Feed production is a significant source of greenhouse gas (GHG) emissions from dairy production and demands large arable and pasture acreage. This study analysed how regional conditions influence GHG emissions of dairy feed rations in a life cycle perspective, that is the carbon footprint (CF) and the land area required. Factors assessed included regional climate variations, grass/clover silage nutrient quality, feedstuff availability, crop yield and feed losses. Using the Nordic feed evaluation model NorFor, rations were optimised for different phases of lactation, dry and growing periods for older cows, first calvers and heifers by regional feed advisors and combined to annual herd rations. Feed production data at farm level were based on national statistics and studies. CF estimates followed standards for life cycle assessment and used emissions factors provided by IPCC. The functional unit was ‘feed consumption to produce 1 kg energy corrected milk (ECM) from a cow with annual milk yield of 9 900 kg ECM including replacement animals and feed losses’. Feed ration CF varied from 417 to 531 g CO2 e/kg ECM. Grass/clover silage contributed more than 50% of total GHG emissions. Use of higher quality silage increased ration CF by up to 5% as a result of an additional cut and increased rates of synthetic N-fertiliser. Domestically produced horse bean (Vicia faba), by-products from the sugar industry and maize silage were included in the rations with the lowest CF, but horse bean significantly increased ration land requirement. Rations required between 1.4 to 2 m2 cropland and 0.1 to 0.2 m2/kg semi-natural grassland per kg ECM and year. Higher yield levels reduced ration total CF. Inclusion of GHG emissions from land use change associated with Brazilian soya feed significantly increased ration CF. Ration CF and land use depended on ration composition, which was highly influenced by the regional availability and production of feedstuffs. The impact of individual feedstuffs on ration CF varies due to, for example, cultivation practices and climate conditions and feedstuffs should therefore be assessed in a ration and regional perspective before being used to decrease milk CF. Land use efficiency should be considered together with ration CF, as these can generate goal conflicts.
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机译:饲料生产是乳制品生产温室气体(GHG)排放的重要来源,需要大的耕作和牧场面积。本研究分析了区域条件如何影响生命周期的乳制品饲料口粮的温室气体排放,即碳足迹(CF)和所需的土地面积。评估因素包括区域气候变化,草/三叶草青贮营养质量,饲料可用性,作物产量和饲料损失。使用Nordic Feed评估模型诺威尔士,通过区域饲料顾问的较旧奶牛,第一个卡维尔和小母牛的不同阶段进行了优化了口粮,并将区域饲料顾问合并为年度畜群口粮。农业水平的饲料生产数据基于国家统计和研究。 CF估计遵循终身循环评估标准和IPCC提供的排放因子。功能单位是从母牛生产1公斤能量矫正牛奶(ECM)的饲料消耗,每年牛奶产量为9 900公斤ECM,包括替代动物和饲料损失。饲料配给CF从417变化到531g CO2 E / kg ECM。草/三叶草青贮饲养总温室气体排放量的50%以上。由于合成N-肥料的额外切割和提高,使用更高质量的青贮饲料越来越高达5%的比例增加了5%。国内生产的马豆(Vicia Faba),来自糖业和玉米青贮饲料的副产品被包含在CF最低的口粮中,但马豆的原价明显增加。每公斤ECM和年份需要1.4至2平方米的农田和0.1至0.2平方米/千克半天然草地。屈服水平较高降低总共CF.将GHG排放与巴西大豆饲料相关的土地利用变化含量显着提高了比例。配给CF和土地使用依赖于配给组合物,这受到区域可用性和生产的高度影响。各种饲料对比率Cf的影响因,例如,应在用于减少牛奶之前以分配和区域角度评估培养实践和气候条件和饲料。土地利用效率应与口粮CF一起考虑,因为这些可能会产生目标冲突。
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