Guest Post by Willis Eschenbach [See update at the end.]
Let me start explaining the link from Picasso to climate science by looking at what Dr. Nir Shaviv called “the most boring graph I have ever plotted in my life”.
This is the graph of the changes in the best estimate of the range of what is called “climate sensitivity” over the last forty years or so.
What is climate sensitivity when it’s at home? To explain that, I’ll have to take a slight detour. First, downwelling radiation.
“Downwelling” in climate science means headed down towards the planetary surface. Downwelling radiation is the total radiation going downwards towards the surface. It is composed of sunshine (shortwave) plus thermal radiation from the atmosphere (longwave). In climate science, this quantity, total downwelling radiation, is called “forcing”, abbreviated “F”
The central paradigm of modern climate science is that if you change the amount of downwelling radiation (forcing), that the surface temperature perforce will change. The claim is that everything else averages out, and if the forcing increases, then surface temperature needs to change to maintain the global energy balance. It has to change. It must.
In short, the central paradigm of modern climate science is the following:
In the long run, global temperature change is proportional to global forcing change.
The putatively constant proportion between the two, which is the temperature change divided by forcing change, is called the “climate sensitivity”.
“Climate sensitivity” is often expressed as the assumed change in temperature given a change of 3.7 watts per square metre (W/m2) in downwelling radiation. The determination of this so-called “climate sensitivity” is a central question arising out of the paradigm that temperature change is proportional to temperature change.
Which leads me to the most boring graph below. It shows the changes over time in the estimate of the value of the climate sensitivity.
Figure 1. Changes over time in the estimate of the climate sensitivity parameter “lambda”. “∆T2x(°C)” is the expected temperature change in degrees Celsius resulting from a doubling of atmospheric CO2, which is assumed to increase the forcing by 3.7 watts per square metre. FAR, SAR, TAR, AR4, AR5 are the UN IPCC 1st, second, third, fourth and fifth Assessment Reports giving an assessment of the state of climate science as of the date of each report
It is worth noting that since 1979, entire new scientific fields like DNA analysis have first been envisioned, then have come into being, and now have reached amazing levels of development … and during that same time, what Dr. Shaviv rightly calls “the most important question in climate” has gone nowhere. No progress at all.
Since 1979, the amount of computing power that we have available, both as individuals and large organizations, has skyrocketed. My trusty PowerMac has more computing ability than most universities had available in 1979. The cost has dropped as well, from $100,000 per “MIPS” (million instructions per second) to less than $1 per MIPS today. And the speed has gone through the roof, with supercomputers running climate models at more than a trillion floating point operations (which have the lovely name of “TeraFLOPs”) every second. The number of people investigating the value of climate sensitivity has also grown over time. And billions and billions of dollars have been spent on trying to answer the question.
So … since the Charney report on climate sensitivity in 1979 we’ve had huge, stupendous increases in:
• Computing power working on the question
• Hours of intensive research applied to the question
• Discussion, debate, and interest in the question
• Money spent on the question
And despite those huge increases in time, work, discussion, and computer power, the investigation of the question of the value of climate sensitivity has gone exactly nowhere. No progress.
How can we understand this scientific oddity? What is the reason that all of that valuable time, money, and effort has achieved nothing? I mean zero. Nada. No movement at all. The most boring graph.
Let me suggest that climate science is the victim of what I call the “Picasso Problem”. Pablo Picasso once said something that has stuck with me for a long time. He said:
“What good are computers? They can only give you answers.”
Now, I wrote my first computer program in 1963, more than half a century ago. I was sixteen. It ran on a computer the size of a small room. I’ve been programming computers ever since then. I’ve written programs to do everything from designing fabric patterns for huge catenary tents, to calculating next year’s tides from this year’s tide tables, to making the plasma-cutting files to guide the cutting of the steel parts for building 25-metre fishing boats, to analyzing the data and doing the math and creating the graphics for this very post. And over the years I’ve made big bucks with my succession of computers.
So when I read that Picasso was dissing computers with that statement, my initial response was to say “Whaa? Computers are great! What is this mad artist on about? I’ve made lots of money with my computer. How can they be no good?”
But upon more mature reflection, I realized that Picasso was right. Here’s what he meant:
Even the best computer can’t give you the right answer unless you ask it the right question.
To me, this was a crucial insight, one that has guided many of my scientific peregrinations—don’t focus too much on the answers. Put some focus on the questions as well.
So regarding climate science, what is the wrong question, and what is the right question? Once again, please allow me to get side-tractored a bit.
I first got interested in climate science around the turn of the century because of the increase in serial doomcasting regarding some rumored upcoming Thermageddon™. So I started with the basics, by learning how the poorly-named “greenhouse effect” was keeping the earth far warmer than the temperature of the Moon, which is at the same distance from the sun.
However, along the way, I read that the best estimate of the warming over the entire 20th century was on the order of 0.6 degrees Celsius. When I read that, I thought … “Whaa … less than one degree??? All this fuss and the temperature has changed much less than one degree?”
I was surprised because of my experience repairing machinery which had a governor, and my experience with solar energy. I viewed the climate as a giant solar-driven heat engine, wherein the energy of the sun is converted into the ceaseless movement of the atmosphere and the ocean working against the brake of friction against the mountains and shores and the endless turbulent losses.
When one analyzes the efficiency or other characteristics of a heat engine, or when one uses tools like the Stefan-Boltzmann equation to convert temperature into the equivalent amount of thermal radiation, you have to use the Kelvin temperature scale (abbreviated “K”). This is the scale which starts at absolute zero. Temperature is a function of the motion of the molecules or atoms involved. And absolute zero is where molecular motion stops entirely.
You can’t use degrees Celsius or Fahrenheit for these calculations, because °C and °F have arbitrary zero points. You have to use the Kelvin scale, it’s the only one that works. Kelvin has the same size units as Celsius, just a different zero point, which is at minus 273.15°C (minus 459.67°F).
Now, the average surface temperature of the Earth is on the order of 14° Celsius, which is 57° Fahrenheit … or 287 Kelvin. And with that average global temperature of 287 Kelvin, the global temperature variation of 0.6 K over the 20th century is a temperature variation of a fifth of one percent.
This was the oddity that shaped my investigation of the climate … during a hundred year period, the temperature had varied by only about one fifth of one percent. This was amazing to me. I’d had lots of experience with governed systems because of my work with electrical generators. These need to be tightly governed so that their speed remains constant regardless of the changing load on the system. And what I’d found in my work with mechanical governors is that it’s quite hard to regulate a mechanical system to within one percent.
Yet despite droughts and floods, despite huge volcanic eruptions, despite constantly changing global cloud cover, despite all kinds of variations in the forcing, despite the hemispheric temperatures changing by ~ 13°C twice over the course of each and every year, despite the globe being balanced on a greenhouse effect which is holding it on the order of ~ 50°C warmer than the moon … despite all of those variations and changes, the average temperature of the Earth didn’t vary by a quarter of one percent over the entire 20th century.
That is amazingly tight regulation. Here’s a real-world example of why I was surprised by that stability.
I was looking at the speedometer today with my truck on “cruise control”. Cruise control in your car is a governor that keeps the speed of the vehicle the same regardless of changes in load on the truck. I set it for 50 miles per hour. Up and down hills it varied by plus and minus one mile per hour. That’s a computer-controlled engine that is speed-regulated to within ±2%, pretty tight regulation … but the Earth’s temperature is far better regulated than that. It stays within less than plus or minus one tenth of a percent.
To me at the time, that thermal stability was a clear sign of the existence of some unknown of natural thermostatic processes that acted in a very efficient manner to maintain the Earth’s temperature within those narrow bounds. So my own quest in the field of climate science was to find out what the natural phenomena were that explained the tight regulation of century-long planetary surface temperatures.
Which left me in a curious position. All of the established climate scientists were, and still are, trying to find out why the temperature is changing so much. They spend time looking at graphs like this, showing the variations in the Earth’s surface temperature:
Figure 2. HadCRUT global average surface temperature anomaly.
On the other hand, because I’m someone with an interest in heat engines and governors, I was trying to find out why the temperature has been changing so little. I spent my time looking at the exact same data as in Figure 2, but expressed in graphs like this:
Figure 3. HadCRUT global average actual surface temperature (the same data shown in Figure 2) and also the approximate average lunar temperature, in kelvin.
And that brings me back, after plowing that distant field, to the question of climate sensitivity and to Picasso’s prescient question, viz: “What good are computers? They can only give you answers.”.
I say that we have made zero progress in four decades of attempting to measure or calculate climate sensitivity because we are using our awesome computer power to investigate why the global temperature changes so much.
For me, this is entirely the wrong question. The question that we should be asking is the following:
Why does the global temperature change so little?
After much thought and even more research, I say the reason that global average temperature changes so little is that temperature is NOT proportional to forcing as is generally believed. As a result, the so-called “climate sensitivity” is not a constant as is assumed … and since it is not a constant, trying to determine its exact value is a fool’s errand because it has none. That’s why we can’t make even the slightest advance on measuring it … because it’s a chimera based on a misunderstanding of what is happening.
Instead, my hypothesis is that the temperature is maintained within narrow bounds by a variety of emergent phenomena that cool the earth when it gets too hot, and heat it up when it gets too cool. I have found a wide variety of observational evidence that this is actually the case. See the endnotes for some of my posts on my hypothesis.
But hey, that’s just my answer. And I freely agree that my answer may be wrong … but at least it is an answer to the right question. The true mystery of the climate is its amazing thermal stability.
Finally, how did an entire field of science get involved in trying to answer the wrong question? I say that it is the result of the 1988 creation of the Intergovernmental Panel on Climate Change (IPCC) by the United Nations.
In 1988, the field of climate science was fairly new. Despite that, however, the UN was already convinced that it knew what the problem was. Typical bureaucratic arrogance. As a result, in the UN General Assembly Resolution 43/53 from 1988, the Resolution which set up the IPCC, it says that the UN General Assembly was:
Concerned that certain human activities could change global climate patterns, threatening present and future generations with potentially severe economic and social consequences,
Noting with concern that the emerging evidence indicates that continued growth in atmospheric concentrations of “greenhouse” gases could produce global warming with an eventual rise in sea levels, the effects of which could be disastrous for mankind if timely steps are not taken at all levels,
And in response, it jumped right over asking if whether or not this was scientifically correct, and went straight to taking action on something that of course, the General Assembly knew nothing about. The Resolution says that the General Assembly:
… Determines that necessary and timely action should be taken to deal with climate change within a global framework;
Calls for action always make bureaucrats happy. So the IPCC, an expressly political “Intergovernmental” organization, became the defacto guiding light for an entire field of science … which turned out to be a huge mistake.
Now, up until that time, and since that time as well, every other field of science has managed to make amazing strides in understanding without any global “Intergovernmental” panel to direct their efforts. We’ve had astounding successes with our usual bumbling catch-as-catch-can scientific method, which involves various scientists working fairly independently around the planet on some scientific question, sometimes cooperating, sometimes competing, without needing or wanting anyone to “summarize the science” as the IPCC claims to do.
And given the lack of progress shown by the “Most Boring Graph” at the top of this post, I’d say that the world should never again put a bunch of United Nations pluted bloatocrats in charge of anything to do with science. If we had set up an “Intergovernmental Panel on DNA Analysis” when the field was new, you can be certain that long ago the field would have gone uselessly haring down blind alleys lined by nonsensical claims that “97% of DNA scientists agree” …
Over at Dr. Judith Curry’s excellent blog, someone asked me the other day what I didn’t like about the IPCC. I replied:
Here are some of the major reasons. I have more.
First, it assumes a degree of scientific agreement which simply doesn’t exist. Most people in the field, skeptics included, think the earth is warming and humans may well have an effect on it. But the agreement ends there. How much effect, and how, and for how long, those and many other questions have little agreement.
Second, it is corrupt, as shown inter alia by the Jesus Paper.
Third, it generally ignores anything which might differ from climate science revealed wisdom.
Fourth, it is driven by politics, not by science. Certain paragraphs and conclusions have been altered or removed because of political objections.
Fifth, in an attempt to be inclusive of developing countries, it includes a number of very poor scientists.
Sixth, any organization that ends up with Rajendra Pachauri as its leader is very, very sick.
Seventh, they’ve ignored actual uncertainty and replaced it with a totally subjective estimate of uncertainty.
Eighth, it lets in things like the Hockeystick paper and the numerous “Stick-alikes” despite them being laughably bad science.
Ninth, it makes “projections” that have little to no relationship to the real world, like Representative Concentration Pathway 8.5 (RCP 8.5).
Tenth, it generally excludes skeptics of all types, either directly or because skeptics know better than to associate with such an organization.
Eleventh, anyone making “projections” that go out to the year 2100 is blowing smoke up your fundamental orifice.
Twelveth, it is far, far too dependent on untested, unverified, unvalidated climate models.
Thirteenth, the IPCC generally thinks without thinking about it that warming is bad, bad, bad … which is the opposite of the actual effects of the warming since the Little Ice Age.
Fourteenth, the IPCC was given the wrong task at its inception. Rather than setting out to find what actually controls the climate, it was given the task of finding out how much CO2 we could emit before it became dangerous. That tasking assumed a whole host of things which have never been established.
Fifteenth … aw, heck, that’s enough. I have more if you are interested.
So … that’s the climate Picasso Problem. The field of climate science is trying to use computers to find an answer to the wrong question, and as a result, the field is going nowhere.
[UPDATE]
In the comments below, someone brought up the following graphic of recent estimates of climate sensitivity and said that it showed I was wrong about the climate sensitivity.
Here is my answer from below:
Thanks, David. The discrepancy in your first graph is much more apparent than real. Here are the recent ECS estimates overlaid on the Charney/IPCC data:
As you can see, the only ones outside the IPCC uncertainty limits are the estimates at 5 & 6 °C per doubling of CO2.
Here’s a boxplot of the recent estimates
The recent estimates are not at all unusual given the Charney/IPCC estimates.
Finally, you still haven’t grasped the nettle. The surface temperature is NOT a function of the forcing. For example, in large areas of the Pacific, the surface temperature controls the amount of sunshine. Here’s a plot showing that result.
Correlation between the solar radiation at the surface, and the surface temperature. This is calculated on a 1° x 1° gridcell basis.
Now, the areas in green and blue are areas in which, as the temperature goes UP, the amount of sunshine hitting the ground goes DOWN.
So here’s the question. What is the “climate sensitivity” in those areas?
The answer, of course, is that in such a situation the entire concept of climate sensitivity goes out the window. In those areas, the temperature is NOT a function of the forcing, linear or otherwise. Instead, in those areas, the forcing is a function of the temperature.
That’s the point I’ve been trying to make. The fundamental idea underlying modern climate science is incorrect—temperature is NOT a function of forcing.
So yes, people can calculate the putative “climate sensitivity” and get various answers … but it is a meaningless quest, and the results carry no weight at all.
My best to you,
w.
Here, we’re still in haze and smoke from the Camp Fire, and the number of fatalities is over seventy. I’m wearing an N95 mask when I go outside. Here’s the latest smoke map … Anthony Watts is up in Chico, in the bright red spot at the top, over 100 micrograms per cubic metre of smoke. I’m near the coast to the west of Santa Rosa, north of San Francisco, where it’s much better but still bad.
Keep a good thought over the fire victims, it’s hard times for all.
My best wishes to every one,
w.
PS—As usual, I ask that when you comment, please quote the exact words you are discussing, so we can all understand both who and what you are replying to.
FURTHER READING: These are some of my posts explaining my hypothesis regarding why the global temperature is so stable, and providing evidence for the hypothesis
The Thermostat Hypothesis 2009-06-14
Abstract: The Thermostat Hypothesis is that tropical clouds and thunderstorms actively regulate the temperature of the earth. This keeps the earth at a equilibrium temperature.
Which way to the feedback? 2010-12-11
There is an interesting new study by Lauer et al. entitled “The Impact of Global Warming on Marine Boundary Layer Clouds over the Eastern Pacific—A Regional Model Study” [hereinafter Lauer10]. Anthony Watts has discussed some early issues with the paper here. The Lauer10 study has been controversial because it found that…
The Details Are In The Devil 2010-12-13
I love thought experiments. They allow us to understand complex systems that don’t fit into the laboratory. They have been an invaluable tool in the scientific inventory for centuries. Here’s my thought experiment for today. Imagine a room. In a room dirt collects, as you might imagine. In my household…
Further Evidence for my Thunderstorm Thermostat Hypothesis 2011-06-07
For some time now I’ve been wondering what kind of new evidence I could come up with to add support to my Thunderstorm Thermostat hypothesis (q.v.). This is the idea that cumulus clouds and thunderstorms combine to cap the rise of tropical temperatures. In particular, thunderstorms are able to drive…
It’s Not About Feedback 2011-08-14
The current climate paradigm believed by most scientists in the field can be likened to the movement of balls on a pool table. Figure 1. Pool balls on a level table. Response is directly proportional to applied force (double the force, double the distance). There are no “preferred” positions—every position…
Estimating Cloud Feedback From Observations 2011-10-08
I had an idea a couple days ago about how to estimate cloud feedback from observations, and it appears to have panned out well. You tell me. Figure 1. Month-to-month change in 5° gridcell actual temperature ∆T, versus gridcell change in net cloud forcing ∆F. Curved green lines are for…
Sun and Clouds are Sufficient 2012-06-04
In my previous post, A Longer Look at Climate Sensitivity, I showed that the match between lagged net sunshine (the solar energy remaining after albedo reflections) and the observational temperature record is quite good. However, there was still a discrepancy between the trends, with the observational trends being slightly larger…
Forcing or Feedback? 2012-06-07
I read a Reviewer’s Comment on one of Richard Lindzen’s papers today, a paper about the tropics from 20°N to 20°S, and I came across this curiosity (emphasis mine): Lastly, the authors go through convoluted arguments between forcing and feed backs. For the authors’ analyses to be valid, clouds should…
A Demonstration of Negative Climate Sensitivity 2012-06-19
Well, after my brief digression to some other topics, I’ve finally been able to get back to the reason that I got the CERES albedo and radiation data in the first place. This was to look at the relationship between the top of atmosphere (TOA) radiation imbalance and the surface…
The Tao of El Nino 2013-01-28
I was wandering through the graphics section of the TAO buoy data this evening. I noted that they have an outstanding animation of the most recent sixty months of tropical sea temperatures and surface heights. Go to their graphics page, click on “Animation”. Then click on “Animate”. When the new…
Emergent Climate Phenomena 2013-02-07
In a recent post, I described how the El Nino/La Nina alteration operates as a giant pump. Whenever the Pacific Ocean gets too warm across its surface, the Nino/Nina pump kicks in and removes the warm water from the Pacific, pumping it first west and thence poleward. I also wrote…
Slow Drift in Thermoregulated Emergent Systems 2013-02-08
In my last post, “Emergent Climate Phenomena“, I gave a different paradigm for the climate. The current paradigm is that climate is a system in which temperature slavishly follows the changes in inputs. Under my paradigm, on the other hand, natural thermoregulatory systems constrain the temperature to vary within a…
Air Conditioning Nairobi, Refrigerating The Planet 2013-03-11
I’ve mentioned before that a thunderstorm functions as a natural refrigeration system. I’d like to explain in a bit more detail what I mean by that. However, let me start by explaining my credentials as regards my knowledge of refrigeration. The simplest explanation of my refrigeration credentials is that I…
Dehumidifying the Tropics 2013-04-21
I once had the good fortune to fly over an amazing spectacle, where I saw all of the various stages of emergent phenomena involving thunderstorms. It happened on a flight over the Coral Sea from the Solomon Islands, which are near the Equator, south to Brisbane. Brisbane is at 27°…
Decadal Oscillations Of The Pacific Kind 2013-06-08
The recent post here on WUWT about the Pacific Decadal Oscillation (PDO) has a lot of folks claiming that the PDO is useful for predicting the future of the climate … I don’t think so myself, and this post is about why I don’t think the PDO predicts the climate…
The Magnificent Climate Heat Engine 2013-12-21
I’ve been reflecting over the last few days about how the climate system of the earth functions as a giant natural heat engine. A “heat engine”, whether natural or man-made, is a mechanism that converts heat into mechanical energy of some kind. In the case of the climate system, the…
The Thermostatic Throttle 2013-12-28
I have theorized that the reflective nature of the tropical clouds, in particular those of the inter-tropical convergence zone (ITCZ) just above the equator, functions as the “throttle” on the global climate engine. We’re all familiar with what a throttle does, because the gas pedal on your car controls the…
On The Stability and Symmetry Of The Climate System 2014-01-06
The CERES data has its problems, because the three datasets (incoming solar, outgoing longwave, and reflected shortwave) don’t add up to anything near zero. So the keepers of the keys adjusted them to an artificial imbalance of +0.85 W/m2 (warming). Despite that lack of accuracy, however, the CERES data is…
Dust In My Eyes 2014-02-13
I was thinking about “dust devils”, the little whirlwinds of dust that you see on a hot day, and they reminded me that we get dulled by familiarity with the wonders of our planet. Suppose, for example, you that “back in the olden days” your family lived for generations in…
The Power Stroke 2014-02-27
I got to thinking about the well-known correlation of El Ninos and global temperature. I knew that the Pacific temperatures lead the global temperatures, and the tropics lead the Pacific, but I’d never looked at the actual physical
Albedic Meanderings 2015-06-03
I’ve been considering the nature of the relationship between the albedo and temperature. I have hypothesized elsewhere that variations in tropical cloud albedo are one of the main mechanisms that maintain the global surface temperature within a fairly narrow range (e.g. within ± 0.3°C during the entire 20th Century). To…
An Inherently Stable System 2015-06-04
At the end of my last post , I said that the climate seems to be an inherently stable system. The graphic below shows ~2,000 climate simulations run by climateprediction.net. Unlike the other modelers, whose failures end up on the cutting room floor, they’ve shown all of the runs ……
The Daily Albedo Cycle 2015-06-08
I discussed the role of tropical albedo in regulating the temperature in two previous posts entitled Albedic Meanderings and An Inherently Stable System. This post builds on that foundation. I said in the latter post that I would discuss the diurnal changes in tropical cloud albedo. For this I use…
Problems With Analyzing Governed Systems 2015-08-02
I’ve been ruminating on the continuing misunderstanding of my position that a governor is fundamentally different from simple feedback. People say things like “A governor is just a kind of feedback”. Well, yes, that’s true, and it is also true that a human being is “just…
Cooling And Warming Clouds And Thunderstorms 2015-08-18
Following up on a suggestion made to me by one of my long-time scientific heroes, Dr. Fred Singer, I’ve been looking at the rainfall dataset from the Tropical Rainfall Measuring Mission (TRMM) satellite. Here’s s the TRMM average rainfall data for the entire mission to d…
Tropical Evaporative Cooling 2015-11-11
I’ve been looking again into the satellite rainfall measurements from the Tropical Rainfall Measurement Mission (TRMM). I discussed my first look at this rainfall data in a post called Cooling and Warming, Clouds and Thunderstorms. There I showed that the cooling from th…
How Thunderstorms Beat The Heat 2016-01-08
I got to thinking again about the thunderstorms, and how much heat they remove from the surface by means of evaporation. We have good data on this from the Tropical Rainfall Measuring Mission (TRMM) satellites. Here is the distribution and strength of rainfall, and thus …
Where the Temperature Rules The Sun
I’ve held for a long time that there is a regulatory mechanism in the tropics that keeps the earth’s temperature within very narrow bounds on average (e.g. ± 0.3°C over the 20th Century). This mechanism is the timing and amount of the daily emergence of the cumulus cloud field, and the timing and emergence of thunderstorms.
Where the Temperature Rules The Total Surface Absorption
Reflecting upon my previous post, Where The Temperature Rules The Sun, I realized that while it was valid, it was just about temperature controlling downwelling solar energy via cloud variations. However, it didn’t cover total energy input …
Willis claims without evidence that the “central paradigm of modern climate science is”
“In the long run, global temperature change is proportional to global forcing change.
No as far as I know no-one thinks this is correct since it just plain wrong. The global temperature
is an approximate measure for the amount of energy stored in the climate while the forcing
is the instantaneous difference between the energy absorbed and the energy emitted by the earth.
Hence the temperature change depends on the integral of the forcing. And the earth responds
slowly — the oceans store most of the heat and it takes about 5000 years for the water in the
oceans to reach equilibrium. What climate scientists actually want to know is how much additional energy
will be stored in the earth’s climate system if we continue to add CO2 to the atmosphere.
And if you wanted to get more precise the Stefan-Boltzmann law says that the energy radiated by a
black body goes as the temperature to the fourth power. Hence any change in forcing will result in a
temperature change going as the 4th root of the change.
Wonderfully Wicked Willis. If only our politicians and “scientists” could comprehend the stupidity of their single-minded stubbornness.
Keep asking that key question: Why does the global temperature change so little?
Robber,
That is not the key question. The key question is whether or not a small temperature change of
2 degrees (less than a 1% temperature change) will have serious consequences for human society.
The past tells us that an increase of 2 degrees and triple the amount of co2 is optimal for all life on Earth.
Marcus,
It is not optimal for those living within 10 metres of the current high tide mark. But it
would benefit those living in Northern Canada or Siberia. And you don’t have to be a genius
to work out which of those two groups is larger.
–For me, this is entirely the wrong question. The question that we should be asking is the following:
Why does the global temperature change so little?–
The main reason global temperature changes so little is because global temperature is directly related
to the entire ocean’s temperature.
You change global average temperature by changing average ocean temperature and average ocean temperature
is about 3.5 C
But what is global average temperature is the average ocean surface temperature, which is currently about 17 C. This surface of ocean is moving and changing: it has patterns of circulation and are interrupted or evolving into other patterns. Or the surface ocean temperature have a lot to do global weather and regional weather/climate. But surface ocean temperature is controlled or restrained by the average ocean temperature which currently about 3.5 C.
Another reason for constant temperature is the constant surface temperature of the tropical ocean- which normally is not restrained by the average ocean temperature- due to a thick warm ocean surface temperature- though it does have upwelling of colder water, but in terms all of tropical ocean, it’s a minor effect upon surface temperatures. Or tropical ocean surface temperatures are fairly constant despite the periodic upwelling of a significant amount of colder water.
Or if the ocean average temperature was 10 C rather than 3.5 C, this not have much effect upon the surface temperature of tropical waters, but has huge effect upon the average global temperature. Or if average ocean temperature was 1 to 2 C, this would little effect upon tropical surface temperature, but it would huge effect upon global average temperatures.
And in our icebox climate the average ocean temperature has been in a range of 1 to 5 C. And last time Earth had a high average global temperature was during the last interglacial period which the average ocean temperature was about 5 C and sea levels were at least 5 meter higher than today. And there were hippos and alligators in Germany.
Another well-written and interesting article, Willis. Thank you.
Some great comments, too
For what it is worth, here is my obsessive proofreader’s micro-correction:
“First, it assumes a degree of scientific agreement which simply doesn’t exist. Most people in the field, skeptics included, think the earth is warming AN humans may well have an effect on it.” (emphasis added)
AN —-> AND
Thanks, Robert. Fixed. I’m obsessive about that stuff too. My motto regarding typos is
w.
Excellent post, Willis! Allow me to pick some nits, if you will… Seventh paragraph (or thereabouts, depending upon whether or not I count the bold as a header for the next paragraph, or as simply a highlighted statement within a paragraph):
While this master of circular reasoning is a feat I would not put past the IPCC, I just want to make sure it’s what you meant to say?
The paragraph after you introduce Kelvin degrees (BTW, whatever happened to Rankine degrees?), then you say the Earth’s temperature varies by…
…which I understand to translate to approximately 0.2%. Then just a few paragraphs later, when you talk about the cruise control on your truck (BTW, yours does better than mine, upon a hillclimb I get as much as -3 mph before it will downshift to pick it back up again, and when going downhill it will allow +5 mph before it will downshift to slow it down), you say…
…which doesn’t equal… Oh, wait, you’re saying that the absolute value of plus one-tenth of a percent, plus the absolute value of minus one-tenth of a percent, is equal to a total variation of two tenths of one percent. OK, I’ll give you that. “Never mind!” (in my best Emily Litella impersonation, which isn’t very good).
Stay safe!
Pynchon’s Proverbs for Paranoids
Rule number 3. If they can get you asking the wrong questions, they don’t have to worry about answers.
Modeling multiple non-linear closely coupled complex chaotic systems accurately like climate is not possible, as weather models show after a short period of time the result is unreliable.
Willis, as usual, I liked your post. One of the nice things about your hypothesis is that it is testable. More satellite data and at a finer scale will help quantify the effect of the emergent phenomena. Just one other comment – molecules still vibrate at absolute zero, just in their ground state. If they stopped entirely, then we could determine both their position and momentum with higher precision than is allowed by Heisenberg’s uncertainty principle. Not that quantum mechanics forces this, rather the reverse – quantum mechanics describes the real world. The world is what it is regardless of whether we have a mathematical description of it.
P. S. I have family in Ukiah, which is probably not far from where you are.
The lack of progress on refining ECS has been my principal argument for ages. It gets even better when you point out that the unknown portion of 1.1 leaves with an unknown portion of 0.4 to 3.4 deg C per doubling.
How confident are they when your maximum unknown is 8.5 times higher than your minimum, and this has persisted for almost 40 years?
What this single concept reveals is the level of complexity we are dealing with.
Stagnating “Climate Scientists” have the same problem that Black Rhinos and other herd animals have, aging, dominant bulls, beyond useful fertility, who injure and kill the younger more vigorous animals.
As the physicist Max Planck observed, “Science advances one funeral at a time.”
Eisenhower in his farewell address stressed the need for “an alert and knowledgeable citizenry” to ensure that the “free university, historically the fountainhead of new ideas and scientific discovery” not become places where, because of the “great costs involved, a government contract becomes, virtually, a substitute for intellectual curiosity.” and the “equal and opposite danger that public policy could itself become the captive of a scientific-technological elite.”
https://www.cnn.com/2015/05/21/opinions/rhino-hunt-is-conservation/index.html
My first computer course was in 1964. The computer was in a large climate controled room we were not allowed to enter. Just turn in your stack of punch cards at the window. Go back the next day to pick up the endless loop print out and start finding the errors.
Computers are like roller skates; you’re going to the same place, but faster.
Any list of problems with the IPCC should start with the inacting language. The role of the IPCC is defined in item 2 of its document “Principles Governing IPCC Work”, (online at http://www.ipcc.ch/about/princ.pdf)
“The role of the IPCC is to assess on a comprehensive, objective, open and transparent basis the scientific, technical and socio-economic information relevant to understanding the scientific basis of risk of human-induced climate change, its potential impacts and options for adaptation and mitigation.” (Heads I win; tails you loose.)
Shouldn’t we also have an IPCU? Intergovernmental Panel on Climate Uniformity?
“The role of the IPCU is to assess on a comprehensive, objective, open and transparent basis the scientific, technical and socio-economic information relevant to understanding the scientific basis for the amazing climate uniformity on planet Earth during the present Holocene Interglacial Period.”
And another one: The IPIA…Intergovernmental Panel on the Ice Age.
“The role of the IPIC is to assess on a comprehensive, objective, open and transparent basis the scientific, technical and socio-economic information relevant to understanding the scientific basis for the initial cause and continued existence for 2.6 million years of the current Ice Age and to predict the onset of the next glacial period and it’s potential impacts on civilization and options for adaptation and mitigation.”
Very nice post W.
Has the fact that the fossil record….https://kwanten.home.xs4all.nl/fossils.htm
shows that at least somewhere on the planet life has continued basically uninterrupted (meaning stable temps between say above freezing and 40C) been included into the computer modelling? That despite the proxy co2 data showing huge swings it did not affect the entire planet? That runaway warming is not possible on this planet?
My belief is that Earth definitely has a ”thermostat” and this is the one and only reason life has continued for hundreds of millions of years. It would seem to me that the Earth’s sensitivity to current pitifully low co2
concentrations is basically 0.0, certainly as far as the biosphere is concerned and given observations probably the temp as well.
Right. If this old Earth had a tipping point, it would have tipped already. We are here to discuss it, so it doesn’t.
Willis: “…my hypothesis is that the temperature is maintained within narrow bounds by a variety of emergent phenomena that cool the earth when it gets too hot, and heat it up when it gets too cool.”
Previously you have shown fairly convincing data that this is true in the tropics. Have you considered that it is only partially true in temperate regions, and may not the case at all in northern polar regions? Then in some cases a regional climate sensitivity might make sense.
The “emergent phenomena” fail to maintain narrow bounds of temperatures during the periodic glaciations that have occurred as recorded in the ice core data.
Steve, the phenomena operate all over the planet. I saw the clear morning/cumulus field/thunderstorm regulating system at work in England when I was there.
The key is that these emergent phenomena only emerge as and when the local conditions are favorable … which generally means when there is excess surface heat. Some places that doesn’t happen often … but when it does, you’ll find emergent phenomena to counteract it.
It is only in the tropics that the conditions occur enough to make it the predominant phenomenon … but that absolutely does not mean that those phenomena don’t emerge elsewhere. They just do less frequently.
w.
Thermal inertia is a much better explanation than “emergent phenomena” for the stability we see in global temperatures. Not only are your “emergent phenomena” local, and not global, but they fail to explain why the earth undergoes periodic glaciations.
Dave Burton November 18, 2018 at 5:39 pm
Dave, perhaps you missed the part where I pointed out that each entire hemisphere goes up on average by ~ 13°C and then down by ~ 13°C every year … and given that the temperature can change that fast, I’m afraid that the claim that “thermal inertia” can hold the temperature to a change of 0.6°C over a century simply won’t hold water.
Next, while the phenomena are local, they occur all over the globe. Yes, dust devils are quite small … but they only occur where there is a localized hot spot. And while that local spot is hot, you can sit there and watch them form on that spot and then drift away with the wind, over and over, cooling the surface by moving the heat from that hot spot high up into the atmosphere.
Multiply that local effect by the number of dust devils that are forming all over the planet and presto! Your local effect just became a global effect. See my post “The Details Are In The Devil” for more discussion of this issue.
And some of the emergent phenomena, like the El Nino/La Nina pumping action and the Pacific Decadal Oscillation, act across half the planet.
As to glaciations, they are driven by the Milankovich cycles. As you might imagine, different outcome, different cause … and it’s worth noting that the glacial part of the Milankovich cycle is quite thermally stable as well, just at a lower temperature.
My best to you and yours,
w.
Willis Eschenbach November 18, 2018 at 9:01 pm
Thermal inertia is perfectly capable to explain why the temperature of the deep oceans is ~80K above the average surface temperature of the moon, and why the deep oceans have cooled some 10-15C over the last ~85 million years.
That the sun only increases the temperature of the mixed surface layer of the oceans some 13C in half a year is another example of the effect of thermal inertia. Each day the sun adds some 20 MJ/m^2 energy to the mixed surface layer of the oceans, slowly increasing its temperature during spring and summer. That energy is released again at the surface during autumn and winter.
Diurnal variation also is very small, in spite of the solar input in the tropics going from 0 to maybe 1000 W/m^2 and back to 0 within ~12 hours.
Looking for mechanisms that may explain how the surface can lose energy to space is pretty useless when we actually need to explain why the average surface temperature is ~90K above that of our moon, which is at the same distance of the sun and reflects less solar radiation than Earth does.
Ben Wouters November 19, 2018 at 4:45 am
That one is well understood. It is the very poorly-named “greenhouse effect”. See my post “The Steel Greenhouse” for an explanation of how it works.
Well, that plus the fact that the moon rotates very slowly, so the dark side can get very cold … see my post “The Moon Is A Cold Mistress” for further discussion of these issues.
w.
Willis Eschenbach November 19, 2018 at 9:12 am
Seems you believe that increasing the rotation rate of the moon to that of the Earth plus adding an Earth like atmosphere will increase the average surface temperature some 90K.
Assuming this to be the case, we still need a mechanism that transports surface heated water down to the ocean floor.
http://www.climate4you.com/images/ArgoTimeSeriesTemp59N.JPG
Whatever heats the surface in this example, its influence doesn’t reach below ~400m and is seasonal. So conduction and mixing doesn’t warm the deep oceans.
The only water that sinks all the way to the ocean floor is Antarctic Bottom Water. The coldest, densest water of the oceans that actually cools the oceans.
Very interested to hear how in your opinion the deep oceans became so hot (~275K).
So two options imo:
– the atmosphere heats the surface PLUS the deep oceans above what the sun is capable of.
– the sun heats the surface layer of the geothermally heated oceans to our pleasant surface temperatures and the surface heats the atmosphere, that only slows down the energy loss to space.
Obviously the second option is the one that makes sense imo.
Willis Eschenbach November 19, 2018 at 9:12 am
Seems you believe that increasing the rotation rate of the moon to that of the Earth plus adding an Earth like atmosphere will increase the average surface temperature some 90K.
Assuming this to be the case, we still need a mechanism that transports surface heated water down to the ocean floor.
http://www.climate4you.com/images/ArgoTimeSeriesTemp59N.JPG
Whatever heats the surface in this example, its influence doesn’t reach below ~400m and is seasonal. So conduction and mixing doesn’t warm the deep oceans.
The only water that sinks all the way to the ocean floor is Antarctic Bottom Water. The coldest, densest water of the oceans that actually cools the oceans.
Very interested to hear how in your opinion the deep oceans became so hot (~275K).
So two options imo:
– the atmosphere heats the surface PLUS the deep oceans above what the sun is capable of.
– the sun heats the surface layer of the geothermally heated oceans to our pleasant surface temperatures and the surface heats the atmosphere, that only slows down the energy loss to space.
Obviously the second option is the one that makes sense imo.
Ben Wouters November 19, 2018 at 12:48 pm
Well, let’s start by looking at what the temperature of the moon would be if it were rotating and tumbling say once per minute so it was evenly heated everywhere.
Like the Earth, the Moon receives 340 W/m2. The lunar albedo is 0.12. That means the surface is absorbing 340 * 0.88 = 299 W/m2. It also means that the surface would be radiating 299 W/m2.
Per the Stefan-Bolzmann equation, the temperature of an object radiating 299 W/m2 is -4°C … explaining most of your “90°C” temperature difference between the Earth and the Moon.
So … why is the average lunar temperature so much lower? It’s because the moon rotates slowly, leading to large temperature differentials between different parts of the surface … and when that happens, the average temperature drops.
Note that the average radiation doesn’t drop—the moon actually does radiate ~ 299 W/m2. But because of the fourth-power relation between temperature and radiation, any temperature variation lowers the average temperature.
Hope this helps,
w.
Willis Eschenbach November 19, 2018 at 1:53 pm
Better to start from a physically realistic situation, one side of the moon continuously facing the sun. (1 rotation / orbit)
The average radiation on the sunny side is 0,88 * 680 W/m^2 = ~598 W/m^2.
Radiative balance temperature would be ~320K. (actually a bit lower, since the radiation is not evenly distributed). Dark side would be close to 0K.
So average temperature ~160K.
When introducing rotation we need to specify how much heat storage takes place at a given rotation rate.
The faster the rotation, the higher the temperature, but even at eg 1 rotation/second the temperature will not reach the Effective temperature of ~270K, since the radiation will still be unevenly distributed. The poles still receive no radiation at all.
I’ve seen some modelling where the average surface temperature of the moon rotating at the same rate as Earth would be around 220K. if I remember correctly.
Ben Wouters November 19, 2018 at 2:53 pm
In other words, you have no answers to the issues that I raised, so you want to talk about something completely different.
Pass …
w.
Willis Eschenbach November 19, 2018 at 3:12 pm
Obviously. The moon rotating AND tumbling once a minute would be torn apart by the incredible forces involved in this process.
I’m afraid you’ll have to come to terms with the simple fact that not one planet or one moon in our solar system is heated evenly by the single sun we have available.
All spherical bodies will have only one half of their surface exposed to the sun at any one time. So assuming radiative balance for an entire planet / moon is nonsense.
Our moon is a prime example of this basic physical principle.
Ben, ALL of these have been thought experiments. If you prefer, instead of the moon rolling and tumbling, consider it to be made of a superconducting material. The point I’m trying to make is simple:
If the heating of the moon were evenly distributed over its entire surface, the temperature of the moon would be ~ -4°C.
In other words, most of the temperature difference comes from uneven heating. How about you deal with that instead of raising pointless objections?
Thanks,
w.
Willis Eschenbach November 20, 2018 at 9:16 am
Yes, this is the Effective temperature for the moon (~270K). For Earth this number is ~255K.
These numbers have no relevance in the real world.
On the moon solar only heats the upper 50 cm or so of the surface, no superconducting.
And the rotation speed is low enough to let the daytime temperatures be in radiative balance with incoming solar (although with some delay).
Night side average temperature is around 80K, well above the ~3K radiative balance would give. Explanation is 25-40K due to geothermal flux. The rest is some carry over energy from the dayside.
So starting from the non-rotating radiative balance blackbody temperature of ~160K, it is pretty straightforward to explain the actual average surface temperature of ~197K for our moon.
This makes the non-rotating radiative balance blackbody temperature the relevant starting point for explaining the surface temperature of a planet / moon.
For Earth the number is ~150K.
To explain the ~288K average temperature we need the oceans, the atmosphere and the rotation rate we have.
Surface heat is all relative. This image from polar oceans shows ocean heat triggering cumulus clouds showing transfer from surface to the atmosphere.
“Why does the global temperature change so little?” That one item that has always amazed me even when I was in 7th grade larning about earth science. The heating and cooling system in your house isn’t that tight.
The stratospheric polar vortex pattern is now compatible with the geomagnetic field in the north.
Surely it is as important to give it the right data to base those answers on as to give it the right question. It was only the race relations laws that stopped scientists referring to engineers as grease monkeys for fear of offending the coloured section of the community. That contempt for practical skills and the need to both do that part as diligently as any academic work and to have proper quality control procedures to ensure that the standards are maintained has continued quite openly even if not so publicly expressed.
It is this failure that is at the heart of the failures of climate science. The practical side of collecting not just CO2 man made emissions and temperature but natural emissions has received a tiny fraction of the total budgets and has always been at the heart of any budgetary skimping.
Why do we not see the matching man made and natural CO2 emissions alongside the temperatures in all public airing of the life threatening climate change argument? It is relatively easy to find files like AMSRE_SSTAn_M but try to find the equivalent man made and natural explanation for providing correlation let alone proof of cause and effect and it is at best a challenge. Clearly there are huge and vastly profligate barbecues being held by Eskimos off the Alaska coast. Or are there and natural sources are actually at work here?
Sadly asking questions like this puts you on a par with Nazi supporters and denier is justified as a label according to the BBC from a reply they sent to a complaint about the use of that label for legitimately rejecting climate science predictions.
Some basic meteorology.
All those emergent phenomena referred to by Willis are simply local irregularities within the bulk movement of the atmosphere.
The average surface pressure is close to 1000 millibars.
All low pressure cells are at lower pressure than that and are comprised of rotating air spiralling upward around the centre.
All high pressure cells are at higher pressure than that and are comprised of rotating air spiralling downwards from the centre.
At any given moment half the atmosphere is rising and half is falling.
The surface heat taken upwards in a low pressure cell does not remain as heat as it rises. Due to the gas laws it becomes potential energy which does not register as heat, hence the lapse rate slope.
That potential energy then appears as heat again as the air descends within a high pressure cell.
It is that reversible process that causes the greenhouse effect because the ground beneath a high pressure cell is warmed both by fresh incoming sunlight AND reappearing heat from the descent phase of convective overturning.
The extra heat beneath the high pressure cell then flows across the surface to the base of nearest low pressure cell where it then feeds the next uplift.
Once the bulk atmospheric turnover is in place there is a net zero energy gain/loss within convective overturning but the surface is then warmer than it otherwise would have been from external insolation alone.
A contributor above correctly pointed out that the weather systems require a reservoir of energy to keep them moving and it is the energy comprising the greenhouse effect that is utilised for that purpose.
Willis’s emergent phenomena are the system in action on a local, visible scale.
More radiative gases within an atmosphere simply facilitates radiative energy transfers at the expense of non radiative energy transfers such that bulk convective overturning would become less vigorous to a miniscule extent with a net zero effect on surface temperature.
Stephen Wilde November 19, 2018 at 1:36 am
“Local irregularities”????
The daily emergence of the cumulus field covers the entire tropical ocean areas with a reflective shield that sends sunlight back out into space.
And you call that a “local irregularity”?
The emergent La Nina pumping action moves water from the Equatorial Pacific to the poles, and thus covers nearly half the planetary surface.
And you call that a “local irregularity”?
Really???
Stephen, sometimes you outdo yourself in the art of auto-footshooting …
w.
The problem is that in the period of very low solar activity El Niño does not work.
http://tropic.ssec.wisc.edu/real-time/mtpw2/product.php?color_type=tpw_nrl_colors&prod=epac×pan=24hrs&anim=html5
Sorry.
Very low solar activity will last at least until the end of 2019.
After the conjunction of Jupiter and Saturn in 2020, the solar cycle will be weak.
In terms of the planet as a whole with its bulk convective processes of uplift and descent both those features are indeed local irregularities though being at the larger end of the scale one could perhaps term them ‘regional’ instead.
You really should try to understand rather than picking out a perverse interpretation in order to try to score an invalid and misleading point.
The field of climate science is trying to use computers to find an answer to the wrong question.
42.
To answer the question of why earth’s temperature is above the expected black body temperature:
We have a heated atmosphere. It is heated every single day, 24 hours per day. If it were to remain dark long enough, the overall temperature would drop, as when massive volcanoes obliterate part of the sun.
The point is that the air temperature where we walk around increases nearly every day, and drops nearly every night. Why doesn’t it drop lower? Because the sun returns before it can cool all the way down. You can see this on a daily basis and a yearly basis. Everyone knows heat rises via convection, but there is no opposite force bringing that thermal energy back down to the surface. (Yes, I understand sinking air, but that is not the return of the thermal energy.) Air heats quickly, but cools slowly, which is why it is coolest just before dawn. The atmosphere is cooled at night by surface radiation – via conduction. The air is coolest right at the surface, and is warmer just above the surface at night. That is because the surface radiation drops the temperature of the air in contact with it, then warmer air above that mixes, etc, and that continues until the sun returns. On clear, windless nights, the surface temperature can be several degrees below the air temperature at the standard thermometer height of about 2 meters.
So, it is simply the presence of an atmosphere that does it, not the makeup of the atmosphere. CO2 has nothing to do with air temperature, since it CANNOT be a different temperature than the molecules around it. The ideal gas laws stipulate that all gases behave the same way, and that is based on the volume/temperature/pressure relationship only.
John Shotsky
The only way your proposition can work is if there is indeed an ‘opposite’ force (I prefer the word ‘process’ bringing that thermal energy back to the surface).
Every high pressure cell (in total constituting half the atmosphere) is indeed constantly bringing that thermal energy back to the surface by converting non thermal potential energy to thermal kinetic energy during the descent.
How else do you suppose the volume/temperature/pressure relationship could possibly work ?
“So, it is simply the presence of an atmosphere that does it, not the makeup of the atmosphere. CO2 has nothing to do with air temperature, since it CANNOT be a different temperature than the molecules around it. The ideal gas laws stipulate that all gases behave the same way, and that is based on the volume/temperature/pressure relationship only.”
I think the ocean has a lot to do with “it”.
Obviously, the ocean warms Europe.
And it’s well known or mentioned often, that tropical ocean is the heat engine of the world.
And would say if a tropical ocean was isolated so that warmed water could not flow poleward- as in case with Gulf stream. A tropical ocean would still warm the rest of the world.
Other than warming the rest of the world, the tropical ocean is warm in terms of average night and day temperature, and if covers 40% of total surface area of planet- it’s like smart kids in a class, it bring up the class average score. Or if remove the smart kids from the class, the class average score lowers.
Or earth has average temperature of 15 C, because 40% of planet has average temperature of about 26 C.
So ocean warms rest of world, it has higher average surface temperature of about 17 C [global land average is 10 C]. So it increases average global to 15 C just because it’s 70% of surface area of planet AND it warms the land area.
If nothing else, this is the best finger-flicking exercise I have ever partaken!
But I think the point was missed, namely that the angle of the dangle is directly proportional to the sag of the bag, provided the heat of the meat remains constant!
Willis Eschenbach says: Let me suggest that climate science is the victim of what I call the “Picasso Problem”. Pablo Picasso once said something that has stuck with me for a long time. He said: “What good are computers? They can only give you answers.”
Another year has gone by, and it’s now the Fall of 2018. But winter will be here in another month. Having escaped the snow country of my youth for the dry boring flatlands of the US Northwest, I can’t say I miss it.
However, it’s time once again to put up ‘Beta Blocker’s Parallel Offset Universe Climate Model’, a graphical GMT prediction tool first posted on Climate Etc. and on WUWT in the summer of 2015.
Willis Eschenbach’s essay ‘The Picasso Problem” seems an appropriate place for my annual repost of this graph here on WUWT. So here it is:
Referring to the illustration, Beta Blocker’s Scenario #1 predicts a +3C rise in GMT by the year 2100 from the year 2015, roughly equivalent to a +4C rise from the year 1860, which should be considered the pre-industrial baseline year for this graphical analysis. Scenario #2 predicts a +2C rise from 2015, roughly equivalent to a +3C rise from 1860. Scenario #3 predicts a +1C rise from 2015, roughly equivalent to a +2C rise from 1860.
The above illustration is completely self-contained. Nothing is present which can’t be inferred or deduced from something else also contained in the illustration.
For example, for Beta Blocker’s Scenario #1, the rise in GMT of + 0.35 Degrees C / Decade is nothing more than a line which starts at 2016 and which is drawn graphically parallel to the rate of increase in CO2 which occurs in the post-2016 timeframe. Scenario #1’s basic assumption is that “GMT follows CO2 from Year 2016 forward.”
Beta Blocker’s Scenario #2 parallels Scenario #1 but delays the start of the strong upward rise in GMT through use of an intermediate slower rate of warming between 2025 and 2060 that is also common to Scenario #3. Scenario #2’s basic assumption is that “GMT follows CO2 but with occasional pauses.”
Beta Blocker’s Scenario #3 is simply the repeated pattern of the upward rise in GMT which occurred between 1860 and 2015. That pattern is reflected into the 2016 – 2100 timeframe, but with adjustments to account for an apparent small increase in the historical upward rise in GMT which occurred between 1970 and 2000.
Scenario #3’s basic assumption is that “Past patterns in the rise of GMT occurring prior to 2015 will repeat themselves from 2016 on through 2100, but with a slight upward turn as the 21st Century progresses.”
That’s it. That’s all there is to it. What could be more simple, eh?
All three Beta Blocker scenarios for Year 2100 lie within the IPCC AR5 model boundary range — which, it should also be noted, allows the trend in GMT in the 2000 – 2030 timeframe to stay essentially flat while still remaining within the error margins of the IPCC AR5 projections. (For all practical purposes, anyway.)
Scenario #3 should be considered as the bottom floor of the three scenarios, which is approximately two degrees C from pre-industrial CO2 concentration levels. It is also the scenario I suspect is most likely to occur.
The earth has been steadily warming for more than 150 years. The earth isn’t going to stop warming just because some people think we are at or near the top of a long-term natural fluctuation cycle. The thirty-year running average of GMT must decline steadily for a period of fifty years or more before we can be reasonably certain that a long-term reversal of current global warming has actually occurred.
How did Beta Blockers Parallel Offset Universe Climate Model come about?
Back in 2015, I had been criticizing the IPCC’s climate models as being a messy hodge-podge of conflicting scientific assumptions and largely assumed physical parameterizations. Someone at work said to me, “If you don’t like the IPCC’s models, why don’t you write your own climate model?”
So I did. However, not having access to millions of dollars of government funding and a well-paid staff of climate scientists and computer programmers to write the modeling code, I decided to do the whole thing graphically. The illustration took about thirty hours to produce.
I don’t know what Pablo Picasso might have thought about ‘Beta Blockers Parallel Offset Universe Climate Model’ as a piece of pictorial art drawn in response to a public policy issue that would certainly be dear to his own philosophical and political heart were he alive today.
But he certainly couldn’t argue with its cost effectiveness, given the many millions of dollars it takes to produce the IPCC’s climate models.
If I’m still around in the year 2031, I will take some time to update the above illustration to reflect the very latest HadCRUT numbers published through 2030, including whatever adjusted numbers the Hadley Centre might publish for the period of 1860 through 2015.
In the meantime, I’ll see you all next year in the fall of 2019 when the topic of ‘Are the IPCC’s models running too hot’ comes around once again.
If you’re so scientifically brilliant, why are you reduced to hauling gravel to make ends meet?
1sky1 November 21, 2018 at 10:05 pm
“Hauling gravel to make ends meet”? Say what? I’m retired after a lifetime of joyously making money doing more things in more outrageous places than you can imagine. I live in a house I built with my own hands, on land that my gorgeous ex-fiancee and I paid for through our own work.
What does any of that have to do with “hauling gravel”? And more to the point, what does “hauling gravel” have to do with climate science?
Best regards,
w.
Complete knowledge of a system is required before one can determine that it is “emergent.”
The climatic data is too noisy for us to claim that we have such knowledge.