Mass timber has captured the imaginations of architects and builders. Supporters argue that mass timber can replace steel and concrete in construction, reducing carbon pollution from those sectors. In addition, mass timber can use smaller diameter logs, potentially creating a market for products from forest restoration and fuel-load reduction harvests. Yet to achieve these worthy objectives, wood for mass timber must come from responsibly managed forests. Without explicit efforts focused on sourcing, there is no assurance that conventional forest products will yield climate-smart mass timber.
Mass timber refers to buildings where “the load-bearing structure is made of either solid wood or engineered wood,” according to Andrew Tsay Jacobs, director of the Building Technology Lab at Perkins + Will. Cross-laminated timber (CLT), glued-laminated timber (glu-lams), dowel-laminated timber (DLT), and nail-laminated timber (NLT) can all bear structural loads in a building, meaning they are all mass timber products.
By replacing structural steel and concrete, the argument goes, mass timber can reduce carbon emissions from construction materials. 5 percent of global greenhouse gas emissions come from concrete manufacturing and another 5 percent comes from steel. Yet recent research by engineering firm Arup in “The New Carbon Architecture,” found that “the final life cycle emissions of the timber design could arrive very close to the final emissions of the concrete design option if both worst-case sourcing and worst-case transport scenarios were realized.” In other words, mass timber can be a climate solution as long as the wood is sourced from a local, responsibly managed forest.
What does climate-smart forestry look like? Recent research by Ecotrust and the University of Washington suggest an answer: “FSC certification is a good surrogate for ensuring additional carbon storage” in forests. This makes sense, as application of FSC’s Forest Management Standard tends to extend rotation lengths, increase buffer widths around waterways, reduce opening sizes (resulting in more soil moisture in the forest) and restrict carbon-intensive chemical use. All of these factors, and others, shape the carbon benefits of FSC-certified forests.
What does this look like on the ground, or actually from the air? FSC recently flew a drone over forests in Oregon to see the differences between FSC and conventional practices. The resulting video is designed to show people what the differences look like.
Of course, no two forests are identical. Yet FSC is widely recognized as the world’s most trusted forest certification exactly because of the differences it requires on the ground. And these differences are not only good for carbon storage, they also benefit wildlife, water quality and local communities.
How can you find FSC certified mass timber? Easy, just visit the FSC Wood Finder, which was developed collaboratively with our partners at Northwest Natural Resource Group. Part of an Eco-Friendly Builder’s Guide, the FSC Wood Finder is quickly developing into a powerful tool to help architects, engineers and builders specify and source FSC-certified products. If you want to add your FSC-certified company into the FSC Wood Finder, simply complete this questionnaire for vendors of FSC-certified wood products.
Over the coming year, FSC will be investing significantly in continued development and marketing of the FSC Wood Finder, so don’t miss the opportunity to drive sales and inquiries.
In March 2019, FSC will be organizing a launch event for the Climate-Smart Wood Group with Ecotrust, Sustainable Northwest, Northwest Natural Resource Group, and Washington Environmental Council, alongside the Mass Timber Conference in Portland, OR. If you are interested in participating or learning more, please email Brad Kahn (email@example.com).