Guest Post by Willis Eschenbach
I’ve tried writing this piece several times already. I’ll give it another shot, I haven’t been happy with my previous efforts. It is an important subject that I want to get right. The title comes from a 1954 science fiction story that I read when I was maybe ten or eleven years old. The story goes something like this:
A girl stows away on an emergency space pod taking anti-plague medicine to some planetary colonists. She is discovered after the mother ship has left. Unfortunately, the cold equations show that the pod doesn’t have enough fuel to land with her weight on board, and if they dump the medicine to lighten the ship the whole colony will perish … so she has to be jettisoned through the air lock to die in space.
I was hugely impressed by the story. I liked math in any case, and this was the first time that I saw how equations can provide us with undeniable and unalterable results. And I saw that the equations about available fuel and weight weren’t affected by human emotions, they either were or weren’t true, regardless of how I or anyone might feel about it.
Lately I’ve been looking at the equations used by the AGW scientists and by their models. Figure 1 shows the most fundamental climate equation, which is almost tautologically true:
Figure 1. The most basic climate equation says that energy in equals energy out plus energy going into the ocean. Q is the sum of the energy entering the system over some time period. dH/dt is the change in ocean heat storage from the beginning to the end of the time period. E + dH/dt is the sum of the outgoing energy over the same time period. Units in all cases are zettajoules (ZJ, or 10^21 joules) / year.
This is the same relationship that we see in economics, where what I make in one year (Q in our example) equals what I spend in that year (E) plus the year-over-year change in my savings (dH/dt).
However, from there we set sail on uncharted waters …
I will take my text from HEAT CAPACITY, TIME CONSTANT, AND SENSITIVITY OF EARTH’S CLIMATE SYSTEM, Stephen E. Schwartz, June 2007 (hereinafter (S2007). The study is widely accepted, being cited 193 times. Here’s what the study says, inter alia (emphasis mine).
Earth’s climate system consists of a very close radiative balance between absorbed shortwave (solar) radiation Q and longwave (thermal infrared) radiation emitted at the top of the atmosphere E.
Q ≈ E (1)
The global and annual mean absorbed shortwave irradiance Q = γ J, where γ [gamma] is the mean planetary coalbedo (complement of albedo) and J is the mean solar irradiance at the top of the atmosphere (1/4 the Solar constant) ≈ 343 W m-2. Satellite measurements yield Q ≈ 237 W m-2 [Ramanathan 1987; Kiehl and Trenberth, 1997], corresponding to γ ≈ 0.69. The global and annual mean emitted longwave irradiance may be related to the global and annual mean surface temperature GMST Ts as E = ε σ Ts^4 where ε (epsilon) is the effective planetary longwave emissivity, defined as the ratio of global mean longwave flux emitted at the top of the atmosphere to that calculated by the Stefan-Boltzmann equation at the global mean surface temperature; σ (sigma) is the Stefan-Boltzmann constant.
Within this single-compartment energy balance model [e.g., North et al., 1981; Dickinson, 1982; Hansen et al., 1985; Harvey, 2000; Andreae et al., 2005, Boer et al., 2007] an energy imbalance Q − E arising from a secular perturbation in Q or E results in a rate of change of the global heat content given by
dH/dt = Q – E (2)
where dH/dt is the change in heat content of the climate system.
Hmmm … I always get nervous when someone tries to slip an un-numbered equation into a paper … but I digress. Their Equation (2) is the same as my Figure 1 above, which was encouraging since I’d drawn Figure 1 before reading S2007. S2007 goes on to say (emphasis mine):
The Ansatz of the energy balance model is that dH/dt may be related to the change in GMST [global mean surface temperature] as
dH/dt = C dTs/dt (3)
where C is the pertinent heat capacity. Here it must be stressed that C is an effective heat capacity that reflects only that portion of the global heat capacity that is coupled to the perturbation on the time scale of the perturbation. In the present context of global climate change induced by changes in atmospheric composition on the decade to century time scale the pertinent heat capacity is that which is subject to change in heat content on such time scales. Measurements of ocean heat content over the past 50 years indicate that this heat capacity is dominated by the heat capacity of the upper layers of the world ocean [Levitus et al., 2005].
In other words (neglecting the co-albedo for our current purposes), they are proposing two substitutions in the equation shown in Figure 1. They are saying that
E = ε σ Ts^4
and that
dH/dt = C dTs/dt
which gives them
Q = ε σ Ts^4 + C dTs/dt (4)
Figure 2 shows these two substitutions:
Figure 2. A graphic view of the two underlying substitutions done in the “single-compartment energy balance model” theoretical climate explanation. Original equation before substitution is shown in light brown at the lower left, with the equation after substitution below it.
Why are these substitutions important? Note that in Equation (4), as shown in Figure 2, there are only two variables — radiation and surface temperature. If their substitutions are valid, this means that a radiation imbalance can only be rectified by increasing temperature. Or as Dr. Andrew Lacis of NASA GISS recently put it (emphasis mine):
As I have stated earlier, global warming is a cause and effect problem in physics that is firmly based on accurate measurement and well established physical processes. In particular, the climate of Earth is the result of energy balance between incoming solar radiation and outgoing thermal radiation, which, measured at the top of the atmosphere, is strictly a radiative energy balance problem. Since radiative transfer is a well established and well understood physics process, we have accurate knowledge of what is happening to the global energy balance of Earth. And as I noted earlier, conservation of energy leaves no other choice for the global equilibrium temperature of the Earth but to increase in response to the increase in atmospheric CO2.
Dr. Lacis’ comments are an English language exposition of the S2007 Equation (4) above. His statements rest on Equation (4). If Equation (4) is not true, then his claim is not true. And Dr. Lacis’ claim, that increasing GHG forcing can only be balanced by a temperature rise, is central to mainstream AGW climate science.
In addition, there’s a second reason that their substitutions are important. In the original equation, there are three variables — Q, E, and H. But since there are only two variables (Ts and Q) in the S2007 version of the equation, you can solve for one in terms of the other. This allows them to calculate the evolution of the surface temperature, given estimates of the future forcing … or in other words, to model the future climate.
So, being a naturally suspicious fellow, I was very curious about these two substitutions. I was particularly curious because if either substitution is wrong, then their whole house of cards collapses. Their claim, that a radiation imbalance can only be rectified by increasing temperature, can’t stand unless both substitutions are valid.
SUBSTITUTION 1
Let me start with the substitution described in Equation (3):
dH/dt = C dTs/dt (3)
The first thing that stood out for me was their description of Equation (3) as “the Ansatz of the energy balance model”.
“And what”, sez I, “is an ‘Ansatz’ when it’s at home?” I’m a self-educated reformed cowboy, it’s true, but a very well-read reformed cowboy, and I never heard of the Ansatz.
So I go to Wolfram’s Mathworld, the internet’s very best math resource, where I find:
An ansatz is an assumed form for a mathematical statement that is not based on any underlying theory or principle.
Now, that’s got to give you a warm, secure feeling. This critical equation, this substitution of the temperature change as a proxy for the ocean heat content change, upon which rests the entire multi-billion-dollar claim that increased GHGs will inevitably and inexorably increase the temperature, is described by an enthusiastic AGW adherent as “not based on any underlying theory or principle”. Remember that if either substitution goes down, the whole “if GHG forcings change, temperature must follow” claim goes down … and for this one they don’t even offer a justification or a citation, it’s merely an Ansatz.
That’s a good thing to know, and should likely receive wider publication …
It put me in mind of the old joke about “How many legs does a cow have if you call a tail a leg?”
…
“Four, because calling a tail a leg doesn’t make it a leg.”
In the same way, saying that the change oceanic heat content (dH/dt) is some linear transformation of the change in surface temperature (C dTs/dt) doesn’t make it so.
In fact, on an annual level the correlation between annual dH/dt and dTs/dt is not statistically significant (r^2=0.04, p=0.13). In addition, the distributions of dH/dt and dTs/dt are quite different, both at a quarterly and an annual level. See Appendix 1 and 4 for details. So no, we don’t have any observational evidence that their substitution is valid. Quite the opposite, there is little correlation between dH/dt and dTs/dt.
There is a third and more subtle problem with comparing dH/dt and dTs/dt. This is that H (ocean heat content) is a different kind of animal from the other three variables Q (incoming radiation), E (outgoing radiation), and Ts (global mean surface air temperature). The difference is that H is a quantity and Q, E, and Ts are flows.
Since Ts is a flow, it can be converted from the units of Kelvins (or degrees C) to the units of watts/square metre (W/m2) using the blackbody relationship σ Ts^4.
And since the time derivative of the quantity H is a flow, dH/dt, we can (for example) compare E + dH/dt to Q, as shown in Figure 1. We can do this because we are comparing flows to flows. But they want to substitute a change in a flow (dT/dt) for a flow (dH/dt). While that is possible, it requires special circumstances.
Now, the change in heat content can be related to the change in temperature in one particular situation. This is where something is being warmed or cooled through a temperature difference between the object and the surrounding atmosphere. For example, when you put something in a refrigerator, it cools based on the difference between the temperature of the object and the temperature of the air in the refrigerator. Eventually, the object in the refrigerator takes up the temperature of the refrigerator air. And as a result, the change in temperature of the object is a function of the difference in temperature between the object and the surrounding air. So if the refrigerator air temperature were changing, you could make a case that dH/dt would be related to dT/dt.
But is that happening in this situation? Let’s have a show of hands of those who believe that as in a refrigerator, the temperature of the air over the ocean is what is driving the changes in ocean heat content … because I sure don’t believe that. I think that’s 100% backwards. However, Schwartz seems to believe that, as he says in discussing the time constant:
… where C’ is the heat capacity of the deep ocean, dH’/dt is the rate of increase of the heat content in this reservoir, and ∆T is the temperature increase driving that heat transfer.
In addition to the improbability of changes in air temperature driving the changes in ocean heat content, the size of the changes in ocean heat content also argues against it. From 1955 to 2005, the ocean heat content changed by about 90 zettajoules. It also changed by about 90 zettajoules from one quarter to the next in 1983 … so the idea that the temperature changes (dT/dt) could be driving (and thus limiting) the changes in ocean heat content seems very unlikely.
Summary of Issues with Substitution 1: dH/dt = C dT/dt
1. The people who believe in the theory offer no theoretical or practical basis for the substitution.
2. The annual correlation of dH/dt and dT/dt is very small and not statistically significant.
3. Since H is a quantity and T is a flow, there is no a priori reason to assume a linear relationship between the two.
4. The difference in the distributions of the two datasets dH/dt and dT/dt (see Appendix 1 and 4) shows that neither ocean warming nor ocean cooling are related to dT/dt.
5. The substitution implies that air temperature is “driving that heat transfer”, in Schwartz’s words. It seems improbable that the wisp of atmospheric mass is driving the massive oceanic heat transfer changes.
6. The large size of the quarterly heat content changes indicates that the heat content changes are not limited by the corresponding temperature changes.
My conclusion from that summary? The substitution of C dT/dt for dH/dt is not justified by either observations or theory. While it is exceedingly tempting to use it because it allows the solution of the equation for the temperature, you can’t make a substitution just because you really need it in order to solve the equation.
SUBSTITUTION 2: E = ε σ Ts^4
This is the sub rosa substitution, the one without a number. Regarding this one, Schwartz says:
The global and annual mean emitted longwave irradiance may be related to the global and annual mean surface temperature GMST Ts as
E = ε σ Ts^4
where ε (epsilon) is the effective planetary longwave emissivity, defined as the ratio of global mean longwave flux emitted at the top of the atmosphere [TOA] to that calculated by the Stefan-Boltzmann equation at the global mean surface temperature; σ (sigma) is the Stefan-Boltzmann constant.
Let’s unpick this one a little and see what they have done here. It is an alluring idea, in part because it looks like the standard Stefan-Boltzmann equation … except that they have re-defined epsilon ε as “effective planetary emissivity”. Let’s follow their logic.
First, in their equation, E is the top of atmosphere longwave flux, which I will indicate as Etoa to distinguish it from surface flux Esurf. Next, they say that epsilon ε is the long-term average top-of-atmosphere (TOA) longwave flux [ which I’ll call Avg(Etoa) ] divided by the long-term average surface blackbody longwave flux [ Avg(Esurf) ]. In other words:
ε = Avg(Etoa) /Avg(Esurf)
Finally, the surface blackbody longwave flux Esurf is given by Stefan-Boltzmann as
Esurf = σ Ts^4.
Substituting these into their un-numbered Equation (?) gives us
Etoa = Avg(Etoa) / Avg(Esurf) * Esurf
But this leads us to
Etoa / Esurf = Avg(Etoa) / Avg(Esurf)
which clearly is not true in general for any given year, and which is only true for long-term averages. But for long-term averages, this reduces to the meaningless identity Avg(x) / Avg(anything) = Avg(x) / Avg(anything).
Summary of Substitution 2: E = ε σ Ts^4
This substitution is, quite demonstrably, either mathematically wrong or meaninglessly true as an identity. The cold equations don’t allow that kind of substitution, even to save the girl from being jettisoned. Top of atmosphere emissions are not related to surface temperatures in the manner they claim.
My conclusions, in no particular order:
• Obviously, I think I have shown that neither substitution can be justified, either by theory, by mathematics, or by observations.
• Falsifying either one of their two substitutions in the original equation has far-reaching implications.
• At a minimum, falsifying either substitution means that in addition to Q and Ts, there is at least one other variable in the equation. This means that the equation cannot be directly solved for Ts. And this, of course, means that the future evolution of the planetary temperature cannot be calculated using just the forcing.
• In response to my posting about the linearity of the GISS model, Paul_K pointed out the Schwartz S2007 paper. He also showed that the GISS climate model slavishly follows the simple equations in the S2007 paper. Falsifying the substitutions thus means that the GISS climate model (and the S2007 equations) are seen to be exercises in parameter fitting. Yes, they can can give an approximation of reality … but that is from the optimized fitting of parameters, not from a proper theoretical foundation.
• Falsifying either substitution means that restoring radiation balance is not a simple function of surface temperature Ts. This means that there are more ways to restore the radiation balance in heaven and earth than are dreamt of in your philosophy, Dr. Lacis …
As always, I put this up here in front of Mordor’s unblinking Eye of the Internet to encourage people to point out my errors. That’s science. Please point them out with gentility and decorum towards myself and others, and avoid speculating on my or anyone’s motives or honesty. That’s science as well.
w.
Appendix 1: Distributions of dH/dt and dT/dt
There are several ways we can see if their substitution of C dT/dt for dH/dt makes sense and is valid. I usually start by comparing distributions. This is because a linear relationship, such as is proposed in their substitution, cannot change the shape of a distribution. (I use violinplots of this kind of data because they show the structure of the dataset. See Appendix 2 below for violinplots of common distributions.)
A linear transformation can make the violinplot of the distribution taller or shorter, and it can move the distribution vertically. (A negative relationship can also invert the distribution about a horizontal axis, but they are asserting a positive relationship).But there is no linear transformation (of the type y = m x + b) that can change the shape of the distribution. The “m x” term changes the height of the violinplot, and the “b” term moves it vertically. But a linear transformation can’t change one shape into a different shape.
First, a bit of simplification. The “∆” operator indicates “change since time X”. We only have data back to 1955 for ocean heat content. Since the choice of “X” is arbitrary, for this analysis we can say that e.g. ∆T is shorthand for T(t) – T(1955). But for the differentiation operation, this makes no difference, because the T(1955) figure is a constant that drops out of the differentiation. So we are actually comparing dH/dt(annual change in ocean heat content) with C dT/dt (annual change in temperature)
Figure 2 compares the distributions of dH/dt and dT/dt. Figure A1 shows the yearly change in the heat content H (dH/dt) and the yearly change in the temperature T (dT/dt).
Figure A1 Violinplot comparison of the annual changes in ocean heat content dH/dt and annual changes in global surface temperature dT/dt. Width of the violinplot is proportional to the number of observations at that value (density plot). The central black box is a boxplot, which covers the interquartile range (half of the data are within that range). The white dot shows the median value.
In addition to letting us compare the shapes, looking at the distribution lets us side-step all problems with the exact alignment of the data. Alignment can present difficulties, especially when we are comparing a quantity (heat content) and a flow (temperature or forcing). Comparing the distributions avoids all these alignment issues.
With that in mind, what we see in Figure A1 doesn’t look good at all. We are looking for a positive linear correlation between the two datasets, but the shapes are all wrong. For a linear correlation to work, the two distributions have to be of the same shape. But these are of very different shapes.
What do the shapes of these violinplots show?
For the ocean heat content changes, the peak density at ~ – 6 ZJ shows that overall the most common year-to-year change is a slight cooling. When warming occurs, however, it tends to be larger than the cooling. The broad top of the violinplot means that there are an excess of big upwards jumps in ocean heat content.
For the temperature changes, the reverse is true. The most common change is a slight warming of about 0.07°C. There are few examples of large warmings, whereas large coolings are more common. So there will be great difficulties equating a linear transform of the datasets.
The dimensions of the problem become more apparent when we look at the distributions of the increases (in heat content or temperature) versus the distributions of the decreases in the corresponding variables. Figure A2 compares those distributions:
Figure A2. Comparison of the distribution of the increases (upper two panels) and the decreases (lower two panels) in annual heat content and temperature. “Equal-area” violinplots are used.
Here the differences between the two datasets are seen to be even more pronounced. The most visible difference is between the increases. Many of the annual increases of the ocean heat content are large, with a quarter of them more than 20 ZJ/yr and a broad interquartile range (black box, which shows the range of the central half of the data). On the other hand, there are few large increases of the temperature, mostly outliers beyond the upper “whisker” of the boxplot.
The reverse is also true, with most of the heat content decreases being small compared to the corresponding temperature decreases. Remember that a linear transformation such as they propose, of the form (y = m x + b), has to work for both the increases and the decreases … which in this case is looking extremely doubtful.
My interpretation of Figure A2 is as follows. The warming and cooling of the atmosphere is governed by a number of processes that take place throughout the body of the atmosphere (e.g. longwave radiation absorption and emission, shortwave absorption, vertical convection, condensation, polewards advection). The average of these in the warming and cooling directions are not too dissimilar.
The ocean, on the other hand, can only cool by releasing heat from the upper surface. This is a process that has some kind of average value around -8 ZJ/year. The short box of the boxplot (encompassing the central half of data points) shows that the decreases in ocean heat content are clustered around that value.
Unlike the slow ocean cooling, the ocean can warm quickly through the deep penetration of sunlight into the mixed layer. This allows the ocean to warm much more rapidly than it is able to cool. This is why there are an excess of large increases in ocean heat content.
And this difference in the rates of ocean warming and cooling is the fatal flaw in their claim. The different distributions for ocean warming and ocean cooling indicate to me that they are driven by different mechanisms. The Equation (3) substitution seen in S2007 would mean that the ocean warming and cooling can be represented solely by the proxy of changes in surface temperature.
But the data indicates the ocean is warming and cooling without much regard to the change in temperature. The most likely source of this is from sunlight deeply heating the mixed layer. Notice the large number of ocean heat increases greater than 20 ZJ/year, as compared to the scarcity of similarly sized heat losses. The observations show that this (presumably) direct deep solar warming both a) is not a function of the surface temperature, and b) does not affect the surface temperature much. The distributions show that the heat is going into the ocean quickly in chunks, and coming out more slowly and regularly over time.
In summary, the large differences between the distributions of dH/dt and dT/dt, combined with the small statistical correlation between the two, argue strongly against the validity of the substitution.
Appendix 2: Violinplots
I use violinplots extensively because they reveal a lot about the distribution of a dataset. They are a combination of a density plot and a box plot. Figure A3 shows the violin plots and the corresponding simple boxplots for several common distributions.
Figure A3. Violin plots and boxplots. Each plot shows the distribution of 20,000 random numbers generated using the stated distribution. “Normal>0” is a set comprised all of the positive datapoints in the adjacent “Normal” dataset.
Because the violin plot is a density function it “rounds the corners” on the Uniform distribution, as well as the bottoms of the Normal>0 and the Zipf distributions. Note that the distinct shape of the Zipf distribution makes it easy to distinguish from the others.
Appendix 3: The Zipf Distribution
Figure A3. Violinplot of the Zipf distribution for N= 70, s = 0.3. Y-axis labels are nominal values.
The distinguishing characteristics of the Zipf distribution, from the top of Figure A3 down, are:
• An excess of extreme data points, shown in the widened upper tip of the violinplot.
• A “necked down” or at least parallel area below that, where there is little or no data.
• A widely flared low base which has maximum flare not far from the bottom.
• A short lower “whisker” on the boxplot (the black line extending below the blue interquartile box) that extends to the base of the violinplot
• An upper whisker on the boxplot which terminates below the necked down area.
Appendix 4: Quarterly Data
The issue is, can the change in temperature be used as a proxy for the change in ocean heat content? We can look at this question in greater detail, because we have quarterly data from Levitus. We can compare that quarterly heat content data to quarterly GISSTEMP data. Remember that the annual data shown in Figures A1 and A2 are merely annual averages of the quarterly data shown below in Figures A4 and A5. Figure A4 shows the distributions of those two quarterly datasets, and lets us investigate the effects of averaging on distributions:
Figure A4. Comparison of the distribution of the changes in the respective quarterly datasets.
The shape of the distribution of the heat content is interesting. I’m always glad to see that funny kind of shape, what I call a “manta ray” shape, it tells me I’m looking at real data. What you see there is what can be described as a “double Zipf distribution”.
The Zipf distribution is a very common distribution in nature. It is characterized by having a few really, really large excursions from the mean. It is the Zipf distribution that gives rise to the term “Noah Effect”, where the largest in a series of natural events (say floods) is often much, much larger than the rest, and much larger than a normal distribution would allow. Violinplots clearly display this difference in distribution shape, as can be seen in the bottom part of the heat content violinplot (blue) in Figure A4. Appendix 3 shows an example of an actual Zipf distribution with a discussion of the distinguishing features (also shown in Appendix 2):
The “double” nature of the Zipf distribution I commented on above can be seen when we examine the quarterly increases in heat and temperature versus the decreases in heat and temperature, as shown in Figure A5:
Figure A5. Comparison of the distribution of the increases (upper two panels) and the decreases (lower two panels) in quarterly heat content (blue) and quarterly temperature (green)
The heat content data (blue) for both the increases and decreases shows the typical characteristics of a Zipf distribution, including the widened peak, the “necking” below the peak, and the flared base. The lower left panel shows a classic Zipf distribution (in an inverted form).
What do the distributions of the upward and downward movements of the variables in Figure A5 show us? Here again we see the problem we saw in the annual distributions. The distributions for heat content changes are Zipf distributions, and are quite different in shape from the distributions of the temperature changes. Among other differences, the inter-quartile boxes of the boxplots show that the ocean heat content change data is much more centralized than the temperature change data.
In addition, the up- and down- distributions for the temperature changes are at least similar in shape, whereas the shapes of the up- and down- heat content change distributions are quite dissimilar. This difference in the upper and lower distributions is what creates the “manta-ray” shape shown in Figure A4. And the correlation is even worse than with the annual data, that is to say none.
So, as with the annual data, the underlying quarterly data leads us to the same conclusion: there’s no way that we can use dT/dt as a proxy for dH/dt.
Appendix 5: Units
We have a choice in discussing these matters. We can use watts per square metre (W m-2). The forcings (per IPCC) have a change since 1955 of around +1.75 W/m2.
We can also use megaJoules per square metre per year (MJ m-2 y-1). The conversion is:
1 watt per square metre (W m-2) = 1 joule/second per square metre (J sec-1 m-2) times 31.6E6 seconds / year = 31.6 MJ per square metre per year (MJ m-2 yr-1). Changes in forcing since 1955 are about +54 MJ per square metre per year.
Finally, we can use zettaJoules (ZJ, 10^21 joules) per year for the entire globe. The conversion there is
1 W/m2 = 1 joule/second per square metre (J sec-1 m-2) times 31.6E6 seconds / year times 5.11E14 square metres/globe = 16.13 ZJ per year (ZJ yr-1). Changes in forcing since 1955 are about +27 ZJ per year. I have used zettaJoules per year in this analysis, but any unit will do.
See Trenbeth’s figures at
http://stephenschneider.stanford.edu/Climate/Climate_Science/EarthsEnergyBalance.html
He has a total flux of 492 watts, with 102 in latent heat of vaporization of water vapor and convection.
E = ε σ Ts^4 is wrong! It should be something like
E = ε σ Ts^4 + Latent heat, and their argument doesn’t give any indication of how this should be broken down. I suspect that as E increases, the sensible heat should increase at a lower rate than latent heat.
As to
dH/dt = C dTs/dt
“The total mean mass of the atmosphere is 5.1480×1018 kg with an
annual range due to water vapor of 1.2 or 1.5×1015 kg depending on
whether surface pressure or water vapor data are used; somewhat
smaller than the previous estimate. The mean mass of water vapor is
estimated as 1.27×1016 kg and the dry air mass as 5.1352
A 4C rise or higher this century would see the world warm almost as
much in 100 years as it did during the 15,000 years since the end of
the last ice age.”
During last ice age, there were 71.3 million k3 ice *0.917 vol ice/vol
water=
65.3821 million cubic kilometers of water.
1 cubic meter= 1000 kg.
1 cubic km = 10^12 kg
65.3821 million cubic km= 65.3821*10^18 kg
Total heat to melt glaciers =65.3821 *10^18 *1000*334 kj=2.18*10^25
joules
Cp air= 1.012 joules/gram K
1012 Joules/kg K * 5.148^10^18 =5.209776 *10^21 joules
4degree increase=2.0839 *10^22 joules
So about 1000 times as much heat went into melting the glaciers at
the end of the Pleistocene as went into heating the atmosphere.
C in the above equation is on the order of 0.001
too small to be measured over any reasonable interval- random fluctuations will
overwhelm any attempted measurement of correlation, and as you stated, it would be the ocean heat driving air temperature rather than vice versa.
Willis,
As I understand it, a “flow” is a transfer of something from one place to another. [Eg “there was a flow of 2 gallons of water into my sink.”]
A “flow rate” would be a measure of the rate at which the flow occurred. [Eg “there was a 0.5 gal/min flow rate of water into my sink.”]
Q is a flow rate of energy (at least it is in this article; more typically “Q” is used for a flow). E is a flow rate of energy. dH/dt is a flow rate of energy. [ie some number of joules of energy are transferred from one place to another place in a given amount of time]
That would mean that C dTs/dt is a flow rate. C dTs would be a flow. dTs by itself is neither a flow nor a flow rate (although it is related to both). Ts is also not a flow or a flow rate, but it is related to both via Stefan-Boltzmann.
If you have a different definition of “flow” or “flow rate” that you would like to propose, I will listen.
I think they meant that equation was the starting point.
***
Ansatz (pronounced [ˈanzats], English: “onset”; today, “approach, setup, starting point”; plural: Ansätze) is a German noun with several meanings in the English language. [1] It is widely encountered in physics and mathematics literature. Since ansatz is a noun, in German texts the initial a of this word is always capitalised.
***
http://en.wikipedia.org/wiki/Ansatz
Given a constant amount of CO2, if weather conditions change so that there are more rainstorms, more of the heat will bypass the atmospheric CO2. Everyone says the equations take it into account, but how can it when it can vary by such a large amount from year to year?
How much heat was released at high altitude by the rainstorms in Australia? I don’t think the amount of heat released by weather at high altitude is consistent from one year to the next.
Willis, from Appendix 1 downward, very interesting as usual. What a great way to visualize the fallacy in the use of such simple equations without all of the other factors never addressed.
Probably you have already asked yourself, can the dissimilarity of the shapes of warming to cooling now be brought closer together by adding or subtracting a proper factor of the cloud cover data over this period or maybe some of the other major factor?
It’s so logical, and real, that the deep absorption of short wave radiation would be the primary cause, and the thermal conductivity and diffusivity, being quite low, greatly slows the movement of that energy back out of the ocean. I’m surprised those violin graphs don’t look even further apart in shape.
Leonard Weinstein says:
…2) The air temperature does have an effect on ocean heat retention. It is a small effect, and not dominate (thus the low correlation), but don’t say there is no effect at all. The mechanism is that the ocean loses the absorbed solar radiation three ways….
++++
I agree Leonard that the radiation of heat from the water surface is often misunderstood or overlooked. Water is a powerful radiator of heat, about the same as liquid black oil!
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kwinterkorn says:
…But it must be true that as the the temperature of the atmosphere increases, the net rate of heat transfer from the oceans to the atmosphere will slow (for radiative and conductive heat transfer). Rising atmosphere humidity will slow the evaporative cooling of the oceans.
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I believe this is a mistake, confusing specific humidity with relative humidity. It is a common error and many CO2-global warming arguments contain it. Yes it is true that the warmer ocearn (however heated) will give off more water vapour into a warmer atmosphere, but the warmer air will remove more moisture (total mass) to achieve the same relative humidity.
If the whole system, air and water, increases 0.1 degerees in temperature, the rate of evaporation is the same. Evaporation is not blocked by air that is now ‘full’. By ‘full’ I mean, stabilising at the same relative humidity as before the increase. As the air is warmer, it can hold more water.
I recently mentioned elsewhere a related error which is to think that if it contains more moisture (in g/m^3) is will rain more. If the land over which the cloud passes is also 0.1 deg warmer, then the cooling effect will be down to a temperature that is also 0.1 degrees higher than before, so the amount of rain is the same, the dried air moving away at 0.1 degrees higher, retaining its little increase of moisture as to goes because the old rained-out _relative_ humidity has been reached. This misunderstanding drives claims about New York snow being caused by ‘warmer air holding more water in a heated world’.
Leonard’s point is that there is an insulative effect from the higher absolute humidity. This is correct. The resulting warmer air can contain more moisture (etc) and is part of a positive feedback. All things considered, however, the resulting _relative_ humidity in the end is the same, for the temperature changes with which we are concerned.
KR says:
January 28, 2011 at 1:04 pm
I say again, we are talking about energy, it doesn’t disappear. You can’t simply say that it will average out over several decades without specifying where the energy is stored during those decades. I invited you before to tell us where these huge amounts of energy are stored, without getting an answer.
Second, the time frame specified in the Schwartz S2007 paper is annual. Why would they even talk about an annual scale if it doesn’t work on an annual scale?
Finally, yes, there is a relationship between surface temperature and ocean heat content … because the ocean rules the overlying part of the atmosphere, and that is part of the surface temperature. It only shows up, of course, at longer time spans … does this sound familiar, an increasing correlation as the time spans increase?
You see that increasing correlation with time as some kind of sign that delta T actually is driving oceanic heat content changes. I see it as a very predictable result of the fact that the two datasets (T and H) are not entirely separate.
KR, I fear that you are on a fools errand, trying to provide a physical justification for the Ansatz. Schwartz and Hansen and the rest of those folks would all like to find some physical justification for it as well … and the fact that after thirty years, they are still calling it an Ansatz should give you a clue.
w.
Tim Folkerts says:
January 28, 2011 at 2:11 pm
Tim, I’ve said it before, but I’ll say it again. That formula is true and valid … but only in the case where the gain/loss of heat is governed by ∆T.
However, that’s not the case here. The ocean is not changing temperature based on what the atmosphere does. The gain/loss is not driven by ∆T.
In addition, as you point out, they’re not even using ∆T (difference between air and ocean). They’re using the change in T with time (dT/dt).
So no, the fact that their equation is it’s kinda similar to a valid equation for some different situation means nothing. It has to be judged on its own merit.
w.
Willis Eschenbach says:
January 28, 2011 at 5:14 pm
Hi, Frank. No, that’s not what I’m saying.
In a situation where temperature differential is driving the temperature change, or equivalently where hydraulic head is driving the volume change, that relationship holds. But in this situation, atmospheric temperature is not driving ocean heat content changes, it simply doesn’t have enough thermal mass.
======================================================
Willis, Well I don’t disagree with you, in a sense that is what I was saying that you disagree that Ts is not a suitable proxy.
I have not read S2007 whether that’s what author(s) are saying but my interpretation would be that the sun is heating the ocean (that is part of Q going into the ocean) and cooling is part of E heat rate being dissipated. So wouldn’t the surface temperature also be a reflection of what the sun is also adding to the ocean over the long term.
The fact that they don’t agree (surface temps and ocean) in the short term surely is not the measure since there are time lags involved etc. What bothers me more is the next point:
The Stefan- Boltzmann equation to me with the epsilon parameter is that this parameter has a value somewhere less than 1 and would seem to take into account the fact that the earth is not a truly black body and well as other factors. But where does CO2 and water vapour fit into all of this? It seems all to be lumped into epsilon. One parameter that has no definite value!! In other words this is a fitting parameter and they are trying to extract the contribution that CO2 is making (apart from a more important water vapour) to limit the radiation to space.!! Its open slather – take your pick about the episilon value, but if you are CO2 driven s there’ a clear path available to “validate” your model.
If I have misinterpreted what the S2007 authors have done or intended my apologies.
Any comments on this Willis??
Regards,waiting for your next post.
If it is windier, you will get a lot more water vapor off the oceans.
This is like leaving the lid off the pot and it takes longer to boil.
The colder periods on the Earth were much more windier according to the Greenland ice cores.
Maybe the key is to find the speed control?
Willis,
I’m not really sure what your latest objections are.
“Tim, I’ve said it before, but I’ll say it again. That formula is true and valid … but only in the case where the gain/loss of heat is governed by ∆T.”
It takes energy to warm an object. The amount of energy is C∆T. The heat gained (called dH here) is governed by the temperature change of the object; the temperature change is governed by the heat gained. dH = C∆T. Unless there is also a change of phase, then this equation will hold. (Or there would be potential problems if the mass of the object changed, but I don;t think the overall change in the mass of the ocean due to evaporation will be enough to be a serious concern, since an almost exactly equal amount is returned by precipitation.)
“they’re not even using ∆T (difference between air and ocean)”
They SHOULDN’T be sung the difference between air and ocean. ∆T would be the amount that the ocean warms on average during the year (or cools if ∆T is negative). It is not the temperature difference between air and water. Are you thinking about heat conduction, where the amount of energy that flows is proportional to the temperature difference across some insulating layer? Then the difference between ocean and air would play a role, but that is not the ∆T (or “dTs” as it is called here) that is being used in this paper.
“as you point out, they’re using the change in T with time (dT/dt).”
That is what they should be using. If the temperature of the ocean starts the year at T1 and ends at T2, then the the total energy change is dH = C(T2-T1) = C∆T = C d(Ts). Since we want dH per year, we divide both sides by (t2-t1) = ∆t = dt = 1 year.
The problem that I was trying to point out is that the “object” being heated is not clearly delimited. Just how much of the ocean should be included? A quick look at the actual suggest they try to address that issue, so I am not going to go into more detail here now.
About the units – just a question about dH/dt = Q-E. H is the ‘heat content’ of something. It’s dimension is joules (energy). Rate of change of H with time dH/dt has dimension joules/second. That is watts. OK but Q (irradiance) is not watts but watts/meter^2. So is H heat per square meter? What is the physical meaning of this – a two dimensional surface of no thickness cannot have heat can it?
I wonder if the nub of the argument here is that “global warming theory” says that everything should be warming, the atmosphere, the surface, and the oceans.
However if the atmosphere and surface is warming, but the oceans are cooling, then it is surely simply a transient natural phenomena, to do with the phase of the ocean flow oscillations. The oceans are dumping heat into the atmosphere, and cooling as a result.
Willis,
I think at least four things have been left out of the equation, which make the theory indeterminate.
Firstly there are layers in both the oceans and the atmosphere, which are in turbulent interaction.
Second there is an interchange of heat into and out of all living matter (animal, bacteria & vegetable) as it grows and decays. Individually this is imaterial, but there sure is a lot of it in total.
Third there is the latent heat of melting and evapotation going in both directions. These store and release energy in an indefinite timetable.
Clouds, thunderstorms, volcanos add to the chaotic mix.
Fourth, there are the short term chaotic atmospheric and oceanic perturbances, the Le Nino / La Nina events that happen every few years and then the major 60 year cycles, changing each 30 years as we are seeing at the moment. These also store and release heat.
So it’s easy to say that the physics is settled – case closed, as we hear all the time, which just means that:
The energy coming in, LESS the energy going OUT,
EQUALS ( and must by all the laws of physics always equal) plus or minus the CHANGE in what’s temporarily left WITHIN the system in a particular year.
Now that’s ALL that physics can tell you.
The actual equation, let alone the numerical values is written in the stars.
Now what did Hamlet say to Horatio – something about “more than you can know or understand” I think.
Bother – my memory of English literature is even worse than my physics.
And I was a physics scholar once upon a time when the world was young.
No matter.
My principle is right – I am afeared that you are on a wild goose chase, meboy.
Warmists often talk reeeeele egucated like, but its all spin and make believe.
Balancing global heat budgets in detail is for the birds.
Willis Eschenbach says:
January 28, 2011 at 5:08 pm
A number of people have said that temperature is not a flow. However, temperature can be converted to the equivalent blackbody radiation flow using the familiar Stefan-Boltzmann formula.
Think about it this way. My body is at about 37°C. Like anything at that temperature, there is a constant flow of radiative energy emanating from my body, 525 W/m2. How, then, is a temperature of 37°C not equivalent to a flow of 525 W/m2?
On this logic a voltage is a current! A hill is an acceleration!
I explained in a previous post that the “flow” is encapsulated in the stefan boltzman constant which has the dimensions of watts/m^2T^4. If you do a dimensional analysis of the Stephan Boltzman equation you will clearly see that the dimensions on the left hand side are watts/m^2 and these dimensions are reflected in the Stephan Boltzman constant itself not in T.
To repeat, it is the Stefan boltzman constant which governs the radiative flux generated by the Temperature just as the resistance of a wire governs the flow of current caused by a voltage. Temperature is not a flow.
If you still don’t believe me do the calculation of doubling T. Will the flow double? I don’t think so!
Willis Eschenbach says:
January 28, 2011 at 5:08 pm
“Think about it this way. My body is at about 37°C. Like anything at that temperature, there is a constant flow of radiative energy emanating from my body, 525 W/m2. How, then, is a temperature of 37°C not equivalent to a flow of 525 W/m2?”
Is this making the assumption that the skin surface is a ‘black-body’ radiator? -grin-
If this was the ONLY energy flow I think you would need to consume several thousand calories and HOUR to maintain body temperature.
However net flow means that most of us require far less energy input to maintain our surface temperature.
1)-The ambient temperature determines how much energy is flowing BACK to the body surface, so while the 37degC determines the outgoing flow of 525W/m2 the temperature difference is proportional to the net flow.
2)-We usually modify this further by the use of clothes that absorb the outgoing energy radiated from the body, warm in response and radiate a portion of that energy back to us. The clothes also ensure that the outer radiating surface of the person is at a lower temperature than the skin surface so that energy loss between the system of body+clothes radiates at less than 525W/m2
The parrallel with surface and tropopause temperatures is obvious I hope.
In reply to Izen. The calories humans consume are actually Kilocalories. Given that,
depending on your weight and lifestyle , you may consume about 2000 calories per day, that 2000 actual kilocalories is actually 2,000,000 calories, so yes you DO have to consume several thousand calories per hour to stay alive.
I’m reminded of the joke-when you drink a liter, about 1.09 quarts, of ice water, you
body heats heats it up to 37C. That works out to 37,000 calories. So why can’t you lose weight by sitting around drinking ice water. That 37,000 calories works out to only
37 kilocalories, about 37/2000 or 1.85% of a reasonable daily intake.
Wills:
Except, if there isn’t an equivalent flow of energy into your body, it wouldn’t stay at 37°C for long.
Perhaps a living body is a bad example, as it regulates its temperature, but the principle still holds – for a constant temperature, Ein = Eout.
I discovered the basic principles of this when I was around eight years old. Armed with a clinical thermometer, I filled a bathtub with water at a temperature of 37°C, and was then very surprised that I couldn’t immerse my body in the tub for more than a few seconds before starting to feel unbearably hot.
@- Alan McIntire says:
“In reply to Izen. The calories humans consume are actually Kilocalories. ”
I am well aware of the conversion factors between food calories and kilocalories as used in human nutrion.
But I must admit to a big mistake in my calculation. To expend 525W/m2 ‘only requires around 900 ‘human’ calories (kilocalories) an hour.
Or something over 20,000 calories a day, around ten times the usual human consumption.
In very cold climates increasing the calorie intake is required because the temperature difference increases the NET loss of energy.
But when the temperature difference between your body and the environment is around 15degC then you don’t need to eat 2 big Mac’s an hour to maintain body temperature.
Cal,
As power is voltage x current, W/m2 can be regarded as a measure of flow (current) , provided that either the voltage or resistance is known.
ausiedan said
January 29, 2011 at 3:34 am
“I think at least four things have been left out of the equation, which make the theory indeterminate.” . . . . . “Balancing global heat budgets in detail is for the birds.”
My question is, why is it SO important a thing to do . . . get it exactly right?
Is it because the ability to predict accurately gives the illusion of the power to control? “likened unto a god”
or
Is it because the ability to predict accurately gives the illusion of the power to influence behavior and say SEE it worked?
or
Is it just the ability to instill fear?
I’d like to think it is for forwarning . . . but, thus far this kind of knowledge has historically been used for the former three, (at least from my perspective).
@ur momisugly P. Solar says:
“.. the global temperature is not going to triple (unless Hansen turns out to be correct 😉 ) so what it the error in say comparing 300K to 310K (0C=273K)
the difference of the forth powers is about 14% whereas the diff in temp is around 3%.
So it is not negligible but not an order of magnitude off.”
– Spot on, I only used 1 and 3 to clearly illustrate the faulty maths. To use Stefan-Boltzman to calculate radiative heat output you have to integrate by time and space to account for the fact that different locations have different temperatures at any specific time, and that each location’s temperature varies with time on diurnal and annual cycles. Also, I wonder if there is a difference between land and sea. IIRC land heats up and cools down faster than the sea, so a priori is likely to to emit more radiative heat than sea at the same average temperature.
With regard to the magnitude of the error, I could understand if this was offered as an estimate, with the caveat “we know it’s not correct, but it’s pretty close for practical purposes”, but its not put that way. Further, even a 3% error can be highly significant (try underpaying your taxes by 3% if you don’t believe me). Lastly, my biggest objection is that this is such a crass mistake, in the one little bit of the picture that I understand, that all the stuff I don’t understand, let’s say I am not taking it at face value.
“It all goes to underline how grossly over-simplified all this work is and just how much climate science is in its infancy. Nothing you’d want to trust to redesign life on Earth of start screwing around with geo-engineering.”
– Very nicely put, thank you
Robbo said January 29, 2011 at 8:59 am
“It all goes to underline how grossly over-simplified all this work is and just how much climate science is in its infancy.”
I am sorry, but I completely disagree with this statement . . . In my opinion, Climate Science is fairly old and understood. Wars have been planned and fought based on Climate Science for one . . . To me, what is going on is there has been a “break” in the accurate predictions, and those that plan, based on climate science, are trying to figure out where ‘they’ went wrong. Sad, but true. Climate Science, has been “proprietary” information for many, many, many generations. It’s just like the “secrets” of banking, only different.
Now, how do you prove a secret is a ‘secret’!?
Laurie Bowen:
How many climate scientists were there 30 years ago?
What makes you think that we know any more about how the climate works than we know about the far side of the Moon?
Very interesting Willis. I think you are onto something. It will take me some time to get my head around all of it.
However, my first problem. The assumption that there is a “close radiative balance”.
“Earth’s climate system consists of a very close radiative balance between absorbed shortwave (solar) radiation Q and longwave (thermal infrared) radiation emitted at the top of the atmosphere E.
Q ≈ E (1)
The global and annual mean absorbed shortwave irradiance Q = γ J, where γ [gamma] is the mean planetary coalbedo (complement of albedo) and J is the mean solar irradiance at the top of the atmosphere”
Over longer periods (i.e. centuries) I accept that absorbed shortwave radiation Q will approximately equal longwave (thermal infrared) radiation emitted at the top of the atmosphere E.
In other words
Q ≈ E
But over shorter periods (i.e.years), is it reasonable to assume that albedo approximately constant? Some years there will be more cloud cover making Q lower and vice versa.
So on an annual basis it is unreasonable to assume that Q ≈ E
Even if E is approximately constant, which I doubt, the annual absorbed shortwave radiation Q is quite variable.
Which means everything that follows is questionable as well.