Guest post by Willis Eschenbach
There’s a new study out from NOAA called “Probable maximum precipitation (PMP) and climate change”, paywalled of course, which claims that global warming will lead to a 20%-30% increase in “probable maximum precipitation”. The abstract says:
Probable Maximum Precipitation (PMP) is the greatest accumulation of precipitation for a given duration meteorologically possible for an area. Climate change effects on PMP are analyzed, in particular, maximization of moisture and persistent upward motion, using both climate model simulations and conceptual models of relevant meteorological systems. Climate model simulations indicate a substantial future increase in mean and maximum water vapor concentrations. For the RCP8.5 scenario, the changes in maximum values for the continental United States are approximately 20–30% by 2071–2100. The magnitudes of the maximum water vapor changes follow temperature changes with an approximate Clausius-Clapeyron relationship. Model-simulated changes in maximum vertical and horizontal winds are too small to offset water vapor changes. Thus, our conclusion is that the most scientifically sound projection is that PMP values will increase in the future due to higher levels of atmospheric moisture content and consequent higher levels of moisture transport into storms.
When I heard that number, a 20%-30% increase in maximum rainfalls, my urban legend detector starting ringing like crazy.
Figure 1. The authors’ guess at how much more rain will be falling by the end of the century.
So … why did my urban legend detector go off from this claim? It has to do with energy.
The press release quotes the authors as saying:
“We have high confidence that the most extreme rainfalls will become even more intense, as it is virtually certain that the atmosphere will provide more water to fuel these events,” said Kenneth Kunkel, Ph.D., senior research professor at CICS-NC and lead author of the paper.
Now, the increase in maximum rainfall is said by the authors to be due to the increase in water vapor in the air. It’s unclear if the 30% increase in maximum rainfall will be matched by a corresponding overall increase in rainfall. However, it is highly unlikely that an increase in water vapor will only increase maximum rainfall events. The authors themselves say that their projections show “a substantial future increase in mean and maximum water vapor concentrations”.
So to be conservative, let’s cut the 30% increase in maximum water vapor down to a 20% increase in mean water vapor, and see what that looks like.
I want to determine how much energy we’re talking about here. Suppose the rainfall were to go up (on average) by about 20% globally. Right now, the globally averaged rainfall is on the order of a metre of rain over the entire surface per year, a bit more or less depending on who is measuring. Twenty percent of that is 200 mm. So we need to evaporate an additional 200 mm over every square metre of surface to produce the stated increase in rain.
It takes 2260 joules of energy to evaporate a gram of water. For each square metre we need to evaporate 200 mm, or 200 kg of water. To evaporate that much water takes 4.52e+8 (452,000,000) joules of energy.
Now, a joule is a watt-second. We need 4.52e+8 joules of energy every year to evaporate the additional water, which is 4.52e+8 watt-seconds per year. Dividing that by the number of seconds in a year (3.16e+7) gives us the change in constant 24/7 watts needed to evaporate that much water. Remember, this is an increase in the constant watts of energy striking every square metre of the planet.
And that number, dear friends, the amount of additional energy needed to increase global evaporation and thus rainfall) by 20%, turns out to be 14.3 W/m2. That’s about the amount of energy increase from three doublings of CO2. Yes, CO2 would have to go from the current ~400 ppmv to about 3,200 ppmv to provide that much extra forcing …
So my urban legend detector is still working fine. There’s nowhere near enough energy available to power that claimed jump in rainfall.
Now, I could leave it there, since the energy necessary to make their claims possible doesn’t exist. But in order to confirm that finding, my plan of further inquiry was to see whether either the intensity of rainfall events or the mean rainfall has changed over the last century. People are always claiming that we don’t have any controls for our experiments when we study nature. But nature provides its own experiments. To start with, we have the warming since 1900. On land, according the Berkeley Earth Surface Temperature data, the temperature has gone up about a degree over that time … but did the rainfall go up as well?
Figure 2. Global precipitation over the land, in mm/day. Data Source 1901-2009: CRU TS 3.10.01 (land)
OK … no increase at all in global rainfall, neither in the monthly means nor in the maximums. So no support for their claims there.
So how about local maximum rainfall events? Are those going up?
For this, we can turn to the temperature and precipitation records of England. For the Central England region, we have daily temperatures and daily precipitation records since 1931. Since 1931, the average Central England Temperature (CET) record has gone up by just under one full degree. So we should see any thermal effect on the maximum rainfall. With that 1°C temperature rise as the backdrop, here’s the maximum central England daily rainfalls, month by month, for the last eighty years.
Figure 3. Maximum daily rainfall, 1931-2012, Central England. Data Source Photo Source
Here, we find the same thing. There is no evidence of any increase in maximum rainfall events, despite a 1° temperature rise.
Hmmm …
The part I really don’t like in all of this is that once again, all of their claims are built on computer models. But what I don’t find is any serious testing of their whiz-bang models against things like the global or the CET temperature and rainfall records. In fact, I don’t see any indication in any venue that any computer models are worth a bucket of warm spit when it comes to rainfall. Computer models are known to perform horribly at hindcasting rainfall, they do no better than chance.
So once again, we’re back in the land of Models All The Way Down. I gotta confess, this kind of thing is getting old. NOAA and NASA appear to be falling further and further behind reality, still churning out useless studies based on useless models.
Just one more waste of taxpayers money.
w.
Discover more from Watts Up With That?
Subscribe to get the latest posts sent to your email.
Lars, You say:
“And the problem to the “recirculation of energy which should come back down” as some have repeated, the problem to [sic] that is simple: the missing hot spot does not allow net energy transfer to come from the top of the atmosphere to the ground.”
The problem for you is that the “…net energy transfer to come from the top of the atmosphere to the ground…” is not necessary. The transfer happens in the troposphere. JP
Lars, By the way, you are correct when you say we have different definitions of “remarkably constant”. To me a 15*C change is not “constant”. And the time frame was not chosen by me, it was laid out by the person making the case for a supposed “remarkable stability”. JP
Willis, I’m disappointed that you chose not respond to my last two questions. I always learn something when you do. I’ve followed through on my attempt to get some feedback from the authors. A pretty esteemed group. Should be interesting to compare your work with theirs. I’ll update you if you like. Just let me know. Feel free to use my email address. Best wishes, JP
John Parsons says:
April 8, 2013 at 11:14 pm
So your source for your comment is an uncited, unreferenced blog post? And you think that covers it?
Color me unimpressed.
W
John Parsons says:
April 8, 2013 at 11:27 pm
Since that says absolutely nothing about “the latitude of Florida”, and it occurred 800 MILLION years ago, and the article was written by Pierrehumbert, yes, you are trusting without verifying. Pierrehumbert is a wild alarmist. He’s using a climate model, all of which are unable to model the current world, to model the world of 800 million years ago Me, I wouldn’t trust a word he says, especially about what happened nearly a billion years ago.
I do appreciate the effort, though. You’re on the right track. Now you just have to find some real science.
w.
Curious George says:
April 9, 2013 at 11:17 am
Rain is returning the energy to the surface? Rain?
The net effect of rain on the surface is COOLING. You’re just throwing stuff at the wall and hoping it sticks.
Energy in general doesn’t mix downwards in the atmosphere. If you have such a downdraft it needs to be forced down and that takes an equivalent amount of energy. There’s no free lunch.
RIght … the entire atmosphere is going to warm enough to provide 15 W/m2 of additional energy to the surface … again, it looks like you’re just writing and hoping it makes sense.
No, YOU THINK Nick Stokes has a valid point … but then you’re a guy who thinks rain warms the earth, so I fear your opinion on this question is worth about as much as Nick’s …
w.
John Parsons says:
April 9, 2013 at 7:54 pm
And I’m disappointed that you don’t have a life. However, I have one, and a day job, and right now I’m on the road.
Your bitching and whining that I’m not answering when Johnny wants an answer are noted, however, and will undoubtedly delay any future answers.
And I do hope you get a life, so you can understand the constraints that others work under.
w.
Willis, I was lucky enough to retire at 27, and really have forgotten what a “day job’ is like. Sorry to be a bother. Safe travels. JP
Willis: your take-down was too late. This morning’s Water & Wastewater News carries the headline that global warming will cause severe precipitation:
http://eponline.com/articles/2013/04/05/severe-precipitation-caused-by-global-warming.aspx
[begin quote]
Severe Precipitation Caused by Global Warming
As greenhouses gases in the atmosphere continue to rise, intense precipitation will become even more intense, according to a new NOAA-led study that has been published in Geophysical Research Letters.
[end quote]
Probable Maximum Precipitation is neither probable nor maximum. The source of this statement is VM Yevjevich “Misconceptions in hydrology and their consequences”:
http://onlinelibrary.wiley.com/doi/10.1029/WR004i002p00225/abstract
which I tracked down via quote in CT Haan “Statistical Methods in Hydrology”, P. 177. I have quoted Yevjevich’s abstract in full:
“Keywords: Climatic change; floods; forecasting; ground water; precipitation
“Several misconceptions have been introduced into hydrology that have had adverse consequences on the science and on water-resources development. Persistent use of the concept of maximum precipitation and maximum probable precipitation, for which there is no physical proof, has discouraged research into the structure and probability of extreme events, and may have led to an unwarranted sense of security concerning flood-control works. Attempts at long range forecasts of water supply based entirely on meteorological processes have misdirected research and raised false expectations. A misconception that hydrologic processes are composed of a limited number of hidden periodicities has retarded the use of modern stochastic analyses of time series. Cloud-seeding to increase numbers of raindrops rather than their coalescence may have had a negative effect on precipitation in arid regions. Considering ground water, instead of the aquifer, as a resource has stressed the technology of withdrawal at the expense of study of methods of recharge and has led to much unplanned overdraft of ground water. Use of descriptive instead of numerical variables has delayed the application of modern statistical methods to planning the exploration of the ground-water environment. As a result of the neglect of the stochastic properties of porous mediums, fluid mechanics theory has not departed far from the original works of Darcy. Hydrology has developed slowly because it has been considered an appendage of hydraulic engineering rather than a natural science.”
John Parsons says:
April 9, 2013 at 7:40 pm
The problem for you is that the “…net energy transfer to come from the top of the atmosphere to the ground…” is not necessary. The transfer happens in the troposphere. JP
John the troposphere does not change the rules for net energy transfer, the physic applies, it is still our universe:
http://apollo.lsc.vsc.edu/classes/met130/notes/chapter1/vert_temp_trop.html
“rate of temperature decrease is about 6.5 degrees Celsius per 1 km (called the lapse rate)”
John Parsons says:
April 9, 2013 at 7:47 pm
Lars, By the way, you are correct when you say we have different definitions of “remarkably constant”. To me a 15*C change is not “constant”. And the time frame was not chosen by me, it was laid out by the person making the case for a supposed “remarkable stability”. JP
Color me unimpressed. How constant was the orbit of the Earth in terms of billion years? How constant was the duration of the day during the same time frame? How constant is even the quantity of water on the Earth in the same time frame? How constant were the continents & the ocean currents? How constant was the temperature on Mars?
In this time frame 15°C variation is remarkably constant, but yes everybody can have an opinion.