From the YALE SCHOOL OF FORESTRY & ENVIRONMENTAL STUDIES
Managing uncertainty: How soil carbon feedbacks could affect climate change
There is more than twice as much carbon in the planet’s soils than there is in its atmosphere, so the loss of even a small proportion of that could have a profound feedback effect on the global climate.
Yet in its most recent report, in 2013, the Intergovernmental Panel on Climate Change (IPCC) used models that paid less attention to soil carbon potentially entering the atmosphere than had earlier reports, concluding that there simply wasn’t enough evidence about how warmer global temperatures might impact soil carbon stocks.
A new Yale-led paper makes the case that developing meaningful climate projections will rely on understanding the role of “soil carbon turnover” and how it might potentially trigger climate feedbacks in a warming world.
Writing in the journal Nature Climate Change, a team of scientists calls for more collaboration between modelers and soil scientists to improve the scientific understanding of the mechanisms that control the creation, stabilization, and decomposition of carbon in the soil.
That in turn will promote the kinds of experiments that will begin to remove uncertainties about the competing mechanisms that drive soil carbon stocks, the researchers write.
While scientists might never eliminate all uncertainty when it comes to evaluating the mechanisms driving changes in soil carbon stocks, new research advances are making it possible to predict the full range of potential outcomes, said Mark Bradford, an Associate Professor of Terrestrial Ecosystem Ecology at the Yale School of Forestry & Environmental Studies (F&ES) and lead author of the study.
And that, he says, will increase confidence.
“There is so much discussion of uncertainty in the public debate about climate change that the term now seems ambiguous and politically loaded,” Bradford said. “The discussion should not be about how much uncertainty there is, but rather about how much confidence we have that the real planetary response lies somewhere in the range of projected uncertainty.”
“You gain scientific confidence by representing the best — and sometimes polar opposite — ideas about the how the world works in your models. If someone tells you they have high confidence that something will happen, you can then take actions based on the best knowledge available.”
Warming temperatures can trigger two very different changes in soil carbon soil levels. On the one hand, they can stimulate the growth of plants, increasing the amount of carbon storage potential. Conversely, those higher temperatures can also accelerate the activity of organisms that live in the soil and consume decaying plant matter. In that case, there is a net increase in the amount of carbon released from the biosphere into the atmosphere.
In other words, one function puts carbon into the soil, keeping it out of the atmosphere, while the other emits it into the atmosphere. The twist, however, is that the processes that emit carbon from the soil also convert a small fraction of the decaying plant matter into stores of carbon that can be locked away over millennial timescales, which would be optimal to minimizing climate impacts.
While scientists have made great advances in understanding how plants will respond, their ability to evaluate how much carbon goes into the soil, and where it ends up, is made difficult because it’s not possible to measure directly.
“In the soil, we don’t know how things are working because, if you like, it’s as clear as mud,” Bradford said. “Often we can’t measure what we’re trying to measure because we can’t see the organisms. You have millions of individual microbes — from thousands of cryptic species — in just a handful of soil.”
For these reasons, he said, much of the understanding of how soil carbon stocks will respond to warming is based only on the outputs, which is like trying to calculate the balance of a bank account based simply on how much money is being withdrawn.
Another complicating factor is that our knowledge of how soil carbon is created and stabilized is undergoing somewhat of a conceptual revolution, and only one set of ideas is represented in the climate models, the new paper says. For decades scientists assumed that carbon entering the soil through materials that are harder to “digest” by microbes — like, say, wood — would be more likely to remain in the soil longer.
In recent years, however, there has emerged a growing consensus that carbon is more likely to remain in the soil if it enters through more digestible plant matter — a cloverleaf, for instance. “The science has flipped,” Bradford said. “The harder it is to digest initially the less of it stays in the soil, whereas the easier it is to be eaten then the more of it stays in the soil.”
This is important because it’s the easily digestible plant matter — such as the sugars released from plant roots into the soil — that likely eventually get converted into the long term stores of soil carbon but they are also the hardest inputs to quantify.
This growing awareness shifts the way scientists view ecosystem management, from thinking about the biomass that you can see aboveground to a focus on thinking about the amount of carbon that can be pumped belowground directly through the roots of the plants and to the organisms in the soils.
Ultimately, Bradford says, it will be impossible to eliminate all uncertainty. But that, he says, is not such a bad thing.
“By increasing our real understanding, we might even end up making our climate projections more uncertain, in terms of a greater range in the extent the planet might warm,” he said. “But we’ll be more confident that the true answer falls within that range.”
“Advancing our confidence and taking necessary actions will ultimately require that we embrace uncertainty as a fact of life.”
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The paper: http://www.nature.com/nclimate/journal/v6/n8/full/nclimate3071.html
Managing uncertainty in soil carbon feedbacks to climate change
Mark A. Bradford, William R. Wieder, Gordon B. Bonan, Noah Fierer, Peter A. Raymond &Thomas W. Crowther
Planetary warming may be exacerbated if it accelerates loss of soil carbon to the atmosphere. This carbon-cycle–climate feedback is included in climate projections. Yet, despite ancillary data supporting a positive feedback, there is limited evidence for soil carbon loss under warming. The low confidence engendered in feedback projections is reduced further by the common representation in models of an outdated knowledge of soil carbon turnover. ‘Model-knowledge integration’ — representing in models an advanced understanding of soil carbon stabilization — is the first step to build confidence. This will inform experiments that further increase confidence by resolving competing mechanisms that most influence projected soil-carbon stocks. Improving feedback projections is an imperative for establishing greenhouse gas emission targets that limit climate change.
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We can’t measure natural flows well enough to assess the impact of fossil fuel emissions on the carbon budget
http://papers.ssrn.com/sol3/papers.cfm?abstract_id=2654191
Do you know what would really help?
If people on this website did not use the word ‘carbon’ in the sloppy, deceptive way that Warmists use it.
There is very little actual ‘CARBON’ in the atmosphere…and not a lot of CARBON DIOXIDE in the soil.
Language matters when dealing with people who are attempting to deceive.
Agree!
After several decades of applied soil geochemistry, I would summarise thus:
There is active organic chemistry in agricultural soils (as opposed to say desert sand, with less).
Some factor limits the accumulation of organic products, otherwise organic C in soils would keep on increasing.
Not much progress will be made until that limiting factor is characterised in detail.
There might be two, three, even 50 limiting factors.
It is a dynamic system with slow and fast cycles, so modelling will be complicated.
Many soils analysed for organic carbon in the traditional manner show relatively predictable levels of a couple of % carbon. The limiting factors, whatever they are, usually hold it around that level.
IMO, these limiting factor(s) will generally involve inputs other than CO2 and related. Increase could be limited by nitrogen chemistry, or by sulphur chemistry, or by water cycles, or by biological entities.
Again IMO, this is a research matter that will be slow to unravel if people approach it with preconceptions such as that CO2 has to be involved. Start with an open book and an open mind. The answer is not beyond the wit of investigation skills and tools now available.
Geoff
Geoff,
Thank you for this very informative summary.
Soil respiration 59 GT Carbon to the atmosphere annually, isotopically fractionated to -21 PDB.
Humans 9 GT Carbon to the atmosphere annually, isotopically fractionated to -24 PDB.
For whatever reason, the planet warms.
Which do you expect to respond more to the warming and how will we know the difference?
Climate science is so incredibly wrong about feedback it’s absurd and the errors (more than 1) go back 3 decades to Hansen and Schlesinger. Whenever I hear ‘Its the feedback’, it reminds me of the line from movie Idiocracy, “It’s the electrolytes”.
One of the errors is how feedback is modeled, where it uses a Bode feedback system to ‘predict’ the change in temperature, dT, resulting from a change in forcing, dR. Bode’s analysis simply doesn’t apply to any system where the input and output are not linearly related to each other (this assumption is stated in the first sentence of the second paragraph of his book). If R is the input and T is the output, linearity means that R/T = dR/dT and anone thinks that this applies to the relationship between power density and temperature apparently hasn’t heard of the Stefan-Boltzmann LAW.
The only proper way to apply Bode is to make the output of the feedback system the equivalent BB emissions of the output temperature and not the temperature itself (these are interchangeable), apply the model once for the reference and again for the new conditions and then subtract the R’s and T’s from each other to determine dR/dT. But when you do this, the nominal feedback is limited to 0.38 positive (assuming Schlesinger’s unit open loop gain did) limiting the sensitivity to about 0.3C per W/m^2, rather than the 0.5-0.8 positive feedback required to support the insane sensitivity claimed by the IPCC. Of course, the IPCC will reject a proper analysis that gets an answer that refutes their reason to exist in favor of an improper analysis that gets the answer then need to justify their very existence. It’s called confirmation bias.
If you’ve been to NOAA’s website lately, they’ve stopped using land use in their calculations for co2 totals. I think that missing co2 has become an issue.
From a long running argument a few years ago, I saw a farmer injecting co2 into the soil in Indiana. The number that stuck with me about the amount of co2 in the soil wasn’t double, but about 10 times. Of course the warmist and farmers had never heard of such a thing. They probably aren’t doing that now as co2 has been identified as a pollutant. It’s one of those times you wish you had taken a picture.