Fuel treatment effects on forest carbon and wildfire

Malcolm North, Sierra Nevada Research Center, mpnorth@ucdavis.edu

Wildfires: A Large Source of Emissions

(Wiedinmyer and Neff 2007)

By one estimate annual forest growth can offset 6-10% of anthropogenic CO2

But these gains can be offset by emissions in fire-prone forests

Premises:

•In California’s fire-dependent forests, significant C can be released during wildfire

•The amount of that release increases with fire severity and size

•General objective: If possible increase C storage, reduce the risk of C loss due to wildfire and in the process minimize C emissions

•Forests need to be managed for more than just carbon sequestration

•Fortunately, forest restoration and C management share a common long-term objective: Redirect ecosystem C away from unstable (the growth of numerous, small trees) to stable pools ( the growth of fewer, large-size trees which are fire-resistance [i.e., pines])

•The question is how to get there and what are the tradeoffs between different means to that end

Removed Tree Size (dbh)

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C.StorageC.EmissionsFire.Sev..ReductionTree C Sequest RateEcosystem.Restoration

Conceptual Model of Tradeoffs in Fire-Dependent ForestsE

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* If Ladder AND Surface fuels are removed

What we know:The general shape of these curves

What we don’t know:The slope and inflection pointsHow these vary by forest type, productivity, etc.

Desired direction

‘Risk’High Low

‘Benefits’Present Future

Total Live Tree Carbon Stocks: 1865: 346 Mg C/ha Current Forest: 249 Mg C/ha

Potential for Increasing Forest C StorageLess carbon in modern fire-suppressed forests than active-fire (1865) forests due to loss of large trees

The plus is forests have potential to sequester a lot more carbon

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Model estimate of wildfire emission is 38 Mg C/ha

Bonnicksen estimated 156 Mg C/ha average for CA wildfires (FCEM Report #2)

A forest structure (1865) of a low density of large pines has lowest wildfire and prescribed fire emissions

Untreated

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1865

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Live tree C and diameter distribution by species before and after 6 treatments

Desired: higher C stocks, greater density and a higher % of pine in the large dbh classes

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Summary: What we may know and what we clearly don’t know

Fuels treatments: • Reducing ladder AND surface fuels reduces fire severity.

• Reducing surface fuels is key to restoring many ecosystem processes

• Thinning overstory trees (reducing crown bulk density) has a limited effect on reducing fire severity.

• Simulations (field data is absent) suggest treating 20-30% of a landscape can significantly reduce fire severity and extent

• Don’t know: How long fuel treatments remain effective

• How treatments affect residual tree growth (rate of C sequestration)

• When reducing crown fire risk, how resistant should the forest be made? (i.e. what percentile weather conditions should be targeted? Impacts of climate change?)

Carbon Dynamics:• Within the limits of current measurements: 60-70% of ecosystem C is above ground, with about 80% of that in live trees.

• In uncut forests, trees 5-25 cm dbh and 25-50 cm generally will contain about 5% and 15-20%, respectively of total live tree C.

• Fuels treatments reduce forest C, losses increase exponentially with tree size

• In most fuels treatments, fossil fuel use is a small % of C loss.

• C losses from milling waste and prescribed burn vary but are probably in the range of 5-20% of aboveground C • Estimates of prescribed fire emissions (15-25 Mg C/ha) are probably within the actual ‘ballpark’ but wildfire emissions (25-45 Mg C/ha) , while improving, are still very rough.

• Estimates of fire CO2 emissions are hampered by our lack of knowledge about C deposition, rates of atmospheric vs. soil incorporation of dead wood C, ‘real’ soil C loss, etc.

Summary: What we may know and what we clearly don’t know