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Comments 51 to 65 out of 65:

51. Ken Lambert at 23:06 PM on 15 July, 2010
    Chris #40 BP#47 Er....not really Chris. Just describe the mechanism for getting heat from the surface to the deep oceans in a couple or three yearly timeframe. As I have suggested elsewhere, measurement of OHC changes needs a baseline viz. a snapshot of the 'tiled' oceans. The 'ideal' system would be a global array of tethered buoys measuring the same 'tile' at the same time. A tile might be 500m deep by 1 degree square to have enough resolution. The gold standard would be a snapshot of temperatures of each tile at time T1 and another snapshot at T2. A summation of each would give accurate changes in OHC. The Argo buoys are at present about 3500 in number covering on average a square of ocean 330km x 330km (about 3.3 degrees square) down to 2000m. The average ocean depth is 3700m. Not all the Argo buoys are measuring down to 2000m. How close the drifting Argo come to the 'ideal' is hard to determine. For sure, strong currents will tend to coagulate drifting buoys so that the same 'tile' of ocean might might not be measured at time T2 as was measured at T1. Two or more buoys might enter a tile of ocean and leave none where a prior measurement was taken. Now this might even itself out with some sort of statistical correction, but currents moving at 3-4 knots would move buoys and water out of a tile in a matter of hours, so it would seem a difficult problem to correct back to the 'ideal' measurement system of tethered buoys. Those more expert that I might explain how this is done. I suspect that the noisy and inconsistent nature of OHC reconstructions is due to this problem.
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52. Ken Lambert at 23:15 PM on 15 July, 2010
    MS #49 & Chris Michael, BP can probably defend himself, but I think you are right on this point, along with Chris. The temperature drop from surface to bottom of roughly 20 degC is not taken account in BP's argument. And Chris, just remember that each of BP's arguments stands on its merits. We all get it wrong on occasion, don't we Chris? That does not mean BP's Von Schukmann analysis is wrong.
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53. Berényi Péter at 06:32 AM on 16 July, 2010
    #49 michael sweet at 09:43 AM on 15 July, 2010 Since deep water is colder then surface water, the graph you copied with constant temperature is not relevant to the discussion. It is not quite so. Volumetric thermal expansion coefficient as a function of depth with an approximate global average temperature profile looks like this: This is the temperature profile used (it is 3°C below 2000 m): The curve above has a minimum around 1000 m. You can only decrease sea level by a simple redistribution of heat if it does not go too deep. On the other hand we know (e.g. from ¹⁴C) almost all the water at intermediate levels is several thousand years old (the time since it has seen surface). It is also the case the deeper you go the less water is in a specific layer. On top of that specific heat of water decreases slightly with increasing pressure. It is not easy to find a realistic heat redistribution pattern that does not increase sea level while sucking in more heat from above. But global ocean is not a very good thermometer, that much is true.
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54. thingadonta at 10:31 AM on 16 July, 2010
    #6: there's one other source of extra water in the oceans worth mentioning: emptying of underground reservoirs. As I, somewhat unreliably, remember it it's a measurable contribution but not huge." There is another source of extra water in the oceans,which is the origin of most of the world's oceans- when magmas in the earths crust cool, they expel water. The Mid Ocean Rifts are several times the length of the earth's circumferance, and cooling, rising magmas expel water all along these locations. Water is also extracted from oceans in subduction zones by descending crust. The overall balance is thought to be neutral, but it may not always be, especially during violent volcanic periods.
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55. michael sweet at 10:40 AM on 16 July, 2010
    On the other hand, the average ocean depth is only about 3700 m. According to: Kohl A, Stammer D: Decadal sea level changes in the 50-Year GECCO ocean synthesis. J Clim 2008, 21:1876-1890. the energy in the deep ocean has only penetrated to the 3000 meter level so far. When I eyeball your graph it seems to me that the average of 0-700m compared to the average of 700-3000 is not that far from what Trenberth stated in Chris's reference in #33. It is difficult to decide the best way to average the values. Why don't we just use Trenberth's numbers, since he has probably spent a lot of effort checking it? Personally, I value a number from a peer reviewed paper more than one that I see in an on-line blog. The authors put in a lot of time writing and reviewing the published calculation and it is not possible for bloggers to match that effort. If an error can be clearly shown that is one thing, but just offering a calculation or a graph and saying the paper is wrong is not convincing to me. If Trenberth is wrong, cite a paper that points out the correct answer.
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56. scaddenp at 11:09 AM on 16 July, 2010
    "here is another source of extra water in the oceans,which is the origin of most of the world's oceans-" Actually this is controversial. Getting our oceans (or even most of our oceans) by outgassing alone is a very tough proposition. "The overall balance is thought to be neutral, but it may not always be, especially during violent volcanic periods. " So Mt St Helens - 0.0032Gt. Himalayan glaciers 47Gt per year. I'm guessing you could make a case for around 3Gt/yr of volcanic outgassing but very difficult to make an estimate for water lost in sedimentary basins and subduction zones. I dont think this water source is material to the debate.
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57. Peter Hogarth at 18:59 PM on 16 July, 2010
    Berényi Péter at 06:32 AM on 16 July, 2010 This really belongs on an Ocean thread, but there is some very recent work in this area from Kawano 2010. A basic conclusion is that there is an extra 5% of the total Pacific Ocean heat content below 3000m. Decadal heat content change in each 100m layer of Pacific from measurements from repeat hydrographic surveys. On the idea that overturning rates and hypothesised lack of vertical mixing to deep layers means it take centuries to change bottom water temperatures, there is a significant amount of measured evidence that suggests otherwise. This is worth a post at some point. It is fair to say vertical mixing processes are not fully understood, but numerous plausible mechanisms and some corroborating evidence have been put forward, and simulations are only now getting to the point of replicating some of the observations. Another very recent contribution is Masuda 2010, which shows it is possible to simulate a fast (40 years lag) mechanism that links surface air heat flux off Antarctica with bottom warming in the North Pacific.
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58. Ken Lambert at 23:38 PM on 16 July, 2010
    Peter Hogarth #56 So are we now seeing bottom warming in the Pacific from heat flux off Antarctica which happened in 1970? 1970 is the era when we were going to have the next ice age and CO2GHG warming had not been pressing. What are we to conclude from that Peter? For sure it does not explain the roughly 0.4 W/sq.m (average 65E20 Joules/year) of unaccounted heat from Dr Trenberth's budget shortfall over the 2004-08 period. Any experts on Argo analyses able to comment on my speculator in Post #49 ?
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59. Ken Lambert at 23:39 PM on 16 July, 2010
    KL #57 = OOps Post#50.
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60. kdkd at 23:53 PM on 16 July, 2010
    Ken, Unless you have new information (i.e. new peer reviewed studies which support your position), your argument (putting all of your eggs in one basket more like) is still not valid. This is because the one thing we can be sure of about the heat balance measurements are that significant components are insufficiently precise over short durations to measure small changes with sufficient accuracy to draw strong conclusions.
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61. JMurphy at 00:42 AM on 17 July, 2010
    Ken Lambert wrote : 1970 is the era when we were going to have the next ice age and CO2GHG warming had not been pressing. Not true, and you've been on this site long enough to know. Selective memory ? "1970s ice age predictions were predominantly media based. The majority of peer reviewed research at the time predicted warming due to increasing CO2." Or were you trying to refer to a specific event in the year 1970 ?
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62. michael sweet at 08:06 AM on 17 July, 2010
    Peter, Your posts always raise the level of discussion. Thank you for informing the rest of us. Is the decrease in heat in the first 100 meters from a La Nina? (I cannot penetrate the paywall). I would have thought surface heat content would have risen since ocean surface temperatures are currently so high. It is amazing how rapidly the science is advancing. The paper I cited as saying heat had not passed 3000 meters is only two years old. OHC is a difficult problem. Hopefully the scientists working on it will continue to rapidly advance the state of knowledge. Are you the Peter Hogarth who studies sea grass?
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63. Peter Hogarth at 05:12 AM on 19 July, 2010
    michael sweet at 08:06 AM on 17 July, 2010 The upper 200m or so are strongly affected by seasonal changes, (the upper 100m particularly so), and remember this is a study based on repeat hydrographic sections rather than continuous monitoring that would allow averaging over annual periods. As we go deeper the Ocean effectively does this averaging for us.
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64. Berényi Péter at 20:43 PM on 26 July, 2010
    #56 Peter Hogarth at 18:59 PM on 16 July, 2010 On the idea that overturning rates and hypothesised lack of vertical mixing to deep layers means it take centuries to change bottom water temperatures, there is a significant amount of measured evidence that suggests otherwise. That's good news. At least we don't have to worry over ocean acidification. However, even if heat (and dissolved carbon dioxide) have an easy way to the abyss, it does not solve the problem at hand. If the bulk of Trenberth's missing heat went that deep, it would have produced more steric sea level rise than observed, as 1. for layers of equal thickness the deeper you go the less mass you have due to bathymetric constraints 2. volumetric thermal expansion coefficient of seawater increases with pressure The most likely solution is the missing heat simply went to the coldest and largest heat reservoir around, to outer space at a temperature of -270.425°C (-454.765ºF). That is, it was not trapped at all.
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65. Peter Hogarth at 00:17 AM on 27 July, 2010
    Berényi Péter at 20:43 PM on 26 July, 2010 Please read the papers rather than jumping in. They cover both your points. Your solution is not most likely. The "missing" heat is not really missing as such but less than the current estimates of uncertainty in factors like TOA radiation. The deep ocean estimates reduce that uncertainty, but as the estimates vary between 5 and up to 20% on recent work we have a way to go before uncertainty is reduced to the point of unambiguous budget balance. In terms of the 0.4W/m2 "missing" I have seen quoted on this thread I note from Palmer 2010 that the interannual variability in net radiation has been estimated as ± 0.7 W m-2 from Wong 2006 whilst Lyman and Johnson 2008 estimated the 2006 Argo coverage in situ sampling uncertainty for the 0-700m layer is approximately ± 0.4 Wm-2 over multi-year time scales at the 95% level, whilst Lyman 2010 slightly increases the estimate of Ocean heating to 0.64 ± 0.11 Wm-2 over the 16 year record at 90% confidence level, and Kawano 2010 may add 5 to 7 % to this. As uncertainties are reduced and estimates revised, we would expect any gaps in error budgets to close. I will be looking at a post on Deep Ocean Heat Content (it will take some time to review the papers). I will also look at any more recent work on net radiation and uncertainties here (I am aware of a few very recent papers).
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