Top

Published in:

2024 | OriginalPaper | Chapter

14. Zellulose

Author : Ololade Olatunji

Published in: Aquatische Biopolymere

Publisher: Springer International Publishing

Activate our intelligent search to find suitable subject content or patents.

search-config

AI-assisted search

Off

Zusammenfassung

Das häufigste Polymer auf der Erde ist auch in der aquatischen Umwelt vorhanden, produziert von Wasserpflanzen, Algen und Zellulose produzierenden Bakterien. Zellulose kann in verschiedene Formen wie Zellulose-Nanofasern und Methylzellulose modifiziert werden und findet vielfältige Anwendungen in verschiedenen Industrien, einschließlich Textilien, Papier und Energie. Die wirtschaftliche Produktion von Bioethanol aus zellulosehaltiger Biomasse ist aufgrund der stabilen Struktur der Zellulose, die sie weniger anfällig für Hydrolyse macht, begrenzt. Zellulose aus aquatischer Biomasse kann jedoch anderen Industrien wie der Textilindustrie dienen, wo die einzigartige Chemie der aus Wasser gewonnenen Zellulose einige wünschenswerte Eigenschaften hat. Die Extraktion von Zellulose aus Biomasse reduziert das in die Umwelt freigesetzte Methan aus dem Abbau von toter Wasserpflanzen- und Algenbiomasse.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

inform now

previous chapter Stärke

next chapter Polyester

Aizenshtein EM (2004) World production of textile raw material. Fibre Chem 36(1):3–7CrossRef

Albrecht W (2004) Regenerated cellulose in chapter „Cellulose“. In: Ullmann’s encyclopedia of industrial chemistry, 7th edn. Wiley-VCH Verlag GmbH & Co. KGaA. https://doi.org/10.1002/14356007.a05_375.pub2

Basile A, Sorbo S, Conte B, Cobianchi RC, Trinchella F, Capasso C, Carginale V (2012) Toxicity, accumulation, and removal of heavy metals by three aquatic macrophytes. Int J Phytorem 14(4):374–387CrossRef

Bayrakci AG, Kocar G (2014) Second-generation bioethanol production from water hyacinth and duckweed in Izmir: a case study. Renew Sustain Energy Rev 30:306–316CrossRef

Beguin P, Aubert JP (1994) The biological degradation of cellulose. FEMS Microbiol Rev 13(1):25–58PubMedCrossRef

Brown RM, Saxena IM Jr (2000) Cellulose biosynthesis: a model for understanding the assembly of biopolymers. Plant Physiol Biochem 38(1–2):57–67CrossRef

Chen P, Min M, Chen Y, Wang L, Li Y, Chen Q, Wang C, Wan Y, Wang X, Cheng Y, Deng S, Hennessy K, Lin X, Liu Y, Wang Y, Martinez B, Ruan R (2009) Review of the biological and engineering aspects of algae to fuels approach. Int J Agric Biol Eng 2:1–30

Chen Q, Jin Y, Zhang G, Fang Y, Xiao Y, Zhao H (2012) Improving production of bioethanol from duckweed (Landoltia punctata) by pectinase pretreatment. Energies 5:3019–3032CrossRef

Chen WY, Lee HV, Juan JC, Phang S (2016) Production of new cellulose nanomaterial from red algae marine biomass Gelidium elegans. Carbohyd Polym 51:1210–1219CrossRef

FAO (2011) A summary of the world apparel fibre consumption survey 2005–2008. International Cotton Advisory Committee

FAO (2017) Pulp and paper capacities. Rome, Italy. ISSN 0255-7665, ISBN 978-92-5-009846-3

Fernandez Diniz JM, Gil MH, Castro JAAM (2004) Hornification – its origin and interpretation in wood pulps. Wood Sci Technol 37:489–510CrossRef

Fusi A, Bacenetti J, Gonzalez-Garcia S, Vercesi A, Bocchi S, Fiala M (2014) Environmental profile of paddy rice cultivation with different straw management. Sci Total Environ 494–495:119–128PubMedCrossRef

Gao H, Duan B, Lu A, Deng H, Du Y, Shi X, Zhang L (2018) Fabrication of cellulose nanofibers from waste brown algae and their potential application as milk thickeners. Food Hydrocolloids 79:473–481CrossRef

Hanhikoski S, Niemela K, Vuorinen T (2019) Biorefining of Scots pine using neutral sodium sulphite pulping: investigation of fibre and spent liquor compositions. Ind Crops Prod 129:135–141CrossRef

Hasan SH, Talat M, Rai S (2007) Sorption of cadmium and zinc from aqueous solution by water hyacinth (Eichhornia crassipes). Bioresour Technol 98:918–928PubMedCrossRef

Heilig G (1994) The greenhouse gas methane (CH₄): sources and sinks, the impact of population growth, possible interventions. Popul Environ 16(2):109–137CrossRef

Hon (1994) Cellulose: a random walk along the historical path. Cellulose 1(1):1–25CrossRef

Istirokhatun T, Rokhati N, Rachmawaty R, Meriyani M, Priyanto S, Susanto H (2015) Cellulose isolation from tropical water hyacinth for membrane preparation. Procedia Environ Sci 23:274–281CrossRef

Jaurez-Luna GN, Favela-Torres E, Quevedo IR, Batina N (2019) Enzymatically assisted isolation of high-quality cellulose nanoparticles from water hyacinth stems. Carbohyd Polym 220:110–117CrossRef

Johnson M, Shivkumar SJ (2004) Filamentous green algae additions to isocyanate based foams. J Appl Polym Sci 93(5):2469–2477CrossRef

Kollah B, Patra AK, Mohanty SR (2016) Aquatic microphylla Azolla: a perspective paradigm for sustainable agriculture, environment and global climate change. Environ Sci Pollut Res 23(5):4358–4369CrossRef

Konda M, Singh S, Simmons BA, Klein-Marcuschamer D (2015) An investigation on the economic feasibility of Macroalgae as a potential feedstock for biorefineries. Bioenergy Res 8:1046–1056CrossRef

Koyama M, Sugiyama J, Itoh T (1997) Systematic survey on crystalline features of algal celluloses. Cellulose 4:147–160CrossRef

Lahnalammi A, Sixta H, Jamsa-Jounela S (2018) Control strategy scheme for the prehydrolysis Kraft process. Comput Aided Chem Eng 44:643–648CrossRef

Lee H, Kim K, Mun SC, Chang YK, Choi SQ (2018) A method to produce cellulose nanofibrils from microalgae and the measurement of their mechanical strength. Carbohyd Polym 180:276–285CrossRef

Lenzing AG (2006) Sustainability in the Lenzing Group. Lenzing AG, Lenzing. http://www.lenzing.com/sites/nh/english/e_index.html

Li W, Khalid H, Zhu Z, Zhang R, Liu G, Chen C, Thorin E (2018) Methane production through anaerobic digestion: participation and digestion characteristics of cellulose, hemicellulose and lignin. Appl Energy 226:1219–1228CrossRef

Ma S, Sun X, Fand C, He X, Han L, Huang G (2018) Exploring the mechanisms of decreased methane during pig manure and wheat straw aerobic composting covered with a semi-permeable membrane. Waste Manag 78:393–400PubMedCrossRef

Martinez de Yuso A, Izquierdo MT, Rubio B, Carrot PJM (2013) Adsorption of toluene and toluene-water vapor mixture on almond shell based activated carbon. Adsorption 19:1137–1148CrossRef

Mihranyan A (2010) Cellulose from Cladophorales green algae: from environmental problems to high-tech composite materials. J Appl Polym Sci 119:2449–2460CrossRef

Mihranyan A, Llagostera AP, Karmhag R, Strømme M, Ek R (2004) Moisture sorption by cellulose powders of varying crystallinity. Int J Pharm 269:433–442PubMedCrossRef

Miranda AF, Biswas B, Ramkumar N, Singh R, Kumar J, James A, Lal B, Subudhi S, Bhaskar T, Mouradov A (2016) Aquatic plant Azolla as the universal feedstock for biofuel production. Biotechnol Biofuels 9(221):1–17

Mitsuo Y, Eisuke Y (1996) (to Mitsubishi Paper Mills). Jpn Pat 08-229318

Mochochoko T, Oluwafemi OS, Jumbam DN, Songca SP (2013) Green synthesis of silver nanoparticles using cellulose extracted from an aquatic weed; water hyacinth. Carbohyd Polym 98(1):290–294CrossRef

Munoz C, Hidalgo C, Zapala M, Jeison D, Riquelme C, Rivas M (2014) Use of cellulolytic marine bacteria for enzymatic pretreatment in microalgal biogas production. Appl Environ Microbiol 80(14):4199–4206PubMedPubMedCentralCrossRef

Olatunji O, Olsson RT (2015) Microneedles from fishscale-nanocellulose blends using low temperature mechanical press method. Pharmaceutics 7:363–378PubMedPubMedCentralCrossRef

Olatunji O, Olsson RT (2016) Processing and characterization of natural polymers. In: Natural polymers, industry techniques and applications. Springer, Switzerland. ISBN 978-3-319-26412-7

Penfound WT, Earle TT (1948) The biology of the water hyacinth. Ecol Monogr 18:447–472CrossRef

Polprasert C, Kongsricharoern N, Kanjana Prapin W (1994) Production of feed and fertilizer from water hyacinth plants in the tropics. Waste Manag Res 12(1):3–11CrossRef

Russel JB, Muck RE, Weimer PJ (2009) Quantitative analysis of cellulose degradation and growth of cellulolytic bacteria in the rumen. FEMS Microbiol Ecol 67(2):183–197CrossRef

Sarkar M, Rahman AKML, Bhoumik NC (2017) Remediation of chromium and copper on water hyacinth (E.crassipes) shoot powder. Water Resour Ind 17:1–6CrossRef

Shen L, Patel MK (2010) Life cycle assessment of man-made cellulose fibres. Lenzinger Ber 88:1–59

Shen J, Qian X (2012) Addressing the water footprint concept: a demonstrable strategy for papermaking industry. BioResources 7(3):2707–2710CrossRef

Shen XL, Xia LM (2003) Studies on immobilized cellobiase. Chin J Biotechnol 19(2):236–239

Shen L, Worrell E, Patel KM (2010) Environmental impact assessment of man-made cellulose fibres. Resour Conserv Recycl 55(2):260–274CrossRef

Siddhanta AK, Chhatbar MU, Mehta GK, Sanandiya ND, Kumar S, Oza MD, Prasad K, Meena R (2011) The cellulose contents of Indian seaweeds. J Appl Phycol 23:919–923CrossRef

Smith J, Connell P, Evans RH, Gellene AG, Howard MDA, Jones BH, Kaveggia Palmer L, Schnetzer A, Seegers BN, Seubert EL, Tatters AO, Caron DA (2018) A decade and a half of pseudo-nitzschia spp. and domoic acid along the coast of southern California. Harmful Algae. https://doi.org/10.1016/j.hal.2018.07.007PubMedCrossRef

Steen DA, Gibbs JP, Buhlmann KA, Carr JL (2012) Terrestrial habitat requirements of nesting freshwater turtles. Biol Conserv 150(1):121–128CrossRef

Stromme M, Mihranyan A, Ek R (2002) What to do with all these algae? Mater Lett 57:569–572CrossRef

Thiripura M, Ramesh A (2012) Isolation and characterization of cellulose nanofibers from the aquatic weed water hyacinth – Eichhornia crassipes. J Carbohyd Polym 87:1701–1705CrossRef

Vulimiri SV, Pratt MM, Kulkarni S, Beedanagari S, Mahadevan B (2017) Reproductive and developmental toxicity of solvents and gases, chap 21. In: Reproductive and developmental toxicology, 2. Aufl. Academic Press, S 379–396

Wi SG, Kim HJ, Mahadevan SA, Yang DJ, Bae HJ (2009) The potential value of the seaweed Ceylon moss (Gelidium amansii) as an alternative bioenergy resource. Bioresour Technol 100:6658–6660PubMedCrossRef

Yadav D, Barbora L, Bora D, Mitra S, Rangan L, Mahanta P (2017) An assessment of duckweed as a potential lignocellulosic feedstock for biogas production. Int Biodeterior Biodegradation 119:253–259CrossRef

Yaich H, Garnaa H, Besbesa S, Paquot M, Beckerc C, Attia H (2011) Chemical composition and functional properties of Ulva lactuca seaweed collected in Tunisia. Food Chem 128(4):895–901CrossRef

Yoon JJ, Kim YJ, Kim SH, Ryu HJ, Choi JY, Kim GS, Shin MK (2010) Production of polysaccharides and corresponding sugars from red seaweed. Adv Mater Res 93–94:463–466CrossRef

Zhao X, Moates GK, Wellner N, Collins SR, Coleman MJ, Waldron KW (2014) Chemical characterisation and analysis of the cell wall polysaccharides of duckweed (Lemna minor). Carbohyd Polym 111:410–418CrossRef

Title: Zellulose
Author: Ololade Olatunji
Publisher: Springer International Publishing
Book: Aquatische Biopolymere
Print ISBN: 978-3-031-48281-6

Electronic ISBN: 978-3-031-48282-3

Copyright Year: 2024
DOI: https://doi.org/10.1007/978-3-031-48282-3_14