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2020 | OriginalPaper | Buchkapitel

Physicochemical Properties of Nanocellulose Extracted from Pineapple Leaf Fibres and Its Composites

verfasst von : Ismail Muhamad Fareez, Nazmul Haque, Der Juin Ooi, Ainil Hawa Jasni, Fauziah Abd Aziz

Erschienen in: Pineapple Leaf Fibers

Verlag: Springer Singapore

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Abstract

Significant advancement on cellulose-based biomaterial research has also led to the development of nano-sized pineapple leaf cellulose fibres with wide application potentials. The present chapter presents the comprehensive review of cellulose fibre structure extracted from different pineapple varieties, covering some aspects related to the structure of this natural cellulose in terms of its morphology, chemical, physical and mechanical properties. This chapter also briefly introduces the fundamentals of nanocellulose and discussed the isolation and properties of pineapple leaf cellulose nanofibrils, nanofibrillated cellulose and cellulose nanocrystals in view to open further areas of composite study on the ideal selection of these nanomaterials for industrial use.

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Vorheriges Kapitel Green Acoustic Absorber from Pineapple Leaf Fibers

Nächstes Kapitel Cellulose Nanostructures Extracted from Pineapple Fibres

Madhu P, Sanjay M, Senthamaraikannan P, Pradeep S, Saravanakumar S, Yogesha B (2018) A review on synthesis and characterization of commercially available natural fibers: part-I. J Nat Fiber 1–13

Mohammed L, Ansari MN, Pua G, Jawaid M, Islam MS (2015) A review on natural fiber reinforced polymer composite and its applications. Int J Polym Sci

Sanyang M, Sapuan S, Jawaid M, Ishak M, Sahari J (2016) Recent developments in sugar palm (Arenga pinnata) based biocomposites and their potential industrial applications: a review. Renew Sustain Energy Rev 54:533–549CrossRef

Trache D, Hussin MH, Haafiz MM, Thakur VK (2017) Recent progress in cellulose nanocrystals: sources and production. Nanoscale 9(5):1763–1786CrossRef

Khakalo A, Vishtal A, Retulainen E, Filpponen I, Rojas OJ (2017) Mechanically-induced dimensional extensibility of fibers towards tough fiber networks. Cellulose 24(1):191–205CrossRef

Satyanarayana K, Pillai C, Sukumaran K, Pillai S, Rohatgi P, Vijayan K (1982) Structure property studies of fibres from various parts of the coconut tree. J Mater Sci 17(8):2453–2462CrossRef

Cherian BM, Leão AL, de Souza SF, Thomas S, Pothan LA, Kottaisamy M (2010) Isolation of nanocellulose from pineapple leaf fibres by steam explosion. Carbohydr Polym 81(3):720–725CrossRef

Fareez IM, Ibrahim NA, Yaacob WMHW, Razali NAM, Jasni AH, Aziz FA (2018) Characteristics of cellulose extracted from Josapine pineapple leaf fibre after alkali treatment followed by extensive bleaching. Cellulose 25(8):4407–4421CrossRef

Fernández G, Pomilio AB (2003) Optimized growth conditions and determination of the catalytic type of the peptidase complex from a novel callus culture of pineapple (Ananas comosus). Mol Med Chem 1:39–49

10.

Chan Y, Coppens DEG, Sanewski GM (2002) Breeding and variety improvement. In: Bartholomew DP, Paull RE, Rohrbach KG (eds) The pineapple, botany, production and uses. CABI Publishing, New York, pp 33–35

11.

Deepa B, Abraham E, Cordeiro N, Mozetic M, Mathew AP, Oksman K, Faria M, Thomas S, Pothan LA (2015) Utilization of various lignocellulosic biomass for the production of nanocellulose: a comparative study. Cellulose 22(2):1075–1090CrossRef

12.

Klemm D, Kramer F, Moritz S, Lindström T, Ankerfors M, Gray D, Dorris A (2011) Nanocelluloses: a new family of nature-based materials. Angew Chem Int Ed 50(24):5438–5466CrossRef

13.

Jose S, Salim R, Ammayappan L (2016) An overview on production, properties, and value addition of pineapple leaf fibers (PALF). J Nat Fiber 13(3):362–373CrossRef

14.

Neto ARS, Araujo MA, Barboza RM, Fonseca AS, Tonoli GH, Souza FV, Mattoso LH, Marconcini JM (2015) Comparative study of 12 pineapple leaf fiber varieties for use as mechanical reinforcement in polymer composites. Ind Crop Prod 64:68–78CrossRef

15.

Verma D, Gope P, Shandilya A, Gupta A, Maheshwari M (2013) Coir fibre reinforcement and application in polymer composites. A Environ Sci 4(2):263–276

16.

Siregar J, Sapuan S, Rahman M, Zaman H (2008) Characterization and chemical composition of short pineapple leaf fibres (PALF). In: Proceeding of postgraduate seminar on natural fibre composites. Faculty of Engineering, Universiti Putra Malaysia, Serdang, Selangor

17.

Khalil HSA, Alwani MS, Omar AKM (2007) Chemical composition, anatomy, lignin distribution, and cell wall structure of Malaysian plant waste fibers. BioResources 1(2):220–232

18.

Idicula M, Boudenne A, Umadevi L, Ibos L, Candau Y, Thomas A (2006) Thermophysical properties of natural fibre reinforced polyester composites. Compos Sci Technol 66(15):2719–2725

19.

Wan Nadirah WO, Jawaid M, Al Masri AA, Abdul Khalil HPS, Suhaily SS, Mohamed AR (2012) Cell Wall Morphology, Chemical and Thermal Analysis of Cultivated Pineapple Leaf Fibres for Industrial Applications. J Polym Env 20 (2):404–411

20.

Santos RMD, Flauzino Neto WP, Silvério HA, Martins DF, Dantas NO, Pasquini D (2013) Cellulose nanocrystals from pineapple leaf, a new approach for the reuse of this agro-waste. Ind Crop Prod 50:707–714CrossRef

21.

Banik S, Nag D, Debnath S (2011) Utilization of pineapple leaf agro-waste for extraction of fibre and the residual biomass for vermicomposting. In: Proceeding Paper, Semantic Scholars

22.

Daud Z, Mohd Hatta MZ, Mohd Kassim AS, Awang H, Mohd Aripin A (2013) Exploring of agro waste (pineapple leaf, corn stalk, and napier grass) by chemical composition and morphological study. BioResources 9(1):872–880

23.

Kengkhetkit N, Amornsakchai T (2014) A new approach to “Greening” plastic composites using pineapple leaf waste for performance and cost-effectiveness. Mater Design 55:292–299

24.

Hazarika D, Gogoi N, Jose S, Das R, Basu G (2017) Exploration of future prospects of Indian pineapple leaf, an agro waste for textile application. J Clean Prod 141:580–586

25.

Fan LT, Gharpuray MM, Lee Y-H (1987) Nature of cellulosic material. Cellulose hydrolysis. Springer, Berlin Heidelberg, GermanyCrossRef

26.

Khalil HA, Bhat A, Yusra AI (2012) Green composites from sustainable cellulose nanofibrils: a review. Carbohydr Polym 87(2):963–979CrossRef

27.

Moon RJ, Martini A, Nairn J, Simonsen J, Youngblood J (2011) Cellulose nanomaterials review: structure, properties and nanocomposites. Chem Soc Rev 40(7):3941–3994CrossRef

28.

Atalla RH, Vanderhart DL (1984) Native cellulose: a composite of two distinct crystalline forms. Science 223(4633):283–285CrossRef

29.

Nishiyama Y, Langan P, Chanzy H (2002) Crystal structure and hydrogen-bonding system in cellulose Iβ from synchrotron X-ray and neutron fiber diffraction. J Am Chem Soc 124(31):9074–9082CrossRef

30.

Song Y, Zhang J, Zhang X, Tan T (2015) The correlation between cellulose allomorphs (I and II) and conversion after removal of hemicellulose and lignin of lignocellulose. Bioresour Technol 193:164–170CrossRef

31.

Razali M, Amira N, Azraaie N, Abidin NAMZ, Ibrahim NA, Abdul Aziz F, Abdul Rahman S (2015) Effect of chemical treatment on crystalline cellulose: changes in crystallinity and functional groups of cellulose. Adv Mater Res 35–39

32.

Lee K-Y, Santmartí A (2018) Crystallinity and thermal stability of nanocellulose. In: Nanocellulose and sustainability. CRC Press, pp 67–86

33.

Nickerson R, Habrle J (1947) Cellulose intercrystalline structure. Ind Eng Chem 39(11):1507–1512CrossRef

34.

Hammel E, Tang X, Trampert M, Schmitt T, Mauthner K, Eder A, Pötschke P (2004) Carbon nanofibers for composite applications. Carbon 42(5–6):1153–1158CrossRef

35.

French AD, Cintrón MS (2013) Cellulose polymorphy, crystallite size, and the Segal crystallinity index. Cellulose 20(1):583–588CrossRef

36.

Nam S, French AD, Condon BD, Concha M (2016) Segal crystallinity index revisited by the simulation of X-ray diffraction patterns of cotton cellulose Iβ and cellulose II. Carbohydr Polym 135:1–9CrossRef

37.

Mtibe A, Linganiso LZ, Mathew AP, Oksman K, John MJ, Anandjiwala RD (2015) A comparative study on properties of micro and nanopapers produced from cellulose and cellulose nanofibres. Carbohydr Polym 118:1–8CrossRef

38.

Yu H-Y, Qin Z-Y, Liu L, Yang X-G, Zhou Y, Yao J-M (2013) Comparison of the reinforcing effects for cellulose nanocrystals obtained by sulfuric and hydrochloric acid hydrolysis on the mechanical and thermal properties of bacterial polyester. Compos Sci Technol 87:22–28CrossRef

39.

Wei Z, Sinko R, Keten S, Luijten E (2018) Effect of surface modification on water adsorption and interfacial mechanics of cellulose nanocrystals. ACS Appl Mater Interface 10(9):8349–8358CrossRef

40.

Makarem M, Lee CM, Sawada D, O’Neill HM, Kim SH (2017) Distinguishing surface versus bulk hydroxyl groups of cellulose nanocrystals using vibrational sum frequency generation spectroscopy. J Phys Chem Lett 9(1):70–75CrossRef

41.

Gauthier R, Joly C, Coupas A, Gauthier H, Escoubes M (1998) Interfaces in polyolefin/cellulosic fiber composites: chemical coupling, morphology, correlation with adhesion and aging in moisture. Polym Compos 19(3):287–300CrossRef

42.

Aziz FA, Surip S, Bonnia N, Sekak K (2018) The effect of pineapple leaf fiber (PALF) incorporation into polyethylene terephthalate (PET) on FTIR, morphology and wetting properties. IOP Conf Ser Earth Environ Sci 1:012082

43.

Vodounon NA, Kanali C, Mwero J (2018) Compressive and flexural strengths of cement stabilized earth bricks reinforced with treated and untreated pineapple leaves fibres. Open J Compos Mater 8(4):145–160CrossRef

44.

Jaafar J, Siregar JP, Oumer AN, Hamdan MHM, Tezara C, Salit MS (2018a) Experimental investigation on performance of short pineapple leaf fiber reinforced tapioca biopolymer composites. BioResources 13(3):6341–6355

45.

Teles MCA, Glória GO, Altoé GR, Amoy Netto P, Margem FM, Braga FO, Monteiro SN (2015) Evaluation of the diameter influence on the tensile strength of pineapple leaf fibers (PALF) by Weibull method. Mater Res 18:185–192CrossRef

46.

Wahyuningsih K, Iriani ES, Fahma F (2016) Utilization of cellulose from pineapple leaf fibers as nanofiller in polyvinyl alcohol-based film. Indones J Chem 16(2):181–189CrossRef

47.

Jaafar J, Siregar JP, Piah MBM, Cionita T, Adnan S, Rihayat T (2018b) Influence of selected treatment on tensile properties of short pineapple leaf fiber reinforced tapioca resin biopolymer composites. J Polym Env 26(11):4271–4281

48.

Munajad A, Subroto C (2018) Fourier transform infrared (FTIR) spectroscopy analysis of transformer paper in mineral oil-paper composite insulation under accelerated thermal aging. Energies 11(2):364CrossRef

49.

Krause C, Dreier L, Fehlmann A, Cross J (2014) The degree of polymerization of cellulosic insulation: review of measuring technologies and its significance on equipment. In: 2014 IEEE electrical insulation conference (EIC). IEEE, pp 267–271

50.

Santmartí A, Lee K-Y (2018) Chapter 5: crystallinity and thermal. In: Nanocellulose and sustainability: production, properties, applications, and case studies. CRC Press, Boca Raton, p 67

51.

Santosha PCR, Gowda ASSS, Manikanth V (2018) Effect of fiber loading on thermal properties of banana and pineapple leaf fiber reinforced polyester composites. Mater Today Proc 5(2):5631–5635CrossRef

52.

Huda MS, Drzal LT, Mohanty AK, Misra M (2008) Effect of chemical modifications of the pineapple leaf fiber surfaces on the interfacial and mechanical properties of laminated biocomposites. Compos Interface 15(2–3):169–191CrossRef

53.

Asim M, Abdan K, Jawaid M, Nasir M, Dashtizadeh Z, Ishak MR, Hoque ME (2015) A review on pineapple leaves fibre and its composites. Int J Polym Sci 2015:1–16CrossRef

54.

George J, Sreekala MS, Thomas S (2001) A review on interface modification and characterization of natural fiber reinforced plastic composites. Polym Eng Sci 41(9):1471–1485CrossRef

55.

Chollakup R, Tantatherdtam R, Ujjin S, Sriroth K (2011) Pineapple leaf fiber reinforced thermoplastic composites: effects of fiber length and fiber content on their characteristics. J Appl Polym Sci 119(4):1952–1960CrossRef

56.

Hujuri U, Chattopadhay SK, Uppaluri R, Ghoshal AK (2008) Effect of maleic anhydride grafted polypropylene on the mechanical and morphological properties of chemically modified short-pineapple-leaf-fiber-reinforced polypropylene composites. J Appl Polym Sci 107(3):1507–1516CrossRef

57.

Cherian BM, Leão AL, de Souza SF, Costa LMM, de Olyveira GM, Kottaisamy M, Nagarajan ER, Thomas S (2011) Cellulose nanocomposites with nanofibres isolated from pineapple leaf fibers for medical applications. Carbohydr Polym 86(4):1790–1798CrossRef

58.

George J, Sabapathi SN (2015) Cellulose nanocrystals: synthesis, functional properties, and applications. Nanotechnol Sci Appl 8:45–54CrossRef

59.

Mahardika M, Abral H, Kasim A, Arief S, Asrofi M (2018) Production of nanocellulose from pineapple leaf fibers via high-shear homogenization and ultrasonication. Fibers 6(2)

60.

Balakrishnan P, Gopi S, Geethamma VG, Kalarikkal N, Thomas S (2018) Cellulose nanofiber vs nanocrystals from pineapple leaf fiber: a comparative studies on reinforcing efficiency on starch nanocomposites. Macromol Symp 380(1)

61.

Shih YF, Chou MY, Lian HY, Hsu LR, Chen-Wei SM (2018) Highly transparent and impact-resistant PMMA nanocomposites reinforced by cellulose nanofibers of pineapple leaves modified by eco-friendly methods. Express Polym Lett 12(9):844–854CrossRef

62.

Abdul Khalil HPS, Davoudpour Y, Saurabh CK, Hossain MS, Adnan AS, Dungani R, Paridah MT, Islam Sarker MZ, Fazita MRN, Syakir MI, Haafiz MKM (2016) A review on nanocellulosic fibres as new material for sustainable packaging: process and applications. Renew Sustain Energy Rev 64:823–836CrossRef

Titel: Physicochemical Properties of Nanocellulose Extracted from Pineapple Leaf Fibres and Its Composites
verfasst von: Ismail Muhamad Fareez
Nazmul Haque
Der Juin Ooi
Ainil Hawa Jasni
Fauziah Abd Aziz
Verlag: Springer Singapore
Buch: Pineapple Leaf Fibers
Print ISBN: 978-981-15-1415-9

Electronic ISBN: 978-981-15-1416-6

Copyright-Jahr: 2020
DOI: https://doi.org/10.1007/978-981-15-1416-6_9

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