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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 860-863Marginal Land-Based Biomass Energy Production in...

Marginal Land-Based Biomass Energy Production in Yellow River Delta

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Abstract:

Energy crops are not only the key to the development of biomass energy, but also canpromote the improvement of saline and other marginal land and mprove the utilization efficiency.The rural biomass energy utilization status and characteristics of different energy crops and researchstatus in Yellow River Delta was introduced; Castor, switchgrass and sweet sorghum grown inmarginal land feasibility are discussed; Finally, the several suggestions of to promote biomassenergy and local marginal land development have been proposed.

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Periodical:

Advanced Materials Research (Volumes 860-863)

Pages:

544-549

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.860-863.544

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Online since:

December 2013

Authors:

Cong Wen Wu, Xiao Bing Chen, Yun Peng Sun, Ming Liang Jiang, Kun Yan, Li Hua Zhang

Keywords:

Biomass Energy, Energy Crops, Marginal Land, Saline, Yellow River Delta

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© 2014 Trans Tech Publications Ltd. All Rights Reserved

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[1] Guan YX, Liu GH, Wang JF (2001) Regionalization of Salt-affected Land for Amelioration in the Yellow River Delta Based on GIS. Acta Geographica Sinica, 56(2): 198-205(in Chinese).

[2] Wang O (2007) The utilization status and policy and future trends of bioenergy and biomass utilization in China. Chinese Rural Economy, 7: 10-15(in Chinese).

[3] Wang LC, Liu Y, Du FG (2009) Actuality and prospect of biomass energy in China. Henan Chemicals Industry 9: 15-19(in Chinese).

[4] Shen XL (2011) Impact factor in the development of biomass energy analysis. Journal of Southwest Petroleum University(Social Sciences Edition), 4(001): 75-80(in Chinese).

[5] Xinhuanet (2011) The People's Republic of China the twelfth five-year plan for national biomass energy development program [DB/OL]. http: /www. china. com. cn/, 2011-03-16 (in Chinese).

[6] Yu HL (2008) The problem of development of biomass energy in Heilongjiang province. Economic Research Guide, 03: 114-117(in Chinese).

[7] Xiong FL, Zhu HG, Shi HR (2011) Analysis on the price of the biogas for rural centralized biogas plant. China Biogas, 29(4): 16-19(in Chinese).

[8] Pan ZQ, Liu GH, Zhou CH (2003) The crop distribution of Yellow River Delta using remote sensing method. Geographical Research, 22(6): 799-807(in Chinese).

[9] Wan TP, Qi Y (2013) Tianjin rural biogas biomass energy development overview. Renewable Energy Resources, 03: 125-128(in Chinese).

[10] Statistical yearbook of shandong province in 2012[M]. Beijing: China statistics press(in Chinese).

[11] Li JJ, Ren DM, Zhuang X (2001) Systemic evaluation method of renewable energy resources and its practical application. Journal of Natural Resources, 16(4): 373-380(in Chinese).

[12] Bassam NE. (1998) Energy Plant Species, Their use and impact on environment and development [M]. James and James(SciencePublishers)Ltd. London.

[13] Li J, Wu PZ, Li MR (2007) Development of Energy Plant: Progress and Suggestions. Chinese Journal of Nature, 01: 21-25(in Chinese).

[14] Zhang H, Chen RK (2002) Research and development of our country's energy sugarcane. Sugacane, 04: 33-35(in Chinese).

[15] Fei SM, Zhang XD, Yang GY. (2005)On domestic and international situation of energy plant resources and their exploitation. Journal of Sichuan Forestry Science and Technology, 03: 20-26(in Chinese).

[16] Li S, Yang PZ, Yang GY (2003) Practical significance of study the development of energy sugarcane production. Guangxi Sugarcane & Canesugar, 03: 44-45(in Chinese).

[17] Wu GJ, Liu J, Lou ZP (2006) Development of energy plant: Progress and suggestions, Bulletin of Chinese Academy of Sciences, 21(1): 53-57(in Chinese).

[18] Fei SM, Chen XP, He YP (2006) Prospects of studies on jatropha curcas biodiesel in Sichuan. Biomass Chemical Engineering, 40: 193-199(in Chinese).

[19] Cheng X (2013) Grasses as biofuel play a significant role for biomass energy in future. Acta Prataculturae Sinica, (1): 27-29(in Chinese).

[20] Samac D A（2006）Development of alfalfa as a feedstock for production of ethanol and other bio-products[A]. Shelley Minteer, Alco-holic Fuel[M]. Taylor & Francis.

[21] Pande, M.,A.N. Bhaskarwar. (2012) Biomass conversion to energy, in Biomass Conversion[M]. Springer Berlin Heidelberg. 1-90.

DOI: 10.1007/978-3-642-28418-2_1

[22] Thurmond W (2012)Algae 2020: biofuels Markets, business models, strategies, players and commercialization outlook, 2012–(2020).

[23] Pulz, O.,W. Gross. (2004)Valuable products from biotechnology of microalgae. Applied Microbiology and Biotechnology, 65(6): 635-648.

DOI: 10.1007/s00253-004-1647-x

[24] Pienkos PT, Darzins A. (2009) The promise and challenges of micro-algal derived biofuel. Biofuel Bioproducts Biorefin. (3): 431–440.

[25] Venturi P, Venturi G（2003） Analysis of energy comparison for crops in European agricultural systems. Biomass and Bioenergy, 25(3): 235~255.

DOI: 10.1016/s0961-9534(03)00015-1

[26] Yu CY (1985)Determination of Ricinus communis seedling emergence and seedling stage. Shandong Agricultural Sciences, 3: 15-17(in Chinese).

[27] Wang JM, Ruan CJ, Huang MY (2011) Preliminary study of salt-tolerant of castor. Journal of Henan Agricultural Sciences, 40(5): 67-73(in Chinese).

[28] Zhang HJ, Zhao HY (2010) Amelioration effects of ricinus communis to salinized soil. Soil and Water Conservation in China, (007): 43-44(in Chinese).

[29] Li GY, Li JL, Wang Y (2008) Research progress on the clean bio-energy production from high yield Panicum virgatum. Pratacultural Science, 25(5): 15-21(in Chinese).

[30] Fan XF, Hou XC, Zhu Y (2012) Impacts of salt stress on the growth and physiological characteristics of Panicum virgatum seedlings. Chinese Journal of Applied Ecology, 23(6): 1476-1480(in Chinese).

[31] Cong QY, Zhang H, Yang GY (2011) Salt-tolerance in different varieties of Sweet sorghum seeding. Chinese Agricultural Science Bulletin, 26(19): 128-135(in Chinese).

[32] Gao SJ, Liu XH, Li YF (2006) Sweet sorghum resources and its utilization in China. Rain Fed Crops, 26(4): 273-274(in Chinese).