Build buildings out of wood -> Plant more trees -> build more buildings out of wood -> plant more trees, etc. This can sequester a lot of carbon over time, especially if said wood buildings are in places trees can't easily grow.
> Structures composed of wood do not remove carbon dioxide from the atmosphere.
Why not? Just some napkin math here but:
Say you have three 10K kg trees. Wood is ~50% carbon, so that means they collectively contain around 15K kg of carbon. Cut them down and turn them into framing lumber and build a house. You now have a house frame with roughly 15K kg of carbon.
Now plant 3 trees where the old ones were. Once grown you have now collectively sequestered 30K kg of carbon - half of it is in the trees themselves, half in the house.
Keep doing that. After a decade you now you have 1000 houses that have each sequestered 15K kg of carbon from the atmosphere, or 15M kg of carbon.
> > Structures composed of wood do not remove carbon dioxide from the atmosphere.
Why not?
> Why not?
On average, does wood in structures release carbon through decay, fire, etc., faster or slower than if the wood was left in a living tree? Intuitively, I don't see any reason to expect effective sequestration.
Your analysis seems to suppose that if wood was not used to make a structure, the trees would instantly release their carbon and not be replaced, rather than continuing to grow.
> On average, does wood in structures release carbon through decay, fire, etc., faster or slower than if the wood was left in a living tree?
Trees don't grow at the same rate forever. They sprout up quickly and rapidly sequester carbon until they reach maturity, at which point there are diminishing returns in terms of carbon sequestration.
Treated wood is much more resistant to decay and fire than untreated wood.
> Your analysis seems to suppose that if wood was not used to make a structure, the trees would instantly release their carbon and not be replaced, rather than continuing to grow.
No, I'm saying that a mature tree sequesters carbon much more slowly than growing trees. Think about it. It's the same for animals. Babies grow like crazy and gain mass at an amazing rate. Adults... don't. I've been 150 lbs for the past 10 years. My son, however, was 6 lbs 2 years ago, 20 lbs last year, and 40 lbs this year. That means his body is locking away 20 lbs worth of matter per year.
Take a mature tree, turn it in to a building. Grow another mature tree in its spot and you've now sequestered effectively twice as much as having never turned the tree into a building. That's what I'm suggesting.
> Take a mature tree, turn it in to a building. Grow another mature tree in its spot and you've now sequestered effectively twice as much as having never turned the tree into a building.
It takes several (in many cases 5+) decades for a tree to mature (in the sense of growth levelling off.) The average proportion of original wood building remaining after 50 years is, well, less than 100%.
Probably significantly, more than if the old tree died and fell, so you could have some net gain, but it's not going to be 100%. (And its going to be even less if you are clearing land for the building.)
1. Forests reach their maximum level of carbon sequestration after around 70 years. After this point, they are no longer a net carbon sink.
2. If you periodically cut down the trees, turn the wood into long-lived products (like buildings), and then replant, you can sequester more carbon.
3. Exactly how much more depends on assumptions about the length of the useful life of a building and what is done with the wood after the building reaches the end of its useful life.
4. If you're looking at net carbon emissions, you also need to consider substitution -- by using wood in a building, you're decreasing the need for other building materials like concrete and steel, which emit a lot of CO2 in their production. They model various scenarios on the paper.