Agema said:
You have two atmospheric compartments, the troposphere and the stratosphere. CFCs are released into the troposphere, and do their damage in the stratosphere. When small molecules are released into the air, they will be carried around by all the convection currents in the atmosphere. They can move hundreds of miles (laterally) in a day. After Chernobyl, for instance, Sweden was detecting the radiation within 48h. In effect, what is released locally will within a relatively short time frame of weeks be distributed globally. The distribution might not be uniform of course, but that's a digression.
What the Swedes detected on 28 April was ejecta from the explosion itself. Why they thought it originated from an incident at one of their own reactors, was because they detected short-lived fission byproducts (Xe-135 if I remember right) that could not have originated from the Soviet Union (or even the UK) under non-explode-y circumstances because they would have decayed by the time they reached Sweden. That's how the Swedes knew, once they had ruled out an incident at one of their own reactors, something had to have gone catastrophically wrong at a power plant in the Soviet Union. Hell if I remember right, the Swedes' initial assumption was a reactor at
Leningrad had exploded, and they never imagined they might detect ejecta from a reactor as far away as Ukraine.
It took particulates from the fire proper (i.e. the "fallout cloud") two
weeks to reach Sweden. Ejecta from the explosion was also detected hundreds of miles away
across and against prevailing winds as well, just to provide a sense of scale here -- that was the source of the Xe-135 detected at Cherepovets, for example. What happened, was the plasma jet and explosion accelerated particulates on a ballistic trajectory, at speeds better-compared to escape velocity than anything else, and prevailing winds didn't do much more than
kinda aim it.
That's what you're comparing to gaseous emissions from more or less standard industrial activity. Now, back to the realm of reason.
You just said it yourself: gases in the atmosphere can move hundreds of miles in a day, but
not laterally.
Longitudinally. Because it is still carried by prevailing winds in whatever cell the gas originates. If it originates in the subtropics, it's carried by the Hadley cell to the doldrums, back through the Hadley cell to the horse latitudes;
if it transitions to the Ferrel cell, or originates there, it has to transit through it to the polar front,
then is it deposited by the polar cell at its destination. That "hundreds of miles" is more like "tens of thousands of miles"; it takes ODS's two years just to reach the stratosphere before it can even
start that latitudinal journey.
That's why equatorial concentrations of ODS and ozone are so important to measuring the long-term impact of ozone depletion, by the way; northern and southern Hadley zones concentrate gaseous emissions along the intertropical convergence zone. That's 40% of the Earth's surface area, 36% of its landmass, and the location of damn near every RDC, that can be tracked by one metric. It also happens to by why even though
polar ozone levels are replenishing,
equatorial ozone levels are
depleting. That all factors into HFC's contribution to ozone depletion by way of being a greenhouse gas and the Kigali amendment, which is a conversation for another point.
Have a shit-tier MSPaint visualization of how this works, assuming the worst-case scenario for most rapid transit.
This is perhaps a moot point, because your graph of atmospheric concentrations does indeed suggest linear growth, so this exponential growth thing looks like a straw man. And one way or another, CFC levels were clearly sufficient to degrade the ozone layer even back in the 70s.
That's why I take issue with "world avoided" scenarios, because they take for granted production would continue growing indefinitely and exponentially, ignoring basic economics. The energy crisis factors into this for a number of reasons, but here to show ODS's are/were not only price-elastic, but highly so. This means production is a function of demand, and there is a point of market saturation which will dictate peak production. By definition, this means production could not nor would ever grow exponentially or indefinitely as assumed by "world avoided" scenarios, and to wit "world avoided" scenarios don't even model hypothetical production as a factor of historic real-world demand, influenced as it was by market-based transitions to more efficient technologies, and cheaper replacement or analog products, not even under the Montreal Protocol's purview.
What I was on about a page ago, is most of those replacement and analog products are
petroleum products. Which is the
other side of the energy crisis' impact: when the energy crisis ended petrol prices dropped, and so did the price of petroleum products -- including CFC replacements. Because HCFC's and HFC's are petroleum products (specifically, they're synthesized from ethane, propane, and naphtha if I remember right).
