Saturday, January 30, 2016

Climate Science Legal Defense Fund Celebrates its Four-Year Anniversary

by Jeff Masters, WunderBlog, January 28, 2016

Whenever scientific research uncovers truths that threaten the profits of large and powerful corporations, those companies--and the politicians these corporations' money help elect -- inevitably fight back by attacking the scientists. As I discussed in detail in my 2009 blog post, "The Manufactured Doubt Industry and the Hacked Email Controversy," we've seen this behavior most clearly with the tobacco industry, but manufacturers of chlorofluorocarbons, asbestos, benzene, beryllium, chromium, MTBE, perchlorates, phthalates, and a slew of many other toxic chemicals have all waged elaborate campaigns to attack the scientific findings and the scientists that threatened their profits. These attacks often take the form of legal action, which government or university-funded scientists do not have the resources to combat. Such attacks against climate scientists have been particularly pernicious and numerous in recent years, and multiple climate scientists are currently involved in litigation in state and federal courts across the United States. 

The Climate Science Legal Defense Fund (CSLDF) was created to help these climate scientists fight back. CSLDF works to help raise funds for scientists’ legal defenses, serves as a resource in finding pro bono legal representation, and provides support during difficult litigation proceedings as well as when legal action is threatened. I'm proud to say that I'm a founding board member of the charity, and this week marks the four-year anniversary of their official debut. Over that time, they’ve helped nearly a hundred researchers across the country, from Arizona to Virginia. 

In celebration of their birthday, they’ve launched a new website at climatesciencedefensefund.org. The new site explains their history, details their initial work defending Dr. Michael Mann, and describes their current projects. I hope you will consider making a donation to this worthy cause in the future. 



Figure 1. Screen shot of the new website at climatesciencedefensefund.org.

To learn more about the well-funded attacks on climate science and climate scientists by the fossil fuel industry, my fellow CSLDF board member, Noami Oreskes, has co-authored the excellent book, Merchants of Doubt, which has also been made into a fascinating documentary (available on Netflix.)

http://www.wunderground.com/blog/JeffMasters/climate-science-legal-defense-fund-celebrates-its-fouryear-anniversar

Sunday, January 17, 2016

Ben Santer & Carl Mears: A Response to Ted Cruz's “Data or Dogma?” hearing

by Benjamin D. Santer (Program for Climate Model Diagnosis and Intercomparison, Lawrence Livermore National Laboratory, Livermore, CA) and Carl Mears (Remote Sensing Systems, Santa Rosa, CA), Skeptical Science, January 17, 2016

[PDF available here:  http://skepticalscience.com/docs/Santer_Mears_Data_Dogma.pdf]

On December 8, 2015, Senator Ted Cruz – the chairman of the Senate subcommittee on Space, Science, and Competitiveness – convened a hearing entitled “Data or Dogma?” The stated purpose of this event was to promote “…open inquiry in the debate over the magnitude of human impact on Earth’s climate” (ref. 1). In the course of the hearing, the chairman and several expert witnesses claimed that satellite temperature data falsify both “apocalyptic models” and findings of human effects on climate by “alarmist” scientists. Such accusations are serious but baseless. The hearing was more political theatrics than a deep dive into climate science.  
Satellite-derived temperature data were a key item of evidence at the hearing. One of the witnesses [a] for the majority side of the Senate subcommittee showed the changes (over roughly the last 35 years) in satellite- and weather-balloon-based measurements of the temperature of the mid-troposphere (TMT), a layer of the atmosphere extending from the Earth’s surface to roughly 18 km (ref. 2). Satellite TMT measurements are available from late 1978 to present. Observed TMT data were compared with TMT estimates from a large number of model simulations. This comparison was ‘Exhibit A’ for the majority side of the subcommittee.
Senator Cruz used Exhibit A as the underpinning for the following chain of arguments: (1) Satellite TMT data do not show any significant warming over the last 18 years, and are more reliable than temperature measurements at Earth’s surface; (2) The apparent “pause” in tropospheric warming is independently corroborated by weather balloon temperatures; (3) Climate models show pronounced TMT increases over the “pause” period; and (4) The mismatch between modeled and observed tropospheric warming in the early 21st century has only one possible explanation – computer models are a factor of three too sensitive to human-caused changes in greenhouse gases (GHGs). Based on this chain of reasoning, Senator Cruz concluded that satellite data falsify all climate models, that the planet is not warming, and that humans do not impact climate.
This logic is wrong. First, satellites do not provide direct measurements of atmospheric temperature: they are not thermometers in space. The satellite TMT data plotted in Exhibit A were obtained from so-called Microwave Sounding Units (MSUs), which measure the microwave emissions of oxygen molecules from broad atmospheric layers (refs. 24)[b]. Converting this information to estimates of temperature trends has substantial uncertainties [c]. The major uncertainties arise because the satellite TMT record is based on measurements made by over 10 different satellites, most of which experience orbital decay (ref. 5) and orbital drift (refs. 68) over their lifetimes. These orbital changes affect the measurements of microwave emissions, primarily due to gradual shifts in the time of day at which measurements are made. As the scientific literature clearly documents, the adjustments for such shifts in measurement time are large [d], and involve many subjective decisions (refs. 24, 68). Further adjustments to the raw data are necessary for drifts in the on-board calibration of the microwave measurements (refs. 9, 10), and for the transition between earlier and more sophisticated versions of the MSU[e].
In navigating through this large labyrinth of necessary adjustments to the raw data, different plausible adjustment choices lead to a wide range of satellite TMT trends (refs. 210). This uncertainty has been extensively studied in the scientific literature, but was completely ignored in the discussion of Exhibit A by Senator Cruz and by witnesses for the majority side of the subcommittee (refs. 215). The majority side was also silent on the history of satellite temperature datasets. For example, there was no mention of the fact that one group’s analysis of satellite temperature data – an analysis indicating cooling of the global troposphere – was repeatedly found to be incorrect by other research groups (refs. 2, 3, 510).
Such corrective work is ongoing. Satellite estimates of atmospheric temperature change are still a work in progress (refs. 2, 3, 8), and the range of estimates produced by different groups remains large.[f] The same is true of weather balloon atmospheric temperature measurements (refs. 2, 1113, 1517)[g]. Surface thermometer records also have well-studied uncertainties (refs. 2, 19, 20), but the estimated surface warming of roughly 0.9 °C since 1880 has been independently confirmed by multiple research groups (refs. 2, 15, 19, 20).
The hearing also failed to do justice to the complex issue of how to interpret differences between observed and model-simulated tropospheric warming over the last 18 years. Senator Cruz offered only one possible interpretation of these differences – the existence of large, fundamental errors in model physics (refs. 2, 21). In addition to this possibility, there are at least three other plausible explanations for the warming rate differences shown in Exhibit A: errors in the human (refs. 2225), volcanic (refs. 2630), and solar influences (refs. 24, 31) used as input to the model simulations; errors in the observations (discussed above) (refs. 220); and different sequences of internal climate variability in the simulations and observations (refs. 23, 24, 30, 3236). We refer to these four explanations as “model physics errors,” “model input errors,” “observational errors,” and “different variability sequences.” They are not mutually exclusive. There is hard scientific evidence that all four of these factors are in play (refs. 220, 2236).
“Model input errors” and “different variability sequences” require a little further explanation. Let’s assume that some higher extraterrestrial intelligence provided humanity with two valuable gifts: a perfect climate model, which captured all of the important physics in the real-world climate system, and a perfect observing system, which reliably measured atmospheric temperature changes over the last 18 years. Even with such benign alien intervention, temperature trends in the perfect model and perfect observations would diverge if there were errors in the inputs to the model simulations [h], or if the purely random sequences of internal climate oscillations did not “line up” in the simulations and in reality (refs. 23, 24, 30, 3236).
In short, “all models are too sensitive to CO2” is not the only valid explanation [i] for the modeldata differences in Exhibit A (refs. 2, 11, 13, 18, 2224, 26, 30, 3238). Dozens of peer-reviewed scientific studies show that the other three explanations presented here (“model input errors,” “observational errors,” and “different variability sequences”) are the primary reasons for most or all of the warming rate differences in Exhibit A [j].  
But what if climate models really were a factor of three or more too sensitive to human-caused GHG increases, as claimed by the majority side of the subcommittee? The telltale signatures of such a serious climate sensitivity error would be evident in many different comparisons with observations, and not just over the last 18 years. We’d expect to see the imprint of this large error in comparisons with observed surface temperature changes over the 20th century (refs. 3742), and in comparisons with the observed cooling after large volcanic eruptions (refs. 30, 43, 44). We don’t. There are many cases where observed changes are actually larger than the model expectations (refs. 41, 42), not smaller.
In assessing climate change and its causes, examining one individual 18-year period is poor statistical practice, and of limited usefulness. Analysts would not look at the record of stock trading on a particular day to gain reliable insights into long-term structural changes in the Dow Jones index. Looking at behavior over decades – or at the statistics of trading on all individual days – provides far greater diagnostic power. In the same way, climate scientists study changes over decades or longer (refs. 3942, 45), or examine all possible trends of a particular length (refs. 23, 38, 4648). Both strategies reduce the impact of large, year-to-year natural climate variability [k] on trend estimates. The message from this body of work? Don’t cherry-pick; look at all the evidence, not just the carefully selected evidence that supports a particular point of view.
In summary, the finding that human activities have had a discernible influence on global climate is not falsified by the supposedly “hard data” in Senator Cruz’s Exhibit A. The satellite data and weather balloon temperatures are not nearly as “hard” as they were portrayed in the hearing. Nor is a very large model error in the climate sensitivity to human-caused GHG increases the only or the most plausible explanation for the warming rate differences in Exhibit A. Indeed, when the observational temperature data sets in Exhibit A are examined over their full record lengths – and not just over the last 18 years – they provide strong, consistent scientific evidence of human effects on climate (refs. 41, 42, 48)  as do many other independent observations of changes in temperature, the hydrological cycle, atmospheric circulation, and the cryosphere (refs. 41, 42).
Climate policy should be formulated on the basis of both the best-available scientific information and the best-possible analysis and interpretation. Sadly, neither was on display at the Senate hearing on “Data or Dogma?” There was no attempt to provide an accurate assessment of uncertainties in satellite data or to give a complete and balanced analysis of the reasons for short-term differences between modeled and observed warming rates. Political theater trumped true “open inquiry.”
Climate change is a serious issue, demanding serious attention from our elected representatives in Washington. The American public deserves no less.  

Acknowledgments

We gratefully acknowledge the comments and valuable suggestions from Professor Susan Solomon (M.I.T.) and Dr. Mike MacCracken (The Climate Institute). 

Footnotes

  1. Prof. John Christy from the University of Alabama at Huntsville.
  2. MSU estimates of the temperature of tropospheric layers also receive a small contribution from the temperature at Earth’s surface.
  3. This conversion process relies on an atmospheric radiation model to invert the observations of outgoing, temperature-dependent microwave emissions from oxygen molecules. Since oxygen molecules are present at all altitudes, the microwave flux that reaches the satellite is an integral of emissions from thick layers of the atmosphere.  
  4. At the end of the hearing, Senator Cruz questioned the reliability of thermometer measurements of land and ocean surface temperature and highlighted the large adjustments to “raw” surface temperature measurements (adjustments which are necessary because of such factors as changes over time in thermometers and measurement practices). He did not mention that the surface temperature adjustments are typically much smaller than the adjustments to “raw” MSU data (refs. 2, 3, 8).
  5. This transition occurred in 1998, at the beginning of the 18-year “no significant warming” period highlighted by Senator Cruz.
  6. For example, over the longer 1979–2014 analysis period, tropospheric warming is a robust feature in all observational TMT datasets. For shorter, noisier periods (such as 1996–2014), the sign of the TMT trend is sensitive to dataset construction uncertainties.
  7. Disappointingly, Exhibit A neglects to show at least one weather balloon temperature data set with substantial tropospheric warming over the last 18 years (18).
  8. Such as leaving out volcanic cooling influences that the real world experienced (refs. 23, 24, 26–30).
  9. The model results shown in Exhibit A are from so-called “historical climate change” simulations. These simulations involve changes in a number of different human and natural influences (e.g., human-caused changes in GHG levels and particulate pollution, and natural changes in solar and volcanic activity). They are not simulations with changes in GHG levels only, so it is incorrect to interpret the model-versus-observed differences in Exhibit A solely in terms of model sensitivity to GHG increases.   
  10. Another incorrect claim made at the hearing was that the mainstream scientific community had failed to show the kind of model–data comparisons presented in Exhibit A. Results similar to those in Exhibit A have been presented in many other peer-reviewed publications (refs. 2, 13, 18, 23, 24, 30, 32, 35, 38, 46, 47).
  11. Such as the variability associated with unusually large El Niño and La Niña events, which yield unusually warm or cool global-mean temperatures, respectively. The El Niño event during the winter of 1997 and spring of 1998 was likely the largest of the 20th century and produced a large warming “spike” in surface and tropospheric temperatures.

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Mauri Pelto: What is Up in Disko-Uummannaq Bay, Greenland, January 9-16, 2016?

by Mauri Pelto, "From A Glacier's Perspective," January 17, 2016

@TenneyNaumer contacted Alun Hubbard, Jason Box and me with an astute observation last evening: “But what I am getting at is that in general the temperature anomalies over the region of Jakobshavn have been high in the last few days, and I spotted weird temperatures off the coast via Climate Reanalyzer (which is seriously low resolution).  I just checked with the manati satellite (also seriously low resolution), and it seems some sort of event has taken place.”
Following up on what are typically good observations from Tenney, I looked at the Radarsat-2 and Sentinel-1 imagery posted by the Danish Meteorological Institute.  Weather records from automatic weather stations in the region from PROMICE and the surface mass balance model results for the week from Polar Portal.
The arrow at location 1# is an area of sea ice across the fjord in front of Jakobshavn Glacier on January 9 that disappears by January 13. Location #2 is at the fjord mouth, and location #3 is at the sea front south of Disko Island on January 9.  There is no real cloud cover evident in any of images.  Maybe low-level fog in places. By January 11th, a plume is sweeping from Point 2 towards Point 3. Notice the sea ice in the fjord disappears by January 13th, and the ice front is pushed back in a concave fashion at Point #3. This indicates a clear push of water driving sea ice offshore. (The Ilulissat Fjord mouth lack of ice is also evident in Webcam images from 01/1/16 and 01/17/16 at the Hotel Arctic, with the last images, below, showing two boats plying the open water on the 16th and icebergs clogging the fjord mouth on the 17th.)  
The Sentinel-1 image from January 16th shows a significant flushing of icebergs from Ilulissat Fjord, pointed out by black arrows.  This image has better clarity and, with the icebergs scattered through the plume, indicate more clearly the plume is a water source change event, even if wind driven. The iceberg plume in the fjord has a brighter aspect due to the varied surface aspect-reflectance and has expanded down fjord.  The event must be due to or enhanced by strong offshore winds and @ruth_mottram indicates there was at least one foehn event [Readers, best to read what these are: https://en.wikipedia.org/wiki/Foehn_wind]. The plume indicates the ice melange in front of Jakobshavn has largely been removed.
In Uummannaq Bay, a very similar sequence plays out; note on January 9 the sea ice connecting islands near #4.  By January 13th, the ice at location #4 is gone.  The ice front is now at location #3, which on January 9th was well into the ice pack.  Again, we have a clear push of water leading to a concave sea ice front that is pushed well offshore. Icebergs can be seen amidst plume on January 16th; the plume opacity and size has diminished since January 13th.
In both of the January 13th images, there is a plume leading to the concave sea ice front, the question being is this sediment-laden water, with the resultant higher reflectivity, or is it a combination of a surface water change from wind or a combination? Jason Box suggests it is aeration of the surface water from the strong offshore winds. The ice must in part be driven back by a surface water push. You can see icebergs in sections of the plumes closer to shore suggesting this is a surface near surface phenomenon. This is a short-term event.  However, it could have broader implications; Moon et al. (2015) indicate the importance of a rigid ice melange at the front of tidewater outlet glaciers in Greenland.  In this case, the ice melange in front of Jakobshavn has been removed, and probably from in front of other glaciers. I look forward to further insights from the community.
20160109s01disko
RADARSAT-2 image of Disko Bay, 01/09/2016.

20160111rs02disko
RADARSAT-2 image of Disko Bay, 01/11/2016.

20160113rs02disko
RADARSAT-2 image of Disko Bay, 01/13/2016.

20160116disko
Sentinel-1 imagery of Disko Bay, 01/16/16. Notice expanded brightness area in the fjord by #1.

20160109s01uummann
 Sentinel 1 imagery of Uummannaq Bay, 01/09/2016.

20160113rs02umman
RADARSAT-2 image of Uummannaq Bay MODIS, 01/13/2016.

20160116s01uumann
Sentinel 1 imagery of Uummannaq Bay, 01/13/2016, with plume size and opacity diminishing. 

illusiat webcam 1-16-2016
Ilulissat Fjord mouth webcam view, 01/16/16.

ilulissat webcam11-17-16
Ilulissat Fjord mouth webcam view, 01/17/16.



x

Saturday, January 16, 2016

Looks like a major event in the Jakobshavn region of the Greenland's west coast sometime between Jan 10 and Jan 13, 2016

Possibly, there was some kind of subglacial lake collapse in the firn, or there was a major hill slide of ice, hard to say since there is still 24-hour darkness until the second week of March.

Below are satellite images from the manati star 


This is from January 10:
Inline image 2

This is the manati image from Jan. 14:

Inline image 1

Here is the Disko view from the DMI on January 16, 2016:









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Here it was on January 9 (notice the lack of sediment in the water):



xx


North of Jakobshavn (January 8, 2016):

http://ocean.dmi.dk/arctic/images/MODIS/Uummannaq/20160108s01a.ASAR.jpg





Monday, January 11, 2016

Melting of the surface of Greenland's ice sheet is adding to sea level rise faster than previously realized

by Tim Radford, Climate News Network, January 9, 2016

LONDON – Water may be flowing from the Greenland icecap and into the sea more quickly than anybody expected.

It doesn’t mean that global warming has got conspicuously worse: rather, researchers have had to revise their understanding of the intricate physiology of the Northern Hemisphere’s biggest icecap.

There is enough ice and snow packed deep over 1.7 million square kilometres of Greenland that, were it all to melt, would cause a rise in global sea levels of about six metres.

Climate calculations

Since the icecap is melting as the atmospheric levels of the greenhouse gas carbon dioxide rise, and global temperatures rise with them, as a consequence of the human combustion of fossil fuels, the rate at which summer meltwater gets into the oceans becomes vital to climate calculations.

The latest rethink begins not with the pools of water that collect on the surface each summer, or the acceleration of the glaciers as they make their way to the ocean, but with a granular layer of snow just below the surface, called firn.

This is old snow in the process of being compacted into glacier ice, and covers the island in a layer up to 80 metres thick.

Until now, researchers have understood this firn layer as a kind of sponge that absorbs meltwater and holds it, thus limiting the flow of melting ice into the sea.

But a new study in Nature Climate Change by researchers from the US, Denmark and the University of Zurich suggests that earlier assumptions may be wrong.

“Meltwater couldn’t penetrate vertically through the solid ice layer, and instead drained along the ice sheet surface towards the ocean”

However, the findings are not definitive, and they deliver a picture more of science in progress, rather than any long-term conclusion.

To work out how much meltwater might be stored within the pores of the firn, the scientists set up camp in 2012, 2013 and 2015 on the ice cap to use radar and to drill a series of holes 20 metres deep into the porous firn layer − also choosing sites where samples had been taken 20 years ago.

The conclusion was that meltwater is being released faster than anticipated.

Horst Machguth, a research associate in the Department of Geography at the University of Zurich, says: “Basically, our research shows that the firn reacts fast to a changing climate. Its ability to limit mass loss of the ice sheet by retaining meltwater could be smaller than previously assumed.”

Storage capacity

An extreme melt in 2012 left a sheet of solid ice, several metres thick, on top of the porous firn, in some places.

“In subsequent years, meltwater couldn’t penetrate vertically through the solid ice layer, and instead drained along the ice sheet surface towards the ocean,” says William Colgan, assistant professor in the Department of Earth and Space Science and Engineering at York University in Toronto, Canada.

“It overturned the idea that the firn can behave as a nearly bottomless sponge to absorb meltwater. Instead, we found that the meltwater storage capacity in the firn could be capped off relatively quickly.”

The implication is that sea level rise from Greenland’s icecap is liable to be higher than predicted. Just how much higher is unknown, and the next step is to confirm the latest findings and incorporate the research so far into climate models.

Since detailed research in a hostile environment is always a challenge, any clear answer may take a few years more to emerge.