Guest Post by Willis Eschenbach
[UPDATE 2 AM Christmas morning, and of course Murphy is still alive and his Law is still in operation. I find a decimal point error in my calculations … grrr, I hates that, ocean energy flows shows at 1/10th size. Public exposure of error, the bane of any scientific endeavor.
And Murphy being who he is, the correction doesn’t solve the puzzle at all. It only makes it more complex. I have updated Figure 2 and some of the text, and added a third figure. The only good news is, it doesn’t affect my conclusions, there’s still something very wrong in the canonical climate equations.
Merry Christmas to all, it can only get better from here.]
In the Climategate emails, Kevin Trenberth wrote:
How come you do not agree with a statement that says we are no where close to knowing where energy is going or whether clouds are changing to make the planet brighter. We are not close to balancing the energy budget. The fact that we can not account for what is happening in the climate system makes any consideration of geoengineering quite hopeless as we will never be able to tell if it is successful or not! It is a travesty!
Although I sympathized with him, I was unclear about exactly where the hole was in the energy budget. However, my research into the climate sensitivity of the GISS model has given me some new insights into the question. Intrigued by the findings I reported in “Model Charged With Excessive Use of Forcing“, I wanted to look closer at the results from the NASA GISS climate model. As you may recall, I was trying to understand the low sensitivity I had calculated for the GISSE model. I went to the CMIP archive to see if I could get the top-of-atmosphere (TOA) forcing for the GISS model month by month, but the GISS folks didn’t archive that data. Rats.
Figure 1 (may take a moment to load). Anomalies in the heat content of the top 700 metres of the ocean from 1955 to 2003. Units are zettaJoules (10^21 Joules).
Someone pointed out on that previous thread that I was neglecting the ocean in my calculations … guilty as charged. The basic energy equation for the planet is that energy added to the climate system equals energy leaving the system plus energy going into the ocean. Energy can’t just disappear, it has to go somewhere. It either leaves the system, or it goes into the ocean. So I went off to see what the change in the heat content of the ocean has looked like over the period of record. The National Oceanographic Data Center (NODC) has the data. Figure 1 shows a movie of what I found. Not much of a movie, but it’s the first one that I’ve made in R, so I was happy about that. The legend says “∆H” where it should say “H”, but it’s 3AM and I’m not going to fix it. So how can this ocean heat content information be related to the question of climate sensitivity?
As you can see in Fig. 1, nature is a puzzle. Things happen in blobs and patches, without immediately obvious reasons. However, we can see that the heat content of the top layer of the ocean has increased since 1955 by a total of 154 ZJ.
First, a bit of math. Not much math, and not complex math. We’re looking at one of the fundamental equations of the current climate paradigm. The statement above was that:
Energy added to the climate system equals energy leaving the system plus energy going into the ocean.
Mathematically this can be restated as ∆Q (change in energy added, Joules/year) = ∆U (change in energy lost, Joules/year) + ∆Ocean (change in energy in/out of ocean, Joules/year), or
∆Q = ∆U + ∆Ocean (Joules/year) (Equation 1)
Note that this is different from a statement about a general equilibrium, which may or may not be satisfied in any given year. This is an absolute requirement, because energy cannot be created or destroyed. If we add extra energy to the system, it has to either leave the system via increased radiation or get stored in the ocean. There is no “lag” or “in the pipeline” possible with Equation 1. The atmosphere has far too small a thermal mass to store a significant amount of energy. The earth warms too slowly to serve as a reservoir for annual changes. Global ice amounts are fairly stable (although they might make a very small change over the long-term, global annual variations are small). So any large annual change of incoming energy has to either change the ocean storage or leave the system.
Now, the current climate paradigm holds that “U”, the energy leaving the system, is equal to the surface temperature “T” divided by the climate sensitivity “S” (∆U=∆T/S). This is another way of stating the idea that the surface temperature is linearly related to changes in the top-of-atmosphere radiation. [See e.g. Kiehl (PDF). Be aware that Kiehl uses lambda (λ) as sensitivity, which in my terminology would be 1/Sensitivity].
The current paradigm also holds (wrongly, in my opinion) that the sensitivity “S” is a constant. The IPCC says that the central value for the climate sensitivity constant “S” is about 0.8 °C per W/m2 (or 3°C per doubling of CO2). So according to the current paradigm, we can replace ∆U (change in energy leaving the system) with ∆T/0.8. This gives us:
∆Q = ∆T / 0.8 + ∆Ocean (Joules/year) (Equation 2)
It struck me when I was looking into this that we actually have the means to test this claim of mainstream climate science. We have the historical forcings, from the GISS tables. We have the historical GISS temperatures. And we have the historical heat content of the ocean. (The conversion from Watts/m2 to joules/year is covered in the Appendix.)
Figure 2 shows annual changes in incoming energy (∆Q, red), outgoing energy (∆T/S, light blue), and energy moving into and out of the ocean ∆Ocean (dark blue). We can express them either in joules per year or in W/m2. I have chosen joules per year, to emphasize that this is the movement of actual energy that cannot be created or destroyed. It has to go somewhere, and there’s not many choices.
Figure 2. The missing energy puzzle. Every year, the amount of energy entering the system (red) should equal the energy leaving the system (light blue) plus the energy going into/out of the ocean (dark blue). It doesn’t.
Figure 3. Annual Energy Budget Error, ∆T/S + ∆H – ∆Q. Positive errors indicate excess heat in the ocean. Some folks have commented that they don’t like having photos in the background. This Figure’s for you.
As you can see, something is really, really off the rails in this. The total forcing Q is known through observation to take large drops after volcanic eruptions (from the volcanic aerosols reflecting away the sunlight), with similarly large and fast recoveries. But this is not reflected in the sum of the outgoing energy (∆T/S) plus the ocean changes. In other words, the forcing drops because of the volcanoes, but there is no corresponding drop in temperature or ocean heat storage as you would expect. The forcing springs back when the stratosphere clears after the eruption, but there is no corresponding rise in either temperature or ocean storage.
The real surprise is the absolute size of the missing energy. It is often more than 20 ZJ. This means that something very fundamental is wrong here.
Some of the possibilities for unraveling this koan are:
• Foolish math or logic error on my part. I don’t think so, as I have checked and rechecked my figures, units, and logic. But I’ve made plenty of mistakes in my life. Please check my numbers and everything else. [UPDATE – well, I sure called that one …]
• Bad data in one or more of the datasets. Always possible. However, the huge size of the discrepancy argues against that. Even though there are errors in all datasets, these would have to be very large errors. Even the forcings dataset is mostly based on observations (CO2 and volcanic aerosol changes). So bad data seems doubtful, it would have to be really, really bad.
• One of the datasets is off by one year, so the timing is wrong. That doesn’t work, though, correlation doesn’t improve with a lag or a lead.
• IPCC climate sensitivity is too large. If it were smaller, ∆T/S would be larger to help balance out the ∆Q. The problem is, the temperature changes are not well correlated with the forcing changes. In addition, the regression of (∆Q – ∆Ocean) on ∆T has an R^2 of 0.01. This means that the climate sensitivity has no explanatory power in respect to the error, regardless of its value.
• The change in energy at the top of the atmosphere (∆U) is not represented by ∆T/S. I would say that this is the most likely explanation. I think that the current paradigm, in which the temperature is linearly related to the forcing, is highly unlikely. Simple consideration of the complexity of the system discourages assumptions of linearity.
• The change in energy at the top of the atmosphere ∆U is correctly represented by ∆T/S, but S in turn is not a constant but a function of T “f(T)”. Thus the substitution in Eqn. 1 should actually be
∆U = ∆T/f(T)
This is a refinement of the previous possibility. I put this forward because of the obvious daily change in climate sensitivity in the tropics, with the sensitivity dropping as the day progresses and the temperature increases. Since that variation in the climate sensitivity occurs daily over about a third of the planet, the part of the planet where the energy enters the system, it is not unreasonable to think that the global climate sensitivity should be a function of temperature. (Note that even here the sensitivity is unlikely to be a linear function of temperature, as the natural situation contains clear thresholds at which the climate sensitivity changes rapidly.)
• Something else that I haven’t thought of yet.
I make no hard claims about any of this, as I don’t know where the missing energy really is. I don’t even know if this is the missing energy that Trenberth was talking about. My theory is that the energy is not missing, but that Equation 2 is wrong. My hypothesis is that the earth responds to volcanoes and other forcing losses by cutting back on clouds and thunderstorms. This lets in lots of energy, and as a result neither the air temperature nor the ocean heat storage change very much. I have detailed that hypothesis here.
About the only solid thing I can say out of this analysis is that if my numbers and logic are correct, then one of the fundamental equations of the current climate paradigm is falsified …
We’ll see how it plays out. All comments and explanations gladly accepted.
w.
[UPDATE: This discussion continues at Some of the Missing Energy]
APPENDIX: Converting Joules/year to W/m2 involves the fundamental relationship:
1 Joule is the application of 1 Watt for 1 second
So … one Watt/m2 applied for one year gives us 1 * 31.6E6 Joules/m2 per year. (Watts/m2 times seconds in 1 year.)
To get total Joules for the planet, we need to multiply that answer by 5.1E14 square metres, to include the total surface area. So one Watt/m2 of forcing, acting on the planet for 1 year, delivers 16.3E21 Joules/year (16.3 zettaJoules). This allows us to convert easily between Joules/year and W/m2
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Hi Willis – please could you add a start/stop function to the graphic? This would help with scrolling through and observing specific locations over time. Thanks.
Rob R says:
December 23, 2010 at 2:37 pm
Rob, you’re talking to the wrong guy. I didn’t “choose” to ignore heat storage in soils. Equation 1 above is settled climatology, and has nothing at all to do with my description of it. I agree with it, but I am certainly not the originator of that equation. Run the numbers yourself about the amount of missing energy, and see how much the top metre or two of the earth would heat up if that enormous amount of energy were actually being stored there. You’ll be very surprised.
Because to disprove equation 1, you’ll have to do more than a simple bit of handwaving …
walt man says:
December 23, 2010 at 3:06 pm
A lot of people are ignoring the need for speed. You need a possible system that can accept or release a great deal of energy in a short time. Deep ocean currents are a lot of things … but they are not a quick-reacting system.
kuhnkat says:
December 23, 2010 at 4:53 pm
kuhnkat, good question. Those are the changes resulting from volcanic eruptions. See my previous post for the total forcings and the individual forcings.
slow to follow says:
December 23, 2010 at 6:54 pm
I would if I knew how … you could download it, it’s just an animated gif. Hope that helps.
w.
http://www.ftexploring.com/me/me2.html
What missing energy?
Willis,
Here in the temperate part of Australia, when it’s hot, it’s dry.
When it’s cold, it’s wet.
I take it from this, that cloudiness plays a great part in determing temperaure, reflecting heat back into space before it lands.
Plus the latent heat of evaporation after rain, taking moisture and energy from the drying land back into the upper atmosphere and out to space.
Plus thunder storms doing the same.
Unless your incoming heat measure accurately captures these effects, then your formula will be all wrong.
To me, the climatologists have built a very sofisticated superstructure on shifting sands – the lack of understanding of the basic forces and structures of the climate.
I did not mean to imply that the rising moisture escapes into space, but only the energy.
“Dave Springer says:
December 23, 2010 at 6:32 am
I think a better measure of energy content is global average sea level.”
This calculation would be extremely complex. Normal water with no salt has a maximum density at 3.98 C. So water could warm up from 2 C to 4 C and actually contract. Sea water acts similarly. See http://nsidc.org/seaice/intro.html
Willis, what about the heat going into the massive volume on Antarctic ice? Not just the sheer volume but the great abilty of that ice mass to absorb heat and send it down where there are ice at -60ºC.
There is a big difference between the relation air temperature have with ocean temperatures at 4-30ºC in the surface, and that with ice Antarctic tempertures way down below zero degree.
As has been observed in the paleo record, there seem to be two basic default modes, Hot House and Ice Box. The former sits around 25°C for millions or 100s of millions of years, and then flips to Ice House, which does likewise. There may be one or two way stations that last a mere few 10s of millions of years.
Maybe the kind of timing that wobbles in and out of the plane of the galaxy provide?
I made a few comments over at Dr. Curry”s blog on this subject, and got some responses that both agreed with and disputed my assertion. It concerns an area of thermodynamics that I have not heard discussed much, if indeed at all, on any climate blogs both skeptic and alarmist.
If I remember my thermodynamics professor correctly (it has been many years!) the energy equation always involves creating entropy. This results in a certain amount of the energy being lost from the climate system forever. There is also the fact that much of the energy has been used to do work (enthalpy) that may or may not show up as heat in the system. Much of it is also lost to the climate system forever.
Anybody out there that remembers more of their thermodynamics classes than I do?
Bruce;
If entropy is indistinguishable from averaged heat or other lowest-contrast (no-gradient) states, then you need to specify your baseline. Since the Earth is not a closed system, what is high-entropy locally may not be so vis-a-vis its wider environment. So energy that “smooths out” in a patch of the planet surface or liquid-gas envelope is not energy which has vanished, it is energy which is unavailable for local work; as soon as that patch is hooked up to the cosmic background, though, it is again on a (fairly steep) gradient.
So I don’t think you can say that high-entropy energy is lost to the climate system forever if it has somewhere else it can still leak to. And it does.
But here’s a quibble I retain with those who assert that all work done by wind and wave etc. on the Earth’s surface rapidly turns into mere heat:
If I place a weight on a shelf, it has/stores potential energy. If I then return it to the floor, whether gently or by dropping it, that energy becomes heat.
However, if I move it 20′ away, but at the same height, it has no added potential energy. No simple way of unwinding that displacement into heat is evident. Similarly, work done by moving masses of air and water hither and yon does not spontaneously (or in any other evident way) degrade to heat. The “dismissive” way of thinking of such work done seems to say that the displacement “doesn’t count” as real work (unless it was done against the gravitational field). No heat energy was lost/used/tied up?
Steven Kopits says:
December 23, 2010 at 6:49 am
What drives the weather? Isn’t that a result of solar energy converted to kinetic energy? If it gets hot, don’t we have a storm, a tornado, or a hurricane? How much energy does one of them consume, and where does it come from?
NOAA gives a good calculation here:: http://www.aoml.noaa.gov/hrd/tcfaq/D7.html
The cloud and rain formation: “This is equivalent to 200 times the world-wide electrical generating capacity – an incredible amount of energy produced!”
and the kinetic energy: :“This is equivalent to about half the world-wide electrical generating capacity – also an amazing amount of energy being produced!”
That is a lot of energy from one hurricane in one day and it puts the hubris of the human race in perspective. The hydrologic cycle is massively more powerful than most people seem to comprehend.
Energy added to the climate system equals energy leaving the system plus energy going into the ocean.
Appears to me, uneducated as I am in this, lacking dimension.
How much energy is used and produced and kept, by life on earth? Plants take in energy from the sun using it for their own growth in life and from that apex more and more complex life systems utilise some of that energy with man at the bottom of the triangle, using it for growth and work which doesn’t ‘escape from the system’. How much energy does one ant use from the sun in its lifetime via plants?
It appears to me, caveat as above, that AGW has created a lifeless system in thinking in this ‘energy balance’ much as it has done with CO2 with its destruction of the dynamical system which is all life by thinking of plants merely as ‘carbon sinks’, somewhere merely to store CO2; from which the used to be known fact that CO2 was food for all living carbon life forms is practically unknown and now at the absurd reasoning from not knowing it, that it can defy gravity and stay removed and out of reach from the carbon life forms which evolved from its property of being available at ground level. This equation is flat and lifeless. Life is your missing energy.
“the forcing drops because of the volcanoes”
The red line drops at 1981 and 1990 well before El Chichon and Pinatubo erupt. Over a year.
WUWT?
Willis Eschenbach says:
December 23, 2010 at 7:42 pm
walt man says:
December 23, 2010 at 3:06 pm
If sst is increasing.
If there is a thermohaline circulation (cool salty water sinking in the arctic).
If the THC is surface warm traveling to arctic and cold traveling at 2000 to 4000 metres down towards antarctic (arrival time 700 years?).
If Argo dives to 2000 metres they will not see the antarctic traveling THC.
“Estimates of Meridional Atmosphere and Ocean Heat Transports Kevin E. Trenberth and Julie M. Caron” suggest 1.27± 0.26 PW of heat is carried by THC north
If you heat the north going surface layer which then sinks warmer and travels south at below 2000 metres warmer this must surely be a good hiding place for a fair bit of missing TSI energy! (for a few hundred years)
“A lot of people are ignoring is the need for speed. You need a possible system that can accept or release a great deal of energy in a short time. Deep ocean currents are a lot of things … but they are not a quick-reacting system.
Willis”
Willis, is it not possible that some systems receive energy quickly, but manifest it slowly? While riding a bicycle up a steep hill I can quickly increase the energy in my legs, which, if I am in a low gear will efficiently manifest as a change in speed, but if I am in a high gear this speed change will manifest far slower. Do we really have the understanding and sensitivity in all of our measuring to capture the energy budget as it changes form, phase, and location, or are there possibly slow changes in thermocline depths, hydrologic cycle speeds, atmospheric elevations, large ocean currents etc, that can receive energy quickly but manifest it as temperature slowly or even imperceptibly in regard to our ability to capture these changes?
Also have you looked at the annual cycles in all that you are measuring to see if the earth’s seasonal energy pulse can reveal some of this mystery? Sunlight, falling on the Earth when it’s about 3,000,000 miles closer to the sun in January, is about 7% more intense than in July. Because the Northern Hemisphere has more land which heats easier then water most people state that the Earth’s average temperature is about 4 degrees F higher in July than January, when in fact they should be stating that the ATMOSPHERE is 4 degrees higher in July. In January this extra SW energy is being pumped into the oceans where the “residence time” within the Earth’s ocean land and atmosphere is the longest
As these immense changes in SWR TSI happen annually, then how much and how rapidly changes in those things you measured in Figure 1 and Figure 2 match these annual changes, as well as changes in albedo and cloud cover should give deeper insight relative to heat and energy flux within our earth system.
Maybe we should be measuring the greening of the oceans. Kelp anyone?
Brian H.
I agree completely with you about the fact that the work done by wind and waves etc., does not turn into mere heat. It went into doing work that will probably never be returned to the atmosphere or oceans as heat. This amount of energy is massive as Ian W has pointed out. The point I am trying to make about the entropy losses is much the same. If you cannot account for it directly by measuring it, you cannot assume it goes into mere heat either.
Woot! My Quibble Question was #500,000! I win, I win! I’m currently try to extract a list from Anthony of the swag I can expect from him.
As for the displacements, they are not without consequence. Thinking on it, they affect the LOD in some measure, as the center of gravity of the planet has been shifted. Etc.
Pamela Gray says:
December 24, 2010 at 8:18 am
“Maybe we should be measuring the greening of the oceans. Kelp anyone”
Pamela, yes Kelp, plankton blooms, etc. This bio energy has massive fluctations and the organic matter falls to the bottom as ocean snow. On land under the heat of the day it would make a large compost pile indeed. Take just salmon for instance, this past year their population increased dramaticaly:
http://www.google.com/url?sa=t&source=web&cd=7&ved=0CD4QFjAG&url=http%3A%2F%2Fonline.wsj.com%2Farticle%2FSB10001424052748703657604575005562712284770.html&ei=478VTYTVFImqsAPghYGxAg&usg=AFQjCNH-KNwWceCMOxZ8VYvJ10ben3gugQ
How much energy such process gobble up for how long I have no idea, which is a travesty I think. (-;
Brian H says:
December 24, 2010 at 12:31 am
I resemble that remark! (Archie Bunkerism)
Friction as the block was moved through the air is where the energy went. Both the block and the air heated up a tiny bit. That’s not counting the energy you expended to keep it aloft and walk with it of course. That also heated the air, your body, your shoes, and the floor.
The frictional heating might seem imperceptable but it’s there. A dearth of friction is why satellites can orbit the orbit the earth so long and a plethora of friction is why it burns up when the orbit decays.
rAr says:
December 23, 2010 at 11:54 am
re; heat
I hear ya. “Heat” isn’t really a technical term and is loosely used for energy quite often. Latent heat and sensible heat are technical terms. So let’s call it energy that is being transported from surface to cloud layer by vaporization and that energy won’t register on a thermometer during transit. All a thermometer will indicate is a cooler surface after evaporation and warmer air in the cloud layer after condensation.