Month: April 2017

Uncategorized 18 Apr 2017

Another New Paper Confirms Global Warming Pause

via The Global Warming Policy Forum (GWPF)
http://www.thegwpf.com

The “uncertainty monster” strikes again

We’ve been highly critical for some time of the paper in summer 2015 by Karl et al. that claimed “the pause” or hiatus went away once “properly adjusted” ocean surface temperature data was applied to the global surface temperature dataset. Virtually everyone in the climate skeptic community considers Karl et al. little more than a sleight of hand.

No matter, this paper published today in Nature Climate Change by Hedemann et al. not only confirms the existence of “the pause” in global temperature, but suggests a cause, saying “…the hiatus could also have been caused by internal variability in the top-of-atmosphere energy imbalance“.

That’s an important sentence, because it demonstrates that despite many claims to the contrary, CO2 induced forcing of the planetary temperature is not the control knob, and natural variability remains in force.

Also of note, see the offset as designated by the two colored X’s in Figure 1:

Models and observations don’t even begin to match.

The subtle origins of surface-warming hiatuses

Christopher Hedemann, Thorsten Mauritsen, Johann Jungclaus & Jochem Marotzke
Nature Climate Change (2017) doi:10.1038/nclimate3274
Received 12 July 2016 Accepted 17 March 2017 Published online 17 April 2017

During the first decade of the twenty-first century, the Earth’s surface warmed more slowly than climate models simulated1. This surface-warming hiatus is attributed by some studies to model errors in external forcing2, 3, 4, while others point to heat rearrangements in the ocean5, 6, 7, 8, 9, 10caused by internal variability, the timing of which cannot be predicted by the models1. However, observational analyses disagree about which ocean region is responsible11, 12, 13, 14, 15, 16. Here we show that the hiatus could also have been caused by internal variability in the top-of-atmosphere energy imbalance. Energy budgeting for the ocean surface layer over a 100-member historical ensemble reveals that hiatuses are caused by energy-flux deviations as small as 0.08 W m−2, which can originate at the top of the atmosphere, in the ocean, or both. Budgeting with existing observations cannot constrain the origin of the recent hiatus, because the uncertainty in observations dwarfs the small flux deviations that could cause a hiatus. The sensitivity of these flux deviations to the observational dataset and to energy budget choices helps explain why previous studies conflict, and suggests that the origin of the recent hiatus may never be identified.

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(paywalled)

Full post

EUROPE TO HAVE A LATE COLD SNAP

via climate science
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This piece tells us that central Europe is going to have a late cold spell due to winds coming down from the Arctic. This was the opposite of what was being forecast a few weeks ago.

via climate science http://ift.tt/2jXH2Ie

April 17, 2017 at 06:30PM

Uncategorized 18 Apr 2017

Global Greening in the New York Times (CO2 benefits contradict SCC)

via Master Resource
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… Dr. [J. Elliott] Campbell and his colleagues have discovered that in the last century, plants have been growing at a rate far faster than at any other time in the last 54,000 years. Writing in the journal Nature, they report that plants are converting 31 percent more carbon dioxide into organic matter than they were before the Industrial Revolution. The increase is because of the carbon dioxide that humans are putting into the atmosphere, which fertilizes the plants, Dr. Campbell said.

– Carl Simmer, A Global Greening, New York Times, April 5, 2017.

There are benefits, not only costs, to the human influence on climate. Photosynthesis from carbon dioxide (CO2) emissions is part of this.

Expect the benefits of CO2 to show up in a recalculation of the “social costs” of the enhanced greenhouse effects, which will dramatically lower the Obama-era estimates that looked at (exaggerated) costs, not benefits.

Who can forget the excellent video by the Greening Earth Society back in 1992, which was updated in 1998. I remember showing this video to Enron executives who were pushing the climate issue for political profits. Stunned, one sadi: “Wait, if this is true, then we should be subsidizing coal.” To which I though to myself: “Yes, but skip the subsidies and just call it even.”

Posts at MasterResource have documented the neglected side of increasing atmospheric concentrations of carbon dioxide:

Hero or Villain: The Myth of Harmful CO2

CO2 Coalition: Time to Play Offense

Goklany for COP21: The Wonders and Happy Data of Carbon Dioxide (CO2)

CO2 Benefits Exceed Costs by … 50:1, more?

Carbon Dioxide: The Green Greenhouse Gas of Life (and ‘miracle molecule’)

U.S. Rejection of CO2 Emission Cuts: Just Do the Math (16% and falling ….)

55 Positive Externalities: Hail to Atmospheric CO2 Enrichment

Back to the recent New York Times piece. After confirming the greening of Planet Earth, caveats are added that make this anthropogenic factor negative (and for the article to be published by the Times!)

“It is still an open question what plants will do in years to come if carbon dioxide emissions continue to rise,” the article states. “More carbon dioxide might spur even more growth.” Then comes the warning:

But many climate models project that plants will suffer as temperatures rise and rainfall patterns shift. Despite the extra carbon dioxide, worldwide plant growth may fall, and plants will no longer help to buffer the impact of global warming.

“I’ve been referring to this as a carbon bubble,” Dr. Campbell said. “You see ecosystems storing more carbon for the next 50 years, but at some point you hit a breaking point.”

Still, a half-century of continued global greening will be a powerful benefit versus the (speculative) cost of “a breaking point.”

Let the fun and games begin on a more realistic comparison of benefits and costs in the “social cost of carbon” (SCC).

————

The Times piece by Carl Simmer, A Global Greening, is reproduced in full (in green font, of course):

For decades, scientists have been trying to figure out what all the carbon dioxide we have been putting into the atmosphere has been doing to plants. It turns out that the best place to find an answer is where no plants can survive: the icy wastes of Antarctica.

As ice forms in Antarctica, it traps air bubbles. For thousands of years, they have preserved samples of the atmosphere. The levels of one chemical in that mix reveal the global growth of plants at any point in that history.

“It’s the whole Earth — it’s every plant,” said J. Elliott Campbell of the University of California, Merced.

Analyzing the ice, Dr. Campbell and his colleagues have discovered that in the last century, plants have been growing at a rate far faster than at any other time in the last 54,000 years. Writing in the journal Nature, they report that plants are converting 31 percent more carbon dioxide into organic matter than they were before the Industrial Revolution.

The increase is because of the carbon dioxide that humans are putting into the atmosphere, which fertilizes the plants, Dr. Campbell said. The carbon in the extra plant growth amounts to a staggering 28 billion tons each year. For a sense of scale, that is three times the carbon stored in all the crops harvested across the planet every year.

“It’s tempting to think of photosynthesis at the scale of the entire planet as too large to be influenced by human actions,” said Christopher B. Field, the director of the Stanford Woods Institute for the Environment, who was not involved in the study. “But the story here is clear. This study is a real tour de force.”

Starting in the Industrial Revolution, humans began to pump carbon dioxide into the atmosphere at a prodigious rate. Since 1850, the concentration of the gas has increased over 40 percent.

Since plants depend on carbon dioxide to grow, scientists have long wondered if that extra gas might fertilize them. The question has been hard to answer with much certainty.

For one thing, a plant relies on more than just carbon dioxide. It also needs water, nitrogen and other compounds. Even with a perfect balance of nutrients, plants may grow at different rates depending on the temperature.

To get some real-world measurements of plant growth, some scientists have built enclosures so that they can determine the precise amounts of carbon dioxide as well as the growth of plants. They can even run experiments by flooding the enclosures with extra carbon dioxide.

Trees and other plants in these enclosures have indeed grown faster with more carbon dioxide. But it has been hard to extend these results to the planet as a whole. Scientists found that plants responded differently to carbon dioxide in different parts of the world. The logistical challenge of these experiments has mostly limited them to Europe and the United States, leaving huge swaths of forests in the tropics and the far north little studied.

More recently, scientists have turned to satellites to get clues to what plants have been doing. They have measured how green the land is, and from that data they have estimated the area covered by leaves.

But this method has its shortcomings, too. Satellites cannot see leaves hiding under clouds, for example. And the size of leaves serves as only a rough guide to a plant’s growth. If a plant builds bigger roots, that growth will be hidden underground.

In the mid-2000s, atmospheric scientists discovered a powerful new way to measure plant growth: by studying an unimaginably rare molecule called carbonyl sulfide.

Carbonyl sulfide — a molecule made of a carbon atom, a sulfur atom and an oxygen atom — is present only in a few hundred parts per trillion in the atmosphere. That is about a million times lower than the concentration of carbon dioxide. Decaying organic matter in the ocean produces carbonyl sulfide, a gas that then floats into the atmosphere.

Plants draw in carbonyl sulfide along with carbon dioxide. As soon as it enters their tissues, they destroy it. As a result, the level of carbonyl sulfide in the air drops as plants grow.

“You can see it in real time,” said Max Berkelhammer, an atmospheric scientist at the University of Illinois at Chicago. “In the morning when the sun rises, they start to pull it out.”

This discovery led scientists to go to Antarctica. The air that reaches the South Pole is so well mixed that its carbonyl sulfide level reflects the worldwide growth of plants.

It is more challenging to interpret the more recent record in the ice. Since the Industrial Revolution, humans have added extra carbonyl sulfide through textile manufacturing and other activities. This infusion of carbonyl sulfide has raised levels of the gas in the ice over the past century.

But Dr. Campbell and his colleagues found that it hasn’t increased very much. As we have been adding carbonyl sulfide to the atmosphere, plants have been pulling it out. In fact, the scientists found, they have been pulling it out at a staggering rate.

“The pace of change in photosynthesis is unprecedented in the 54,000-year record,” Dr. Campbell said. While photosynthesis increased at the end of the ice age, he said, the current rate is 136 times as fast.

With all that extra carbon dioxide going into plants, there has been less in the air to contribute to global warming. The planet has warmed 1.4 degrees Fahrenheit since 1880, but it might be even hotter if not for the greening of the Earth.

Dr. Berkelhammer, who was not involved in the new study, said the research would serve as a benchmark for climate projections. “It means we can build more accurate models,” he said.

To test out climate models, researchers often go back to the historical record and see how well they can replay it. Now they can see if their models project plants growing at the rate observed by Dr. Campbell and his colleagues.

It is still an open question what plants will do in years to come if carbon dioxide emissions continue to rise.

More carbon dioxide might spur even more growth. But many climate models project that plants will suffer as temperatures rise and rainfall patterns shift. Despite the extra carbon dioxide, worldwide plant growth may fall, and plants will no longer help to buffer the impact of global warming.

“I’ve been referring to this as a carbon bubble,” Dr. Campbell said. “You see ecosystems storing more carbon for the next 50 years, but at some point you hit a breaking point.”

The post Global Greening in the New York Times (CO2 benefits contradict SCC) appeared first on Master Resource.

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April 17, 2017 at 06:07PM

Uncategorized 17 Apr 2017

New ‘Karl-buster’ paper confirms ‘the pause’, and climate models failure

via Watts Up With That?
http://ift.tt/1Viafi3

Also of note, note the offset as designated by the two colored X’s in Figure 1:

Models and observations don’t even begin to match.

The subtle origins of surface-warming hiatuses

Christopher Hedemann, Thorsten Mauritsen, Johann Jungclaus & Jochem Marotzke
AffiliationsContributionsCorresponding author
Nature Climate Change (2017) doi:10.1038/nclimate3274
Received 12 July 2016 Accepted 17 March 2017 Published online 17 April 2017

During the first decade of the twenty-first century, the Earth’s surface warmed more slowly than climate models simulated¹. This surface-warming hiatus is attributed by some studies to model errors in external forcing^{2, 3, 4}, while others point to heat rearrangements in the ocean^{5, 6, 7, 8, 9, 10}caused by internal variability, the timing of which cannot be predicted by the models¹. However, observational analyses disagree about which ocean region is responsible^{11, 12, 13, 14, 15, 16}. Here we show that the hiatus could also have been caused by internal variability in the top-of-atmosphere energy imbalance. Energy budgeting for the ocean surface layer over a 100-member historical ensemble reveals that hiatuses are caused by energy-flux deviations as small as 0.08 W m⁻², which can originate at the top of the atmosphere, in the ocean, or both. Budgeting with existing observations cannot constrain the origin of the recent hiatus, because the uncertainty in observations dwarfs the small flux deviations that could cause a hiatus. The sensitivity of these flux deviations to the observational dataset and to energy budget choices helps explain why previous studies conflict, and suggests that the origin of the recent hiatus may never be identified.

From the Introduction:

The surface temperature of the Earth warmed more slowly over the period 1998–2012 than could be expected by examining either most model projections or the long-term warming trend1. Even though some studies now attribute the deviation from the long-term trend to observational biases17, 18, the gap between observations and models persists. The observed trend deviated by as much as −0.17 °C per decade from the CMIP5 (Coupled Model Intercomparison Project Phase 5; ref. 19) ensemble-mean projection1—a gap two to four times the observed trend. The hiatus therefore continues to challenge climate science.

Key excerpts:

…

The coupled climate model MPI-ESM1.1 is forced with CMIP5-prescribed historical forcing from 1850 until 2005, and extended until 2015 with the RCP4.5 scenario (see Methods). When the red line lies above the grey line, at least one ensemble member is experiencing a hiatus, defined as a deviation of more than 0.17 °C per decade below the ensemble mean. This deviation is the same as the gap between the CMIP5 ensemble mean (black cross) and the observed (yellow cross) GMST trends for the period 1998–2012. Contours represent the number of ensemble members in bins of 0.05 °C per decade.

…

From our analysis of observational estimates, we are unable to exclude the TOA anomaly as a possible cause of the recent hiatus. Referencing the observations to an alternative energy budget (rather than that of the large ensemble) could shift the absolute position of the green and yellow crosses in Fig. 3c. However, their relative distance from one another and the size of their error bars would not change.

The role of the TOA and the ocean in each hiatus can be determined by comparing their relative contributions to the flux-divergence anomaly. For hiatuses in the large historical ensemble, the negative (cooling) anomaly is caused entirely by the TOA in 12% of cases and by the ocean in 24% of cases. In the remainder (64%), the negative anomaly is caused by the TOA and ocean acting together (bottom left quadrant of Fig. 3c). TOA variability is therefore involved in 76% of all hiatuses.

…

We conclude that the TOA may have been a source of significant internal variability during the hiatus. Our conclusions are not an artefact of model-generated TOA variability29—the large ensemble produces TOA variability that is similar to that in the observational record (Supplementary Fig. 7). Rather, our conclusions are based on a simple yet robust principle, namely that the Earth’s surface layer has a small heat capacity. The surface temperature can therefore be influenced by small variations in the large yet mutually compensating fluxes that make up this layer’s energy budget. Comparing the small variability in the TOA imbalance with the total TOA imbalance under global warming27, 30 obscures the significance of these small variations for the hiatus.

…

(bold mine)

This is the true dilemma at the heart of the hiatus debate: the variability in ocean heat content alone has no power to explain the hiatus, and the measure that can—the surface-layer flux divergence—is dwarfed by observational uncertainty. While there are attempts to fill the gaps in observations with ocean reanalyses such as ORAS4 (refs 9,23), the resulting data are of questionable integrity during the hiatus14, 21 and, as we show, disagree with the budget based on CERES21 and WOA22. Even if these disagreements could be reconciled, the process of anchoring satellite observations with ocean heat uptake makes the contributions from TOA and ocean difficult to disentangle, because their absolute difference is unknown. Therefore, unless the uncertainty of observational estimates can be considerably reduced, the true origin of the recent hiatus may never be determined.

Code availability.
The MPI-ESM1.1 model version was used to generate the large ensemble and is available at http://ift.tt/2psH4yN. Computer code used in post-processing of raw data has been deposited with the Max Planck Society: http://ift.tt/2oiCHCC.

Data availability.
Raw data from the large ensemble were generated at the Swiss National Computing Centre (CSCS) and Deutsches Klimarechenzentrum (DKRZ) facilities. Derived data have been deposited with the Max Planck Society (http://ift.tt/2oiCHCC). Supplementary Fig. 7 uses TOA flux reconstructions provided by R Allan40 (http://ift.tt/2psvDH6) and satellite observations provided by the NASA CERES project31 (http://ift.tt/1dTAKQn). For observational estimates in Fig. 3c, we make use of data provided by the NOAA World Ocean Atlas22(http://ift.tt/2pshXMu) and by the ECMWF Ocean Reanalysis System 4 (ref. 9; http://ift.tt/2oiMvfR).

PDF files
Supplementary Information (3,616 KB)

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April 17, 2017 at 11:22AM