New Study Finds Earth’s Rocks Are A Net Source Of CO2 Rivaling Volcanic Emissions

For decades rock weathering has been thought to be a net sink in carbon budget models.

New research finds rock emissions are a large net source of CO2 into the atmosphere.

A few years ago Buesseler et al., 2020 discovered that all of the climate modelers’ previous estimates of global ocean carbon uptake were substantially wrong because they were measuring from the fixed “canonical fixed 150-m depth.” [emphasis, links added]

The alleged new-and-improved way to assess carbon uptake is from much shallower depths: the euphotic zone (Ez).

This is the section of the upper ocean layer that sunlight is able to penetrate, and it can “vary from less than 20 m to almost 200 m” in depth.

When the variable Ez depth is used to estimate carbon absorption versus export, the absorption estimate changes by more than a factor of two, from 2.8 petagrams of carbon (PgC) per year to 5.7.

Now, new research reverses the decades-long assumption that rocks exposed to the air absorb CO2 from the atmosphere.

Instead, weather-exposed rocks “act as a large CO2 source,” as they release “as much carbon dioxide as the world’s volcanoes.”

Rock weathering as a net source of CO2 is thus “not captured in climate models.”

Sedimentary rocks on the banks of the Mackenzie River, Canada, a major river basin where rock weathering is a CO2 source. Image credit: Robert Hilton.

About five years ago it was discovered that modeled estimates of CO2 emissions from volcanoes are 10 times smaller than actual measurements indicate (Illyinskaya et al., 2018).

Another 2018 study (Gray et al., with a Physics Today press release) estimated the carbon uptake for the Southern Ocean.

But instead of using the traditional ship-based measurement, the authors utilized biochemical floats. The results upended decades of modeling.

Instead of absorbing close to one petagram of carbon (PgC) per year, the Southern Ocean is barely even a carbon sink at all – just 0.08 PgC of yearly absorption (with a ~14 times larger uncertainty range, ±0.55 PgC/year).

Large regions of the Southern Ocean near Antarctica are now considered a net source of CO2 to the atmosphere.

In other words, when estimates are float-based rather than ship-based, one estimate can be more than 10 times different than another.

These wildly varying results and consequent large uncertainties underscore just how guess-based carbon-budget-modeled estimates are.

Read more at No Tricks Zone

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