Livestock feeding and biogas production consume large amounts of silage. However, the gas emission of silage respiration during feed-out remains poorly characterized. This information may be directly applicable to assessment of silage degeneration and to determination of its detrimental impacts on environmental quality. Here a fundamental and comprehensive study is proposed focusing on both issues, oxidative rate/energy loss and greenhouse and precursor gas emissions, using two novel, automated multi–sensor systems to capture and decompose the signals of gas emission from silage. Two common types of silage management, bunker silos of maize silage and round bales of ryegrass, alfalfa and maize, will be assessed in situ. The positive or negative effect of chemical and biological additives on gas emission from silage will also be investigated. Digital signal processing will be used to partition CO2 into two pools, one accumulated in the silage during previous anaerobic phases and one produced real-time after opening of the silage. The formal part/pool is a noise signal and the latter part/pool, resulted from the aerobic respiration of microorganism, directly reflects the oxidative rate/energy loss of the feed-out silage. Using these novel data, we will update/extend the commonly used Pitt-Muck model to simulate CO2 flux from the open face of a bunker silo, and use a data-model fusion approach to compare and reconcile the in situ measurements from on-farm experiments with the numerical results.

DFG Programme Research Grants