibers as reinforcement of phenolic matrices. In: ISNaPol; 2004. p. 249–52.

Horeau, 2004, Sugarcane bagasse and curauá lignins oxidised and reacted with furfuryl alcohol: Characterization and stability, Polym Degrad Stability, 86, 567, 10.1016/j.polymdegradstab.2004.07.005

Passos C. Comércio do curauá isento do ICMS. Gazeta Mercantil Pará, Belém, 25 July 2000a. p. 1 [in Portuguese].

http://www.cnpa.embrapa.br/produtos/sisal/colheita.html (accessed February 2005).

http://www.conab.gov.br/download/cas/semanais/Semana07a11022005/Juta%20-2007a11-02-05.pdf (accessed February 2005).

http://globoruraltv.globo.com/cgi-in/globorural/montar_texto.pl?controle=9042 (accessed February 2005).

http://www.ceplac.gov.br/radar/piacava.htm (accessed February 2005).

Aquino RCMP, Monteiro SN, Almeida JRM. Tensile mechanical properties and morphological aspects of piassava (Attalea funifera) fibers. In: International conference ISNaPol; 2004. p. 144–147 and 272–74.

Aquino, 2001, Flexural mechanical properties of piassava fibers (Attalea funifera) – resin matrix composites, J Mater Sci Lett, 20, 1017, 10.1023/A:1010904306820

Aquino, 2003, Evaluation of the critical fiber length of piassava fibers (Attalea funifera), J Mater Sci, 21, 1495

Satyanarayana, 1986, Structure and properties of some vegetable fibers – Part3: Talipot and plamyrah fibers, J Mater Sci, 21, 57, 10.1007/BF01144699

http://personales.ciudad.com.ar/ecoespon/portugues/principal.html (accessed February 2005).

Boynard, 2000, Morphological characterization and mechanical behaviour of sponge gourd (Luffa cylindrica) – polyester composite materials, Polym Plast Technol Eng, 39, 489, 10.1081/PPT-100100042

Boynard, 2003, Aspects of alkali treatment of sponge gourd (Luffa cylindrica) – polyester matrix composite, J Appl Polym Sci, 87, 1927, 10.1002/app.11522

Boynard, 1999, Water absorption by sponge gourd (Luffa cylindrica) – polyester composite materials, J Mater Sci Lett, 18, 1789, 10.1023/A:1006643630959

Tanobe VOA, Mochnacz S, Mazzaro I, Syndenstricker THD, Amico SC. Characterization of biocomposites of polyester reinforced with Luffa cylindrica or sisal. In: 58th Congresso Anual da Associação Brasileira de Metalurgia e Materiais – ABM, Rio de Janeiro – RJ; 2003. p. 1670–680 [in Portuguese].

Tanobe VOA, Sydenstricker THD, Amico SC, Souza GP. Fabrication and characterization of Luffa cylindrica fiber reinforced polymer composites. In: XV Brazilian chemical engineers congress (COBEQ), Curitiba-PR; 2004. p. 1–8 [in Portuguese].

Tanobe, 2005, A comprehensive chemically treated Brazilian sponge gourds (Luffa cylindrica), Polym Testing, 24, 474, 10.1016/j.polymertesting.2004.12.004

Almeida JMR, Boynard CA, Monteiro SN. Effect of chemical treatments on the surface morphology of sponge gourd (Luffa cylindrica) fibers. In: Conference ISNaPol; 2000. p. 27–31.

Filho, 2004, Biomass resources for energy in North-Eastern Brazil, Appl Energy, 77, 51, 10.1016/S0306-2619(03)00095-3

Sartori, 2001, Determination of optimum quantity of crop residues for energy in sugarcane crop using linear programming in variety selection and planning strategy, Energy, 26, 1031, 10.1016/S0360-5442(01)00052-4

Brazilian Institute of Geography and Statistics. Index of pub/Produção_Agrícola/Fascículo_indicadores_ IBGE.www2.ibge.gov.br/pub/Produção_Agrícola/Fascículo_indicadores_IBGE/File:01_2001.zip;2002 [in Portuguese] [Accessed 7 April 2005].

Costa HM, Visconte LY, Nunes RR, Furtado CR. Rice husk ash – a new resource of silica for natural rubber compounds. In: International symposium ISNaPol; 2000. p. 37–42.

Satyanaryana, 2004, Development of new materials based on agro and industrial wastes towards ecofriendly society, vol. II, 583

Tomczak F, Satyanarayana KG, Sydenstricker THD. Studies on lignocellulosic fibers of Brazil – part II: morphology and properties of coconut fibers. Compos Sci Technol [in press].

Tomczak F, Satyanarayana KG, Sydenstricker THD. Studies on lignocellulosic fibers of Brazil – part iii: morphology and properties of curauá fibers. Compos Sci Technol [submitted].

Guimarães JL, Satyanarayana KG, Wypych F. Availability, production, marketing and potential applications of natural fibers of Brazil. In: International conference FAO/ESCORENA; 2005. p. 503–16 [in CD].

Razera IAT, Trindade WG, Leão AL, Frollini E. Jute and curaúa fibers as reinforcements in phenolic and lignophenolic matrix composites. In: International Conference ISNaPol; 2002. p. 507–14.

Razera IAT, Frollini, E. Use of coir fiber as reinforcing material for phenolic and lignophenolic matrix comosites. In: International Conference ISNaPol; 2004. p. 253–56.

Wieldman GA, Costa CZ, Nahuz MA. Coir based fiberboard for moulded components. In: International conference ISNaPol; 2000, p. 488–92.

Carvalho LH, Ladchumananandasivam R, Alexandre MEO, Cavalcanti WS. Mechanical properties of pineapple leaf fiber reinforced unsaturated polyester composites. In: International conference ISNAPol; 2004. p. 176–78.

Amico SC, Costa THS, Carrera LC, Santana W, Galvão D. Characterization of sisal fibers of north east region of Brazil. In: 16th Brazilian mechanical engineering congress (cobem), Uberlandia, vol. 2, 2001. p. 33–41 [in Portuguese].

Amico SC, Monachnacz S, Syndenstricker THD. Improved properties of treated sisal fibers for use in composites, plastico industrial; 2004. p. 72–81 [in Portuguese].

Sydenstricker, 2003, Pull-out and other evaluations in sasal reinforced polyester composites, Polym Testing, 22, 375, 10.1016/S0142-9418(02)00116-2

Sydenstricker THD, Monachnacz S, Tanobe VOA, Amico SC. Characterization of polyester/luffa cilíndrica and sisal biocomposites. In: 58th annual congress of association of metallurgy and materials of Brasil (ABM), Rio de Janeiro; 2003. p. 1671–679 [in Portuguese].

Ghavami, 1999, Behaviour of composite soil reinforced with natural fibers, Cement & Concrete Compos, 21, 39, 10.1016/S0958-9465(98)00033-X

Toledo, 2000, Durability of alkali sensitive sisal and coconut fibers in cement based composites, Cement & Concrete Compos, 6, 127, 10.1016/S0958-9465(99)00039-6

Toledo, 2003, Development of vegetable fiber–mortar composites of improved durability, Cement & Concrete Compos, 25, 1

Almeida ALFS, Barreto DW, Calado V, Almeida JRM. Chemical surface modification on piassava fibers (Attalea funifera). In: Conference ISNPol; 2004. p. 22–24.

Ferreira LC, Trindade WG, Frollini E, Kawano Y. Raman and infrared spectra of natural fibers. In: International Conference ISNaPol; 2004. p. 269–71.

Mothé, 2004, Thermal and mechanical charaterization of polyurethane composites with curauá fibers, Polímeros – Ciência e Tecnologia, 14, 274, 10.1590/S0104-14282004000400014

Medeiros ES, Agnelli JAM, Joseph K, Carvalho LH, Mattoso LHC. Mechanical properties of phenolic composites reinforced with hybrid fabrics. In: International conference ISNaPol; 2002. p. 515–22.

Silva, 2000, Mechanical and thermal characterization of native Brazilian coir fiber, J Appl Polym Sci, 76, 1197, 10.1002/(SICI)1097-4628(20000516)76:7<1197::AID-APP23>3.0.CO;2-G

Almedia, 2006, Tensile mechanical properties, morphological aspects and chemical characterization of piassava (Attalea funifera) fibers, Composites A, 37, 1473, 10.1016/j.compositesa.2005.03.035

2004

Amico, 2005, Evaluation of the influence of chemical treatment on the tensile strength of sisal fibres by a Weibull distribution analysis, Met Mater Proc, 17, 233

Amico SC, Costa THS, Silva PS. Tensile strength of sisal fibers I: the Weibull distribution. In: 11th international molecular colloquium and 6th Brazil polymers congress, Gramado; 2001. p. 1537–40.

Amico SC, Costa THS, Monachnacz S. Tensile strength of sisal fibers II: influence of chemical treatment from the point of view of a Weibull distribution. In: 11th international molecular colloquium and 6th Brazil polymers congress, Gramado; 2001. p. 1541–44.

Martins MA, Joenkes I. A preliminary study on the use of sisal fibers as reinforcement for tire rubber. In: International conference ISNaPol; 2000. p. 437–40.

Frollini E, Leão A, Mattoso LHC. Natural polymers and agrofibers composites. USP/UNESP and Embrapa, São Carlos, Brasil; 2000.

Satyanarayana, 1986, Material science of lignocellulosic fibres, Metallography, 19, 389, 10.1016/0026-0800(86)90073-X

Hon, 1992, Chemical modification of lignocellulosic materials: old chemistry, new approaches, Polym News, 17, 102

Hon, 1988, Cellulose: a wonder material with promising future, Polym News, 13, 34

Rowell RM, Han JS, Rowell JS. Characterization and factors affecting fiber properties. In: Frollini E, Leão A, Mattoso LHC, editors. Natural polymers and agrofibers composites. USP/UNESP and Embrapa, Sao Carlos, Brasil; 2000. p. 115–34.

Sukumaran, 2001, Structure, physical and mechanical properties of plant fibers of Kerala, Met Mater Proc, 13, 21

Mukherjee, 1986, An empirical evaluation of structure and properties relationships in natural fibers and their fracture behavior, J Mater Sci, 21, 4162, 10.1007/BF01106524

Hatakeyama, 1982, Studies on heat capacity of cellulose and lignin by differential scanning calorimetry, Polymer, 23, 1801, 10.1016/0032-3861(82)90125-2

Satyanarayana, 2007, Characterization of natural fibers

Cao, 2006, Mechanical properties of biodegradable composites reinforced with bagasse fiber before and after alkali treatments, Composites A, 37, 423, 10.1016/j.compositesa.2005.05.045

Satyanarayana KG, Tomczak F, Sydenstricker THD. Natural fiber based hybrid composites – an overview. In: SriBandopdhyay, Zeng Q, Berndt CC, Rizkalla S, Gowripalan N, Matisons J, editors. International conference ACUN-5, 10–14 July, UNSW, Sydney, Australia; 2006. p. 438–451.

http://www.ibge.gov.br/home/estatistica/economia/pam/tabela1pam_2001.shtm.

http://www.poematec.com.br.

Salzar VLP, Leão AL. Life cycle assessment of automobile seats based on coconut and latex. In: Conference ISNaPol; 2000. p. 484–7.

Annunciado TR. Studies on Chorisia speciosa and other vegetable fibers as absorbents for petroleum sector. M.S. Thesis. Federal University of Paraná, Curitiba (Brasil); 2004.

Wiggers D, Annunciado TR, Amico SC, Sydenstricer THD. Vegetable fibers used as sorbent materials in the petroleum sector. In: IV Encontro dos Programas de Recursos Humanos em Petróleo e Gás Natural do Paraná – IVRAA, Curitiba – PR. 29 September 2004 [in Portuguese].

Paiva, 1999, Thermophenolic matrix reinforced with vegetable fiber composites, Polímeros: Ciência e tecnologia, 9, 170, 10.1590/S0104-14281999000400028

Paiva, 1992, Thermoset matrix-sugarcane bagasse reinforced composite, Polímeros – Ciência e tecnologia, 2, 78

Frollini, 2004, Lignophenolic and phenolic resins as matrix in vegetal fibers reinforced composites, 193

Paiva, 2002, Sugarcane bagasse reinforced phenolic and lignophenolic composites, J Appl Polym Sci, 83, 880, 10.1002/app.10085

Monteiro, 1998, Sugar cane bagasse waste as reinforcement in low cost composites, Adv Perform Mater, 5, 183, 10.1023/A:1008678314233

Steal, 2001, Impact behavior of sugar cane bagasse waste – EVA composites, Polym Testing, 20, 869, 10.1016/S0142-9418(01)00014-9

Zarate, 2000, Resol vegetable fibers composites, J Appl Polym Sci, 7, 1832, 10.1002/1097-4628(20000822)77:8<1832::AID-APP21>3.0.CO;2-U

Savastano Jr. H, Joacquim AP, Warden PG, Coutts RSP. Sisal waste chemi-thermomechanical pulping for use in fiber-cement composites. In: International conference ISNaPol; 2004. p. 208–10.

Duntas RR, Carvalho LH, Nascimento JWB. Effect of aging in cement on the tensile and impact properties of polyester-jute composites. In: International conference ISNaPol; 2004. p. 173–5.

Toledo RDF, Ghavami K. Behaviour under indirect tension of vegetable fiber reinforced mortar composites. In: International conference ISNaPol; 2000. p. 399–407.

Toledo RDF, Ghavami K, Lima PRL. Flexural toughness of sisal and coconut fiber reinforced cement mortar composites. In: International Conference ISNaPol 2002. p. 465–72.

Silva FA, Ghavami K, Almeida JRM. Strain rate behaviour of fiber reinforced cement composite materials. In: International Conference ISNaPol 2004. p. 205–07.

Satyanarayana, 1990, vol. I, 339

Holberg, 2006, Natural fiber reinforced polymer composites in automotive applications, JOM, 58, 80, 10.1007/s11837-006-0234-2