I've been trying to read up a bit on the methane clathrate "bomb" or "gun" theory lately, it seems to be popular among some fringe "we're all gonna die anyway" communities. Though my impression was that the vast majority of climate scientists don't consider it to be a very plausible threat [1]. It is based on some real scientific publications, but as far as I can tell in the realm of "very implausible theory".
There is definitely a concern about multiple feedback loops involving methane from clathrates, permafrost and also wetlands. There's also considerable uncertainty about the origin of methane emissions. But as far as I can tell the methane "bomb" theory shouldn't be our major concern.
I believe this same dynamic will apply to the oceans as they warm. They're like a can of Coke. Heat it up and the carbonation goes away. It's a horrifying positive feedback loop of global warming.
And then the whole melting of sea ice thing. Sea ice is pretty much the whitest/most reflective surface on the planet. It then melts into the darkest/most absorbent surface on the planet.
Are there any stabilizing forces we know about? I only ever hear about these types of positive feedback loops, and it scares the hell out of me.
increased temp > increased evaporation > increased cloud coverage which reflects more sunlight
increased co2 > increased tree growth
increased co2 > increased algae, plankton growth to absorb co2... other marine animals will also feed on these, increasing their mass, and when they die, they'll sink to the bottom, where they'll mostly remain.
increased co2 > increased diffusion into seawater.. clams, oysters, etc combine this carbon with calcium to produce shells.. and when they die, they accumulate on the sea floor eventually turning into rock.
Unfortunately, the fact that co2 in the atmosphere is growing indicates we're overwhelming these.. I take zero comfort in the fact that these exists.. it actually makes me nervous because once they reach their maximum, co2 will start growing even more rapidly.. and then it'll be so much worse.
Not only is CO2 continuing to rise, but it's rate of growth appears to be accelerating, from ~1.5ppm/year in the 80s/90s to 2ppm/year earlier this decade and now as much as 2.5-3ppm/year average now.
If this continues, we'll hit 420ppm within a couple years, 430ppm maybe 4 years after that, over 440ppm if not nearing 450ppm by the end of the 2020s with no slowdown in sight.
> increased evaporation > increased cloud coverage which reflects more sunlight
Also increased evaporation > increased latent heat transport to upper atmosphere where it can more easily escape to space. According to the numbers in Kiehl & Trenberth's global energy budget, total latent heat transport is about 80 W/m^2, which means a 5 percent increase in it would entirely cancel out the increased radiative forcing from a doubling of CO2. This is a negative feedback that I don't see discussed much at all.
> the fact that co2 in the atmosphere is growing indicates we're overwhelming these
No, it doesn't, it just indicates different timescales for CO2 emissions vs. uptake.
>> the fact that co2 in the atmosphere is growing indicates we're overwhelming these
>No, it doesn't, it just indicates different timescales for CO2 emissions vs. uptake.
It's not clear to me what the distinction is you're trying to make here? If the time scale for emissions vs. uptake is different such that emissions are exceeding uptake capacity due to the different timescales, isn't the previous comment correct?
> It's not clear to me what the distinction is you're trying to make here?
If the uptake timescale is longer, uptake will catch up to emissions over time (I realize I didn't make that sufficiently clear in my previous post), so CO2 growth does not indicate that uptake has reached "maximum", which is what the post I responded to was claiming.
If uptake capacity is decreasing and CO2 emissions are increasing, which I'm lead to believe is the case, and atmospheric and oceanic CO2 levels are increasing, which I'm also lead to believe the case...
I never said that, and I don't think it's true. The timescale I was referring to is the timescale for uptake capacity to respond to a change in CO2 levels. For example, trees grow and reproduce more slowly than CO2 levels have been changing, so the increase in uptake from tree growth and reproduction takes some time to respond to an increase in CO2. But that doesn't mean it never responds. It does; uptake capacity does increase.
Have you looked at Project Vesta? It's a proposal to create olivine beaches around the tropics to boost sequestration due to rock weathering. I think it's somewhat disputed because rock weathering in a surf happens at a different rate than normal, but their analysis is that if "only" 2 percent of tropical beaches were covered in olivine the weathering would counteract current emissions. I can't tell how serious this proposal is and am curious to hear from anyone who knows more about this process.
I’ve seen this thrown around as well, and would love to hear more. I’m interested in helping the project since it’s about the only one that has stood up to any scrutiny that I’ve seen
increased evaporation - water vapor is a potent green house gas
increased co2 > increased diffusion into seawater - isnt acidity of the ocean increasing, making it more difficult for the shelled sea life to even develop?
> increased evaporation - water vapor is a potent green house gas
But its lifetime in the atmosphere is very short; the evaporated water vapor condenses in the upper atmosphere into clouds and precipitation.
What longer term numbers I have seen indicate that the average water vapor content of the atmosphere has been roughly constant during the warming of the last half century or so.
More importantly there is tons and tons of water in the atmosphere, even in so-called dry places. There’s just no wiggle room in the water vapor spectral bands, optical path is pretty constant.
We will probably get more water vapor in the future but most of the PWAT ends up in clouds. And that’s where the feedbacks get interesting, cloud height is very important to radiative balance and there are a couple of indirect effects to consider too.
microplastics aggregate in longer lived predators organisms, killing sharks before plankton. Lowering the maximum size of animal paradoxically increases total biomass, though it's unclear by how much, and it's a pretty unstable proposition at its core what happens to humans in a mass extinction of large organisms.
Based on geological history, the negative feedbacks seem predominant for small perturbations, but if you push things a little too hard the positive feedbacks take over. It's happened before several times; a little initial heating from orbital variations, which leads to greenhouse gas emissions, which leads to the global average temperature going up several degrees. A good explanation of the evidence for this is in James Hansen's Storms of My Grandchildren.
People have long thought the threshold to be around 2 degrees C, but now some are thinking it's more like 1.5. The CO2 level everybody agreed was safe was 350 ppm.
Yah, the point is if we draw a set of hills with bumps and stable equilibria for a ball to roll down-- there is resistance to perturbation near an initial point, and then a sufficient "nudge" to get over a hill and roll somewhere else... but the ball always ends up in a stable region at the bottom of a hill.
How different a place that new equilibrium is ... is open to debate and not really known. What climate scientists have shown is that it can be, and likely is, pretty bad.
The primary negative feedback loop is increased photosynthesis. As CO2 concentrations rise, there's more carbon in the air that can support plant life. There also tends to be both more sunlight (warmer air can support more water vapor before it precipitates into clouds) and more water (in absolute terms, from increased evaporation).
Note that in the near term, the negative feedback of photosynthesis may be overwhelmed by changes in ecosystems: if the climate changes rapidly, whole forests may find themselves in a different biome, ocean circulation patterns may change, more freshwater may enter estuaries, etc. Plants evolve quickly, though, and most of their carbon sequestration is through algae and seaweed with short lifespans.
Unfortunately, I think human land use is impeding that feedback mechanism, as there are large portions of land area that are not allowed to freely green up anymore.
That'll change as human-caused global warming results in widespread crop failures and migration of people. We're at the top of the food pyramid; change an ecosystem and (most of) humanity is the first to go. It only takes about one human generation for an ecosystem to recover after humans leave: Chernobyl and the Korean DMZ are among the most pristine environments on earth now.
This is probably cold comfort for the billions of people that will die.
Global Dimming is caused by pollution emitted into the air. This has caused a decline in the Pan Evaporation rate. Meaning, less water is evaporating now than decades prior.
My concern is, if we stop polluting the environment and the global dimming is stopped, then climate change will get much worse.
Global Dimming might explain why the climate hasn't changed as much as some would expect.
If you are rich, why not? When sea level rise, increased frequency or intensity of bad storms, etc., makes it not worth living there...they can buy another house somewhere inland. Even if they have to completely write off the waterfront property, they should be reasonably OK.
It's the people who aren't rich who have to worry the most--the people that have most of their wealth tied up in their house, and so need to be able to sell it for a good price to afford to move.
With sea level rise projected to be less than two meters in the next century, why not? Unless the land is extremely low lying, like some sand covered atoll in the Pacific, the property will outlast both yourself and your children.
I don't know about you, but I don't sweat what happens to my investments after myself and my children are long gone. Honestly, most of the time I have trouble just planning ten years out.
Flood insurance is a national program underwritten by FEMA. We have it on our house in inland New Jersey, because we're on a river.
You may be thinking of the windstorm insurance program. The state of Florida underwrites that, and started it as insurance of last resort after insurers started bailing following Andrew.
Possible. The point was that people kept building mansions in clearly unsuitable areas and when the private market wouldn’t insure them they made the government do so.
Yes, the people who can buy multi-million dollar cars just to have them sit uselessly in a garage can also afford to buy properties that may be useless in a few decades. Others are buying up land in New Zealand on the belief it's relative isolation will protect them from societal collapse.
Insurers and the Pentagon seem to be treating it as a real threat, which is probably more indicative than the purchasing habits of people who tend to love rapidly depreciating status symbols.
There are actually maps which show where the water levels will be at each year. My great grandma's house was recently sold for over $1m and only has 70 years before it will be permanently underwater and likely destroyed by 50 years if there is any heavy rainfall.
I wish more wealthy people would lead by example though. Like instead if Obamas bought much smaller place and made it carbon neutral.
Also, I have no idea, but what is the timeline for ocean's rising to make a place like his on beach uninhabitable? I thought it was much less time, like 12 years or so, there are so many predictions out there.
I'm really curious about marine cloudseeding as a potential mitigator to permafrost melt. Essentially, high-efficiency saltwater aerosolization to create nuclei for cloud formation...
The climate changes with or without human behaviour. Only 8000 years ago, you could walk from England to Europe! So we need solutions for managing climate stability, not just cleaning up after humans.
Well, if we fail to develop solutions to clean up after ourselves, we won't need to worry about climate stability because we'll all be dead. So that's one way to handle things.
>> soil microbes transform it into carbon dioxide and methane
> rot
That's what the previous comment just said.
Decomposition of plant matter occurs in many stages. It begins with leaching by water; the most easily lost and soluble carbon compounds are liberated in this process. Another early process is physical breakup or fragmentation of the plant material into smaller bits which have greater surface area for microbial colonization and attack. In smaller dead plants, this process is largely carried out by the soil invertebrate fauna, whereas in the larger plants, primarily parasitic life-forms such as insects and fungi play a major breakdown role and are not assisted by numerous detritivore species.
The same way all these hydrocarbons got there, organic matter got there (at some previous time or through processes that moved it there) and then, under the right conditions, microbes decomposed it.
As the other comment points out, some of the major GHG's CO2 and CH4 are comprised of carbon. It is often used as a catch-all.
For example, the news earlier this year about treeplanting, spoke about removing Carbon from the atmosphere. Typically, the GHG's will be rolled up into either CO2e (CO2-equivalent) or just C. In the latter case, you often just have to do some molar math to get the CO2e from C.
No, but when we say "carbon emitter", we're talking about methane and other alkanes... and CO2.
CH4 is itself a greenhouse gas that is more potent than CO2 in the short term... and then it decays to water vapor and CO2 in reactions with radicals in the upper atmosphere.
So, it's overall somewhat worse than CO2 in the short term (since it's not just CO2), and equivalent in the long term?
Regardless of the truth of this story and the facts surrounding climate change Canadian media is not a credible source of information.
The CBC gets $2 BILLION/yr from the Trudeau Liberal government. All other private news orgs have a hand in a $600 Million/yr pot. For example, the Toronto Star alone receives $5.2 Million/yr from the Canadian federal government.
We can all agree this is a bad system apt to produce favourable results for the Liberals. For example, they won re-election on Monday.
I agree that the Conservatives suffered a colossal loss because Andrew Scheer is not leadership material.
Also, there will never be another typical Conservative majority due to mass migration. The Liberals bring 1 million Liberal-voting migrants per year into Canada. The population of which is 35 million. Simple math.
But none of this invalidates my argument that the Canadian media system is broken.
https://en.wikipedia.org/wiki/Clathrate_gun_hypothesis