Guest Post By William DiPuccio
Albert Einstein once said, “No amount of experimentation can ever prove me right; a single experiment can prove me wrong.” Einstein’s words express a foundational principle of science intoned by the logician, Karl Popper: Falsifiability. In order to verify a hypothesis there must be a test by which it can be proved false. A thousand observations may appear to verify a hypothesis, but one critical failure could result in its demise. The history of science is littered with such examples.
A hypothesis that cannot be falsified by empirical observations, is not science. The current hypothesis on anthropogenic global warming (AGW), presented by the U.N.’s Intergovernmental Panel on Climate Change (IPCC), is no exception to this principle. Indeed, it is the job of scientists to expose the weaknesses of this hypothesis as it undergoes peer review. This paper will examine one key criterion for falsification: ocean heat.
Ocean heat plays a crucial role in the AGW hypothesis, which maintains that climate change is dominated by human-added, well-mixed green house gasses (GHG). IR radiation that is absorbed and re-emitted by these gases, particularly CO2, is said to be amplified by positive feedback from clouds and water vapor. This process results in a gradual accumulation of heat throughout the climate system, which includes the atmosphere, cryosphere, biosphere, lithosphere, and, most importantly, the hydrosphere. The increase in retained heat is projected to result in rising atmospheric temperatures of 2-6ºC by the year 2100.
In 2005 James Hansen, Josh Willis, and Gavin Schmidt of NASA coauthored a significant article (in collaboration with twelve other scientists), on the “Earth’s Energy Imbalance: Confirmation and Implications” (Science, 3 June 2005, 1431-35). This paper affirmed the critical role of ocean heat as a robust metric for AGW. “Confirmation of the planetary energy imbalance,” they maintained, “can be obtained by measuring the heat content of the ocean, which must be the principal reservoir for excess energy” (1432).
Monotonic Heating. Since the level of CO2 and other well-mixed GHG is on the rise, the overall accumulation of heat in the climate system, measured by ocean heat, should be fairly steady and uninterrupted (monotonic) according to IPCC models, provided there are no major volcanic eruptions. According to the hypothesis, major feedbacks in the climate system are positive (i.e., amplifying), so there is no mechanism in this hypothesis that would cause a suspension or reversal of overall heat accumulation. Indeed, any suspension or reversal would suggest that the heating caused by GHG can be overwhelmed by other human or natural processes in the climate system.
A reversal of sufficient magnitude could conceivably reset the counter back to “zero” (i.e., the initial point from which a current set of measurements began). If this were to take place, the process of heat accumulation would have to start again. In either case, a suspension or reversal of heat accumulation (excepting major volcanic eruptions) would mean that we are dealing with a form of cyclical rather than monotonic heating.
Most scientists who oppose the conclusions of the IPCC have been outspoken in their advocacy of cyclical heating and cooling caused primarily by natural processes, and modified by long-term human climate forcings such as land use change and aerosols. These natural forcings include ocean cycles (PDO, AMO), solar cycles (sunspots, total irradiance), and more speculative causes such as orbital oscillations, and cosmic rays.
Temperature is not Heat!
Despite a consensus among scientists on the use of ocean heat as a robust metric for AGW, near-surface air temperature (referred to as “surface temperature”) is generally employed to gauge global warming. The media and popular culture have certainly equated the two. But this equation is not simply the product of a naïve misunderstanding. NASA’s Goddard Institute for Space Studies (GISS), directed by James Hansen, and the British Hadley Centre for Climate Change, have consistently promoted the use of surface temperature as a metric for global warming. The highly publicized, monthly global surface temperature has become an icon of the AGW projections made by the IPCC.
However, use of surface air temperature as a metric has weak scientific support, except, perhaps, on a multi-decadal or century time-scale. Surface temperature may not register the accumulation of heat in the climate system from year to year. Heat sinks with high specific heat (like water and ice) can absorb (and radiate) vast amounts of heat. Consequently the oceans and the cryosphere can significantly offset atmospheric temperature by heat transfer creating long time lags in surface temperature response time. Moreover, heat is continually being transported in the atmosphere between the poles and the equator. This reshuffling can create fluctuations in average global temperature caused, in part, by changes in cloud cover and water vapor, both of which can alter the earth’s radiative balance.
Hype generated by scientists and institutions over short-term changes in global temperature (up or down) has diverted us from the real issue: heat accumulation. Heat is not the same as temperature. Two liters of boiling water contain twice as much heat as one liter of boiling water even though the water in both vessels is the same temperature. The larger container has more thermal mass which means it takes longer to heat and cool.
Temperature measures the average kinetic energy of molecular motion at a specific point. But it does not measure the total kinetic energy of all the molecules in a substance. In the example above, there is twice as much heat in 2 liters of boiling water because there is twice as much kinetic energy. On average, the molecules in both vessels are moving at the same speed, but the larger container has twice as many molecules.
Temperature may vary from point to point in a moving fluid such as the atmosphere or ocean, but its heat remains constant so long as energy is not added or removed from the system. Consequently, heat-not temperature-is the only sound metric for monitoring the total energy of the climate system. Since heat is a function of both mass and energy, it is normally measured in Joules per kilogram (or calories per gram):
Q = mc∆T
Where Q is heat (Joules)
m is mass (kg)
c is the specific heat constant of the substance (J/kg/°C)
∆T is the change in temperature (°C)
The Thermal Mass of the Oceans
Water is a more appropriate metric for heat accumulation than air because of its ability to store heat. For this reason, it is also a more robust metric for assessing global warming and cooling. Seawater has a much higher mass than air (1030 kg/m3 vs. 1.20 kg/m3at 20ºC), and a higher specific heat (4.18 kJ/kg/°C vs. 1.01 kJ/kg/°C for air at 23°C and 41% humidity). One kilogram of water can retain 4.18x the heat of an equivalent mass of air. This amounts to a thermal mass which is nearly 3558x that of air per unit volume.
For any given area on the ocean’s surface, the upper 2.6m of water has the same heat capacity as the entire atmosphere above it! Considering the enormous depth and global surface area of the ocean (70.5%), it is apparent that its heat capacity is greater than the atmosphere by many orders of magnitude. Consequently, as Hansen, et. al. have concluded, the ocean must be regarded as the main reservoir of atmospheric heat and the primary driver of climate fluctuations.
Heat accumulating in the climate system can be determined by profiling ocean temperature, and from precise measurements of sea surface height as they relate to thermal expansion and contraction of ocean water. These measurements are now possible on a global scale with the ARGO buoy array and from satellite measurements of ocean surface heights. ARGO consists of a world-wide network of over 3000 free-drifting platforms that measure temperature and salinity in the upper 2000m of ocean. The robotic floats rise to the surface every 10 days and transmit data to a satellite which also determines their location.
Pielke’s Litmus Test
In 2007 Roger Pielke, Sr. suggested that ocean heat should be used not just to monitor the energy imbalance in the climate system, but as a “litmus test” for falsifying the IPCC’s AGW hypothesis (Pielke, “A Litmus Test…”, climatesci.org, April 4, 2007). Dr. Pielke is a Senior Research Scientist in CIRES (Cooperative Institute for Research in Environmental Sciences), at the University of Colorado in Boulder, and Professor Emeritus of the Department of Atmospheric Science, Colorado State University, Fort Collins. One of the world’s foremost atmospheric scientists, he has published nearly 350 papers in peer-reviewed journals, 50 chapters in books, and co-edited 9 books.
Pielke’s test compares the net anthropogenic radiative forcing projected by GISS computer models (Hansen, Willis, Schmidt et al.) with actual ocean heat as measured by the ARGO array. To calculate the annual projected heat accumulation in the climate system or oceans, radiative forcing (Watts/m2) must be converted to Joules (Watt seconds) and multiplied by the total surface area of the oceans or earth:
[#1] Qannum = (Ri Pyear Aearth) .80
or, [#2] Qannum = (Ri Pyear Aocean) .85
Where Qannum is the annual heat accumulation in Joules
Ri is the mean global anthropogenic radiative imbalance in W/m2
P is the period of time in seconds/year (31,557,600)
Aocean is the total surface area of the oceans in m2 (3.61132 x 1014)
Aearth is the total surface area of the earth in m2 (5.10072 x 1014)
.80 & .85 are reductions for isolating upper ocean heat (see below)
Radiative Imbalance. The IPCC and GISS calculate the global mean net anthropogenic radiative forcing at ~1.6 W/m2(-1.0, +.8), (see, 2007 IPCC Fourth Assessment Summary for Policy Makers, figure SPM.2 and Hanson, Willis, Schmidt et al., page 1434, Table 1). This is the effective total of all anthropogenic forcings on the climate system. Projected heat accumulation is not calculated from this number, but from the mean global anthropogenic radiative imbalance (Ri). According to Hanson, Willis, Schmidt et al., the imbalance represents that fraction of the total net anthropogenic forcing which the climate system has not yet responded to due to thermal lag (caused primarily by the oceans). The assumption is that since the earth has warmed, a certain amount of energy is required to maintain the current global temperature. Continuing absorption will cause global temperatures to rise further until a new balance is reached.
Physically, the climate system responds to the entire 1.6 W/m2 forcing, not just a portion of it. But while energy is being absorbed, it is also being lost by radiation. The radiative imbalance is better described as the difference between the global mean net anthropogenic radiative forcing and its associated radiative loss. The global radiative imbalance of .75 W/m2 (shown below) would mean that the earth system is radiating .85 W/m2 in response to 1.6 W/m2of total forcing (1.6 – .85 = .75). For a more detailed discussion of radiative equilibrium see, Pielke Sr., R.A., 2003: “Heat storage within the Earth system.” Bulletin of the American Meteorological Society, 84, 331-335.
Projected Ocean Heat. Since observed heat accumulation is derived from measurements in the upper 700m-750m of the ocean, an “apples to apples” comparison with model projections requires some adjustments. Eq. #1, used by the GISS model, assumes that nearly all of the energy from anthropogenic radiative forcing is eventually absorbed by the oceans (80%-90% according to Willis, U.S. CLIVAR, 1, citing Levitus, et. al.). Based on modeling by Hansen, Willis, Schmidt, et. al., (page 1432) upper ocean heat is thought to comprise 80% of the total as shown in the illustration. So, the calculated heat must be multiplied by 0.8 to subtract deep ocean heat (below 750m) and heat storage by the atmosphere, land, and cryosphere (see discussion on deep ocean heat and melting ice below).
Another method for calculating heat accumulation is shown in Eq. #2. This method assumes that only 71% (i.e., the fraction of the earth covered by oceans) of the energy from anthropogenic radiative forcing is absorbed by the oceans. Hence, the net global anthropogenic radiative flux is scaled to ocean surface area. To compare to upper ocean measurements, deep ocean heat must be subtracted by multiplying the results by ~0.85. As shown in the illustration above, the deep ocean absorbs about 0.11 W/m2 of the total ocean flux of 0.71 W/m2 (estimates vary, see discussion on deep ocean heat, below). Since this equation is not used by climate models, it is not included in the following tables. But, it is displayed in the graph below as a possible lower limit of projected heat accumulation.
In his blog, “Update On A Comparison Of Upper Ocean Heat Content Changes With The GISS Model Predictions” (climatesci.org, Feb. 9, 2009), Pielke projects heat accumulation based on an upper ocean mean net anthropogenic radiative imbalance of 0.6 W/m2as shown below (see Hanson, Willis, Schmidt et al., 1432). This is only a slight variance from his 2007 blog and affords the best opportunity for the GISS models to agree with observed data. A failure to meet this benchmark would be a robust demonstration of systemic problems.
Observed Ocean Heat. A comparison of these projections to observed data is shown below. Despite expectations of warming, temperature measurements of the upper 700m of the ocean from the ARGO array show no increase from 2003 through 2008. Willis calculates a net loss of -0.12 (±0.35) x 1022Joules per year (Pielke, Physics Today,55) from mid-2003 to the end of 2008 (Dr. Pielke received permission from Josh Willis to extend the ARGO data to the end of 2008).
According to a recent analysis of ARGO data by Craig Loehle, senior scientist at the Illinois-based National Council for Air and Stream Improvement, the loss is -0.35 (±0.2) x 1022Joules per year from mid-2003 to the end of 2007 (see Loehle, 2009: “Cooling of the global ocean since 2003.″ Energy & Environment, Vol. 20, No. 1&2, 101-104(4)). Loehle used a more complex method than Willis to calculate this trend, enabling him to reduce the margin of error.
My calculations for observed global heat, shown below, are based on observed upper ocean heat. Since upper ocean heat is calculated to be 80% of the global total (Eq. #1), observed global heat equals approximately 125% (1/0.8) of the observed upper ocean heat.
|
PROJECTED vs. OBSERVED HEAT ACCUMULATION, 2003-2008 (6 YEARS) |
||||
|
Model |
Projected Global Heat Accumulation (Joules x 1022) |
Observed Global Heat Accumulation (Joules x 1022) |
Projected Upper Ocean Heat Accumulation (Joules x 1022) |
Observed Upper Ocean Heat Accumulation (Joules x 1022) |
|
GISS |
7.26 |
-0.83 Willis (5.5 yr) -1.98 Loehle (4.5 yr) |
5.82 |
-0.66 Willis (5.5 yr)-1.58 Loehle (4.5 yr) |
Heat Deficit. The graph below shows the increasing deficit of upper ocean heat from 2003 through 2008 based on GISS projections by Hansen, Willis, Schmidt, et. al. Actual heat accumulation is plotted from observed data (using ARGO) and shows the overall linear trend (after Willis and Loehle). Seasonal fluctuations and error bars are not shown.
The projection displays a range representing the two ways of calculating heat accumulation discussed above. The upper limit assumes that virtually all of the energy from anthropogenic radiative forcing is eventually absorbed by the oceans (Eq. #1). The lower limit scales the total radiative imbalance to the surface area of the oceans (Eq. #2). The upper limit represents the actual GISS model projection.
The 5.5 year accumulated heat deficit for GISS model projections (red line) ranges from 6.48 x 1022 Joules (using Willis) to 7.92 x 1022 Joules (Loehle, extrapolated to the end of 2008). Pielke is more conservative in his calculations, given the substantial margin of error in Willis’ data (±0.35). Accordingly, he assumes zero heat accumulation for the full 6 year period (2003-2008), yielding a deficit of 5.88 x 1022Joules (Pielke, “Update…”). Loehle’s work, which was not yet known to Pielke in February of 2009, has a much smaller margin of error (±0.2).
|
OCEAN HEAT DEFICIT FOR GISS MODEL PREDICTIONS, MID 2003-2008 (5.5 YEARS) |
||
|
ARGO Data Analyzed by Willis |
ARGO Data Analyzed by Loehle (extrapolated to end of 2008) |
Pielke (based on Willis) |
|
-6.48 x 1022 Joules |
-7.92 x 1022 Joules |
-5.39 x 1022 Joules (-5.88 for 6 full years ) |
These figures reveal a robust failure on the part of the GISS model to project warming. The heat deficit shows that from 2003-2008 there was no positive radiative imbalance caused by anthropogenic forcing, despite increasing levels of CO2. Indeed, the radiative imbalance was negative, meaning the earth was losing slightly more energy than it absorbed. Solving for Riin Eq. #1, the average annual upper ocean radiative imbalance ranged from a statistically insignificant -.07 W/m2 (using Willis) to -.22 W/m2(using Loehle).
As Pielke points out (”Update…”), in order for the GISS model to verify by the end of 2012 (i.e., one decade of measurements), the annual radiative imbalance would have to increase to 1.50 W/m2 for the upper ocean which is 2.5x higher than the .6 W/m2projected by Hansen, Willis, Schmidt, et. al. (1432). This corresponds to an annual average accumulation of 2.45 x 1022 Joules in the upper ocean, or a 4 year total of 9.8 x 1022 Joules.
Using Loehle’s deficit, the numbers are even more remarkable. Assuming that heating resumes for the next 4.5 years (2009 to mid 2013), the annual average accumulation of heat would need to be 2.73 x 1022 Joules in the upper ocean, for a 4.5 year total of 12.29 x 1022 Joules. The derived radiative imbalance for the upper ocean would increase to 1.7 W/m2, or nearly 3x higher than the projected imbalance.
Improbable Explanations for the Failure of Heat Accumulation
Hidden Heat. A few explanations have been proposed for the change in ocean heat. One popular suggestion is that there is “hidden” or “unrealized” heat in the climate system. This heat is being “masked” by the current cooling and will “return with a vengeance” once the cooling abates.
This explanation reveals a fundamental ignorance of thermodynamics and it is disappointing to see scientists suggest it. Since the oceans are the primary reservoir of atmospheric heat, there is no need to account for lag time involved with heat transfer. By using ocean heat as a metric, we can quantify nearly all of the energy that drives the climate system at any given moment. So, if there is still heat “in the pipeline”, where is it? The deficit of heat after nearly 6 years of cooling is now enormous. Heat can be transferred, but it cannot hide. Without a credible explanation of heat transfer, the idea of unrealized heat is nothing more than an evasion.
Deep Ocean Heat. Is it possible that “lost” heat has been transferred to the deep ocean-below the 700 meter limit of our measurements? This appears unlikely. According to Hansen, Willis, Schmidt et al., model simulations of ocean heat flow show that 85% of heat storage occurs above 750 m on average (with the range stretching from 78 to 91%) (1432). Moreover, if there is “buried” heat, widespread diffusion and mixing with bottom waters may render it statistically irrelevant in terms of its impact on climate.
The absence of heat accumulation in deep water is corroborated by a recent study of ocean mass and altimetric sea level by Cazenave, et. al. Deep water heat should produce thermal expansion, causing sea level to rise. Instead, steric sea level (which measures thermal expansion plus salinity effects) peaked near the end of 2005, then began to decline nearly steadily. It appears that ocean volume has actually contracted slightly.
Melting Ice. Another possibility is that meltwater from glaciers, sea ice, and ice caps is offsetting heat accumulation. Perhaps the ocean temperature has plateaued as the ice undergoes a phase change from solid to liquid (heat of fusion).
This explanation sounds plausible at first, but it is not supported by observed data or best estimates. In a 2001 paper published in Science, Levitus, et. al. calculates that the absorption of heat due to melting ice amounts to only 6.85% of the total increase in ocean heat during the 41 year period from about 1955 to 1996:
Observed increase in ocean heat (1955-1996) = 1.82 x 1023 J
Observed/estimated heat of fusion (1950’s-1990’s) = 1.247 x 1022 J
This work is quoted by Hansen, Willis, Schmidt, et. al. and further supported by their calculations (1432), which are even more conservative. Given a planetary energy imbalance of approximately +0.75 W/m2, their simulations show that only 5.3% (0.04 W/m2) of the energy is used to warm the atmosphere, the land, and melt ice. The balance of energy is absorbed by the ocean above 750 m (~0.6 W/m2), with a small amount of energy penetrating below 750 m (~0.11 W/m2).
The absorption of heat by melting ice is so small that even if it were to quadruple, the impact on ocean heat would be miniscule.
Cold Biasing. The ARGO array does not provide total geographic coverage. Ocean areas beneath ice are not measured. However, this would have a relatively small impact on total ocean heat since it comprises less than 7% of the ocean. As mentioned above, quality controlled water temperature below 700m is not available, though the floats operate to a depth of 2000m. Above 700m, the analysis performed by Willis includes a quality check of raw data which revealed a cold bias in some instruments. This bias was removed (Willis, CLIVAR, 1).
Loehle warns that the complexities of instrumental drift could conceivably create such artifacts (Loehle, 101), but concludes that his analysis is consistent with satellite and surface data which show no warming for the same period (e.g., see Douglass, D.H., J.R. Christy, 2009: “Limits on CO2 climate forcing from recent temperature data of Earth.” Energy & Environment, Vol. 20, No. 1&2, 178-189 (13)). So it is unlikely that cold biasing could account for the observed changes in ocean heat.
In brief, we know of no mechanism by which vast amounts of “missing” heat can be hidden, transferred, or absorbed within the earth’s system. The only reasonable conclusion-call it a null hypothesis-is that heat is no longer accumulating in the climate system and there is no longer a radiative imbalance caused by anthropogenic forcing. This not only demonstrates that the IPCC models are failing to accurately predict global warming, but also presents a serious challenge to the integrity of the AGW hypothesis.
Analysis and Conclusion
Though other criteria, such as climate sensitivity (Spencer, Lindzen), can be used to test the AGW hypothesis, ocean heat has one main advantage: Simplicity. While work on climate sensitivity certainly needs to continue, it requires more complex observations and hypotheses making verification more difficult. Ocean heat touches on the very core of the AGW hypothesis: When all is said and done, if the climate system is not accumulating heat, the hypothesis is invalid.
Writing in 2005, Hansen, Willis, Schmidt et al. suggested that GISS model projections had been verified by a solid decade of increasing ocean heat (1993 to 2003). This was regarded as further confirmation the IPCC’s AGW hypothesis. Their expectation was that the earth’s climate system would continue accumulating heat more or less monotonically. Now that heat accumulation has stopped (and perhaps even reversed), the tables have turned. The same criteria used to support their hypothesis, is now being used to falsify it.
It is evident that the AGW hypothesis, as it now stands, is either false or fundamentally inadequate. One may argue that projections for global warming are measured in decades rather than months or years, so not enough time has elapsed to falsify this hypothesis. This would be true if it were not for the enormous deficit of heat we have observed. In other words, no matter how much time has elapsed, if a projection misses its target by such a large magnitude (6x to 8x), we can safely assume that it is either false or seriously flawed.
Assuming the hypothesis is not false, its proponents must now address the failure to skillfully project heat accumulation. Theories pass through stages of development as they are tested against observations. It is possible that the AGW hypothesis is not false, but merely oversimplified. Nevertheless, any refinements must include causal mechanisms which are testable and falsifiable. Arm waiving and ad hoc explanations (such as large margins of error) are not sufficient.
One possibility for the breakdown may relate back to climate sensitivity. It is assumed that most feedbacks are positive, amplifying the slight warming (.3º-1.2ºC) caused by CO2. This may only be partially correct. Perhaps these feedbacks undergo quasi-cyclical changes in tandem with natural fluctuations in climate. The net result might be a more punctuated increase in heat accumulation with possible reversals, rather than a monotonic increase. The outcome would be a much slower rate of warming than currently projected. This would make it difficult to isolate and quantify anthropogenic forcing against the background noise of natural climate signals.
On the other hand, the current lapse in heat accumulation demonstrates a complete failure of the AGW hypothesis to account for natural climate variability, especially as it relates to ocean cycles (PDO, AMO, etc.). If anthropogenic forcing from GHG can be overwhelmed by natural fluctuations (which themselves are not fully understood), or even by other types of anthropogenic forcing, then it is not unreasonable to conclude that the IPCC models have little or no skill in projecting global and regional climate change on a multi-decadal scale. Dire warnings about “runaway warming” and climate “tipping points” cannot be taken seriously. A complete rejection of the hypothesis, in its current form, would certainly be warranted if the ocean continues to cool (or fails to warm) for the next few years.
Whether the anthropogenic global warning hypothesis is invalid or merely incomplete, the time has come for serious debate and reanalysis. Since Dr. Pielke first published his challenge in 2007, no critical attempts have been made to explain these failed projections. His blogs have been greeted by the chirping of crickets. In the mean time costly political agendas focused on carbon mitigation continue to move forward, oblivious to recent empirical evidence. Open and honest debate has been marginalized by appeals to consensus. But as history has often shown, consensus is the last refuge of poor science.
References
Cazenave, A., et al., 2008: “Sea level budget over 2003-2008: A reevaluation from GRACE space gravimetry, satellite altimetry and Argo,” Glob. Planet. Change, doi:10.1016/j.gloplacha.2008.10.004.
Douglass, D.H., J.R. Christy, 2009: “Limits on CO2 climate forcing from recent temperature data of Earth.” Energy & Environment, Vol. 20, No. 1&2, 178-189 (13).
Hansen, J., L. Nazarenko, R. Ruedy, Mki. Sato, J. Willis, A. Del Genio, D. Koch, A. Lacis, K. Lo, S. Menon, T. Novakov, Ju. Perlwitz, G. Russell, G.A. Schmidt, and N. Tausnev, 2005: “Earth’s energy imbalance: Confirmation and implications.” Science, 308, 1431-1435.
IPCC, 2007: Summary for Policymakers. In: Climate Change 2007: The Physical Science Basis. Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change[Solomon, S., D. Qin, M. Manning, Z. Chen, M. Marquis, K.B. Averyt, M.Tignor and H.L. Miller (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA. See www.ipcc.ch/pdf/assessment-report/ar4/wg1/ar4-wg1-spm.pdf
Levitus, S., J.I. Antonov, J. Wang, T.L. Delworth, K.W. Dixon, and A.J. Broccoli, 2001: “Anthropogenic warming of Earth’s climate system.” Science, 292, 267-268.
Loehle, Craig, 2009: “Cooling of the global ocean since 2003.″ Energy & Environment, Vol. 20, No. 1&2, 101-104(4).
Pielke Sr., R.A., 2008: “A broader view of the role of humans in the climate system.” Physics Today, 61, Vol. 11, 54-55.
Pielke Sr., R.A., 2003: “Heat storage within the Earth system.” Bulletin of the American Meteorological Society, 84, 331-335.
Pielke Sr., R.A., “A Litmus Test For Global Warming – A Much Overdue Requirement“, climatesci.org, April 4, 2007.
Pielke Sr., R.A., “Update On A Comparison Of Upper Ocean Heat Content Changes With The GISS Model Predictions“, climatesci.org, Feb. 9, 2009.
Willis, J.K., D. Roemmich, and B. Cornuelle, 2004: “Interannual variability in upper ocean heat content, temperature, and thermosteric expansion on global scales.” J. Geophys. Res., 109, C12036.
Willis, J. K., 2008: “Is it Me, or Did the Oceans Cool?”, U.S. CLIVAR, Sept, 2008, Vol. 6, No. 2.
* William DiPuccio was a weather forecaster for the U.S. Navy, and a Meteorological/Radiosonde Technician for the National Weather Service. More recently, he served as head of the science department for St. Nicholas Orthodox School in Akron, Ohio (closed in 2006). He continues to write science curriculum, publish articles, and conduct science camps.
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“”” eric (12:26:35) :
George,
One more point about this which may clarify things for you.
It is easy to see that the downwelling radiation will cause in increase in temperature of the surface skin.
Your claim, correctly, that the evaporation rate and convection away from the surface will go up when additional downwelling radiation hits the surface. In order for that to happen the temperature of the surface must increase. “””
Well Eric somehow I think everything is perfectly clear to me; so I actually am not in need of having anything clarified (re this subject).
If you have been reading Anthony’s site for very long you may have noticed that I have described this ocean thermal process maybe a dozen times here.
And at no time have I ever indicated that some elctromagnetic radiation being absorbed in the ocean will lead to an increase in temperature but radiation of another wavelength will not lead to an increase in surface temperature. I have many times pointed out that the surface absorption of long wave infra red (EM) radiation causes prompt evaporation from that surface, and it is self evident that that evaporation happens because the energy input (from LWIR) increases the mean Kinetic energy of the surface molecules (which after all is exactly what temperature is), and as a result of the Maxwell Boltzmann distribution of kinetic energies, the number of water molecules having sufficient vibrational velocity to overcome the surface binding forces and escape into the atmosphere increases, so more water escapes.
Do I have to specifically mention that the temperature muct increase any time more energy is absorbed from any source, Or should I presume that the reader can figure that out for himself.
After all, Anthony has only so much space here for posts; and I can’t be writing a Doctor of Science dissertation, to make every simple point obvious to every reader.
I presume that most of the people who come here have enough common sense to understand what are quite simple concepts.
But I’m glad that you understand it anyway; most of the time, I get the idea that exactly nobody ever reads anything I put here; well I put it here in the hope that even one single individual might gain something from it; or have his/er own independent thoughts stimulated as a result.
Besides that, I come here to learn from the other posters.
Lucy Skywalker: Thanks for quoting me in your 10:44:21 comment above, but please note that my complaints about the differences in the OHC data and the usefulness of the data pertained to the long-term comparison included in the most recent Levitus et al paper. I was not referring to the methodologies used by Craig Loehle or Josh Willis in the short-term comparison used by Bill DiPuccio.
And let me clarify my complaint about usefulness.
Given: El Nino events redistribute heat from the tropical Pacific to the high latitudes so that it can be radiated into space more readily. Let’s say I wanted to analyze the 1997/98 El Nino to the determine how much of that heat was released to the atmosphere and how much was simply redistributed to the extratropical North and South Pacific and to other ocean subsets. Refer to the following graph. It’s the comparative graph of Levitus et al, Ishii and Kimoto, and Domingues et al OHC datasets, the graph that’s been cited a few times in this thread. I’ve highlighted 1997 and 1998. In 1997, the OHC in all three datasets increased, and in 1998, they all decreased. BUT look at the differences in the magnitudes of the changes in 1998. Which dataset depicts the changes correctly? Right now, I don’t have enough confidence in any of the OHC reconstructions to do the study I’ve suggested.
http://i40.tinypic.com/25rfurs.jpg
Stephen Wilde (14:21:20) :
No problem. I have no trouble with the idea that a body of warm air over a body of cooler water will transfer heat to the water in a stable condition. However add the mechanical convection of say a slight breeze over the cooler moist surface and you could quite possibly end up with a cooler body of water than you started do to increased evaporation from both thermodynamic and mass transfer effects.
A simple example is go to Arizona in Aug, spray water on you body and stand outside….then turn on a fan while standing outside (try the shade first). Your skin will cool (evaporative effects with and with out mechanical transport). Standing in the sun changes the effect dramatically with no resultant change in air temp (addition of solar radiative component).
Manuel (00:44:54) : I am still missing a thorough explanation on how does global mean temperature relates to total heat contents
Poorly, very very poorly…
Aside from all the measuring errors, and all the fabrication steps in the creation of the fictional numbers that are called temperatures, there is the simple physical fact that the specific heat of all the things being heated and the phase change for things like water (and rocks) make temperature without a known mass of substance, it’s known specific heat, and it’s known degree of phase change along with it’s known heats of vaporization and solidification useless as a gauge of heat. Then you get to toss in things like chemical reactions adding / removing heat… How much heat goes into making CaCo2 in the ocean? Or comes out? … And don’t even get me started on U and Th core / crustal heating…
Basically, we can come close to some idea what the heat balance is for the ocean since it’s roughly the same physical stuff for most of the bulk. We can’t have a clue for the planet as a whole. One big lava flow can spoil your whole Deccan Trap energy balance…
http://en.wikipedia.org/wiki/Deccan_Traps
Even the ocean has its issues… Exactly how much heat is added from all the mid oceanic ridges and exactly how does it change over time?… Heck, we just recently found out there was a ridge and volcanoes going off under the Arctic ice cap.
Then there is the small matter of defining how deeply you want your “total heat” to extend. “On Average” the heat content of the planet is such that it’s a molten ball of iron and rock. Not very useful for weather predictions…
If we’re interested in the surface, define “surface”. 1 mm? 1 km up in the air? 2 m below the surface? They all have very different temperatures and even more different heats.
But the good news is that you could spend your whole life taking in research grants to study parts of this and never have to worry about reaching an answer that would cut off the funding!
This is excellent research.
I could send this to any mechanical engineer and it would immediately be understood as irrefutable proof that the hypothesized radiative forcing is not there. If you add 1 W/m^2 the heat has to go somewhere. This is brilliant accounting and I am thrilled that we finally have the data.
Is there any discussion of how the heat moved during the observation period? I assume that the ocean circulation oscillations would be very apparent and could provide great insight into regional weather patterns.
Kudos
Eric: You wrote, “Also it has been mentioned by Bob Tisdale that the data on ocean heat content may have problems.”
And now for the third time on this thread, my comment about the differences in the OHC data pertained to the long-term comparison included in the most recent Levitus et al paper. I was not referring to the methodologies used by Craig Loehle or Josh Willis in the short-term comparison used by Bill DiPuccio.
Regards
E.M.Smith (14:45:36) :
If we’re interested in the surface, define “surface”. 1 mm? 1 km up in the air? 2 m below the surface? They all have very different temperatures and even more different heats.
———————————
I wonder if there has been any attempt to understand the grand magnitude of temperature variations caused by density changes with depth, or Cp with density and temperature?
The one thing you could say about the oceans which has an almost certain chance of being correct, is that the conditions are chaotic. All sorts of processes are going on as waves break on ocean beaches, or hurricanes build up in the Atlantic. I once spent a month on a boat/ship most of it on the Pacific Ocean. None of those things happened on that voyage; well we did get hit by a tidal wave as a result of an underwsea earthquake; everybody lined the ships rails and the blew the horn to announce that the wave had hit us; otherwise we would never have known. Maybe it was a foot high and 20 miles wavelength and went by at 400 miles per hour; some silly numbers like that; but it did a whole lot of damage when it hit Hawaii.
And I’ve spent wuite a lot of other times sitting out in deep ocean waters; and most of the time nothing in any way turbulent is going on; but I know it is happening somewhere, and when it does, there will be some mixing of colder deeper waters with warmere shallower waters.
But through thick and thin, 24 hours a day, and seven days a week, the continuous process of water warmed by the sun or atmosphere keeps inexorably driving towards the surface.
A model of the thermal processes in the ocean will be more true to the observed reality on a global scale, if you ignore the surface water churned up by the propellors of an oil tanker, or aircraft carrier, but include the vertical convection current that never stops raising warmed deep waters towards the surface, which is even warmer.
The trouble is that the usual practice is to ignore the never stopping process of convection and go into raptures over anecdotal episodes of turbulence and turnovers, or high surface winds; or something else which happens but locally and sporadically.
It is not helpful to start from quantum chromodynamics, and try working backwards to something simpler, that may be a whole lot more instructive.
I find it better to start with the simplest possible edifice first, and only add bells and whistles, as they become necessary to explain the inevitable exceptiuons which crop up.
George E. Smith (15:11:26) :
I suppose it depends whose “usual practice” you are referring to. Could you clarify?
Stephen Wilde (12:42:46) :
“Gerald Machnee (10:47:44) :
I have dealt with that issue extensively here and in other articles on the same site:
http://climaterealists.com/index.php?id=1645
Thanks Stephen.
It seems that there is a group that refuses to accept well researched thermodynamics about the ocean.
Lest anybody think that the rules for salt water are simple,
since nobody else has mentioned it, consider the phenomena
of solar ponds.
http://en.wikipedia.org/wiki/Solar_pond
Hot and salty on the bottom, cool and brackish on the top.
Somehow the vertical convective current _does_ halt. Halocline
thermocline collision: Halocline wins in this case.
The sun is certainly responsible for sub-surface energy storage
in this case.
George, just so you know, I have read every single post you have written. FWIW, between my father, you and Lief, I can say without doubt that I have learned more from the 3 of you than all my years in school. Thank you and keep ’em coming !! Eyes open and sails unfurled !!
“”” oms (15:26:10) :
George E. Smith (15:11:26) :
The trouble is that the usual practice is to ignore the never stopping process of convection and go into raptures over anecdotal episodes of turbulence and turnovers, or high surface winds; or something else which happens but locally and sporadically.
I suppose it depends whose “usual practice” you are referring to. Could you clarify? “””
The easiest way for me to clarify would be to ask you; for just one peer reviewed paper detailing the upward convection process I mentioned just anecdotally; that would illustrate the point.
“”” An intermediate insulating layer with a salt gradient, which establishes a density gradient that prevents heat exchange by natural convection. “””
From Frank’s Wiki citation above.
A perfect example of Wiki gobbledegook. “prevents heat exchange by natural convection. ”
NO! you WIKI idiots; your own description of the process shows clearly that the process of heat exchange by natural convection IS WORKING !!
But as you also mention the heat exchange natural convection is now DOWNWARD; and it is downward BECAUSE the salinity gradient establishes a density gradient that happens to be opposite to that which solar heating establishes in the depp open ocean.
As Frank mentions, the salinity increases towards the bottom; and at such a clip, that the density increases towards the bottom; despite the fact that the bottom is a lot hotter than the top.
But the convection current still follows the density gradient; except this time it is in the opposite direction, and is STILL in the direction of NATURAL CONVECTION.
In fact Frank’s reference makes my case for me; natural convection is a powerful thermal energy transport process; whether it is going down in a shallow salt pond or going up in a deep ocean.
George
Roger Carr (00:07:31) : Karl Popper: Falsifiability. In order to verify a hypothesis there must be a test by which it can be proved false. A thousand observations may appear to verify a hypothesis, but one critical failure could result in its demise.
While plenty of others have given the answer that “There ought to be a test that COULD show it wrong, but the test could itself fail, lending support to the thesis” I’m going in a different tack…
While Popper has his points, and they support the notion that AGW is bunk, he still bothers me.
By Popper’s definition, If I’m fooling about in the lab and find out that U causes photo film to fog, and I start thinking that maybe this means something, and maybe even that it has to do with some “light like” particle (or wave or wavicle…) that I just can’t see… so I decided that doing a bit of discovery on this U stuff and it’s properties might benefit the world. I’m not doing science.
Now I don’t know what to call that, but to me it sure smells like science…
Basically, I think Popper is good when it comes to testing a THESIS and defining what can support it or not and testing if the THESIS is well constructed; but I think that SCIENCE needs a bigger tent than that.
To me, a geologist doing field work looking for new kinds of rock or interesting structures IS doing science. He has no thesis yet, he’s looking for something to stimulate a thesis. But it’s still science. Science begins before the Thesis creation step.
To me, a botanist crossing a couple of interesting nearby species IS doing science. He’s finding out if he can cross a lion and a tiger and THEN he’ll find out what this means in terms of genetics, wild animal populations, the definition of species, etc. Experimentation prior to thesis has merit and is a part of Science, IMHO. (Yes, you can make the strained thesis that “I’ve heard a cross is possible so my thesis is ‘it can be’ and I’m finding out if that thesis is true or false.” but the reality is often quite different. They guy who discovered post-it note semi-glue had an accident, but then he INVESTIGATED and that investigation was, IMHO, science even if his only “thesis” was “maybe I’ll find out how to do this again and what it’s good for”. Science includes serendipity and it’s investigation in an organized way.
And when a mathematician finds the solution to a particularly tough bit of math, I would call that, too “science”. There are folks who argue that math is ‘discovered’ or ‘invented’ and thus not science. That seems, to me, way too limiting. Is the solution to Penrose tiling in 2 and 3D not worthy of being called science just because it’s Math? Is the thesis “Look, I can do this!” insufficient in some way? DIscovery of the roots of all nature are science.
Finally, when an economist says that the velocity of money is important, since the quantity alone does not determine the aggregate price ( QuantityM x VelocityM = aggregate price ) how is this falsified? Is it a thesis or a definition? Is it “non-scientific” yet somehow insightful, yet not an art either… some kind of chimera of sci-art or math-o-vision?
The problems that strict adherence to Popper brings are in many ways more than the issues he solves. And we won’t even get started on what his interpretation of science means for the archeologist trying to scientifically discover our history in controlled digs and artifact interpretation. Nor what Popper implies for things like weather science where there may well be “plug functions” that work well, but are not well formed as a thesis and not falsifiable. (How does a hurricane decide which way to go, and how do you falsify that statement? Yet we have cones of probability that work…)
When The Beagle went to Galapagos, when did the “science” part begin? Can there never be a “scientific expedition” until AFTER the data are analyzed? Or is it after the answers are pretty well known so you can start to form a decent thesis of what’s going on and THEN maybe test it? Does “science” only begin in the very last step before being done? If so, what was all that other part called? Fooling around? “Dear Ford Foundation: I’d like a grant to fool around for 5 years. When I’ve got a pretty good thesis to test, then I’ll be wrapping up a few months later and writing a ‘Science Paper’. Please send check soon.” Hmmm?
So I’ll just leave you with this: Is light a particle, or a wave? How do you falsify “both and neither”? Is the world deterministic, or not? How do you falsify “maybe, it depends on what answer you got”? (There are interesting physics experiments that show that a particle “decided” in the past where to go based on what door you opened in the future…) Is the process of research into these questions not “Science”? If so, please go tell all the physics departments to start issuing B.A. degrees… (And this, BTW, is why PhDs are issued… it’s all, at it’s root “Philosophy”… not “science” in a way…)
So while the Popperian straight jacket is useful at times for tightening up a thesis, I find it way too limiting for deciding what is, and is not, a scientific endeavour. To insist that anything non-Poperian is non-science would toss out a great deal of the history of science. I find that too much to swallow.
That it would toss out a great deal of the future of investigation and discovery makes it too much to even want around the house much 😉
George E. Smith (15:11:26) :
I suppose I am not understanding your point very well. Virtually any oceanography paper which observes the mixed layer describes semidiurnal “pumping” of the thermocline depth, along with deepening of the mixed layer during strong wind mixing and restratification under calm conditions and solar heating; these are all well-observed on both event-by-event bases and seasonal cycles.
-oms
George E. Smith (13:59:28) :
“”” Nasif Nahle (12:50:34) :
George E. Smith (11:55:50) :
“”” Nasif Nahle (10:45:00) :
David L. Hagen (09:50:04):
Popular article at NASA’s Earth Observatory reviewing the issues:
Correcting Global Cooling Nov. 2008
Unfortunately; it is a popular misconception that the surface (ocean or land) heats during the day, and cools during the night; as in “solar photons overwhelming spontaneous emissions”.
Exactly… That’s why I’m saying that the photon stream created during nighttime by the heat stored by the ground, ground subsurface materials and oceans overwhelms the spontaneous emission of photons from the atmosphere (from u-state to l-state). Thus, the surface (lands and oceans cools during nighttime).
During daytime, the ground, the ground subsurface materials (including water) and the oceans also generate an upwelling photon stream; however, the spontaneous emission from the surface is driven downwards by the solar photon stream (from u-state to l-state). As the air gets contact with the surface, it heats up, becomes lesser dense and lifts up. Air also spontaneously emits photons at frequencies different from the frequencies of solar irradiance, so those photons are freely directed towards the outer space (iris effect). Thus, the surface is being cooled also during daytime. Surface stores heat during daytime, however. “””
Photons are not charged particles and they do not interract with each other; therefore it is not possible for “spontaneous emission” from the surface to be “driven downwards by the solar photon stream.” Also since water is quite opaque to long wave infrared radiation, any such radiation emitted downwards, would immediately be absorbed in the top few microns of the surface. That is why we know that the thermal radiation from the ocean is a result of the surface temperature only and is not affected by anything going on in the cold depths.
In the first place, tell that photons don’t interact with each other to Albert Einstein. Besides, I didn’t say photons are charged particles. The interaction of solar photon stream and surface photon stream has been verified analytically, so your assertion is a simple negative. You must consider the next formula from experimentation:
Iav = h 1/4π [(Aul / Bul) / (gl *Blu / gu * Bul) e^hν/kT – 1,
That is the best evidence that the interaction exists. The incoming radiative intensity from the Sun during daytime and the outgoing radiative intensity from the surface induce the molecules (not the photons. It is a misconception that you introduced in your post) to emit photons in the same direction of the photon stream:
(dnu / dt)u->l = [-nu (Aul + Bul ∫4π Iv dΩ)]
This induced emission of photons overwhelms the spontaneous emission of the air and the surface during daytime. Photons with frequencies which don’t match with frequencies of the incoming radiation escape to the outer space (iris effect… again).
In the second place, you’re dismissing conduction and convection as you say that the radiation emitted downwards is absorbed in the top few microns of the surface. What happens with the energy that has been absorbed by any material? It seems you think it is “reradiated” immediately without being transferred by other modes of heat transfer.
In the third place, you’re confounding energy with temperature and practically you’re saying the radiated energy (you call it “thermal radiation”) is a product of temperature, when the basic concept is that temperature is a product of energy absorbed. It’s a tiny line, but we must to know how to differentiate each concept.
The solar insolation, and the surface IR emission are quite independent of each other; which is exactly why a hot surface which is being heated by the sun, can simultaneously emit long wave infrared radiation at a high rate.
Again, how would you explain spontaneous emission, induced negative absorption and induced absorption? Those are real things observed in nature, how would you explain them in there is not interaction between them?
One or two more bits on halocline/thermocline.
I have a friend with an old, spectacular house in San Raphael California.
Installed there is a salt water swimming pool with a dark bottom. It
heats from the bottom up. The effect is very easy to notice. (This
sort of pool was used in the movie Chinatown.)
Could it be there is a thermocline/halocline effect with glaciation?
Giant ice and snow melt raises the ocean level quickly (in geological
terms) and sharply alters the near-surface halocline. Salt pond
effect raises ocean temps until all is well mixed. Then heat escapes
into space, and the snows begin. I am at the edge of my
understanding here.
Like math theories, the proof is used to show that the equation is true. In it’s simplest form, it examines the calculations and proves them true (or not) by solving each step in another way. If the test proves true, therefore the proof stands as a verification of the calculation. In a way, a proof is a falsifiable test. If an equation has no ability to be examined by a proof, the calculation has no proof that it is true. You do the math on the rest of the statement.
The computer models for AGW are mathematical and therefore offer many avenues for the application of proofs, or falsifiable tests. The above post is simply the application of a segment of the model that says if x is this, y will be that. Therefore we have the opportunity to apply a test. The test shows that y is not what it should be. Therefore that part of the model cannot be said to be anywhere near a theory. In fact, it is now not even a hypothesis.
The modelers must now go back to the drawing board regarding ocean heat or be labeled snake oil salesmen.
WARNING: Troll Food Enclosed! 😉
sean (02:55:11) : The last decade of the 20th century averaged 0.268°C above the 61-90 baseline. So far this century is averaging at 0.428°C above the baseline. It a very safe bet that the first decade of the 21st century will end up the warmest since records began.
Unfortunately, the temperatures used to come up with the idea that it’s warming are themselves broken in many many ways. See:
http://www.surfacestations.org/
http://chiefio.wordpress.com/gistemp/
So your “rubber ruler” is a bit useless for deciding what’s actually happened and completely pointless for talking about what will happen.
When average temperatures go up, that’s called warming.
And what is an average temperature? Especially one calculated to one onehundredth of a degree based on 1F increments? It’s a folly. A mathematical farce.
http://chiefio.wordpress.com/2009/03/05/mr-mcguire-would-not-approve/
That increase is due to human activity. […[
The isotopic signature of CO2 in the atmosphere also confirms this.
Um, nope:
http://chiefio.wordpress.com/2009/02/25/the-trouble-with-c12-c13-ratios/
It might be possible that there is some completely unknown and as yet to be discovered mechanism that is responsible for the warming trend.
Actually, it’s well known and very simple. The measuring point starts at the bottom of the Little Ice Age:
http://chiefio.wordpress.com/2009/03/02/picking-cherries-in-sweden/
Maybe you can come back after you’ve got a little more substance to work with… For now, I’m tossing the minnow back in the brook…
This is a troubling development. I like to keep things simple. Yet another indicator of cooling. The only questions, as I have stated before, are, for how long will cooling continue, and how low will it go?
Noelene: ‘“If we are ever silly enough to build the CCB White Elephants, they will be as useful to us as the pyramids were to the Pharaohs – we will be creating our own burial
tombs. “If Carbon Capture and Burial is the answer, it must have been a very silly question.” Is this true?’
From my analysis, yes, it is absolutely true. A friend who is (sadly) convinced of the evil of mankind asked me “Name one good thing humanity has ever done for the other animals on this planet.” EVentually and surprisingly, the answer I came up with was “Man has burned huge amounts of fossil fuel.”
Don’t get me wrong, I am not in favour of wasting non-renewable resources, but that is a human-centred reason: future generations might absolutely need it for a reason far more important than merely burning it. But as far as life on Earth goes, yes, recycling that carbon is entirely a good thing. Strange but true!
Pamela Gray (17:21:14) :
Like math theories, the proof is used to show that the equation is true. In it’s simplest form, it examines the calculations and proves them true (or not) by solving each step in another way. If the test proves true, therefore the proof stands as a verification of the calculation. In a way, a proof is a falsifiable test. If an equation has no ability to be examined by a proof, the calculation has no proof that it is true. You do the math on the rest of the statement.
The computer models for AGW are mathematical and therefore offer many avenues for the application of proofs, or falsifiable tests. The above post is simply the application of a segment of the model that says if x is this, y will be that. Therefore we have the opportunity to apply a test. The test shows that y is not what it should be. Therefore that part of the model cannot be said to be anywhere near a theory. In fact, it is now not even a hypothesis.
The modelers must now go back to the drawing board regarding ocean heat or be labeled snake oil salesmen.
@Pamela… I absolutely agree… AGW is just an idea.
Jeff Alberts (13:46:47) :
”
all about storing heat (which is NOT a noun) in the ocean.
Sure looks like a noun to me.”
Hi Jeff, no, heat is not a noun. You can’t store nouns in the ocean. (And yes, I am actually criticising the opinion of the previous poster. “Heat”, for sure, is a noun, but any statement about the word “heat” cannot have any reference to whether or not a given physical effect is happening, because word definitions do not determine the nature of reality. I.e., the previous poster was confused as can be.)