Producing electricity from biomass is one of the most controversial and least understood forms of renewable energy. In this three part series, we first explored myths and facts about biopower. In this second installment we’ll try to make sense of a seemingly simple question – is biopower good for cutting our carbon emissions? It is anything but simple. This series first appeared on the Energy Transition blog, at energytransition.org.
While rapidly growing wind and solar energy attracts daily headlines, a skirmish in the United States Senate has brought increased attention to the slow-moving and often overlooked biomass power industry. The controversy? How to measure the carbon emissions of biopower.
Until the surprising election of Donald Trump, the US Environmental Protection Agency (EPA) had been developing the Clean Power Plan to reduce carbon emissions in the power sector. Though the Plan is still pending in the courts, the Trump Administration has made it clear they have no intention of implementing it.
While measuring emissions is straightforward for fossil fuels (large) and wind and solar (none), biomass is more complex. The carbon emitted from the smokestack of a biomass power plant comes from recently grown trees and plants, in a short carbon cycle. Scientists use “life cycle analysis” to count the net emissions from the process.
As a result, EPA convened a Scientific Advisory Board to make recommendations on how to measure “biogenic” emissions from biopower. That panel has been meeting for over five years, and has yet to issue a final report.
A number of fundamental questions are essentially impossible to answer, or the answers are determined solely by how the question is asked
Leery of the lingering uncertainty, and the potential impact of the Clean Power Plan, industry backers like the National Association of Forest Owners (NAFO)  convinced friendly senators, including Susan Collins (R) and Angus King (I) of Maine and Amy Klobuchar (D) of Minnesota, to include a “tripartisan” amendment to a budget declaring that biomass should be considered “carbon neutral” under federal policy, circumventing the EPA’s process. The amendment had no opposition in the Senate, and was not addressed by the more conservative House.
Environmental groups, outraged, ratcheted up efforts to block that provision. “Legislating the carbon neutrality of an emissions-producing technology sets a dangerous precedent for all climate science, in that it attempts to override physical facts with policy declarations,” wrote a large coalition of groups, including 350.org and Greenpeace.
While the Clean Power Plan is unlikely to go into effect any time soon, the issue of biogenic carbon accounting hasn’t gone away. State and regional governments can regulate carbon, and a future federal administration is likely to revisit the issue.
Hard questions
The scientific stalemate that led to this political fiat underscores the difficulty of the task – the “physical facts” are simply not clear. A number of fundamental questions are essentially impossible to answer, or the answers are determined solely by how the question is asked.
Four sets of questions have tripped up the process: time frames, spatial boundaries, the fate of the feedstock, and attribution.
Time frames
From a carbon perspective, a forest is a continuous flow, with a total stock that changes over time. Carbon is constantly absorbed into growing trees and it is expelled from leaves and dying trees into the atmosphere. But measuring the carbon impacts of bioenergy requires setting a starting point and an end point.
Scientists have developed the concept of a “payback period” to measure how long it takes for carbon from burned wood to be reabsorbed by growing trees.
But should the clock start when the tree sprouts from a seed, or when it is burned for energy? Are we spending the carbon we have already saved, or are we stealing that carbon from our children?
“Proponents of the use of biomass want long time scales, while those concerned about forest conservation want short time scales”
And how much time for the payback period is acceptable? Should we allow only things that pay back quickly, since climate change is an urgent problem, or should we count longer options that will deliver benefits to future generations when they do pay back?
At a recent meeting of EPA’s Scientific Advisory Board, time frames were a key topic of discussion.  “Proponents of the use of biomass want long time scales, while those concerned about forest conservation want short time scales,” says Harvard’s Daniel Schrag. “Surprise, surprise.”
Steve Hamburg, Chief Scientist for the Environmental Defense Fund (EDF) said that the right time horizon “is a policy decision, not a scientific decision.” He argued that the Board should not talk about 100-year time frames, but instead should “make clear the implications of picking different time horizons, as opposed to a priori picking a time horizon.”
Ken Skog of the USDA Forest Service pointed out that since biopower with longer payback periods still delivers benefits over time, the time frame for the policy is critical. “The science tells us that climate benefits would be ignored with a shorter time frame.”
Spatial boundaries
Measuring the carbon implications of biopower depends hugely on how boundaries are defined. Since everything is connected to everything else, the first task of a life-cycle analysis is to define what is going to be measured and what will be excluded.
The most immediate boundary to define is whether we are measuring the tree, the stand of trees, the forest, or the biome, or the county, state, region, or country.
In one common story line, a single tree grows, is cut and used for energy, and then is replanted and grows again. The carbon in the tree must be paid back, which may take decades.
If a tree is burned for bioenergy, the emissions go into the atmosphere. But what would happen if it weren’t burned?Â
A forest, on the other hand, grows continuously, with carbon flowing in and out. A harvester may take 10 percent of the tree mass each year, with growth adding 10 percent back. From this viewpoint, the carbon is subtracted and added continuously, with no payback period.
Carbon is not “sequestered” for long periods by trees, but by forests. Trees come and go, but a well-managed forest can last forever.
Some have proposed extending this thinking nationwide: if the overall volume of trees stays the same or increases over time (as has been the case in the US for many decades), then there is no net carbon emissions from wood-based biopower.
Fate
Just as in a romance novel, “fate” is the scientific term used in life-cycle analysis to describe the destiny of a given thing.
If a tree is burned for bioenergy, the emissions go into the atmosphere. But what would happen if it weren’t burned? Trees don’t live forever; when they die, the fall down and rot (or they burn in a forest fire) with much of their carbon going into the atmosphere anyway.
While the public language of the debate around biopower carbon accounting tends toward black and white, the science is tangled up in complexity
Likewise, wood waste from harvesting operations can be left in the forest floor to rot, or it can be collected and used for energy. While there are certainly implications for wildlife and forest health, the fate of the carbon is the same – it will be in the air sooner or later. If that is the case, why measure the carbon emissions from biopower at all?
Fate also determines the use of a plot of land. What will a landowner do if they are prevented from cutting down trees for biopower production? Will they develop the land into housing, losing the forest forever and boosting carbon emissions? Or will they donate it to The Nature Conservancy to be preserved, locking up the carbon long term?
Attribution to different products
As we mentioned last time, most wood currently used for biopower production in the US is leftovers from the wood products industry. (Most pellet exports to Europe come from pulpwood, like pine trees.) When a mature tree is harvested, maximum value is extracted from each part of the tree. The trunk is used for high-value products like lumber and furniture, while limbs and bark are used for paper or particleboard. Anything left, or that has no ready market, is often burned for energy production.
“Just as there is no accurate blanket statement about the carbon neutrality of all kinds of biomass, so too there is no all-encompassing statement about the negative climate impacts of biomass”
But when it comes to counting the carbon emissions of that energy production, how do we divvy up the carbon between among the various end products? If the tree was cut for both lumber and energy production, how do we allocate the responsibility?
And since the Clean Power Plan is only regulating emissions from the power sector, we aren’t counting the carbon implications of producing lumber at all. (That brings up the same set of gnarly questions about lumber – how long will it last? What is its fate? Does it have a lower carbon substitute?)
If a tree falls in the forest …
Like Zen riddles, these questions are largely unanswerable by science. And to keep the discussion relatively simple, we have only talked about one form of bioenergy – trees used for electricity production. There are many biomass feedstocks, many conversion technologies, and many end products – all with their own calculations and complications.
The mother of all complications is known as ILUC – indirect land use change – which is part of the carbon accounting of biofuels like ethanol. Because land is finite, the ILUC theory says biofuel production that displaces food production will force food to be produced somewhere else in the world, thus displacing wild land. The loss of that wild land must be counted in carbon terms and added to the total carbon from biofuels. So far this highly contentious topic has not been applied outside of policies for liquid biofuels, since most US ethanol comes from corn.
While the public language of the debate around biopower carbon accounting tends toward black and white, the science is tangled up in complexity.
“Just as there is no accurate blanket statement about the carbon neutrality of all kinds of biomass, so too there is no all-encompassing statement about the negative climate impacts of biomass,” wrote a coalition of Northwestern green groups to Senators Wyden and Merkley of Oregon.
How these questions are resolved by policymakers will have a profound impact on the future of biopower, a topic we will address in the third installment in this series.
Editor’s Note
Bentham Paulos is an energy consultant and writer based in California. His views are his own, and don’t necessarily represent those of any of his clients.
This series first appeared on the Energy Transition blog, at energytransition.org and is republished here with permission. Copyright Bentham Paulos.
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Bob Wallace says
” Should we allow only things that pay back quickly, since climate change is an urgent problem, or should we count longer options that will deliver benefits to future generations when they do pay back?”
We should use all the tools we have on hand to decrease fossil fuel use. Once well extract that deeply buried carbon in coal, petroleum and natural gas we don’t have any reasonable way to remove it from the above ground carbon cycle.
Converting coal plants to biomass burners can decrease coal use now.
Then there’s the yet unsolved problem of “deep backup”, the generation or storage we need for the few times a year we encounter low wind and solar input.
In the fossil fuel grid we have gas peaker plants which run only a few hours a year but are needed at time in order to keep the grid running. US ‘peakers’ run about 5% of the time. Barely used but critical for those hot summer afternoons when the grid is demand stressed.
We may need biomass burners to fill that need in a renewable energy grid.
Now, a request. Could you folks who talk about the number of years for a tree to grow and recapture carbon please use fast growing trees in your math? If we were to operate tree plantations for biomass we’d be more likely to grow fast growing species such as poplar or eucalyptus, not some slow growing species.
Bob Wallace says
“In one common story line, a single tree grows, is cut and used for energy, and then is replanted and grows again. The carbon in the tree must be paid back, which may take decades.”
I’ve planted three woodlots for firewood. In each case we used a species of eucalyptus that grew to harvestable size (about 8″ diameter at chest height) in 5-6 years. And after harvesting sprouts sprung back from the stump the next year.
Those sprouts produce mass much faster, they’re growing on an established root system. Harvest this time is after four years. And subsequent harvests run on a roughly four year cycle.
By choosing an optimal species the “hundred” year cycle becomes a five year cycle.
We’d be taking five year’s worth of tree carbon and putting it in a recycling program. If we, instead, use coal we’d be taking a year’s worth of coal carbon every year – year after year after year – and adding it to our atmospheric CO2 problem.