Liquefaction of metal-contaminated giant reed biomass in acidified ethylene glycol system: Batch experiments

Zhao-hui Guo; Ya-nan Liu; Feng-yong Wang; Xi-yuan Xiao

doi:10.1007/s11771-014-2121-2

Journal of Central South University ›› 2014, Vol. 21 ›› Issue (5) : 1756 -1762. DOI: 10.1007/s11771-014-2121-2

Article

Liquefaction of metal-contaminated giant reed biomass in acidified ethylene glycol system: Batch experiments

Author information +

History +

PDF

Abstract

Giant reed is a suitable pioneer plant for metal-contaminated soil phytoremediation, however, it is imperative to dispose the metal-contaminated biomass after harvesting. The liquefaction of metal-contaminated giant reed biomass in ethylene glycol system with sulfuric acid as catalyst for the precursors of polyurethane compounds was studied. The results show that giant reed biomass from metal-contaminated soil is potentially liquefied and significantly affected by solvent/solid ratio, liquefaction temperature and liquefaction time (P<0.05). The liquefaction rate of biomass in acidified ethylene glycol system can reach 85.2% with optimized conditions of 60 min, 170 °C, 3% sulfuric acid and solvent/biomass ratio of 5:1. The hydroxyl value of liquefied products is of 481 mg KOH/g while reactive hydroxyl groups of them are abundant, which is promised as potential precursors for polyurethane compounds. The solvent liquefaction is a potential method to dispose the metal-contaminated biomass, however, the containing-metal liquefied products should be studied deeply in order to get the suitable precursors in future.

Keywords

Arundo donax L. / metal-contaminated biomass / solvent liquefaction / phytoremediation

Cite this article

Download citation ▾

Zhao-hui Guo, Ya-nan Liu, Feng-yong Wang, Xi-yuan Xiao. Liquefaction of metal-contaminated giant reed biomass in acidified ethylene glycol system: Batch experiments. Journal of Central South University, 2014, 21(5): 1756-1762 DOI:10.1007/s11771-014-2121-2

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	HuangG-x, ZhangY, SunJ-c, JingJ-h, LiuJ-t, WangYing. Effects of different conditions on Pb²⁺ adsorption from soil by irrigation of sewage in South China [J]. Journal of Centural South University, 2012, 19(1): 213-221

[2]	ShulkaO P, JuwarkarA A, SinghS K, KhanS, RaiU N. Growth responses and metal accumulation capabilities of woody plants during the phytoremediation of tannery sludge [J]. Waste Management, 2011, 31(1): 115-123

[3]	CaoX D, MaL, ShiralipourA, HarrisW. Biomass reduction and arsenic transformation during composting of arsenic-rich hyperaccumulator Pteris vittata L [J]. Environmental Science and Pollution Research, 2010, 17(3): 586-594

[4]	ShuklaO P, RaiU N, DubeyS. Involvement and interaction of microbial communities in the transformation and stabilization of chromium during the composting of tannery effluent treated biomass of Vallisneria spiralis L. [J]. Bioresource Technology, 2009, 100(7): 2198-2203

[5]	YamanS. Pyrolysis of biomass to produce fuels and chemical feedstocks [J]. Energy Conversion and Management, 2004, 45(5): 651-671

[6]	Sas-NowosielskaA, KucharskiR, MalkowskiE, PogrzebaM, KuperbergJ M, KrynskiK. Phytoextraction crop disposal-an unsolved problem [J]. Environmental Pollution, 2004, 128(3): 373-379

[7]	TekinK, KaragozS, BektasS. Hydrothermal liquefaction of beech wood using a natural calcium borate mineral [J]. Journal of Supercritical Fluids, 2012, 72: 134-139

[8]	YipJ, ChenM J, SzetoY S, YanS C. Comparative study of liquefaction process and liquefied products from bamboo using different organic solvents [J]. Bioresource Technology, 2009, 100(24): 6674-6678

[9]	AlmaM H, BasturkM A. Liquefaction of grapevine cane (Vitis vinisera L.) waste and its application to phenol-formaldehyde type adhesive [J]. Industry Crops and Products, 2006, 24(2): 171-176

[10]	JuhaidaM F, ParidahM T, HilmiM M, SaraniZ, JalaluddinH, ZakiA R M. Liquefaction of kenaf (Hibiscus cannabinus L.) core for wood laminating adhesive [J]. Bioresource Technology, 2010, 101(4): 1355-1360

[11]	SecaA M, CavaleiroJ A S, DominguesF M J, SilvestreA J D, EvtuguinD, NetoC P. Structural characterization of the lignin from the nodes and internodes of Arundo donax reed [J]. Journal of Agriculture and Food Chemistry, 2000, 48(3): 817-824

[12]	LiuZ-g, ZhangF-shen. Effects of various solvents on the liquefaction of biomass to produce fuels and chemical feedstocks [J]. Energy Conversion & Management, 2008, 49(12): 3498-3504

[13]	FiorentinoN, ImpagliazzoA, VentorinoV, PepeO, PiccoloA, FagnanoM. Biomass accumulation and heavy metal uptake of giant reed on a polluted soil in Southern Italy [J]. Journal of Biotechnology, 2010, 150S: 261

[14]	GuoZ-h, WangF-y, SongJ, XiaoX-y, MiaoX-feng. Leaching and transferring characteristics of arsenic, cadmium, lead and zinc in contaminated soil-giant reed-water system [J]. Journal of Central South University: Science and Technology, 2011, 42(8): 2184-2192

[15]	AngeliniL G, CeccariniL, BonariE. Biomass yield and energy balance of giant reed (Arundo donax L.) cropped in central Italy as related to different management practices [J]. European Journal of Agronomy, 2005, 22(4): 375-389

[16]	IliopoulouE F, AntonakouE V, KarakouliaS A, VasalosI A, LappasA A, TriantafyllidisK S. Catalytic conversion of biomass pyrolysis products by mesoporous materials: Effect of steam stability and acidity of Al-MCM-41 catalysts [J]. Chemistry Engineering Journal, 2007, 134(1/2/3): 51-57

[17]	AysuT, KüçükM M. Liquefaction of giant reed (Arundo donax L.) by supercritical fluid extraction [J]. Fuel, 2013, 103: 758-763

[18]	CarrierM, Loppinet-SeraniA, AbsabonC, MariasF, AymonierC, MenchM. Conversion of fern (Pteris vittata L.) biomass from a phytoremediation trial in sub- and supercritical water conditions [J]. Biomass and Bioenergy, 2011, 35(2): 872-883

[19]	ShatalovA A, PereiraH. High-grade sulfur-free cellulose fibres by pre-hydrolysis and ethanol-alkali delignification of giant reed (Arundo donax L.) stems [J]. Industry Crops and Products, 2013, 43: 623-630

[20]	HassanE M, ShukryN. Polyhydric alcohol liquefaction of some lignocellulosic agricultural residues [J]. Industry Crops and Products, 2008, 27(1): 33-38

[21]	DemirbasA. Mechanism of liquefaction and pyrolysis reactions of biomass [J]. Energy Conversion & Management, 2000, 41(6): 633-646

[22]	TmchyshynM, XuC B. Liquefaction of biomass in hot-pressed water for the production of the phenolic compounds [J]. Bioresource Technology, 2010, 101(7): 2483-2490

[23]	KobayashiM, AsanoT, KajiyamaM, TomitaB. Analysis on residue formation during wood liquefaction with polyhydric alcohol [J]. Journal of Wood Science, 2004, 50(5): 407-414

[24]	WangH, ChenH-zhang. A novel method of utilizing the biomass resource: Rapid liquefaction of wheat straw and preparation of biodegradable polyurethane foam (PUF) [J]. Journal of the Chinese Institute of Chemistry Engineers, 2007, 38(2): 95-102

[25]	YamadaT, OnoH. Rapid liquefaction of lignocellulosic waste by using ethylene carbonate [J]. Bioresource Technology, 1999, 70(1): 61-67

[26]	LiH, YuanX-z, ZengG-m, TongJ-y, YanY, CaoH-t, ChenM-y, ZhangJ-c, YangDan. Liquefaction of rice straw in sub-and supercritical 1,4-dioxane-water mixture [J]. Fuel Processing Technology, 2009, 90(5): 657-663