Making the case for responsible use of timber
作者
Simon Wyatt
查看个人简介Originally published in Building Magazine in September 2021.
There is lots of conflicting talk around timber in the construction industry, with many declaring it as a panacea, an all-encompassing solution to the net zero carbon challenges we face. But is it? In an ideal world where we have abundant supplies of sustainable resourced timber from well-managed forests then, yes. But in the real world, it is much more complicated and sadly there is no silver bullet when it comes to the climate emergency.
Over the course of this Countdown to COP26 series, I have explored many of the challenges and possible solutions we have when it comes to decarbonising the built environment. As COP26 draws ever closer, the debate around the use of timber as a net zero solution is heating up.
The main benefits of using timber are well known; trees are a renewable, natural resource and they absorb carbon when they grow. This is referred to as ‘carbon sequestration’, which is the process by which carbon dioxide is removed from the atmosphere and incorporated as ‘biogenic carbon’ in ‘biomass’ through photosynthesis and other processes associated with the carbon cycle. However, accounting for sequestered carbon is often a source of debate, confusion and inconsistency.
In simple terms, growing trees and locking away carbon in timber buildings can provide significant carbon sinks. But would it be better to leave forests to grow naturally? Do we have time to plant new forests? The recent report from the Intergovernmental Panel on Climate Change (IPCC) indicates that the climate emergency is happening now and that we are at code red, meaning we need low-carbon solutions that have an immediate impact. When we look at timber sequestration, we can see that this lag can take years or even decades to be realised. So, should we really be cutting down any trees in a climate emergency? Shouldn’t we be planting as many as we can?
This however is more complicated when we consider land scarcity and the variation in sequestration rates based on a trees maturity. Carbon uptake in newly planted saplings is initially slow, but then accelerates as these become established. In an unmanaged forest, sequestration continues until the total carbon eventually tends towards a steady state meaning that the greatest sequestration occurs when a tree is in its young growing stage.
A managed forest can therefore achieve similar or even greater carbon storage than an unmanaged forest between harvesting cycles. But the greatest benefits come from the carbon storage in the products produced from it. If these are amassed sufficiently over time, then the total carbon sequestered accumulates and could eventually be greater than that of an unmanaged forest assuming that the timber is used for a significant period to allow for its replacements to sequester enough carbon to offset its production. The question is then what happens to it at the end of its life. Will it be sent to landfill or combusted? If so, then the carbon released in the process will undo most of the gains. Key to this is that all timber is grown in sustainably managed forests which replace felled trees with an equal or greater number of new trees than are cut down.
Updated guidance from London Energy Transformation Initiative (LETI), the Whole Life Carbon network (WLCN), the Royal Institute of British Architects (RIBA) and the Institution of Structural Engineers (IStructE) advises that sequestration should only be aggregated with emissions when end-of-life values are also included, and where the stored carbon is typically cancelled out by re-emission at the end of life.
Carbon accounting for timber should therefore not start at negative. This means that credit should not be taken for a tree planted 50 years ago, even if this eventually ends up being used to construct a building. The benefit should be taken during its use. Where trees are harvested and not replaced (deforestation), no sequestration should be accounted for, which is in line with current European standards.
Without sequestration, timber buildings still typically have lower carbon footprints than traditional steel or concrete structures. However, where high levels of cement replacements or recycled steel are used, then the numbers can be very close. This is due to the production emissions for timber products, from harvesting, drying and sawing, which can be significant.
Steel and timber are framed as direct alternatives but it’s not a straight decision. It also depends on the relative quantities required – the aim is the lowest overall impact for the building, not the lowest carbon material.
But what is clear is that if we are simply looking at upfront embodied carbon which affects carbon emissions right now and not in the future, then retrofit projects which reuse significant parts of an existing structure are almost always the best option, despite some projects claiming the sequestration benefits to justify demolition and new build. Additionally, as re-purposed steel and material passports start to become the norm, then steel has the potential to be significantly lower for the upfront embodied carbon as well as for the end of life, because it can form part of a circular economy.
If all things are equal, i.e., carbon neutral, then the question is what is more recyclable and reusable, steel or timber? Steel can be more easily re-used, repurposed and even melted down and reshaped, whereas timber is a lot more difficult to reuse so if we are looking at it from a circular economy point of view, steel makes more sense.
There is also the fire concern around timber safety, which can be addressed through the right approaches, but the embodied carbon of the whole solution (fire-proofing materials) must be considered in addition.
So timber isn’t a silver bullet. Don’t get me wrong, in most new build cases it is a great solution assuming that the timber is used efficiently and is sustainably sourced. But as sustainably sourced timber is currently limited, we must use it wisely on buildings where it can be locked away for long periods of 60 years plus or even over 100 years. It should not be used in short life structures such as in retail, or in short life products, such as a fuel source in power stations, as a way of playing accounting games with grid emission rates. Timber currently is a finite resource and should be treated as one – over consumption should not be encouraged.
The timber solution of sustainable forestry is potentially a panacea, but we are talking about a supply chain system that will take decades. Is that too late? Given the urgency of the climate emergency, the answer is yes. We need to look at a raft of measures and these will evolve over time, but they should always start with the idea of ‘retrofit first’.
Low Embodied Carbon Design Hierarchy:1) Rationalise and re-use existing buildings2) Retrofit and repurpose existing buildings3) Repurpose and recycle materials using circular economy and whole life carbon principles4) Prioritise natural low material, whilst considering material efficiency5) Design for flexibility and durability to ensure carbon sinks are long life6) Consider end of life, prioritise circular economy principles
- Rationalise and re-use existing buildings
- Retrofit and repurpose existing buildings
- Repurpose and recycle materials using circular economy and whole life carbon principles
- Prioritise natural low material, whilst considering material efficiency
- Design for flexibility and durability to ensure carbon sinks are long life
- Consider end of life, prioritise circular economy principles