A post today from the German site Die Kalte Sonne explains why Trenberth's "missing heat" from CO2 is still AWOL, not in the deep oceans as many alarmists have claimed, for the simple reason that the deep oceans have cooled over the past 20 years. The slight warming of the upper oceans of 0.09C over the past 55 years [Levitus 2012] is also not enough to account for the huge amount of "missing heat" that alarmists claim has been generated by man-made CO2. In reality, there never was any "missing heat," it was all radiated to space by greenhouse gases.
I would add to the Die Kalte Sonne post below that the Gouretski et al 2012 paper states
"Levitus et al. [2009] estimate global temperature anomalies using extensive interpolation of the gridded anomaly fields. A modified version of the time series from Levitus et al. [2009], of mean temperature anomaly 0–400 m, averaged only over gridboxes with data, is shown in Figure 2b. Their time series suggests a more gradual warming since the 1950s than in our analysis. Differences between the two 0– 400m time series may be due to the XBT corrections applied, mapping techniques employed, and/or differences in data and quality control decisions for the data. For instance, modifying the mapping method described here to make it more similar to the method used by Levitus et al. [2009] by not applying the depth extension to shallow profiles results in a change in calculated mean temperature anomaly 0–400 m of < 0.05 C for years prior to 1955, < 0.02 C 1955–1970, and < 0.01 C after 1970. Regarding bias corrections, Lyman et al. [2010] found that differences due to XBT bias corrections were the major factor in differences between ocean heat content estimates. A more detailed discussion of the differences between the two curves is beyond the scope of the present work. However, the differences between the time series are smaller than their respective uncertainty bounds and both time series show the same increase of about 0.2 C since the mid-1950s."
Figure from Gouretski et al 2012
Using the above temperature changes from Gouretski et al 2012 we obtain a rate of ocean temperature changes in the upper 400 meters of
1900-1955: < 0.0009C/yr
1955-1970: < 0.0001C/yr
1970-2010: < 0.00025C/yr
Therefore, the Gouretski et al 2012 paper would imply that the rate of upper 400 m ocean warming was ~3.6 times faster from 1900-1955 compared to 1970-2010, a deceleration of ocean warming in defiance of anthropogenic global warming theory, and the opposite of the acceleration claimed by the "Skeptical Science" website and by other alarmists.
Goggle translation from German [with apologies] from Die Kalte Sonne:
The search for the 'missing heat' in the oceans ends with bust: Deep layers of the ocean have cooled over the past 20 years
5 August 2014 | 07:30
It has meanwhile spread that global warming paused for 16 years. Contrary to the IPCC's forecasts are stagnating temperatures, it is simply no longer getting warmer. How could this happen? The researchers devised a variety of hypotheses. The most widely used model says here that the surface temperatures of the Earth stagnate though, but in silence the waters of the deep sea would heat up strongly. And if these accumulated heat could eventually fight his way to the surface, then we are threatened with the warming disaster!
A nice theory, but how much truth is behind it? Is there data that underpin this model? First of all, you have to lead the complexity of the question in mind: We want to find out if there are layers of water in the world oceans, who warms up. The temperature of the water surface can be relatively easily derived from modern satellites. For up to 11 km deep oceans it will be more difficult. Satellite help here not because they get out of the depths of the oceans no information. The upper water layers obscure the underlying. In order to detect the temperature data in all three dimensions, surface and depth, as well as the temporal change of the values, repeated measurements must be performed in the water column on site, which is located at 362 million square kilometers of ocean surface as a logistical problem.
Because of the enormous importance of such data, science has in recent years, however, come up with something let. Since 2007, for determining the temperature of the deep sea called the Argo program, which consists of more than 3600 automatic diving buoys is drifting in the worlds oceans and regularly dive through the water column of 2,000 m depth to the surface of the water and measure the temperature and salinity. Wikipedia has the details:
This measuring robot are relatively small and weigh 20-30 kg. All profiling drifting buoys belonging to the Argo program, subject to a common data policy and the data are made available in real time without restriction to the general public. In the majority of cases the floats drift at depths of 1000 m (the so-called parking depth) and immerse every ten days then first at 2000 m starting to rise from the depth from the surface. During the ascent to the sea surface the floats measure temperature, conductivity and pressure in the water column. With the aid of the measured parameters then the salt content and the density of the sea water can be calculated also. Density is an important variable in oceanography, as horizontal density differences drive the large-scale currents in the ocean. The mean flow field in the parking depth can be determined from the distance traveled and the direction of successive float positions. The positions are not measured in the parking depth, but only on the surface by positioning systems GPS or ARGOS satellite. The transmission of the measured data is also where all the data collected, quality checked and then provided for use in real-time via satellite to international data centers.
Figure 1: Location map of the Argo buoys on August 2, 2014 Figure:. Argo website .
The following cartoon by Malou Zuidema & Esmee van Wijk describes the Argo measuring run very impressive:
While the Argo program represents a giant step forward, still lack systematic measurements of water depths below 2000 m. The data gap is huge when you consider that the average depth of the oceans is just under 3700 m. Also, of course, a lack of reliable, global data from the pre-Argo era, ie before 2007. Well covered The Argo-measurement period is only 7 years, which is extremely low compared to the climatic minimum interval of 30 years.
Before we go into the available measurement data, we need to introduce another concept, which plays in the description and summary of the oceanic temperature conditions and changes an important role in the so-called "heat content of the oceans", in English "Ocean Heat Content" (OHC) . Wikipedia explains:
The heat content of the oceans [...] (eg oceans) stored thermal energy called (the amount of heat) in the sea or parts thereof.Water has a higher heat capacity than air, therefore, the heat content of the oceans, is higher than in the atmosphere. The atmosphere containing only about 2% of the total heat capacity of the soil.
And this is one of the main reasons why we should deal with all water layers of the oceans and not only with the water surface: In the totality of ocean water can be a thousand times more stored heat, as in the atmosphere. Even small changes in the oceans, therefore, have a meaning.
Changes in the oceanic heat content in the past 50 years
The development of the oceanic heat content (OHC) is usually shown for certain water depth ranges. The North American Oceanographic authority NOAA shown in the following figure, the OHC for the last 60 years for the depth interval 0-700m, so a summary value for the global water body from the water surface to a depth of 700 m:
Figure 2: Evolution of the oceanic heat content for the last 60 years (depth interval 0-700m). Source: NOAA .
The OHC has increased in recent decades to be felt, what little wonder, as the global warming at the same time is advanced by half a degree. The data used in the pre-Argo-time is naturally quite thin . Suppose nevertheless at once that the trend is true. Perhaps you've noticed that on the Y-axis that temperatures are plotted, but the energy in Joules. This energy can, however, translate them back into temperatures (with thanks to Lucia / The Blackboard ):
Figure 3: OHC change the last 60 years, expressed in degrees Celsius. Source: Lucia / The Blackboard .
Have you noticed it? The OHC change in the past 60 years includes a change of less than 0.1 ° C. An extremely small amount, even taking into account the enormous heat capacity of the ocean to the atmosphere (see also Bob Tisdale's curves on WUWT).
Let's look now into the deeper water layers, 0-2000m:
Figure 4: OHC of the past 60 years, 0-2000m. Source: NOAA .
In principle, the development of water depth intervals 0-700m and 0-2000m are similar. The layers 0-2000m take on a bit more heat, probably mainly because the water column is much larger than in the case of 0-700m.
When the curves are global averages. Interestingly, the developments in the different oceans differ, sometimes significantly (see illustrations of Bob Tisdale at WUWT ). Thus, the cooled northern North Atlantic in the depth range 0-700m between 1955-1997 steadily. A research group led by Sirpa Hakkinen of NASA's Goddard Space Flight Center was also in a 2013 Journal of Geophysical Research published study show that the heat content of the northern North Atlantic is strongly influenced by ocean cycles. The OHC development is largely parallel to the Atlantic Multidecadal Oscillation (AMO), which is characterized by a quasi-cyclic 60-year history.
The cyclic 60-year component in global OHC history is all the more evident when one considers longer series of data. A team led by Viktor Gouretski of the University of Hamburg scoured the global oceanographic databases and found temperature data from water depths up to 400m, dating back to 1900. The work appeared in 2012 in the Geophysical Research Letters . The OHC curve 0-400m (green curve in Figure part b below) runs largely parallel with the known global temperature development: it can be seen two heating phases between 1900 to 1945 and from 1970 to 2003, interrupted by a warming break. The data for the study come from, according to authors:
1) bottle casts, 2) Conductivity-Temperature-Depth (CTD) profilers, 3) Mechanical BathyThermographs (MBT), 4) Expendable BathyThermographs (XBT), 5) Argo profiling floats, and 6) pinniped mounted sensors (sensors attached to marine mammals).
Figure 5: Development of the global oceanic heat content for the last 110 years after Gouretski et al. In 2012 . Green curve in Figure b shows part OHC for the depth interval 0-400m.
In 2012, a team led by Dean Roemmich of the Scripps Institution of Oceanography published in the journal Nature Climate Change even a study on the warming of the oceans during the past 135 years, and it includes data of the known Challenger Expedition took from 1872 to 1876. In an associated press release Roemmich explains that the warming of the oceans is a process that not only in this age of increased industrial CO 2 emissions began, but began more than 100 years:
"The Significance of the study is not only did we see a temperature difference did indicates warming on a global scale, but did the magnitude of the temperature change since the 1870s is twice did Observed over the past 50 years," Said Roemmich, co- chairman of the International Argo Steering Team. "This Implies did the time scale for the warming of the ocean is not just the load 50 years but at least the load 100 years."
Changes in the oceanic heat content in the past 10 years
As we have seen, the OHC has grown over the long term as part of the re-heating of the 20th century following the Little Ice Age. 60-year ocean cycles and other processes have modulated and shaped the course of heating. Now some IPCC researchers have close speculated that the lack of surface warming during the past 16 years by a sinking of the heat was indebted in the world oceans. We will therefore in the following, especially the last one, take two decades closer look. Fortunately, we can in this case - at least for the upper half of the water column - help the new Argo data.
According to Argo data from the U.S. National Oceanographic Data Center (NODC) of the NOAA OHC for the two depth ranges 0-700m and 0-2000m has risen in the last 10 years ( Figure 6 ). An acceleration of the heating with respect to the front of the last decade, however, can not be seen ( Figures 2-4 ).
Figure 6: Development of OHC for the two depth ranges 0-700m and 0-2000m in the last 10 years. Data: NODC, Graphics: Bob Tisdale .
The observed on the sea and land surface warming pause seems to be true that is not for the top 2 km of the water column. Here is the heating continued under NODC data set. You can see the IPCC supporters already funny to a bonfire dancing: "Yippie, the heating goes on! Did we have always told you. Must seek only to place your stop! ". Warming in the ocean, yes, but by how much? At this point, the party suddenly stops: The current Ewärmungstrend the upper ocean is only half pitiful 0.03 ° C per decade ( Figure 7 ). In 30 years here, only a tenth of a degree together, in 300 years, a full degree - if the heating so would go on as before. A heat disaster is different.
Figure 7: Global temperature development of the oceans for the two depth ranges 0-700m and 0-2000m in the last 10 years. Data: NODC, Graphics: Bob Tisdale .
The IPCC near U.S. scientist Kevin Trenberth - known for its "it's a travesty!" - Email sobs for heating break - have a in May 2014 in the Journal of Climate published work even admit that the warming of the oceans from 2001 - 2010 has slowed, the rate of increase OHC thus has decreased (Figure 8).
Figure 8: Evolution of the rate of change in OHC from 1980 to 2010. From Trenberth et al. 2014 .
Apparently, however, there are differences of opinion among scientists, as the heterogeneous measurement data are to be prepared.Researchers at the Pacific Marine Environment Laboratory (PMEL) NOAA suspect that data from XBT measurements (expendable bathythermograph) have not been processed correctly . In an improved analysis of the PMEL scientists come to an OHC development for the low floor 0-700m, which no longer contains a rise in the curve since 2003 ( Figure 9 ). Thus, the warming of the oceans would be virtually to a depth of 700 so come to a standstill .
Figure 9: Development of the OHC for the depth interval 0-700m during the last 20 years. Data and Graphics: NOAA Pacific Marine Environment Laboratory ( PMEL )
In March 2014 was published in the Journal of Climate , a Paper of the two PMEL researchers John Lyman and Gregory Johnson, in which they also pointed to problems with the selected climatological reference period. If you select the period to which the anomalies relate too early to go many interpolated values with one and change the trends. The spatial coverage and the uncertainties due to "infill" grow with increasing distance from the present time. In this work the OHC anomalies 1950-2011 redetermined by a reference period 2005-2010 is chosen, with the most accurate monthly data are available: Argo. The result can sit up ( Figure 10 ): The OHC had about 2003 peak and has stagnated ever since. No evidence of "missing heat" in depths up to 1800m.
Figure 10: OHC development for (a) 0-100m, (b) 0-300m, (c) 0-700m, (d) 0-1800m. From Lyman & Johnson in 2014 .
Also, the UK Met Office has a OHC record (UKMO EN3) developed showing almost no warming in the 0-700m and 0-2000m curves since 2003 (see Figures 4 and 5 in Bob Tisdale's post on WUWT ).
Again, the developments in the different oceans are very different from each other. While the Indian Ocean and South Atlantic heat above average, the heat content has in the North Atlantic and Pacific over the last 10 years hardly changed (depth interval 0-2000m) ( Figure 11 ). Also, the Southern Ocean around Antarctica process currently seems to lose heat than to accumulate, as Schulz et al. 2012 documented.
Again, the warning may be mentioned that there definitely ocean cycles are taken into account, the effect over time periods which exceed the Argo Messära many times. A simplistic extrapolation of the observed Argo Trends in the next 20-30 years, therefore, makes little sense.
Figure 11: OHC trends from the Argo era, broken down by major oceans. data: NODC, Graphics: Bob Tisdale
Was mentioned in passing briefly that the OHC values from year to year show larger fluctuations. Therefore, in practice often running averages are shown for several years, in order to suppress this "noise". The annual fluctuations stem from changes in the Pacific, where El Nino and La Nina phases make noticeable and affect the global OHC budget. Wikipedia knows this:
Model studies have shown that during La Niña years by shifting winds warmer water masses about ocean currents into the deeper layers of the sea are increasingly being transported. This leads to greater heat absorption of deep and less heat absorption of the atmosphere and temperature of the surface of the sea. Years with increase in temperature in deeper waters are associated with a negative phase of the interdecadal Pacific Oscillation (IPO). During the El Niño years of the ENSO circulation ocean currents carry significantly less water masses in the deep sea, thus the temperatures of the water at the sea surface and the atmospheric ground layer above the sea surface to rise more.
The unknown depth: here Hides perhaps the missing warming?
It is becoming increasingly clear that the failed at the surface warming has not redirected in the upper half of the ocean. The now available up to 2000 m depth measurement data suggest rather to the fact that has weakened the heating here, may come to a halt even for nine years. That leaves the deep water below. Here Hides perhaps the missing warming? The data situation is poor, as the Argo buoys not penetrate into this area. Nevertheless, there are also in this investigation and evidence to OHC development. So published Carl request from Harvard University with Patrick Heimbach Massachusetts Institute of Technology (MIT) this year (2014) in the Journal of Physical Oceanography a paper that deals with the Abyssal, ie the lower floors of the oceans. The conclusion is made clear: the water masses below 2000m have cooled in the last 20 years (Figure 12 ). No trace of the ominous heat that had hypothesized here are some IPCC researchers close. In summary, the authors write:
A dynamically consistent state estimate is used for the period 1992-2011 to describe the changes in oceanic heat content and temperatures applications, with emphasis on deterministic mining to the noise background in the abyssal (below 2000 m) depths.Interpretation requires close attention to the long memory of the deep ocean, and meteorological forcing of implying did Decades to Thousands of years ago shoulderstand be silent Producing trend-like changes in abyssal heat content. Much of the deep ocean volume Remained unobserved. At the present time, warming is seen in the deep western Atlantic and Southern Ocean , Roughly consistent with Those regions of the ocean expected to display the earliest responses to surface disturbances.Parts of the deeper ocean, below 3600 m, show cooling. Most of the variation in the abyssal Pacific Ocean is comparativelyfeatureless , consistent with the slow, diffusive, approach to a steady state expected there.
Figure 12: OHC development over the last 20 years. The deep water below 2000m has apparently cooled steadily during this period. Figuredesire & Heimbach 2014 .
Figure 13: OHC change from 1993 to 2011 for water layers below 2000m. With the exception of the western Atlantic and the Southern (zirkumantarktischen) Ocean just cooling down is recorded. Figure desire & Heimbach 2014 .
Desire and Heimbach indicate in the discussion part of the paper that the data are more likely to speak against the model of intermediately stored in the deep ocean heat:
The Uncertainties ... REMAIN too large to rationalize eg, the apparent "pause" in warming
The situation is similar Judith Curry , who wrote in her blog in January 2014:
All in all, I do not see a very convincing case for deep ocean sequestration of heat.
As early as 2012 had Mauritzen et al. in in Nature Geoscience reports published study by cooling of the deep water in the northern North Atlantic for the period 1953-2007. Also Roemmich et al. 2012 appear on a global scale indication of this have been found. The comparison with the Challenger data from 135 years ago suggests a cooling below 1500m down (Figure 3 here ).
Changes in the oceanic heat content in the context of the last 10,000 years
Finally, take a look at the long-term context of the development of ocean temperatures. In November 2013, a team led by Yair Rosenthal of Rutgers University published in the journal Science a reconstruction of the OHC development in the Pacific during the last 10,000 years. On the basis of temperature-sensitive foraminifera from cores they reconstructed the temperature history of a water layer of "medium depth" at about 500-1000m, the so-called North Pacific Intermediate Water '. The result is spectacular: Interestingly, the tested waters were significantly warmer than today during most of the last ten thousand years ( Figure 14 ). Thus, temperatures were in the North Pacific 9000-6000 years before present at the time of mittelholozänen optim