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Biomass Conversion and Biorefinery

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17.08.2020 | Original Article

Low-temperature biochars from cork-rich and phloem-rich wastes: fuel, leaching, and methylene blue adsorption properties

verfasst von: A. U. Şen, C. Nobre, L. Durão, I. Miranda, H. Pereira, M. Gonçalves

Erschienen in: Biomass Conversion and Biorefinery | Ausgabe 9/2022

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Abstract

Waste cork and phloem fractions from the bark of Turkey oak (Quercus cerris) were subject to low-temperature pyrolysis between 250 and 325 °C and residence times of 30 or 60 min. The fuel, leaching, and methylene blue adsorption properties of the produced biochars were evaluated for the first time. The results indicate that cork and phloem containing bark fractions have a promising potential for the production of biochars. The pyrolysis process reduces the bark wastes and contributes to their efficient use. The cork and phloem biochars produced above 300 °C showed promising H/C and O/C atomic ratios that were comparable with lignite. Methylene blue adsorption on cork and phloem biochars was inversely affected by pyrolysis temperature and residence time. Activated carbons for soil amendment applications may be produced from the biochars via a steam activation method with optimum temperature and residence time of approximately 300 °C and 30 min in order to harness the nutrient release while avoiding the potential of toxicity from phenolic leaching.

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Pasztory Z, Mohácsiné IR, Gorbacheva G, Börcsök Z (2016) The utilization of tree bark. BioResources 11:7859–7888CrossRef

Pereira H (2007) Introduction. In: Pereira H (ed) Cork. Elsevier Science B.V., Amsterdam, pp. 1–3

Şen A, Quilhó T, Pereira H (2011) The cellular structure of cork from Quercus cerris var. cerris bark in a materials’ perspective. Ind Crop Prod:34. https://doi.org/10.1016/j.indcrop.2011.02.015

Şen A, Miranda I, Santos S, Graça J, Pereira H (2010) The chemical composition of cork and phloem in the rhytidome of Quercus cerris bark. Ind Crop Prod 31:417–422. https://doi.org/10.1016/j.indcrop.2010.01.002CrossRef

Şen A, Leite C, Lima L, Lopes P, Pereira H (2016) Industrial valorization of Quercus cerris bark: pilot scale fractionation. Ind Crop Prod 92:42–49. https://doi.org/10.1016/j.indcrop.2016.07.044CrossRef

Ronsse F, Van Hecke S, Dickinson D, Prins W (2013) Production and characterization of slow pyrolysis biochar: influence of feedstock type and pyrolysis conditions. GCB Bioenergy 5:104–115CrossRef

Lehmann J, Joseph S (2015) Biochar for environmental management: an introduction. In: Biochar for environmental management. Routledge, pp. 33–46

McHenry MP (2009) Agricultural bio-char production, renewable energy generation and farm carbon sequestration in Western Australia: certainty, uncertainty and risk. Agric Ecosyst Environ 129:1–7CrossRef

Nobre C, Vilarinho C, Alves O, Mendes B, Gonçalves M (2019) Upgrading of refuse derived fuel through torrefaction and carbonization: evaluation of RDF char fuel properties. Energy 181:66–76CrossRef

10.

Singleton VL, Orthofer R, Lamuela-Raventós RM (1999) Analysis of total phenols and other oxidation substrates and antioxidants by means of Folin-Ciocalteu reagent. In: Methods in enzymology. Elsevier, pp. 152–178

11.

Correia R, Gonçalves M, Nobre C, Mendes B (2017) Impact of torrefaction and low-temperature carbonization on the properties of biomass wastes from Arundo donax L. and Phoenix canariensis. Bioresour Technol 223:210–218CrossRef

12.

Sen A, Zhianski M, Glushkova M, Petkova K, Ferreira J, Pereira H (2016) Chemical composition and cellular structure of corks from Quercus suber trees planted in Bulgaria and Turkey. Wood Sci Technol 50:1261–1276. https://doi.org/10.1007/s00226-016-0836-yCrossRef

13.

Chan KY, Xu Z (2012) Biochar: nutrient properties and their enhancement. In: Biochar for environmental management. Routledge, pp. 99–116

14.

Weber K, Quicker P (2018) Properties of biochar. Fuel 217:240–261CrossRef

15.

Şen A, Van Den Bulcke J, Defoirdt N et al (2014) Thermal behaviour of cork and cork components. Thermochim Acta 582:94–100. https://doi.org/10.1016/j.tca.2014.03.007CrossRef

16.

Amonette JE, Joseph S (2012) Characteristics of biochar: microchemical properties. In: Biochar for environmental management. Routledge, pp. 65–84

17.

Enders A, Hanley K, Whitman T, Joseph S, Lehmann J (2012) Characterization of biochars to evaluate recalcitrance and agronomic performance. Bioresour Technol 114:644–653CrossRef

18.

Llorente MJF, García JEC (2005) Comparing methods for predicting the sintering of biomass ash in combustion. Fuel 84:1893–1900CrossRef

19.

Basu P (2010) Biomass gasification and pyrolysis: practical design and theory. Academic press

20.

Xiao X, Chen Z, Chen B (2016) H/C atomic ratio as a smart linkage between pyrolytic temperatures, aromatic clusters and sorption properties of biochars derived from diverse precursory materials. Sci Rep 6:22644CrossRef

21.

Laird DA (2008) The charcoal vision: a win–win–win scenario for simultaneously producing bioenergy, permanently sequestering carbon, while improving soil and water quality. Agron J 100:178–181CrossRef

22.

Laird D, Fleming P, Wang B, Horton R, Karlen D (2010) Biochar impact on nutrient leaching from a Midwestern agricultural soil. Geoderma 158:436–442CrossRef

23.

DeLuca TH, Gundale MJ, MacKenzie MD, Jones DL (2015) Biochar effects on soil nutrient transformations. Biochar Environ Manag Sci Technol Implement 2:421–454

24.

Bachmann HJ, Bucheli TD, Dieguez-Alonso A, Fabbri D, Knicker H, Schmidt HP, Ulbricht A, Becker R, Buscaroli A, Buerge D, Cross A, Dickinson D, Enders A, Esteves VI, Evangelou MWH, Fellet G, Friedrich K, Gasco Guerrero G, Glaser B, Hanke UM, Hanley K, Hilber I, Kalderis D, Leifeld J, Masek O, Mumme J, Carmona MP, Calvelo Pereira R, Rees F, Rombolà AG, de la Rosa JM, Sakrabani R, Sohi S, Soja G, Valagussa M, Verheijen F, Zehetner F (2016) Toward the standardization of biochar analysis: the COST action TD1107 interlaboratory comparison. J Agric Food Chem 64:513–527CrossRef

25.

Deenik JL, McClellan T, Uehara G, Antal MJ, Campbell S (2010) Charcoal volatile matter content influences plant growth and soil nitrogen transformations. Soil Sci Soc Am J 74:1259–1270CrossRef

26.

Lievens C, Mourant D, Gunawan R, Hu X, Wang Y (2015) Organic compounds leached from fast pyrolysis mallee leaf and bark biochars. Chemosphere 139:659–664CrossRef

27.

Zimmerman AR, Gao B (2013) The stability of biochar in the environment. Biochar Soil Biota 1:240

28.

Şen A, Olivella MA, Fiol N et al (2012) Removal of chromium (VI) in aqueous environments using cork and heat-treated cork samples from Quercus cerris and Quercus suber. BioResources 7

29.

Shengyu L (2003) The fate of organic oxygen during coal pyrolysis. Energy Sources 25:479–488CrossRef

30.

Warnock DD, Lehmann J, Kuyper TW, Rillig MC (2007) Mycorrhizal responses to biochar in soil–concepts and mechanisms. Plant Soil 300:9–20CrossRef

31.

Major J, Steiner C, Downie A (2009) Biochar effects on nutrient leaching. In: Lehmann J, Joseph S (eds) Biochar for environmental management, pp 271–287

32.

Major J, Steiner C, Downie A, Lehmann J (2012) Biochar effects on nutrient leaching. In: Biochar for environmental management. Routledge, pp. 303–320

33.

Lehmann J (2007) Bio-energy in the black. Front Ecol Environ 5:381–387CrossRef

34.

Glaser B, Haumaier L, Guggenberger G, Zech W (2001) The ‘Terra Preta’ phenomenon: a model for sustainable agriculture in the humid tropics. Naturwissenschaften 88:37–41CrossRef

35.

Mukherjee A, Zimmerman AR (2013) Organic carbon and nutrient release from a range of laboratory-produced biochars and biochar–soil mixtures. Geoderma 193:122–130CrossRef

36.

Dai L, Li H, Tan F, Zhu N, He M, Hu G (2016) Biochar: a potential route for recycling of phosphorus in agricultural residues. GCB Bioenergy 8:852–858CrossRef

37.

Liu Y, Zhao X, Li J, Ma D, Han R (2012) Characterization of bio-char from pyrolysis of wheat straw and its evaluation on methylene blue adsorption. Desalin Water Treat 46:115–123CrossRef

38.

Maroušek J, Vochozka M, Plachý J, Žák J (2017) Glory and misery of biochar. Clean Techn Environ Policy 19:311–317CrossRef

39.

Pereira H (1992) The thermochemical degradation of cork. Wood Sci Technol 26:259–269CrossRef

40.

Şen A, Miranda I, Pereira H (2012) Temperature-induced structural and chemical changes in cork from Quercus cerris. Ind Crop Prod 37:508–513. https://doi.org/10.1016/j.indcrop.2011.07.028CrossRef

41.

Şen A, Marques AV, Gominho J, Pereira H (2012) Study of thermochemical treatments of cork in the 150-400°C range using colour analysis and FTIR spectroscopy. Ind Crop Prod 38:132–138. https://doi.org/10.1016/j.indcrop.2012.01.018CrossRef

42.

Pintor AMA, Ferreira CIA, Pereira JC, Correia P, Silva SP, Vilar VJP, Botelho CMS, Boaventura RAR (2012) Use of cork powder and granules for the adsorption of pollutants: a review. Water Res 46:3152–3166CrossRef

43.

Novais RM, Caetano APF, Seabra MP, Labrincha JA, Pullar RC (2018) Extremely fast and efficient methylene blue adsorption using eco-friendly cork and paper waste-based activated carbon adsorbents. J Clean Prod 197:1137–1147CrossRef

44.

Sekkoum K, Cheriti A, Taleb S, Belboukhari N (2016) FTIR spectroscopic study of human urinary stones from El Bayadh district (Algeria). Arab J Chem 9:330–334CrossRef

45.

Şen A, Quilhó T, Pereira H (2011) Bark anatomy of Quercus cerris L. var. cerris from Turkey. Turk J Bot 35:45–55. https://doi.org/10.3906/bot-1002-33CrossRef

46.

Vieira PG, de Melo MMR, Şen A, Simões MMQ, Portugal I, Pereira H, Silva CM (2020) Quercus cerris extracts obtained by distinct separation methods and solvents: total and friedelin extraction yields, and chemical similarity analysis by multidimensional scaling. Sep Purif Technol 232:115924CrossRef

47.

Olivella MÀ, Fiol N, de la Torre F et al (2012) A mechanistic approach to methylene blue sorption on two vegetable wastes: cork bark and grape stalks. BioResources 7:3340–3354

Titel: Low-temperature biochars from cork-rich and phloem-rich wastes: fuel, leaching, and methylene blue adsorption properties
verfasst von: A. U. Şen
C. Nobre
L. Durão
I. Miranda
H. Pereira
M. Gonçalves
Publikationsdatum: 17.08.2020
Verlag: Springer Berlin Heidelberg
Erschienen in: Biomass Conversion and Biorefinery / Ausgabe 9/2022
Print ISSN: 2190-6815
Elektronische ISSN: 2190-6823
DOI: https://doi.org/10.1007/s13399-020-00949-x

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