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We’ve had a lot of requests for a single document to summarize the blog posts so far. Some people like to print and read all in one place (that’s me). I hope this helps. Skeptics on threads are busy cracking away at getting a rerouting mechanism fleshed out. The quest… thanks to everyone who is supporting this project in so many ways, whether it be via email, sharing with others, or through donations. We really do appreciate it. We’re going to figure this out. :- ) — Jo
Dr David Evans, 15 November 2015, David Evans’ Basic Climate Models Home, Intro, Previous.
I’ve prepared a synopsis of the 19 posts in this series. It’s a standalone document of 20 pages that explains the important points, some from a different point of view than the blog series. The summary and introduction at the front are non-technical and suitable for politicians and journalists. The synopsis is light on for equations — there are some, but you can pretty much ignore them because it mostly reads fine without them.
If you wanted to show someone the series, this is the document to use. It is downloadable from the project home page, […]
Don’t underestimate the importance of the nameless basic model. It sounds small, but in the culture and philosophy of climate science it’s bigger and carries more weight than the massive hairy GCMs. Like an invisible gossamer web, it’s overarching. It spans and defines all the other models. When they produce “dumb” answers, the basic model holds them in, for thou shalt not stray too far from the climate sensitivity defined by the basic model. It defines what “dumb” is. (It’s just “basic physics” after all.) One model to bind them all. What could possibly go wrong?
A lot, apparently. The physics might be right, but the equations are calculating imaginary conditions. The answers might be arithmetically correct but useless at the same time. They miss the real route that energy flows through to space.
By definition, as long as the basic model is wrong, the GCM models can never get it right.
It’s not like climate scientists consult the oracle of the basic model every day, or even once a year… they don’t need to. They were taught it their climate larval stage, often long before they’d written one paper. The basic model shows that the warming of […]
Image: NASA
In years to come it may be recognized that this blog post produced the first modeled accurate figure for climate sensitivity. Equilibrium Climate Sensitivity sounds dry, but it’s the driving theme, the holy grail of climate science. The accurate figure (whatever it is) summarizes the whole entirety of carbon dioxide’s atmospheric importance. That number determines whether we are headed for a champagne picnic or a baking apocalypse.
To calculate a better estimate, David identified the flaws of the conventional basic model, and rebuilt it. The basic climate model is the top-down approach looking at inputs and outputs of the whole system. It defines the culture and textbooks of the modern global warming movement. GCMs (the big hairy coupled global models) are bottom-up approaches, doomed to failure by trying to add up every detail and ending up drowning in mile-high uncertainty bands. But the GCMs are ultimately tweaked to arrive at a similar ballpark climate sensitivity as the textbook model for the “basic physics” dictates. Hence this core model is where the debate needs to be. (Everyone knows the GCMs are broken.)
For decades the world of conventional climate research has been stuck in a groundhog day […]
Things are hotting up. After all the hard work of the past few posts, the payoff begins. By solving the flaws inherent in the basic conventional model we solve some of its biggest missed-predictions. And the clincher for conventional models has always been the missing hot spot. Without it, over half the projected warming just vanishes. And if it is telling the tale of a negative type of feedback instead of a positive one, then all bets are off — not three degrees, not even one degree, it’s more like “half” a degree. Go panic about that.
Here David gets into the empirical data — the radiosondes, the satellites, and shows how his model fits their results, whereas the establishment models have repeatedly been forced to deny them. Twenty eight million radiosondes get the wrong results: how many ways can we adjust them? Tweak that cold bias, blend in the wind shear, change the color-scales, homogenize the heck. Smooth, sort, shovel and grind those graphs. The fingerprint of CO2 was everywhere in 2005, though gradually became the non-unique signal of any kind of warming, but it still wasn’t there. It kept being “found”, though it was never reported missing. […]
In typical style I looked at this draft and told David that the second half of his post should be at the top (that’s where he discusses how his model solves so many problems). He replied that the equations were the most important part, and he wasn’t going to flip them around. So, for readers who don’t speak mathematica-lingua, all I can say, is don’t miss the second half below.
Also in typical style, David prefers this picture he’s just drawn in his diagramming software, to my cartoon in the intro to post 11:
In this post, David combines the two smaller models to make one basic climate model (that’s the sum-of-warmings and the OLR models). Unlike the mainstream conventional basic model that underlies the entire establishment culture and philosophy, the alternative model uses more empirical data (and from the real world too, not just the lab). It’s also less reliant on hypothetical partial derivatives. Plus, in the alternate model, different forcings can cause different responses. In the conventional model, the architecture assumes the climate responds to to all forcings the same way.
CO2 has a warming effect on the atmosphere, rather than just on the surface, […]
OLR — outgoing longwave radiation — is so key, so central to the climate debate that if we had top notch data on the radiation coming off the planet, we would have solved the effect of extra CO2 a long time ago. That we don’t have a specific satellite monitoring these changes in detail is like the dog that didn’t bark. Apparently a specialist OLR satellite was to be launched in 2015. More info on the RAVAN Satellite here (was supposed to launch in Sept 2015). (UPDATE: Planned for 2016) h/t siliggy.
There are four main pipes to space, and in David’s work each pipe is considered separately. The conventional model assumes that increasing atmospheric CO2 constricts the CO2 pipe, which warms the surface, causing more evaporation, which then constricts the Water Vapor pipe (this is the “water vapor amplification”, even more constriction of radiation to space by water vapor that forces the surface to emit more by being yet warmer). But the missing hot spot tells us that this theory is wrong. In this OLR model, the water vapor pipe could either expand or constrict. An expansion means a drop in the height of the emissions layer, […]
Here’s an idea for commenters to sink their teeth into — Stephen Wilde postulates a mechanism where convection can neutralize the effect of changes in greenhouse gases. The focus in David’s series of blog posts has been on radiation, but the troposphere is governed by convection. The tropopause is the boundary where convection runs out of oomph, and above the tropopause, in the stratosphere, radiation rules supreme. Airliners like to fly at the bottom of the stratosphere (“thirty thousand feet”), just above the convection and water vapor in the troposphere, because it’s calm. But sometimes turbulence from the troposphere punches up into the stratosphere, so think of Fig 1 below if you are asked to suddenly sit in your seat and fasten your seat belt.
All the focus on radiation imbalances tends to ignore the powerful effects of gravity and convection. To get a sense of how important gravity is, ponder that a mere 3km above the surface the pressure is 300hpa lower, but gravity stops the surface air from rushing up and equalizing that. Imagine if there were two sites on the ground where pressure was, say, 1000hpa and 700hpa, and they were only three kilometers apart, we’d […]
Here we get into the nitty-gritty (as much as we can) of the energy coming off the planet. Looking at the spectrum of outgoing infrared we can learn a lot from the Nimbus data. In the graph below we can see a lot more energy comes from certain wavelengths, and given that the curve would follow the “grey” shape if it was a single body emitting, we can also see how some “pipes” are blocked.
The CO2 band shows a large obvious indentation, but don’t be fooled, most of that curve looks the same at much lower concentrations of CO2. As CO2 levels rise in our atmosphere there is little effect on the radiance of the coldest parts of the CO2 band, what changes is in the “wings”.
The hotter a thing is, the more energy it radiates, so in this graph the higher amounts of OLR (outgoing longwave radiation) are coming off the warmer surface or air closer to it. Turn things upside down in your mind, the high readings come from low-altitude places which are warm (like the surface), and as the readings get lower in radiance, they must be coming from colder spots at higher altitudes. […]
We welcome collaboration, but empty, uninformed ill-will doesn’t help the unresourced skeptics to beat the billion dollar green machine. It’s time for Lucia to admit she got it wrong. Lucia’s second post failed to clarify anything. She didn’t acknowledge that she had not found a single real mistake David’s work, nor did she apologize for getting so much wrong. Having decided everything David was doing was “crud” after reading two paragraphs, she now has the onerous and pointless task of trying to defend a hasty uninformed position.
Lucia didn’t have to dig the hole deeper but she tried. To turn her mistaken accusations into something useful she transparently shifts the goals and won’t join the dots. Evans was critiquing Held, Soden, and Pierrehumbert. He described how they relied on partial derivatives of dependent variables, impossibly holding everything else constant in climate and thereby incurring unknown errors. Lucia now says “but they could’ve done it a different way without them” and perhaps hopes no one notices the unspoken admission that David Evans was right.
The bizarre thing is that you don’t need a maths degree to know her method is silly on its face. In […]
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In most ways, David Evans’ alternative model is exactly the same as the conventional model. But a reconnection of one forcing, and an additional factor, can make all the difference. Finally, climate model architecture is getting analyzed and discussed — the conventional structure has been in place for over 40 years.
In the conventional basic model the radiation imbalance caused by CO2 is treated like extra sunlight, amplified by the same feedback processes that amplify warming caused by the sun. But as we explained, the effects of CO2 are not just confined to the surface of Earth, but spread through the atmosphere. In the alternative model the warming caused by CO2 is allowed to have its own unique response. Only after the separate “warmings” of the Sun and CO2 are calculated can they be added together. The conventional model adds them too soon, while they are still radiation imbalances, and assumes the Earth’s climate responds to both in the same way — it’s too simplistic.
David’s model also allows for other factors to change cloud cover, with the addition of an input for externally driven albedo (EDA). In conventional models, clouds are just a feedback to surface warming, […]
Basic models take a top down approach, focusing on gross input and output rather than all the details within the system (which is mainly left to the feedbacks parameter). This makes them very different to the GCMs, which attempt to add up the climate from the bottom up and predict based on adding up grids and guesstimates of clouds, humidity, ice, etc.
The energy coming in to the Earth is called absorbed solar radiation (ASR). It varies significantly. The Earth will absorb the peaks and troughs of this to a certain extent. If we step back and look at the big picture, the question is how many years does it take for a step up in incoming energy to spread its way through the climate system, vanish into the top layer of the ocean, come back out and be released to space. To some extent that extra energy gets absorbed for a while before being released. David analyzed this system from the outside, graphing it like a low pass filter in electronics. (How much “noise” of spikes and troughs in ASR is being smoothed out by the Earth’s climate?)
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In a […]
All pipes lead to Space
Inexorably, energy is headed for the coldest vacuum. It’s just a question of how long and what path it takes to get there. On Earth there are four main “pipes” to space — the CO2, water vapor, cloud tops, and surface pipes (see post 6). The basic establishment model treats “trapped” heat as if it were “adding heat” (see post 9). But partially blocking one exit pipe out of four is not the same as adding energy to the incoming pipe. Adding more energy on the incoming side means the total outflow must be higher. But merely slowing the outflow in one pipe means the total outflow remains the same, it just redistributes itself among the four outflow pipes.
David is proposing a paradigm shift in how a basic climate model is organized. This post is a road-map for building an alternative model.
The current paradigm starts from the assumption that reducing the outflow in one pipe is equivalent to the effect of increasing the inflow on the single incoming pipe — it is a radiation balance, where all imbalances are equivalent regardless of origin. Doubling CO2 is “equal” to 2% […]
Here’s a lesson in when to post and when to email. Over at the Blackboard, Lucia couldn’t make sense of David Evans’ post on partial derivatives, but instead of emailing us or commenting here, she published her unresearched thoughts and and asked her readers instead. Only most of them didn’t know either and it didn’t help that the quotes were misattributed, and Lucia’s assumptions were wrong. Together they generated a thread of fog, arguing about irrelevant points in maths and models that didn’t apply. Having admitted that she is confused about what David was saying, in comments she went ahead and called him confused, declaring he didn’t understand maths, and was spouting nonsense. (Steady on Lucia.) In the nicest possible way David explains he’s right, she’s wrong. And he had defined and cited everything correctly too (it was all in the post, or linked to it).
Her post is titled: “Questions to David Evans: What do you mean about partial derivatives?”. Lucia had my email, but posted: “I’m hoping David or readers who understand his point can clarify for me”. However she didn’t email us after that either. So by the time I tripped over […]
How much sunlight makes it to the surface?
We all know how powerful clouds are. Just stand outside on a patchy day — feel the goosebumps. These megaton floating conglomerates of water act as vast shields — they cover 60% of the surface of Earth, and even a small change makes a big difference. While changes in the total amount of direct sunlight coming off the sun are very small, the changes to the amount of reflecting surfaces floating above Earth are, proportionally, at least twice as large, and possibly much much more influential. The IPCC includes changes in sunlight (TSI), so it does not make sense to ignore the larger and more powerful changes in the Earth’s albedo (fraction of sunlight that is reflected) due to “external” factors (due to factors other than feedbacks to surface warming). Both contribute to the amount of sunlight heating the surface, or “absorbed solar radiation” (ASR) (before feedbacks).
There are lots of reasons clouds might change that are not included in standard climate models. Just for starters — cosmic rays may seed cloud formation. Aerosols released by plants, plankton and marine life do — some aerosols are included, […]
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The ground is not the sky
Here’s a big big flaw that is easy for anyone to understand, yet has lain at the core of the climate models since at least 1984. Indeed, you’ll wonder why we all haven’t been chuckling at this simplistic caricature of our atmosphere for 31 years.
The theory underlying the alarm about CO2 is built around a bizarre idea that blocking outgoing energy in the CO2 pipe is equivalent to getting an increase in sunlight. The very architecture of all the mainstream climate models assumes that the Earth’s climate responds to all radiation imbalances or “forcings” as if they were all like extra sunlight. (We call that extra absorbed solar radiation (ASR) to be more precise. It’s all about the sunlight that makes it through to the surface.)
Extra sunlight adds heat directly to the Earth’s surface, and maybe the climate models have correctly estimated the feedbacks from clouds and evaporation and what-not to surface warming. But it is obvious, in a way even a child could comprehend, that this is not the same as blocking outgoing radiation in the upper atmosphere, which is the effect of increasing CO2. […]
Good news, a spot of media coverage.
Perth Edition, The Sunday Times
Miranda Devine: Perth electrical engineer’s discovery will change climate change debate
Photo: AustralianClimateMadness
A MATHEMATICAL discovery by Perth-based electrical engineer Dr David Evans may change everything about the climate debate, on the eve of the UN climate change conference in Paris next month.
A former climate modeller for the Government’s Australian Greenhouse Office, with six degrees in applied mathematics, Dr Evans has unpacked the architecture of the basic climate model which underpins all climate science.
He has found that, while the underlying physics of the model is correct, it had been applied incorrectly.
He has fixed two errors and the new corrected model finds the climate’s sensitivity to carbon dioxide (CO2) is much lower than was thought.
It turns out the UN’s Intergovernmental Panel on Climate Change has over-estimated future global warming by as much as 10 times, he says…
The series of posts flows under the tag: “Climate Research 2015″
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Energy is emitted to space from many different heights in the atmosphere, depending on the wavelength (not to scale, suggestive only).
One more quick post of mostly uncontroversial foundation for the math-and-physics-heads among us. But it’s a must for anyone who wants to talk Stefan-Boltzmann and follow the details of the next posts. My intro here, just has the gist without the equations.
Mostly the IPCC will agree with this post, but they might be a bit snooty that David thinks their “effective temperature” is too much of an approximation conceptually, and the slightly more complicated idea of a “radiating temperature” is needed. Strictly, the effective temperature idea treats Earth like it is a black-body at infrared, which it isn’t really. Earth is almost a black-body, but not quite.
There is no single layer that radiates to space, instead emissions come from many different heights, depending on the wavelength. We could average the emissions into “one layer”, but doing that would lose detail that matters when computing sensitivity to increasing CO2.
Technically the Stefan-Boltzmann law is not supposed to be applied to Earth, because there is no single physical radiating surface […]
Conventional models assume increasing atmospheric CO2 warms the surface, then apply the feedbacks to the surface warming. But if feedbacks start up in the atmosphere instead, everything changes.
This is a post with big potential. A feedback the other climate models miss?
All the establishment models assume carbon dioxide warms the sky, which leads to the surface warming*, and the feedbacks then apply to the surface warming. It’s in the model architecture, the models can’t do it any other way. But what if the feedbacks don’t wait — what if the feedbacks start right away, up in the atmosphere? What if, say, CO2 warms the air, and that affects humidity and or clouds right then and there? These would be feedbacks operating on tropospheric warming, and they can reroute that energy.
Potentially, this blows everything away. If the energy blocked by increasing CO2 is merely escaping Earth through emissions from another gas in the atmosphere, like say, the dominant greenhouse gas, water-vapor, then could this explain why the effect of Co2 has been exaggerated in the conventional models?
We call this the “rerouting feedback” because when it’s harder for energy to escape to space through the CO2 pipe, this […]
The Earth’s atmosphere is a leaky bucket, with four big holes (and a lot of little ones).
Whole libraries have been filled with talk of a single characteristic emissions layer — a simplistic idea that there is one effective “surface” that radiates to space. It exists in an abstract sense, after sufficient averaging, but it’s a paradigm that doesn’t help us think clearly. In any case, it’s too simple for our purposes in this series. In reality there are many layers that radiate to space, different for each type of molecule that can emit longwave radiation (which means infrared). Then there are the surface and cloud-tops too.
Energy comes in one way but leaves through at least four different paths.
To follow this series you’ll need to understand the concept of four pipes through which energy flows to space. It’s a powerful idea and big advance on the simpler notion of one-pipe-in and one-pipe-out. For those not as familiar with photons and excited molecules, you may want to read the “Background” section at the end of the post first.
For a photon there are a lot of paths to space
Some photons at Earths surface will be at […]
And the series continues, poking another hole in the models, with bigger holes to come.
See the larger version in the post below
What if CO2 caused more greenery, which produced more volatile organic gases, which increased rainfall and changed cloud cover? The models would be blind to it. They’re “supercomputer-complicated”, but miss many of the feedbacks on Earth. The only feedbacks the models consider are ones that occur because of changes in temperature. And worse, it’s not just changes in temperature, but specifically, changes in surface temperature.
If, say, cosmic rays caused a change in cloud cover, or the Sun influenced ozone which in turn caused the jet streams to shift closer to the equator, there are no feedbacks worth mentioning according to the large GCM models. The conventional basic model assumes, is built on the idea that nothing causes changes to Earth’s climate unless it works through surface heating — and the GCMs have the same architecture. Cloud cover does not change ice cover. Ocean currents don’t change cloud cover. Changes in biology don’t change clouds. Only changes in surface temperature changes cloud cover.
It’s a good place to start looking for missing negative feedbacks (though, […]
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