Abstract
A life cycle assessment (LCA) approach was used to examine the greenhouse gas (GHG) emissions and energy balance of short rotation coppice (SRC) willow for heat production. The modelled supply chain includes cutting multiplication, site establishment, maintenance, harvesting, storage, transport and combustion. The relative impacts of dry matter losses and methane emissions from chip storage were examined from a LCA perspective, comparing the GHG emissions from the SRC supply chain with those of natural gas for heat generation. The results show that SRC generally provides very high GHG emission savings of over 90 %. The LCA model estimates that a 1, 10 and 20 % loss of dry matter during storage causes a 1, 6 and 11 % increase in GHG emissions per MWh. The GHG emission results are extremely sensitive to emissions of methane from the wood chip stack: If 1 % of the carbon within the stack undergoes anaerobic decomposition to methane, then the GHG emissions per MWh are tripled. There are some uncertainties in the LCA results, regarding the true formation of methane in wood chip stacks, non-CO2 emissions from combustion, N2O emissions from leaf fall and the extent of carbon sequestered under the crop, and these all contribute a large proportion of the life cycle GHG emissions from cultivation of the crop.
Highlights
With the implementation of the Renewable Energy Directive (RED), there has been significant growth in the uptake of renewable energy in Europe [1]
The life cycle assessment (LCA) study calculates a total gross greenhouse gas (GHG) emission of 27.3 kg CO2 eq./MWh generated from short rotation coppice (SRC) willow chips or 6.8 g CO2 eq./MJ in biomass, excluding carbon sequestration, assuming zero dry matter losses, and excluding any potential GHG emissions from storage
The results of this study suggest that the use of SRC for heat or power causes the release of far fewer GHG emissions per MWh than natural gas
Summary
With the implementation of the Renewable Energy Directive (RED), there has been significant growth in the uptake of renewable energy in Europe [1]. Renewable sources currently provide 14.1 % of the European (EU28) energy supply [2], the overarching target is to generate 20 % by 2020 [3]. Biomass could contribute up to two thirds of the target [4]: equivalent to approximately 124 million tonne of oil equivalent (Mtoe) [5]. By 2020, a total of 19.3 million ha of agricultural land could be diverted to dedicated bioenergy production to provide 100 Mtoe of energy, while complying with good agricultural practice and without significantly affecting domestic food production [6, 7]. A strong forestry sector and competitive pricing has meant that Europe has been the prime market for energy-related biomass trade, for wood chips and pellets [8]
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