Effects of internal factors on surface wettability of corn stalk rind
DOI:
https://doi.org/10.25165/ijabe.v8i6.1996Keywords:
corn stalk rind, wettability, surface contact angle, element analysis, chemical compositions, mechanismAbstract
Corn stalk is one of heterogeneous materials with anisotropy and variability. As the rind of corn stalk consists of rich lignin and cellulose similar to wood properties, and possessing high mechanical strength, then can be used as raw material of stalk artificial board and paper. The corn stalk rind has significant differences in fiber morphology, chemical composition and mechanical properties at different heights. Nano-SiO2 composite material contained in the epidermis of corn stalk rind is not conducive to exert adhesive into a board. To study board-making technology by intact corn stalk rind, the wettability of corn stalk rind at different sampling heights is necessary to be analyzed by keeping or removing the epidermis. To analyze the surface wettability difference, the contact angle with water, element compositions and the chemical compositions of corn stalk rind at different sampling heights were studied before and after removal of epidermis. A Fourier transform infrared (FTIR) analysis was performed. The results showed that the removal of the epidermis could significantly improve the hydrophilicity of corn stalk rind. Before removal of the epidermis, the varying contents of elements including C and Si dominate the surface wettability differences at different sampling heights of corn stalk. With an increase in the sampling height, the mass fraction of C increases while that of Si decreases, which result in increasing hydrophilicity. After removal of the epidermis, the surface wettability of corn stalk rind is mainly determined by the mass fraction of hemicellulose, and the higher the sampling height, the larger the mass fraction of hemicellulose resulting in the increase of hydrophilicity. Keywords: corn stalk rind, wettability, surface contact angle, element analysis, chemical compositions, mechanism DOI: 10.3965/j.ijabe.20150806.1996 Citation: He X, Wang D F. Effects of internal factors on surface wettability of corn stalk rind. Int J Agric & Biol Eng, 2015; 8(6): 77-83.References
Hafezi S M, Hosseini K D. Surface characteristics and physical properties of wheat straw particleboard with UF resin. Journal of Forestry Research, 2014; 25(3): 667–670.
Zhang F, Wu N, Tong J, Zhou J, Yang X, Ma Y H, et al. Preparation and flexural properties of biomimetic laminated boards made from starch and maize straw fibers. Int J Agric & Biol Eng, 2009; 2(2): 24–31.
Wang D F, Yu K Q, Chen Z G. Optimized test of running parameter on rind-pith separation equipment for corn stalk. Transactions of the CSAE, 2013; 29(21): 26–32. (in Chinese with English abstract)
Sunday E. Etuk, Louis E. Akpabio, Ita O. Akpan. Comparative Study of thermal transport in Zea Mays Straw and Zea Mays Heartwood (cork) Boards. Thermal Science, 2010; 14(1): 31–38.
Wang L, Liu R H, Sun C, Cai W F, Tao Y W, Yin R Z, et al. Classification and comparison of physical and chemical properties of corn stalk from three regions in China. Int J Agric & Biol Eng, 2014; 7(6): 98–106.
Lu J, Zhang X Q, Zhang H J. Production technology for corn stalk bark composite with modified lsocyanate resin. Journal of Northeast Forestry University, 2012; 40(7): 142–144. (in Chinese with English abstract)
Pan, M Z, Zhou, D G, Zhou, X Y, Lian Z N. Improvement of straw surface characteristics via thermomechanical and chemical treatments. Bioresource Technology, 2010; 101(20): 7930–7934.
He J C, Zhou Z F, Wang H D. Modification effect study on wettability of corn stalks and bonding performance of adhesive. Forestry Science & Technology, 2014; 39(5): 27–29. (in Chinese with English abstract)
Han G P, Deng J, Zhang S Y, Bicho Paul, Wu Q L. Effect of steam explosion treatment on characteristics of wheat straw. Industrial Crops and Products, 2010; 31(1): 28–33.
Yang X H, Zhang R, Tang L J, Chen M Z, Li Y, Zhou X Y. Dynamic wettability of different adhesives on wheat straw surface modified by cold oxygen plasma treatment. Bioresources, 2014; 9(1): 1578–1587.
Zhou X Y, Zhou D G, Shi D J. Effect of microwave treatment on the surface characteristic of rice straw. China Forest Products Industry, 2005; 32(5): 28–30, 42. (in Chinese with English abstract)
Zhang L, Hu Y C. Novel lignocellulosic hybrid particleboard composites made from rice straws and coir fibers. Materials and Design, 2014; 55: 19–26.
Shen J H, Liu Z M, Li J, Niu J. Wettability changes of wheat straw treated with chemicals and enzymes. Journal of Forestry Research, 2011; 22(1): 107–110.
Mao H Y, Zhou D G, Wang S G, Yang R. Surface characteristic of wheat straw treated with plasma. Advanced Materials Research, 2011; 295–297: 1639–1642.
Wen M Y, Shi J Y, Park H J. Dynamic wettability and curing characteristics of liquefied bark-modified phenol formaldehyde resin (BPF) on rice straw surfaces. Journal of Wood Science, 2013; 59(3): 262–268.
Chen Z G, Wang D F, Li L Q, Shan R X. Experiment on tensile and shearing characteristics of rind of corn stalk. Transactions of the CSAE, 2012; 28(21): 59–65. (in Chinese with English abstract)
He X, Wang D F. Tensile property of corn stalk rind based on analysis of fiber morphology. Transactions of the CSAE, 2015; 31(10): 92–98. (in Chinese with English abstract)
Song H Z, Zheng L W. Nan composite films based on cellulose reinforced with nano-SiO2: Microstructure, hydrophobicity, thermal stability, and mechanical properties. Cellulose, 2013; 20(4): 1737–1746.
Gorecka D, Dziedzic K, Hes M. A characteristic of dietary fiber in barley and buckwheat groats and its bile acid binding capacity. Italian Journal of Food Science, 2014; 26(1): 103–108.
Jiang H, Zhang Y, Wang X F. Effect of lipases on the surface properties of wheat straw. Industrial Crops and Products, 2009; 30(2): 304–310.
Faix O. Classification of lignins from different botanical origins by FT-IR spectroscopy. Holzforschung, 1991; 45(Supp l): 21–27.
Herbette S, Bouchet B, Brunel N, Bonnin E, Cochard H, Guillon F. Immunolabelling of intervessel pits for polysaccharides and lignin helps in understanding their hydraulic properties in Populus tremula x alba. Annals of Botany, 2015; 115(2): 189–199.
Wolfgang G. Comparing mechanical properties of normal and compression wood in Norway Spruce: The role of lignin in compression parallel to the grain. Holzforschung, 2002; 56: 395–401.
Sun Y H, Yang X D, Yang Z J, Wang Q C, Men Y Z. Difference in wettability of lotus leaves in typical states and its mechanism analysis. Transactions of the CSAE, 2014; 30(13): 263–267. (in Chinese with English abstract)
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