Energy balances and greenhouse gas-mitigation potentials of bioenergy cropping systems (Miscanthus, rapeseed, and maize) based on farming conditions in Western Germany

详细信息   

• 作者：Daniel Feltena ; daniel.felten@uni-trier.de ; Norbert Frö ; bab ; n.froeba@ktbl.de ; Jé ; r&ocirc ; me Friesa ; Christoph Emmerlinga ; emmerling@uni-trier.de
• 关键词：Life cycle assessment (LCA) ; CO2-neutral ; C-sequestration ; Sustainability ; Energy efficiency ; GHG
• 刊名：Renewable Energy
• 年：2013
• 期：Complete
• 来源：Elsevier
• 类型：期刊

摘要

Biomass for bioenergy is an important option within global change mitigation policies. The present research focused on energy net production, net reduction of greenhouse gases (GHG) (considered as CO2-equivalents), and energy output:input ratio of the energy cropping systems ¡®rapeseed¡¯, ¡®maize¡¯, and ¡®Miscanthus¡¯. The system-specific main products were biodiesel (rapeseed), electricity from biogas (maize), and Miscanthus chips (loose, chopped material); the related substituted fossil resources were diesel fuel (rapeseed), electricity from the German energy mix (maize), and heating oil (Miscanthus). However, research did not aim for a direct quantitative comparison of the crops. The study followed a case study approach with averaged data from commercial farms within an enclosed agricultural area (<5?km2) in Western Germany. Cultivation techniques were considered as communicated by farmers and operation managers; the diesel fuel consumption of agricultural machinery was modeled using an online-based calculator of the German Association for Technology and Structures in Agriculture (KTBL). Overall, rounded net energy production amounted to 66?GJ?ha?1 (rapeseed), 91?GJ?ha?1 (maize), and 254?GJ?ha?1?yr?1 (Miscanthus); the related energy output:input ratios were 4.7 (rapeseed), 5.5 (maize), and 47.3 (Miscanthus), respectively. Compared to the respective fossil fuel-related energy supply, CO2-equivalent reduction potential ranged between 30 and 76 % for electrical energy from maize biomass, 29-82 % for biodiesel from rapeseed, and 96-117 % for Miscanthus chips, depending on whether or not the accruing by-products rapeseed cake, glycerin (rapeseed cropping system), and waste heat (maize) were considered. True ¡®CO2-neutrality¡¯ was only reached by the Miscanthus cropping system and was related to an additional credit from carbon sequestration in soil during the cultivation period; thus, this cropping system could be attributed to be a CO2-sink.The study indicated that bioenergy can be produced sustainably under commercial farming conditions in terms of a significantly reduced consumption of natural resources.