Guest essay by Nic Lewis
The Otto et al. paper has received a great deal of attention in recent days. While the paper’s estimate of transient climate response was low, the equilibrium/effective climate sensitivity figure was actually slightly higher than that in some other recent studies based on instrumental observations. Here, Nic Lewis notes that this is largely due to the paper’s use of the Domingues et al. upper ocean (0–700 m) dataset, which assesses recent ocean warming to be faster than other studies in the field. He examines the effects of updating the Otto et al. results from 2009 to 2012 using different upper ocean (0–700 m) datasets, with surprising results.
Last December I published an article here entitled ‘Why doesn’t the AR5 SOD’s climate sensitivity range reflect its new aerosol estimates?‘ (Lewis, 2012). In it I used a heat-balance (energy-budget) approach based on changes in mean global temperature, forcing and Earth system heat uptake (ΔT, ΔF and ΔQ) between 1871–80 and 2002–11. I used the RCP 4.5 radiative forcings dataset (Meinshausen et al, 2011), which is available in .xls format here, conformed it with solar forcing and volcanic observations post 2006 and adjusted its aerosol forcing to reflect purely satellite-observation-based estimates of recent aerosol forcing.
I estimated equilibrium climate sensitivity (ECS) at 1.6°C,with a 5–95% uncertainty range of 1.0‑2.8°C. I did not state any estimate for transient climate response (TCR), which is based on the change in temperature over a 70-year period of linearly increasing forcing and takes no account of heat uptake. However, a TCR estimate was implicit in the data I gave, if one makes the assumption that the evolution of forcing over the long period involved approximates a 70-year ramp. This is reasonable since the net forcing has grown substantially faster from the mid-twentieth century on than previously. On that basis, my best estimate for TCR was 1.3°C. Repeating the calculations in Appendix 3 of my original article without the heat uptake term gives a 5–95% range for TCR of 0.9–2.0°C.
The ECS and TCR estimates are based on the formulae:
(1) ECS = F2× ΔT / (ΔF − ΔQ) and (2) TCR = F2× ΔT / ΔF
where F2× is the radiative forcing corresponding to a doubling of atmospheric CO2 concentrations.
A short while ago I drew attention, here, to an energy-budget climate study, Otto et al. (2013), that has just been published in Nature Geoscience, here. Its author list includes fourteen lead/coordinating lead authors of relevant AR5 WG1 chapters, and myself. That study uses the same equations (1) and (2) as above to estimate ECS and TCR. It uses a CMIP5-RCP4.5 multimodel mean of forcings as estimated by general circulation models (GCMs) (Forster et al, 2013), likewise adjusting the aerosol forcing to reflect recent satellite-observation based estimates – see Supplementary Information (SI) Section S1. It Although the CMIP5 forcing estimates embody a lower figure for F2× (3.44 W/m2) than do those per the RCP4.5 database (F2×: 3.71 W/m2), TCR estimates from using the two different sets of forcing estimates are almost identical, whilst ECS estimates are marginally higher using the CMIP5 forcing estimates[i].
Although the Otto et al. (2013) Nature Geoscience study illustrates estimates based on changes in global mean temperature, forcing and heat uptake between 1860–79 and various recent periods, it states that the estimates based on changes to the decade to 2000–09 are arguably the most reliable, since that decade has the strongest forcing and is little affected by the eruption of Mount Pinatubo. Its TCR best estimate and 5–95% range based on changes to 2000-09 are identical to what is implicit in my December study: 1.3°C (uncertainty range 0.9–2.0°C).
While the Otto et al. (2013) TCR best estimate is identical to that implicit in my December study, its ECS best estimate and 5–95% range based on changes between 1860–79 to 2000–09 is 2.0°C (1.2–3.9°C), somewhat higher than the 1.6°C (1.0–2.9°C) per my study, which was based on changes between 1871–80 and 2002–11. About 0.1°C of the difference is probably accounted for by roundings and the difference in F2× factors due to the different forcing bases. But, given the identical TCR estimates, differences in the heat-uptake estimates used must account for most of the remaining 0.3°C difference between the two ECS estimates.
Both my study and Otto et al. (2013) used the pentadal estimates of 0–2000-m deep-layer ocean heat content (OHC) updated from Levitus et al. (2012), and made allowances in line with the recent studies for heat uptake in the deeper ocean and elsewhere. The two studies’ heat uptake estimates differed mainly due to the treatment of the 0–700-m layer of the ocean. I used the estimate included in the Levitus 0–2000-m pentadal data, whereas Otto et al. (2013) subtracted the Levitus 0–700-m pentadal estimates from that data and then added 3-year running mean estimates of 0–700-m OHC updated from Domingues et al (2008).
Since 2000–09, the most recent decade used in Otto et al. (2013), ended more than three years ago, I will instead investigate the effect of differing heat uptake estimates using data for the decade 2003–12 rather than for 2000–09. Doing so has two advantages. First, forcing was stronger during the 2003–12 decade, so a better constrained estimate should be obtained. Secondly, by basing the 0–700-m OHC change on the difference between the 3-year means for 2003–05 and for 2010–12, the influence of the period of switchover to Argo – with its higher error uncertainties – is reduced.
In this study, I will present results using four alternative estimates of total Earth system heat uptake over the most recent decade. Three of the estimates adopt exactly the same approach as in Otto et al. (2013), updating estimates appropriately, and differ only in the source of data used for the 3-year running mean 0–700-m OHC. In one case, I calculate it from the updated Levitus annual data, available from NOAA/NOCDC here. In the second case I calculate it from updated Lyman et al. (2010), data, available here. In the third case I use the updated Domingues et al. (2008) data archived at the CSIRO Sea Level Rise page in relation to Church et al. (2011), here. Since that data only extends to the mean for 2008–10, I have extended it for two years at a conservative (high) rate of 0.33 W/m2 – which over that period is nearly double the rate of increase per the Levitus dataset, and nearly treble that per the Lyman dataset. The final estimate uses total system heat uptake estimates from Loeb et al. 2012 and Stephens et al. 2012. Those studies melded satellite-based estimates of top-of-atmosphere radiative imbalance with ocean heat content estimates, primarily updated from the Lyman et al. (2010) study. The Loeb 2012 and Stephens 2012 studies estimated average total Earth system heat uptake/radiative imbalance at respectively 0.5 W/m2 over 2000–10 and 0.6 W/m2 over 2005–10. I take the mean of these two figures as applying throughout the 2003–12 period.
I use the same adjusted CMIP5-RCP4.5 forcings dataset as used in the Otto et al. (2013) study, updating them from 2000–09 to 2003–12, to achieve consistency with that study (data kindly supplied by Piers Forster). Likewise, the uncertainty estimates I use are derived on the same basis as those in Otto et al. (2013).
I am also retaining the 1860–79 base reference period used in Otto et al. (2013). That study followed my December study in deducting 50% of the 0.16 W/m2 estimate of ocean heat uptake (OHU) in the second half of the nineteenth century per Gregory et al. (2002), the best-known of the earlier energy budget studies. The 0.16 W/m2 estimate – half natural, half anthropogenic – seemed reasonable to me, given the low volcanic activity between 1820 and 1880. However, I deducted only 50% of it to compensate for my Levitus 2012-derived estimate of 0–2000-m ocean heat uptake being somewhat lower than that per some other estimates. Although the main reason for making the 50% reduction in the Gregory (2002) OHU estimate for 1861–1900 disappears when considering 0–700-m ocean heat uptake datasets with significantly higher trends than per Levitus 2012, in the present calculations I nevertheless apply the 50% reduction in all cases.
Table 1, below, shows comparisons of ECS and TCR estimates using data for the periods 2000–09 (Otto et al., 2013), 2002–11 (Lewis, 2012 – my December study) and 2003–12 (this study) using the relevant forcings and 0–700 m OHC datasets.
Table 1: ECS and TCR estimates based on last decade and 0.08 W/m2 ocean heat uptake in 1860–79.
Whichever periods and forcings dataset are used, the best estimate of TCR remains 1.3°C. The 5–95% uncertainty range narrows marginally when using changes to 2003–12, giving slightly higher forcing increases, rather than to 2000–09 or 2002–11, rounding to 0.9–1.95°C. The ‘likely’ range (17–83%) is 1.05–1.65°C. (These figures are all rounded to the nearest 0.05°C.) The TCR estimate is unaffected by the choice of OHC dataset.
The ECS estimates using data for 2003–12 reveal the significant effect of using different heat uptake estimates. Lower system heat uptake estimates and the higher forcing estimates resulting from the 3-year roll-forward of the period used both contribute to the ECS estimates being lower than the Otto et al. (2013) ECS estimate, the first factor being the most important.
Although stating that estimates based on 2000–09 are arguably most reliable, Otto et al. (2013) also gives estimates based on changes to 1970–79, 1980–89, 1990–99 and 1970–2009. Forcings during the first two of those periods are too low to provide reasonably well-constrained estimates of ECS or TCR, and estimates based on 1990–99 may be unreliable since this period was affected both by the eruption of Mount Pinatubo and by the exceptionally large 1997–98 El Niño. However, the 1970–2009 period, although having a considerably lower mean forcing than 2000–09 and being more impacted by volcanic activity, should – being much longer – be less affected by internal variability than any single decade. I have therefore repeated the exercise carried out in relation to the final decade, in order to obtain estimates based on the long period 1973–2012.
Table 2, below, shows comparisons of ECS and TCR estimates using data for the periods 1900–2009 (Otto et al., 2013) and 1973–2012 (this study) using the relevant forcings and 0–700-m OHC datasets. The estimates of system heat uptake from two of the sources used for 2003–12 do not cover the longer period. I have replaced them by an estimate based on data, here, updated from Ishii and Kimoto (2009). Using 2003–12 data, the Ishii and Kimoto dataset gives almost an identical ECS best estimate and uncertainty range to the Lyman 2010 dataset, so no separate estimate for it is shown for that period. Accordingly, there are only three ECS estimates given for 1973–2012. Again, the TCR estimates are unaffected by the choice of system heat uptake estimate.
Table 2: ECS and TCR estimates based on last four decades and 0.08 W/m2 ocean heat uptake in1860–79
The first thing to note is that the TCR best estimate is almost unchanged from that per Otto et al. (2013): just marginally lower at 1.35°C. That is very close to the TCR best estimate based on data for 2003–12. The 5–95% uncertainty range for TCR is slightly narrower than when using data for 1972–2012 rather than 1970–2009, due to higher mean forcing.
Table 2 shows that ECS estimates over this longer period vary considerably less between the different OHC datasets (two of which do not cover this period) than do estimates using data for 2003–12. As in Table 1, all the 1973–2012 based ECS estimates come in below the Otto et al. (2013) one, both as to best estimate and 95% bound. Giving all three estimates equal weight, a best estimate for ECS of 1.75°C looks reasonable, which compares to 1.9°C per Otto et al. (2013). On a judgemental basis, a 5–95% uncertainty range of 0.9–4.0°C looks sufficiently wide, and represents a reduction of 1.0°C in the 95% bound from that per Otto et al. (2013).
If one applied a similar approach to the four, arguably more reliable, ECS estimates from the 2003–12 data, the overall best estimate would come out at 1.65°C, considerably below the 2.0°C per Otto et al. (2013). The 5–95% uncertainty range calculated from the unweighted average of the PDFs for the four estimates is 1.0–3.1°C, and the 17–83%, ‘likely’, range is 1.3–2.3°C. The corresponding ranges for the Otto et al. (2013) study are 1.2–3.9°C and 1.5–2.8°C. The important 95% bound on ECS is therefore reduced by getting on for 1°C.
References
Church, J. A. et al. (2011): Revisiting the Earth’s sea-level and energy budgets from 1961 to 2008. Geophysical Research Letters 38, L18601, doi:10.1029/2011gl048794.
Domingues, C. M. et al. (2008): Improved estimates of upper-ocean warming and multi-decadal sea-level rise. Nature453, 1090-1093, doi:http://www.nature.com/nature/journal/v453/n7198/suppinfo/nature07080_S1.html.
Forster, P. M., T. Andrews, P. Good, J. M. Gregory, L. S. Jackson, and M. Zelinka (2013): Evaluating adjusted forcing and model spread for historical and future scenarios in the CMIP5 generation of climate models, J. Geophys. Res. Atmos., 118, doi:10.1002/jgrd.50174
Ishii, M. and M. Kimoto (2009): Reevaluation of historical ocean heat content variations with time-varying XBT and MBT depth bias corrections. J. Oceanogr., 65, 287 – 299.
Levitus, S. et al. (2012): World ocean heat content and thermosteric sea level change (0–2000 m), 1955–2010. Geophysical Research Letters39, L10603, doi:10.1029/2012gl051106.
Loeb, NG et al. (2012): Observed changes in top-of-the-atmosphere radiation and upper-ocean heating consistent within uncertainty. Nature Geoscience, 5, 110-113.
Lyman, JM et al. (2009): Robust warming of the global upper ocean. Nature, 465, 334–337. http://www.nature.com/nature/journal/v465/n7296/full/nature09043.html
Meinshausen M., S. Smith et al. (2011): The RCP greenhouse gas concentrations and their extension from 1765 to 2500. Climate Change, Special RCP Issue
Otto, A. et al. (2013): Energy budget constraints on climate response. Nature Geoscience, doi:10.1038/ngeo1836
Stephens, GL et al (2012): An update on Earth’s energy balance in light of the latest global observations. Nature Geoscience, 5, 691-696
[i]Total forcing after adjusting the aerosol forcing to match observational estimates is not far short of total long-lived greenhouse gas (GHG) forcing. Therefore, differing estimates of GHG forcing – assuming that they differ broadly proportionately between the main GHGs – change both the numerator and denominator in Equation (1) by roughly the same proportion. Accordingly, differing GHG forcing estimates do not matter very much when estimating TCR, provided that the corresponding F2× is used to calculate the ECS and TCR estimates, as was the case for both my December study and Otto et al. (2013). ECS estimates will be more sensitive than TCR estimates to differences in F2× values, since the unvarying deduction for heat uptake means that the (ΔF − ΔQ) factor in equation (2) will be affected proportionately more than the F2× factor. All other things being equal, the lower CMIP5 F2× value will lead to ECS estimates based on CMIP5 multimodel mean forcings being nearly 5% higher than those based on RCP4.5 forcings.
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“””””…..John Day says:
May 29, 2013 at 4:34 am
@george e. smith
>Wiki of course does NOT publish peer reviewed papers.
Wikipedia is not a system for publishing scholarly papers (yet). It is an on-line encyclopedia that may be reviewed, collaborated or edited by anyone, including experts and yourself. In theory, such a ‘collaborative public encyclopedia’ cannot possibly work, but in practice it works remarkably well. It’s not perfect, but, like a living thing, Wikipedia is evolving and getting better.
George, I know you want to change the subject (which is already far off-topic from ‘aerosol adjusted forcings’) but you really need to face the music and apologize for retweeting those errors in that OPN letter. Just say you’re sorry for any misinformation that you may have inadvertently said or repeated in regard to the 1924 Bose-Einstein paper. There, I said it for you…..”””””
Stop making stuff up John. I don’t “tweet” what ever the hell that is. You can’t seem to understand, that the issue is NOT that the first paper by Bose WAS published with Bose as author which he was; and of course in Einstein’s translation. The letter writer’s comment related to a SECOND PAPER written by Einstein as sole author; but which, according to history, Einstein could not have written, but for the fact that he had already seen the earlier Bose paper. The letter writer asserts based on his understanding of the history; that Einstein should have acknowledged the earlier Bose work, and invited him to be co-author of the second paper which drew heavily on Bose’s work. You have not even acknowledged the existence of the later Einstein paper.
You are the one who is challenging the correctness of the letter writer’s assertions. You owe it to him, to write your objections to the OPN editorial staff, rather than shoot blanks here at WUWT.
I have no cause to alter a syllable of what I posted.
And there was no Bose-Einstein paper in 1924; there was a Bose paper, followed later by an Einstein paper, that drew heavily on the former, without attribution..
As for aerosol adjusted or any other “forcings”, these are childish gobbledegook, trying to simplify an overly complex chaotic system. The actual observationally measured real climate data, to the extent there is any, has not been explained by any of these ramblings that assert to blame a single minor component of atmospheric physics, for changes in the climate. We don’t even have any credible climate data predating about 1980, due to the erroneous substitution of ocean water temperatures from uncontrolled depths, for actual lower atmospheric Temperatures. Not only are they quite different, but they also are not even correlated, so the error is uncorrectable.
@george e. smith
>As for aerosol adjusted or any other “forcings”, these are childish gobbledegook…
Then you should have posted that opinion/comment to Anthony and Nic, instead of posting your other off-topic remarks here in this WUWT article.
> I don’t “tweet” what ever the hell that is.
Of course you don’t. You seem to be a dinosaur and apparently proud of it. I was speaking metaphorically:
http://en.wikipedia.org/wiki/Twitter#Format
> … there was no Bose-Einstein paper in 1924;
Then we could have avoided this whole, apparently useless, discussion if you had properly responded to my initial disclaimer:
You could have just said: “No John, the OPN letter was addressing another paper” and that would have been the end of it.
So now you owe _me_ a really big apology for _your_ lack of due diligence.
😐
“””””…..John Day says:
May 30, 2013 at 4:06 am
So now you owe _me_ a really big apology for _your_ lack of due diligence…….””””””
Well, I have often said: “Ignorance is not a disease; we are all born with it; but stupidity has to be taught, and there are plenty willing and able to teach it. ”
If you check the record, you will see it was YOU who transferred the focus from Einstein’s johny-come-lately paper, to the earlier landmark Bose paper which inspired it.
So don’t come wailing due diligence to me. If you actually learned anything in school you wouldn’t have to google wiki to find out how to spell a publication you never ever heard of.
As for dinosaurs; they managed to survive for 140 million years, just by being big, and mean, and ugly; whereas human “intelligence” is maybe 10% of the way to its first million years of survivability testing by Mother Gaia; and may not last longer than the next generation of time wasting juvenile distraction toys lets it run.
@george e. smith
> If you check the record, you will see it was
> YOU who transferred the focus from
> Einstein’s johny-come-lately paper,
What johnny-come-lately paper? I still don’t know the identity of this so-called “paper”, which Einstein allegedly plagiarized from Bose, even though I very specifically asked you to provide a reference for it before any discussion took place. So, how could _you_ “focus on a paper whose identity has not been cited?
Do Dinosaurs even know what citation means?
http://en.wikipedia.org/wiki/Citation
Actually, I would still like to know which paper you were “focusing” on. Then we can have a nice long discussion on it, and its impact on “aerosol-adjusted forcings”. I’m sure Anthony and Nic would appreciate devoting even more bandwidth to that.
You’ll probably say “Look it up yourself”, but it’s funny that didn’t stop you from pontificating on it, a paper whose existence you still can’t provide a citation for.
😐
@george e. smith
> If you actually learned anything in school you
> wouldn’t have to google wiki to find out how
> to spell a publication you never ever heard of.
George, let me try to fill in another, very annoying gap in your knowledge. You may surprised to learn that the word “wiki” was not coined by Jimmy Wales, and it is _not_ a general abbreviation for “Wikipedia”. There are tons of wikis around on the Internet. They were invented by Ward Cunningham in 1994, long before Wales invented Wikipedia in 2001:
http://en.wikipedia.org/wiki/Wiki
So, Wikipedia consists of many, many thousands of wikis (“articles”), which is why you see the term ‘wiki’ in every single Wikipedia URL reference. But there are tons of wikis on the Internet that don’t belong to Wikipedia.
So please stop using ‘wiki’ as an abbreviation for Wikipedia. (Unless you’re just trying to irritate me, then that’s OK)
> Well, I have often said: “Ignorance is not a disease;
> we are all born with it; but stupidity has to be taught,
> and there are plenty willing and able to teach it. ”
So who taught you to never use Wikipedia? That’s like saying you won’t use any textbook if it contains any factual errors or typos. By doing this you are deliberately depriving yourself of a rich source of knowledge. After using Widipedia for a while, you’ll soon learn to judge the reliability of the articles, and use the contained links to learn more, and navigate around the bogus information that you occasionally find in some Wikipedia wikis.
As I have often said: A person who teaches himself stupidity has a fool for a teacher.
@george e. smith
> If you actually learned anything in school you
> wouldn’t have to google wiki to find out how
> to spell a publication you never ever heard of.
So you believe that schools teach you everything you need to know for the rest of your life?
Most of what I know I taught myself by studying on my own, and asking questions. I think you should do more of that yourself.
As Bertrand Russell (1872-1970), the English philosopher, mathematician and writer famously said:
“Men are born ignorant, not stupid; they are made stupid by education. “
John Day says:
“Most of what I know I taught myself by studying on my own…”
And George Smith’s long professional carreer was in the electro-optics field, which trumps ‘studying on your own’. You really should listen to George, who has probably forgotten more than most folks will ever learn about the subject. He has been helping readers understand the subject for many years here. You showed up only in the past few months, that I know of.
When you need 3 posts to respond to one of George’s comments, you’re taking it way too personally. You could learn something by reading, instead of reacting. George Smith knows what he’s talking about WRT optics.
George hurled a few invectives at me, so I guess I got carried away. Sorry.
@dbstealey>And George Smith’s long professional carreer was in the electro-optics field…
He wouldn’t happen to be the Nobel Laureate who invented the CCD (or related to him)?
http://en.wikipedia.org/wiki/George_E._Smith
“””””…..John Day says:
June 2, 2013 at 5:55 am
George hurled a few invectives at me, so I guess I got carried away. Sorry.
@dbstealey>And George Smith’s long professional carreer was in the electro-optics field…
He wouldn’t happen to be the Nobel Laureate who invented the CCD (or related to him)?
http://en.wikipedia.org/wiki/George_E._Smith…..”””””
The 2009 Nobel Physics Prize co-winner, was a long time Bell Labs researcher. For 30 years, our careers intertwined, but I never met him. Often, at a technical conference, I would go to the registration desk, only to be told that I was already pre-registered, and there were messages for me on the message board. Well it was the Bell labs CCD inventor. By some quirk of fate, the director of R&D at Beckman Instruments, at that time, was also a George E. Smith. Three of us with similar jobs and job functions.
There are folks, who know me, as well as the Nobel Laureate, and have for decades. The inventor of the first practical “visible” LED, knows both of us well. The inventor of the first practical LED ( GaAs infrared) was Bob Baird at Texas Instruments in the early 1960s. He is also still active in the industry, but he would NOT know me.
As for learning in school; the best we can hope for John, is that they teach us HOW to learn. The actual material they teach, is not that important, so long as we learn how to replace it with what we really want to know.
If you don’t already have it, a small cheap ($11) book, I would heartily endorse for your reading enjoyment, as well as reliable information is George Gamow’s “Thirty Years that Shook Physics.”, subtitled, The Story of Quantum Mechanics. It’s extremely readable and informative.
I am fortunate to be able to chat with a PhD Physicist, who was a student of Gamow. He also is a top medical Doctor; not just any medical Doctor, but a world famous star of television news. Well he was back in the days of Mercury, Gemini, and Apollo, when astronauts needed their vitals monitored. As it so happens, he is currently studying Quantum Mechanics at Stanford University.
There is some, not very accurate bio of mine bobbing around on the web, circa 2000; but no, I am not the Nobellist.
Those must have been interesting times for you, George, with three George E. Smith’s working in the same field!
Let’s give our little discussion a rest. Sorry I gave you such a hard time. My only motive is to seek the truth. I like reading about the history of physics, because it gives us some insights into physics today.
Best regards,
John Day
John Day,
It takes a stand-up guy to say “Sorry”. Much appreciated here.
“””””…..John Day says:
June 2, 2013 at 3:23 pm
Those must have been interesting times for you, George, with three George E. Smith’s working in the same field!
Let’s give our little discussion a rest. Sorry I gave you such a hard time. My only motive is to seek the truth. I like reading about the history of physics, because it gives us some insights into physics today.
Best regards,
John Day……””””
Never any hard feelings John; at my age my hide is well tanned like a good Texas saddle.
And I really seriously commend to you that George Gamow book; it’s a Dover paper back, available at any Barnes and Noble or Amazon. And although maybe not a very big name in early 20th century Physics, he was actually there in the midst of all those biggies, while all that earth shattering stuff was going down. You will get a lot of enjoyment, and good learning too out of it.
Ciao.
George