They don't say how much rock they added to each field, but note that the 0.15 tons of CO2 they remove is only 300 lbs. A gallon of gasoline emits 20 lbs of CO2 when burnt.
So, if they use more than 15 gallons of gasoline to mine, crush, transport and spread the rock over 2.47 acres, then this process emits more CO2 than it captures.
I think they'd need to use electric high-tonnage dump trucks and electric tractors to make this process actually capture carbon. Electric tractors are stating to become available, but I don't know of any high-tonnage electric truck manufacturers.
Remember that if you're already distributing something else (eg. fertilizer) over the field, the added money and CO2 costs of distributing this might be negligible.
You could just mix the fertilizer and the rock together at the fertilizer factory, and automatically a large chunk of the worlds farmland gets this added.
It's only negligible if the rock is a negligible amount of extra weight. Otherwise, the energy to transport will still come from somewhere & not be negligible unless all that energy is from a non-carbon fuel source (bulk transportation is nowhere near decarbonized).
The spreading is ok but the transport is high. The key thing is: how many years of weathering do you get out of one load of 47 tons (or 27t)?
The paper provides a very course estimate that what they measured over the year was only 0.15% of total weathering potential, which if we handwave a little turns into 6,000 lbs CO2 over 20 years, or 300 gallons of gas offset, which is probably a net gain. Though there are a ton of "it depends"es in there and it probably only makes sense with further electrification.
(Obviously, the weathering would go on for a lot longer than 20 years, but the unknowns get large there and I'm assuming we're mostly interested in a shorter time frame)
OK, with something something like the F-550 (on the small side for this use case, but also a reasonable choice for an ICE dump truck that's driving to/from agricultural fields), it could work:
That can move 14,870 lbs (minus the weight of the driver and the dump truck bed) per trip, so it would take more than 6.7 trips to deliver rock to treat an acre. At 6.7 trips per acre it would have to use less than 44 gallons of gasoline per trip for breakeven. It should use significantly less than that for fields that are somewhat close to an appropriate quarry / rockery.
The lightning can only move 7000 lbs per trip, so it would have to make 13.5 trips per acre.
I found this[1] link from the EPA with a number similar to yours, 8.8kg per gallon of gas, but they say it "creates" rather than "emits." I'm still struggling with this creation of mass out of thin air...
It's because the majority of the mass of CO2 comes from the oxygen from the air used to burn the carbon. So in this case, it's quite literally creating mass out of thin air.
Specifically, the atomic mass of carbon is 12 and oxygen is 16. So for CO2, 12/44 of the mass is carbon, or about 27%. So of that 20 pounds of CO2, about 5 1/2 pounds are carbon, the other 15 pounds is oxygen sucked out of the atmosphere.
The CO2 contains mass from the atmospheric oxygen consumed during combustion. 12 grams of carbon becomes roughly 44 grams of carbon dioxide when it burns.
Depends on how high “high tonnage” is. Kennworth is offering a 680hp full-electric with a 3 hour range. Volvo offers an electric VNR with identical performance to its standard VNR. Freightliner sells the eCascadia, matching its regular Cascadia.
These vehicles would need to be charged on fully renewables or non emitting sources (like hydro) to offset this. Even if Natgas or Gas plants are much more efficient than engines, the calculation still needs to account for amortized emissions.
Yes? Obviously yes? Idk why everyone is assuming we’re going to keep dragging our feet on something that, at this point, is merely a matter of buying a few batteries and setting up a few more solar panels. Provinces have done it; heck, entire countries have done it. Switch to renewables already.
Because we're still not there yet. In the US, California's grid hits near-100% solar only around midday for an hour and then at night becomes mostly natgas, and can't handle peak demand on hotter days. If you're talking about the load of adding BEV trucks then that's adding a whole different dimension to the equation. I'd like to be optimistic about these things but we're far from it in the US.
So, if they use more than 15 gallons of gasoline to mine, crush, transport and spread the rock over 2.47 acres, then this process emits more CO2 than it captures.
I think they'd need to use electric high-tonnage dump trucks and electric tractors to make this process actually capture carbon. Electric tractors are stating to become available, but I don't know of any high-tonnage electric truck manufacturers.