Jump to content
  • Member Statistics

    17,601
    Total Members
    7,904
    Most Online
    ArlyDude
    Newest Member
    ArlyDude
    Joined

Climate-Driven Changes in Clouds are Likely to Amplify Global Warming


bluewave
 Share

Recommended Posts


 

Scientists know that global warming is changing clouds, but they haven’t been sure whether those changes would heat or cool the planet overall.

It’s an important question, because clouds have been the main source of uncertainty in projecting just how sensitive the climate is to increasing greenhouse gas concentrations, and because clouds have a huge effect on the climate system. Just a 20 percent change in their extent or reflectivity would have more of an impact than all the greenhouse gases released by human activities.

A new study published today in the Proceedings of the National Academy of Sciences may help find an answer. The researchers analyzed 20 years of cloud data from satellites and found that it was 97.5 percent certain that changes in clouds brought about by climate change will amplify warming. 

Since the cloud effect has been uncertain, its accurate measurement also helps affirm other recent projections that a doubling of carbon dioxide in the atmosphere will warm the planet’s surface by about 5.8 degrees Fahrenheit, said said co-author Paulo Ceppi, a climate scientist with the Grantham Research Institute on Climate Change, London School of Economics and Political Science. 

“Most previous cloud studies focused only on certain regions or regimes, so say they look at places where there are low clouds and they look at low clouds only,” he said. “We did this analysis everywhere, at every point regardless of what type of cloud was there, and that allowed us to get a global picture.”

The new research is an important update to the scientific understanding of clouds in the climate system, said Piers Forster, director of the Priestley Centre at Leeds University. 

“It is a really good step forward,” said Forster, who was not involved in the new study, but has worked on other recent research assessing the climate system’s response to building greenhouse gas levels.

“It really tells us how clouds respond to changes in local surface temperature, especially the reflectance of low clouds,” he said. “This is then used to make an accurate estimate of the total cloud feedback: the amplifying effect that clouds have on global warming.”

To get a sense of how important clouds are in the global warming equation, Ceppi said their effects can be compared to the warming effect of carbon dioxide.

“We calculate that, on average globally, clouds reflect something like 50 watts per square meter of solar radiation,” he said. “You can compare that to the forcing from a doubling of CO2, which would be about 4 watts per square meter, much smaller than the average effect of clouds on sunlight. So even a very small change in how much sunlight is reflected by clouds would be comparable to the effect of a CO2 doubling.”

In general, the new research confirms what some of those other studies have suggested, he said. 

“People have argued that clouds will amplify global warming because of solar impacts, so less reflected sunlight from low clouds, but also because of the greenhouse effect of clouds, where high clouds rise, which makes them have a larger warming effect,” he said. “Our study finds evidence of both. I’m not aware of any other studies that have been able to show that, especially the greenhouse part.”

One recent study, led by University of Oslo researchers, shows global warming will reduce the amount of ice particles in widespread low clouds around Antarctica that currently reflect a huge amount of solar radiation back into space. That would make the clouds less reflective and amplify global warming, said cloud researcher Trude Storelvmo.

Machine Learning

Ceppi said using a machine learning approach is especially suited for complex problems like cloud changes.

“It’s a complex situation because clouds depend on so many factors that all co-vary. 

For example, for a certain change in humidity, you get a certain response from clouds,” he said. “The machine learning method we use is smarter about learning these dependencies. It’s a complex statistical problem, and improved statistical methods can really help. There are so many relationships that it’s hard to calculate them manually. The statistical learning step gives us better predictive power.”

Prior studies showed less strong relationships and thus came up with less reliable projections, he added. 

“One strength of our study is that we show, with 20 years of data from observations, we can really predict the feedback in model worlds where we know the answers,” he said. “Our results will mean we are more confident in climate projections and we can get a clearer picture of the severity of future climate change. This should help us know our limits and take action to stay within them.”

While the research helps narrow the range of cloud responses and feedback to global warming, some uncertainties remain.

“I would like to see a physical process understanding of how clouds respond,” Forster said. “This would add confidence that they are looking at the right statistics. It’s really about how much low clouds reflect sunlight in relation to both the local surface temperature and how quickly the temperature drops with altitude. Both of these temperatures are affected by global warming.”

“Understanding how clouds respond locally to these temperatures,” he said, “builds up a complete picture of how clouds respond to global warming, and thereby how much global warming we expect from increasing levels of CO2.”

  • Like 3
Link to comment
Share on other sites

This is another bad break on the climate change front. There had been some hope that cloud changes could somewhat dampen the warming. Research by Jessica Tierney et al., hinted at amplification from the paleoclimate record, but there was no direct evidence. This paper provides that evidence. Its findings underscore the urgency of moving faster rather than more slowly in curbing greenhouse gas emissions.

Link to comment
Share on other sites

Would be more meaningful if clouds were you know...stuck in place, steady in size, of consistent shape and arriving at constant times. I can't see the paper behind the paywall to see the methodology used. But my understanding was part of the reason studying clouds was hard is because most of the Earth is salt water at the surface, and it's hard to get ground observations of clouds that are reliable over a long period over the vast majority of the Earth. Satellites are better than ground observations at some things, but not everything. The other issue with studying clouds is that they'll likely arrive and develop from different places if the climate changes dramatically in a given spot over the coming decades. The changing origin of the clouds (or even introduction of extra sunlight / cloudiness in a over time) is more relevant long-term.

More philosophically, you have different amounts of cloudiness not just by region but by time. So the effects from changing clouds would be by time of day, time of year, and then layered on top of the general pervasiveness of clouds in a region. Presumably, it's not a big deal where I am as we have something like weeks-months of near cloud free days per year, whereas Seattle or Boston would have the opposite, very few true cloud-free days. More generally, these papers usually ignore "ground clouds" like fog, freezing fog, mist, dust, haze, pollution, and so on. Not to mention the differences in terrain with rapid elevation changes where effects like shadows near dawn and dusk take effect and can interact with the "angles" of clouds so to speak. You can be shadowed from a cloud that isn't over head at the right time of day and so on.

Link to comment
Share on other sites

One thing that confused me a couple of years ago is the increase in outgoing longwave radiation (OLR). I naively thought that GHGs would reduce OLR and that's what creates the Earth Energy Imbalance (EEI).

That is what happens initially. But...the warming that results from a positive EEI leads to feedbacks like the cloud feedback. If the cloud feedback is positive then Earth's albedo will drop and the absorbed shortwave radiation (ASR) will also increase. Because EEI = OLR - ASR there two ways for the planet to achieve energy balance after a positive EEI perturbation. The first is if OLR increases (temperature increase). The second is if ASR decreases (albedo increase).  The fact that we observe an increase in OLR while EEI itself continues to increases is a tell that ASR is increasing which means albedo is decreasing. This is consistent with the hypothesis that the cloud feedback is positive. Donohoe et al 2014 has a pretty good explanation for the counter-intuitive OLR increase when the climate system is acted on by increases in GHG. See figure 1c and 1d for how the OLR and ASR respond to pulses of GHG forcing. It is interesting to note that most (not all) global circulation models actually predict this behavior. DeWitte & Clerbaux 2018 point out that OLR is indeed increasing and attribute this to "cloud thinning".

 

  • Like 1
Link to comment
Share on other sites

18 hours ago, donsutherland1 said:

This is another bad break on the climate change front. There had been some hope that cloud changes could somewhat dampen the warming. Research by Jessica Tierney et al., hinted at amplification from the paleoclimate record, but there was no direct evidence. This paper provides that evidence. Its findings underscore the urgency of moving faster rather than more slowly in curbing greenhouse gas emissions.

Yeah, that's almost a complete shutout of ECS <= 2C by their calculations. While the mean looks to be around 3.2, that PDF is .... not great. Anything under 2.5 is pretty unlikely and pretty decent probs of something closer to 4.

From what I'm gathering, that's also just from the observational record. Paleo suggests ECS itself might be variable depending on the state (higher during warmer climates for instance). https://advances.sciencemag.org/content/5/9/eaax1874

Having said all of that -- I'm also wondering if the laser-like focus on ECS is a bit troublesome in itself. It's possible, for instance, that we're focusing a bit too hard on global temps and not enough on downstream effects -- like asymmetric hemispheric response. All evidence points towards the NH losing ice much faster than the SH and indeed paleoclimate tends to suggest that the NH and SH can exist in a "decoupled" state where most of Antarctica can still be relatively cold and glaciated and the NH is essentially much closer to something resembling a greenhouse climate. The GIS will still be around for quite a long time but the amount of resistance it can put up pales in comparison to the combination that the circumpolar current and EAIS can put up. It's worth noting that Antarctica glaciated pretty early on (30-40mya at around 650 ppm I think?). I'm sure the isolating power of the circumpolar current helped, but if folks like Tierney are right, that doesn't have as much of an effect as one might initially think.

 

  • Like 3
Link to comment
Share on other sites

17 hours ago, raindancewx said:

Clouds are difficult to study. Shape, size, location, color all change very quickly. Even something like a count of the clouds is hard. How many clouds are in the GIF below would you say?

 

There are 2 decades of cloud satellite obs. This study is in-line with others estimating cloud feedback using satellite data. Scientists have been gradually paring down the uncertainty in climate sensitivity with better obs and models, as they do that there is no indication that warming has been overstated. Instead the tightening is mainly from raising the lower-bound.

  • Like 1
Link to comment
Share on other sites

On 7/20/2021 at 3:32 PM, csnavywx said:

Yeah, that's almost a complete shutout of ECS <= 2C by their calculations. While the mean looks to be around 3.2, that PDF is .... not great. Anything under 2.5 is pretty unlikely and pretty decent probs of something closer to 4.

From what I'm gathering, that's also just from the observational record. Paleo suggests ECS itself might be variable depending on the state (higher during warmer climates for instance). https://advances.sciencemag.org/content/5/9/eaax1874

Having said all of that -- I'm also wondering if the laser-like focus on ECS is a bit troublesome in itself. It's possible, for instance, that we're focusing a bit too hard on global temps and not enough on downstream effects -- like asymmetric hemispheric response. All evidence points towards the NH losing ice much faster than the SH and indeed paleoclimate tends to suggest that the NH and SH can exist in a "decoupled" state where most of Antarctica can still be relatively cold and glaciated and the NH is essentially much closer to something resembling a greenhouse climate. The GIS will still be around for quite a long time but the amount of resistance it can put up pales in comparison to the combination that the circumpolar current and EAIS can put up. It's worth noting that Antarctica glaciated pretty early on (30-40mya at around 650 ppm I think?). I'm sure the isolating power of the circumpolar current helped, but if folks like Tierney are right, that doesn't have as much of an effect as one might initially think.

 

The differences between the Arctic and the Antarctic are basically because the Arctic has a large quantity of water near the NP while the Antarctic is a continent surrounding the SP correct?

 

Link to comment
Share on other sites

There is another global cloud satellite datasets from the from 1982-2019. The source is https://www.eumetsat.int/about-us/satellite-application-facilities-safs  This dataset like the https://isccp.giss.nasa.gov/index.html  dataset shows that as global cloud cover goes up, temperatures go down and vice versa. This suggests its global cover in part modulating the global average temperature.  But one can argue from this dataset that as we warmed dramatically from the super El Nino in 1998, cloud cover decreased to a new lower level. But it has remained steady since the early 2000s with slight warming. Clearly global cover is about 2 percent lower now than in the 1980s which equates to 2% decrease in albedo. If there was a significant positive feedback we would see temperatures taking off and we are not. 

see  

1310761895_CloudCover_and_MSUUAHGlobalMonthlyTempSince1979With37monthRunningAverageWith201505Reference.gif.ce352e137b142c18ce585b659ddb8718.gif

  • Like 1
Link to comment
Share on other sites

41 minutes ago, bluewave said:
That chart above is using the flawed UAH from before it was corrected.

 

Disagree. RSS detains the warmer NOAA14, UAH matches the radiosondes much better.   The RSS upward trend was done to match the flawed surface records. UAH is the best dataset. Why does RSS maintain data from a spuriously warm NOAA14 satellite?  I will agree to disagree. UAH is the gold standard IMO. 

  • Like 1
Link to comment
Share on other sites

RSS matches RATPAC better. https://www.ncdc.noaa.gov/sotc/upper-air/201813

The claim that UAH matches radiosondes better comes from Dr. Spencer and Dr. Christy themselves. They also use IGRA as their radiosonde data source. The IGRA website warms users against using their dataset for long term trend analysis.

How can you know that UAH (or any dataset for that matter) is "true" and thus a gold standard?

 

  • Like 1
Link to comment
Share on other sites

9 hours ago, blizzard1024 said:

There is another global cloud satellite datasets from the from 1982-2019. The source is https://www.eumetsat.int/about-us/satellite-application-facilities-safs  This dataset like the https://isccp.giss.nasa.gov/index.html  dataset shows that as global cloud cover goes up, temperatures go down and vice versa. This suggests its global cover in part modulating the global average temperature.  But one can argue from this dataset that as we warmed dramatically from the super El Nino in 1998, cloud cover decreased to a new lower level. But it has remained steady since the early 2000s with slight warming. Clearly global cover is about 2 percent lower now than in the 1980s which equates to 2% decrease in albedo. If there was a significant positive feedback we would see temperatures taking off and we are not. 

see  

1310761895_CloudCover_and_MSUUAHGlobalMonthlyTempSince1979With37monthRunningAverageWith201505Reference.gif.ce352e137b142c18ce585b659ddb8718.gif

The only thing I can think of is Kyoto Protocal was enacted in 1997 but I dont believe it made strict cuts on anything just incentivized new cleaner technology paths instead of old paths.  You would think we took another step down with the 15/16 el nino if the super nino struck up something. So at a loss with why there was a 8 year long reduction in cloud cover.

Link to comment
Share on other sites

2 hours ago, so_whats_happening said:

The only thing I can think of is Kyoto Protocal was enacted in 1997 but I dont believe it made strict cuts on anything just incentivized new cleaner technology paths instead of old paths.  You would think we took another step down with the 15/16 el nino if the super nino struck up something. So at a loss with why there was a 8 year long reduction in cloud cover.

It must vary quite a bit from region to region, I can tell you on the east coast the opposite is happening and dew points and rainfall have been on a steep increase, which has led to an explosion of vegetation and allergy levels that last nearly year round now.  Of course in the West the exact opposite has been happening

 

Link to comment
Share on other sites

5 hours ago, so_whats_happening said:

The only thing I can think of is Kyoto Protocal was enacted in 1997 but I dont believe it made strict cuts on anything just incentivized new cleaner technology paths instead of old paths.  You would think we took another step down with the 15/16 el nino if the super nino struck up something. So at a loss with why there was a 8 year long reduction in cloud cover.

Yes, correlation between the two datasets plotted is weak. In addition to problems with UAH, need to look at clouds more carefully - types, low vs high, location, etc. Also don't trust the site that prepared the chart - specializes in flawed datasets to promote climate denial.

12 hours ago, blizzard1024 said:

Disagree. RSS detains the warmer NOAA14, UAH matches the radiosondes much better.   The RSS upward trend was done to match the flawed surface records. UAH is the best dataset. Why does RSS maintain data from a spuriously warm NOAA14 satellite?  I will agree to disagree. UAH is the gold standard IMO. 

NOAA-14 was dropped because it warms "too much" in UAH's judgement, a qualitative call. Surface records are much less uncertain than satellites because multiple stations can be inter-compared within a region to correct equipment changes or malfunctions, heat island, etc.

  • Like 1
Link to comment
Share on other sites

18 hours ago, bdgwx said:

RSS matches RATPAC better. https://www.ncdc.noaa.gov/sotc/upper-air/201813

The claim that UAH matches radiosondes better comes from Dr. Spencer and Dr. Christy themselves. They also use IGRA as their radiosonde data source. The IGRA website warms users against using their dataset for long term trend analysis.

How can you know that UAH (or any dataset for that matter) is "true" and thus a gold standard?

 

http://www.drroyspencer.com/2019/04/uah-rss-noaa-uw-which-satellite-dataset-should-we-believe/

Link to comment
Share on other sites

2 hours ago, blizzard1024 said:

Telling that Spencer avoided the 1998 to 2004 period of interest when comparing to other series. Below are trends from Dec94 to Jan2009, (broadening both ends to improve stats)

Slope deg/decade

UAH:  -.014

RSS:   .175

HAD5: .167

GISS  .184

NOAA  .146

BEST .154

 

UAH is a clear outlier, for the period of interest, but much closer to the other series before and after. 

 

Link to comment
Share on other sites

16 hours ago, chubbs said:

Yes, correlation between the two datasets plotted is weak. In addition to problems with UAH, need to look at clouds more carefully - types, low vs high, location, etc. Also don't trust the site that prepared the chart - specializes in flawed datasets to promote climate denial.

NOAA-14 was dropped because it warms "too much" in UAH's judgement, a qualitative call. Surface records are much less uncertain than satellites because multiple stations can be inter-compared within a region to correct equipment changes or malfunctions, heat island, etc.

Understandable, i remember from college days of learning it was rather difficult to quantify exactly a precise percentage of cloudiness. Im sure it has definitely improved in the past ten years. I completely understand the whole quality control going on with instrument data, i work at BWI airport and they recently put in a new building which we think has definitely played a role in skewing our observations a bit, so as the faa figures out a better placement or way to confront this we sit gathering data which isnt always too far off but can be quite erratic at times.

 

20 hours ago, LibertyBell said:

It must vary quite a bit from region to region, I can tell you on the east coast the opposite is happening and dew points and rainfall have been on a steep increase, which has led to an explosion of vegetation and allergy levels that last nearly year round now.  Of course in the West the exact opposite has been happening

 

Absolutely the dewpoints have been just dumb over the past 5-10 years. Quite the jump for sure compared to the 90s and 2000s where yes we did get some high dewpoints at times but more often was a dryish heat from my recollection. 

  • Like 2
  • Thanks 1
Link to comment
Share on other sites

4 hours ago, so_whats_happening said:

Understandable, i remember from college days of learning it was rather difficult to quantify exactly a precise percentage of cloudiness. Im sure it has definitely improved in the past ten years. I completely understand the whole quality control going on with instrument data, i work at BWI airport and they recently put in a new building which we think has definitely played a role in skewing our observations a bit, so as the faa figures out a better placement or way to confront this we sit gathering data which isnt always too far off but can be quite erratic at times.

 

Absolutely the dewpoints have been just dumb over the past 5-10 years. Quite the jump for sure compared to the 90s and 2000s where yes we did get some high dewpoints at times but more often was a dryish heat from my recollection. 

This huge rise in dewpoints and rainfall, are the higher temperatures in the Gulf of Mexico and Atlantic to blame for this?  It can't be anything else, with how our tropical season now starts earlier than it did before and how wet and humid our springs and summers have become.

 

Link to comment
Share on other sites

2 hours ago, LibertyBell said:

This huge rise in dewpoints and rainfall, are the higher temperatures in the Gulf of Mexico and Atlantic to blame for this?  It can't be anything else, with how our tropical season now starts earlier than it did before and how wet and humid our springs and summers have become.

 

Maybe but probably overall an expansion in its coverage compared to what it use to be. For this you would have to look at the trends along the coastline are temperatures warmer overall? With overall warmer nights (inland) than days, days seem to be warmer in winter compared to days in summer, we can see how just a bit of added moisture can change our temperature records. I would be curious if moisture content has increased in areas that normally dont experience moisture on a regular basis like the west. I know it would be counterintuitive with more heat and forest fires out west to have more moisture in the air but it would be something of interest to check out at some point. Example: areas like phoenix when heat kicks in having dewpoints in the single digits (F) well now they are in the teens or twenties.

Maybe we are seeing a switch of the AMO?

  • Like 1
Link to comment
Share on other sites

35 minutes ago, so_whats_happening said:

Maybe but probably overall an expansion in its coverage compared to what it use to be. For this you would have to look at the trends along the coastline are temperatures warmer overall? With overall warmer nights (inland) than days, days seem to be warmer in winter compared to days in summer, we can see how just a bit of added moisture can change our temperature records. I would be curious if moisture content has increased in areas that normally dont experience moisture on a regular basis like the west. I know it would be counterintuitive with more heat and forest fires out west to have more moisture in the air but it would be something of interest to check out at some point. Example: areas like phoenix when heat kicks in having dewpoints in the single digits (F) well now they are in the teens or twenties.

Maybe we are seeing a switch of the AMO?

Definitely along the coast too.  Higher mins and some blunting of extremes of highs, but still warmer than normal overall.  The added moisture makes it more difficult to achieve higher maximums but does raise the floor with the higher mins.

I noticed the added moisture in the West.  One thing we need to remember is that added moisture in the air does not necessarily equate to more rainfall (it does in the East but maybe not in the West.)

Link to comment
Share on other sites

Definitely along the coast too.  Higher mins and some blunting of extremes of highs, but still warmer than normal overall.  The added moisture makes it more difficult to achieve higher maximums but does raise the floor with the higher mins.
I noticed the added moisture in the West.  One thing we need to remember is that added moisture in the air does not necessarily equate to more rainfall (it does in the East but maybe not in the West.)

Arizona has been getting dew points in the mid 70s lately with the heavy monsoon storms.
  • Like 1
Link to comment
Share on other sites

1 hour ago, LibertyBell said:

Hopefully that puts a big dent into the major drought in the SW.  I saw there was even a flash flood watch for Death Valley National Park today.

This is what I have been saying. If we collectively decide this is the temperature where we are in dire straits then we will miss out on things like the greening of deserts. Best to let the system run it's course population will self-correct overtime in an ethical way.

People just never want to leave their comfort zone. The age of capitalism and communism is gone yet people keep trying to spill blood in the name of these failed ideologies.

Link to comment
Share on other sites

If you look at the daily global temperature anomalies from University of Maine Climate Change Institute.https://climatereanalyzer.org/wx/DailySummary/#t2anom 

you will see that the daily mean global average temperature from the GFS initialzation is very close to normal for the colder 1979-2000 CFSR baseline mean.  Today's is below a whopping 0.1C above the 1979-2000 baseline.

Capture.thumb.PNG.dc0467e59dcfa0de640074fcfb593daf.PNG

 

This dataset has been averaging very close to .1C to .2C above the 1979-2000 for the past several months similar to UHI.   The CDAS daily temperature is a 0.166C above the 1981-2010 baseline. see below 

cdas-all-globe-t2m_c_anom_1day_back-7473600.png.68f7ce4e7e88e03f8f12bcbda9dabbdb.png

 

So there really isn't anything too unusual going on. Its weather which can be extreme at times. It has always been that way. 

Link to comment
Share on other sites

Create an account or sign in to comment

You need to be a member in order to leave a comment

Create an account

Sign up for a new account in our community. It's easy!

Register a new account

Sign in

Already have an account? Sign in here.

Sign In Now
 Share

  • Recently Browsing   0 members

    • No registered users viewing this page.
×
×
  • Create New...