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Journal of Material Cycles and Waste Management

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06-08-2018 | ORIGINAL ARTICLE

Properties and potential use of biochars from residues of two rice varieties, Japanese Koshihikari and Vietnamese IR50404

Authors: Phuong T. M. Do, Taro Ueda, Ryota Kose, Loc X. Nguyen, Takayuki Okayama, Takayuki Miyanishi

Published in: Journal of Material Cycles and Waste Management | Issue 1/2019

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Abstract

Converting rice straw or rice husk into biochars is one of the most effective ways to reuse them. This study examined the effect of rice variety and pyrolysis temperature on the properties of biochars, produced from rice straw and rice husk of Koshihikari (a typical rice variety of Japan) and IR50404 (a typical rice variety of Vietnam), in the temperature range from 300 to 800 °C. Biochars produced at high pyrolysis temperatures (> 500 °C) showed higher surface area (approximately 3 times) and higher Si content (by more than 15%), but lower H/C and O/C ratios in comparison with biochars produced at lower temperature. With regard to rice variety, Japanese Koshihikari biochars possessed higher Si content (almost 20%), but lower specific surface area and O/C and H/C ratios than Vietnamese IR50404 rice residue biochars. The surface area of Vietnamese-rice-straw biochars at 600 and 700 °C was ~ 30% more than Japanese-rice-straw biochars, while the surface area of Vietnamese-rice-husk biochars was slightly more than that of Japanese-rice-husk biochars. Higher Si content in Japanese Koshihikari biochars was predicted as one of the main reasons for the lower surface area in their biochars, due to the higher possibility of pore-filling or blocking by silica.

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World Rice Production (2017) World Rice Production 2017/2018. https://www.worldriceproduction.com/. Accessed 20 Oct 2015

Matsumura Y, Minowa T, Yamamoto H (2005) Amount, availability, and potential use of rice straw (agricultural residue) biomass as an energy resource in Japan. Biomass Bioenerg 29(5):347–354CrossRef

Agency NL (2012) Biomass business opportunities Viet Nam. Netherlands Programmes Sustainable Biomass

Verheijen F, Jeffery S, Bastos A, Van Der Velde M, Diafas I (2010) Biochar application to soils—a critical scientific review of effects on soil properties. Processes and functions, European Commission Joint Research Centre for scientific and Technical reports, pp 51–68

Ścisłowska M, Włodarczyk R, Kobyłecki R, Bis Z (2015) Biochar to improve the quality and productivity of soils. J Ecol Eng 16:3

Brockhoff SR, Christians NE, Killorn RJ, Horton R, Davis DD (2010) Physical and mineral-nutrition properties of sand-based turfgrass root zones amended with biochar. Agron J 102(6):1627–1631CrossRef

Basso AS, Miguez FE, Laird DA, Horton R, Westgate M (2013) Assessing potential of biochar for increasing water-holding capacity of sandy soils. Gcb Bioenergy 5(2):132–143CrossRef

Warnock DD, Lehmann J, Kuyper TW, Rillig MC (2007) Mycorrhizal responses to biochar in soil—concepts and mechanisms. Plant soil 300(1–2):9–20CrossRef

Saito M, Marumoto T (2002) Inoculation with arbuscular mycorrhizal fungi: the status quo in Japan and the future prospects. Plant Soil 244:273–279CrossRef

10.

JiangZhou L, QingZhong Z, YiLai L, LiMeng Z, ZhangLiu D, XingRen L, YiDing W (2015) Effects of biochar addition on nutrient leaching loss of typical tobacco-planting soils in Yunnan Province, China. J Agric Resour Environ 32(1):48–53

11.

Major J, Rondon M, Molina D, Riha SJ, Lehmann J (2012) Nutrient leaching in a Colombian savanna Oxisol amended with biochar. J Environ Qual 41(4):1076–1086CrossRef

12.

Zhang X, Wang H, He L, Lu K, Sarmah A, Li J, Bolan NS, Pei J, Huang H (2013) Using biochar for remediation of soils contaminated with heavy metals and organic pollutants. Environ Sci Pollut Res 20(12):8472–8483CrossRef

13.

Denyes MJ, Langlois VS, Rutter A, Zeeb BA (2012) The use of biochar to reduce soil PCB bioavailability to Cucurbita pepo and Eisenia fetida. Sci Total Environ 437:76–82CrossRef

14.

Lorenz K, Lal R (2014) Biochar application to soil for climate change mitigation by soil organic carbon sequestration. J Plant Nutr Soil Sci 177(5):651–670CrossRef

15.

Woolf D, Amonette JE, Street-Perrott FA, Lehmann J, Joseph S (2010) Sustainable biochar to mitigate global climate change. Nat Commun 1:56CrossRef

16.

Wu W, Yang M, Feng Q, McGrouther K, Wang H, Lu H, Chen Y (2012) Chemical characterization of rice straw-derived biochar for soil amendment. Biomass Bioenergy 47:268–276CrossRef

17.

Peng X, Ye L, Wang C, Zhou H, Sun B (2011) Temperature-and duration-dependent rice straw-derived biochar: characteristics and its effects on soil properties of an Ultisol in southern China. Soil Tillage Res 112(2):159–166CrossRef

18.

Jiang J, Yongbo P, Min Y, Zhineng H, Dejian W, Renkou X (2015) Rice straw-derived biochar properties and functions as Cu(II) and Cyromazine Sorbents as influenced by pyrolysis temperature. Pedosphere 25(5):781–789CrossRef

19.

Zhang Y, Ma Z, Zhang Q, Wang J, Ma Q, Yang Y, Luo X, Zhang W (2017) Comparison of the physicochemical characteristics of Bio-char pyrolyzed from Moso bamboo and rice husk with different pyrolysis temperatures. BioResources 12(3):4652–4669

20.

Standards TAPPI (2002) Acid-insoluble lignin in wood and pulp T 222 om-02. Atlanta, USA

21.

Wise LE, Murphy M, D’addieco AA (1946) Chlorite holocellulose, its fractionation and bearing on summative wood analysis and studies on the hemicelluloses. Pap Trade J 122(2):35–43

22.

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(2):104–115CrossRef

23.

Demirbas A (2009) Biofuels securing the planet’s future energy needs. Energy Convers Manag 50(9):2239–2249CrossRef

24.

de Wild P, Reith H, Heeres E (2011) Biomass pyrolysis for chemicals. Biofuels 2(2):185–208CrossRef

25.

Jindo K, Mizumoto H, Sawada Y, Sanchez-Monedero MA, Sonoki T (2014) Physical and chemical characterization of biochars derived from different agricultural residues. Biogeosciences 11(23):6613–6621CrossRef

26.

Wang Y, Hu Y, Zhao X, Wang S, Xing G (2013) Comparisons of biochar properties from wood material and crop residues at different temperatures and residence times. Energy Fuels 27(10):5890–5899CrossRef

27.

Prins MJ, Ptasinski KJ, Janssen FJ (2006) Torrefaction of wood: Part 1. Weight loss kinetics. J Anal Appl Pyrol 77(1):28–34CrossRef

28.

Capareda S (2013) Introduction to biomass energy conversions. CRC Press, Boca RatonCrossRef

29.

Chen B, Zhou D, Zhu L (2008) Transitional adsorption and partition of nonpolar and polar aromatic contaminants by biochars of pine needles with different pyrolytic temperatures. Environ Sci Technol 42(14):5137–5143CrossRef

30.

Lua AC, Yang T, Guo J (2004) Effects of pyrolysis conditions on the properties of activated carbons prepared from pistachio-nut shells. J Anal Appl Pyrol 72(2):279–287CrossRef

31.

Mukome FN, Parikh SJ (2015) Chemical, physical, and surface characterization of biochar. In: Ok YS, Uchimiya SM, Chang SX, Bolan N (eds) Biochar: production, characterization, and applications. CRC Press, Boca Raton, pp 68–96

32.

Chia CH, Downie A, Munroe P (2015) Characteristics of biochar: physical and structural properties. In: Lehmann J, Joseph S (eds) Biochar for environmental management: science, technology and implementation. Routledge, Abingdon, pp 89–110

33.

Lopez-Capel E, Zwart K, Shackley S, Postma R, Stenstrom J, Rasse DP, Budai A, Glaser B (2016) Biochar properties. In: Shackley S, Ruysschaert G, Zwart K, Glaser B (eds) Biochar in European soils and agriculture: science and practice. Routledge, Abingdon, pp 41–72

34.

Song W, Guo M (2012) Quality variations of poultry litter biochar generated at different pyrolysis temperatures. J Anal Appl Pyrol 94:138–145CrossRef

35.

Schimmelpfennig S, Glaser B (2012) One step forward toward characterization: some important material properties to distinguish biochars. J Environ Qual 41(4):1001–1013CrossRef

36.

Parikh SJ, Goyne KW, Margenot AJ, Mukome FN, Calderón FJ (2014) Soil chemical insights provided through vibrational spectroscopy. In: Sparks DL (ed) Advances in agronomy, vol 126. Elsevier, Oxford, pp 1–148

37.

Xiao X, Chen B, Zhu L (2014) Transformation, morphology, and dissolution of silicon and carbon in rice straw-derived biochars under different pyrolytic temperatures. Environ Sci Technol 48(6):3411–3419CrossRef

38.

Guo J, Chen B (2014) Insights on the molecular mechanism for the recalcitrance of biochars: interactive effects of carbon and silicon components. Environ Sci Technol 48(16):9103–9112CrossRef

39.

Mukome FN, Kilcoyne AL, Parikh SJ (2014) Alteration of biochar carbon chemistry during soil incubations: SR-FTIR and NEXAFS investigation. Soil Sci Soc Am J 78(5):1632–1640CrossRef

40.

Jaafar NM (2014) Biochar as a habitat for arbuscular mycorrhizal fungi. In: Johnson NC, Gehring C, Jansa J (eds) Mycorrhizal fungi: use in sustainable agriculture and land restoration. Springer, Berlin, pp 297–311

41.

Koide RT (2016) Biochar-arbuscular mycorrhiza interaction in temperate soils. In: Johnson NC, Gehring C, Jansa J (eds) Mycorrhizal mediation of soil: fertility, structure, and carbon storage. Elsevier, Oxford, pp 461–478

42.

Asai H, Samson BK, Stephan HM, Songyikhangsuthor K, Homma K, Kiyono Y, Inoue Y, Shiraiwa T, Horie T (2009) Biochar amendment techniques for upland rice production in Northern Laos: 1. Soil physical properties, leaf SPAD and grain yield. Field Crops Res 111(1):81–84CrossRef

43.

Glaser B, Lehmann J, Zech W (2002) Ameliorating physical and chemical properties of highly weathered soils in the tropics with charcoal-a review. Biol Fertil Soils 35(4):219–230CrossRef

44.

Chen B, Yuan M (2011) Enhanced sorption of polycyclic aromatic hydrocarbons by soil amended with biochar. J Soils Sedim 11(1):62–71MathSciNetCrossRef

45.

Yu X-Y, Ying G-G, Kookana RS (2006) Sorption and desorption behaviors of diuron in soils amended with charcoal. J Agric Food Chem 54(22):8545–8550CrossRef

46.

Melo LC, Coscione AR, Abreu CA, Puga AP, Camargo OA (2013) Influence of pyrolysis temperature on cadmium and zinc sorption capacity of sugar cane straw—derived biochar. BioResources 8(4):4992–5004CrossRef

47.

Nguyen TH, Cho H-H, Poster DL, Ball WP (2007) Evidence for a pore-filling mechanism in the adsorption of aromatic hydrocarbons to a natural wood char. Environ Sci Technol 41(4):1212–1217CrossRef

48.

Ma JF (2003) Functions of silicon in higher plants. In: Müller WEG (ed) Silicon biomineralization: biology–biochemistry–molecular biology–biotechnology, vol 33. Springer, Berlin, pp 127–147CrossRef

49.

Koyama S, Katagiri T, Minamikawa K, Kato M, Hayashi H (2016) Effects of rice husk charcoal application on rice yield, methane emission, and soil carbon sequestration in andosol paddy soil. Jpn Agric Res Q 50(4):319–327CrossRef

50.

Koyama S, Hayashi H (2017) Rice yield and soil carbon dynamics over three years of applying rice husk charcoal to an Andosol paddy field. Plant Prod Sci 20(2):176–182CrossRef

51.

Thangarajan R, Bolan N, Mandal S, Kunhikrishnan A, Choppala G, Karunanithi R, Qi F (2015) Biochar for inorganic contaminant management in soil. In: Ok YS, Uchimiya SM, Chang SX, Bolan N (eds.) Biochar: production, characterization, and applications. CRC Press, Boca Raton, pp 100–139

52.

Spokas KA (2010) Review of the stability of biochar in soils: predictability of O:C molar ratios. Carbon Manag 1(2):289–303CrossRef

Title: Properties and potential use of biochars from residues of two rice varieties, Japanese Koshihikari and Vietnamese IR50404
Authors: Phuong T. M. Do
Taro Ueda
Ryota Kose
Loc X. Nguyen
Takayuki Okayama
Takayuki Miyanishi
Publication date: 06-08-2018
Publisher: Springer Japan
Published in: Journal of Material Cycles and Waste Management / Issue 1/2019
Print ISSN: 1438-4957
Electronic ISSN: 1611-8227
DOI: https://doi.org/10.1007/s10163-018-0768-8

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