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- A general framework for including biogenic carbon emissions . . .
In this paper, I present a straightforward approach for accounting for the biogenic carbon emissions and removals, to be applied in LCA models for forestry products
- Scoping Elements for Biogenic Carbon in Life Cycle Assessment
Life Cycle Assessment (LCA) is one method to measure the carbon-derived greenhouse gas balance of bio-based production routes, alongside any other environmental impacts
- Analysis of the Global Warming Potential of Biogenic CO2 . . .
In addition, most of the life cycle assessment (LCA) studies conducted on bioenergy systems also claim that CO 2 emission from biomass has no global warming potential (GWP)
- Comparative analyses of different biogenic CO2 emission . . .
To analyze the climate change impact of biomass utilization, life cycle assessment (LCA) is a widely used tool It was first proposed in 1970 (Hunt and Franklin, 1996) and fully developed in the early 1990s (Boustead, 1996) The LCA studies have been conducted on many different bioenergy products
- Differentiating Biogenic Non-Biogenic Emissions - Cool Farm
The challenges associated with compensating biogenic removals with non-biogenic emissions highlight the need for cautious, well-informed strategies to balance or offset our carbon footprint
- Best Practices for Life Cycle Assessment (LCA) of Biomass . . .
System Boundaries, Life Cycle Stages, and Associated Unique Issues of A Conceptual BiCRS Technology Cradle-To-Grave Is Signified by A Red Box, Encompassing Life Cycle Stages 1–4; Cradle-To-Gate Is Signified by A Blue Box, Encompassing Life Cycle Stages 1 and 2; and Gate-To-Gate Is Figure 4
- Analysis of the Global Warming Potential of Biogenic CO2 . . .
Without considering biogenic CO 2 emission, the life cycle GHG emissions of the five cases closely resembled previous studies 34,35,36,37,38,39 The production of pellet fuel had the lowest GHG emissions because of the high energy conversion efficiency and low energy consumption
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