Curious Correlations

Reblogged from Watts Up With That:

Guest Post by Willis Eschenbach

I got to thinking about the relationship between the Equatorial Pacific, where we find the El Nino/La Nina phenomenon, and the rest of the world. I’ve seen various claims about what happens to the temperature in various places at various lag-times after the Nino/Nina changes. So I decided to take a look.

To do that, I’ve gotten the temperature of the NINO34 region of the Equatorial Pacific. The NINO34 region stretches from 90°W, near South America, out to 170° West in the mid-Pacific, and from 5° North to 5° South of the Equator. I’ve calculated how well correlated that temperature is with the temperatures in the whole world, at various time lags.

To start with, here’s the correlation of what the temperature of the NINO34 region is doing with what the rest of the world is doing, with no time lag. Figure 1 shows which areas of the planet move in step with or in opposition to the NINO34 region with no lag.

Figure 1. Correlation of the temperature of the NINO34 region (90°-170°W, 5°N/S) with gridcell temperatures of the rest of the globe. Correlation values greater than 0.6 are all shown in red.

Now, perfect correlation is where two variables move in total lockstep. It has a value of 1.0. And if there is perfect anti-correlation, meaning whenever one variable moves up the other moves down, that has a value of minus 1.0.

There are a couple of interesting points about that first look, showing correlations with no lag. The Indian Ocean moves very strongly in harmony with the NINO34 region (red). Hmmm. However, the Atlantic doesn’t do that. Again hmmm. Also, on average northern hemisphere land is positively correlated with the NINO34 region (orange), and southern hemisphere land is the opposite, negatively correlated (blue).

Next, with a one-month lag to give the Nino/Nina effects time to start spreading around the planet, we see the following:

Figure 2. As in Figure 1, but with a one month lag between the NINO34 temperature and the rest of the world. In other words, we’re comparing each month’s temperature with the previous month’s NINO34 temperature.

Here, after a month, the North Pacific and the North Atlantic both start to feel the effects. Their correlation switches from negative (blues and greens) to positive (red-orange). Next, here’s the situation after a two-month lag.

Figure 3. As in previous figures, but with a two month lag.

I found this result most surprising. Two months after a Nino/Nina change, the entire Northern Hemisphere strongly tends to move in the same direction as the NINO34 region moved two months earlier … and at the same time, the entire Southern Hemisphere moves in opposition to what the NINO34 region did two months earlier.

Hmmm …

And here’s the three-month lag:

Figure 4. As in previous figures, but with a three month lag.

An interesting feature of the above figure is that the good correlation of the north-eastern Pacific Ocean off the west coast of North America does not extend over the continent itself.

Finally, after four months, the hemispherical pattern begins to fall apart.

Figure 5. As in previous figures, but with a four & five month lag.

Even at five months, curious patterns remain. In the northern hemisphere, the land is all negatively correlated with NINO34, and the ocean is positively correlated. But in the southern hemisphere, the land is all positively correlated and the ocean negative.

Note that this hemispheric land-ocean difference with a five-month lag is the exact opposite of the land-ocean difference with no lag shown in Figure 1.

Now … what do I make of all this?

The first thing that it brings up for me is the astounding complexity of the climate system. I mean, who would have guessed that the two hemispheres would have totally opposite strong responses to the Nino/Nina phenomenon? And who would have predicted that the land and the ocean would react in opposite directions to the Nino/Nina changes right up to the very coastlines?

Second, it would seem to offer some ability to improve long-range forecasting for certain specific areas. Positive correlation with Hawaii, North Australia, Southern Africa, and Brazil is good up to four-five months out.

Finally, it strikes me that I can run this in reverse. By that, I mean I can find all areas of the planet that are able to predict the future temperature at some pre-selected location. Like, say, what areas of the globe correlate well with whatever the UK will be doing two months from now?

Hmmm indeed …

Warmest regards to all, the mysteries of this wondrous world are endless.

w.

Comparison of global climatologies confirms warming of the global ocean

Reblogged from Watts Up With That:

Institute of Atmospheric Physics, Chinese Academy of Sciences

200635_web

IMAGE: Deployment of an APEX float from a German research ship.

Credit: Argo

The global ocean represents the most important component of the Earth climate system. The oceans accumulate heat energy and transport heat from the tropics to higher latitudes, responding very slowly to changes in the atmosphere. Digital gridded climatologies of the global ocean provide helpful background information for many oceanographic, geochemical and biological applications. Because both the global ocean and the observational basis are changing, periodic updates of ocean climatologies are needed, which is in line with the World Meteorological Organization’s recommendations to provide decadal updates of atmospheric climatologies.

“Constructing ocean climatologies consists of several steps, including data quality control, adjustments for instrumental biases, and filling the data gaps by means of a suitable interpolation method”, says Professor Viktor Gouretski of the University of Hamburg and a scholarship holder of the Chinese Academy of Sciences’ President’s International Fellowship Initiative (PIFI) at the Institute of Atmospheric Physics, Chinese Academy of Sciences, and the author of a report recently published in Atmospheric and Oceanic Science Letters.

“Sea water is essentially a two-component system, with a nonlinear dependency of density on temperature and salinity, with the mixing in the ocean interior taking place predominantly along isopycnal surfaces. Therefore, interpolation of oceanic parameters should be performed on isopycnals rather than on isobaric levels, to minimize production of artificial water masses. The differences between these two methods of data interpolation are most pronounced in the high-gradient regions like the Gulf Stream, Kuroshio, and Antarctic Circumpolar Current,” continues Professor Gouretski.

In his recent report, Professor Gouretski presents a new World Ocean Circulation Experiment/ARGO Global Hydrographic Climatology (WAGHC), with temperature and salinity averaged on local isopycnal surfaces. Based on high-quality ship-board data and temperature and salinity profiles from ARGO floats, the new climatology has a monthly resolution and is available on a 1/4° latitude-longitude grid.

“We have compared the WAGHC climatology with NOAA’s WOA13 gridded climatology. These climatologies represent alternative digital products, but the WAGHC has benefited from the addition of new ARGO float data and hydrographic data from the North Polar regions”, says Professor Gourteski. “The two climatologies characterize mean ocean states that are 25 years apart, and the zonally averaged section of the WAGHC-minus-WOA13 temperature difference clearly shows the ocean warming signal, with a mean temperature increase of 0.05°C for the upper 1500-m layer since 1984”.

Levin Interviews Dr. Patrick Michaels On Climate

From Musings from the Chiefio:

 

Fourteen minutes well spent that shows how wrong the “Climate Models” are, and why that matters to all of us due to the EPA “Endangerment Finding” being based 100% on those broken models.

I find it interesting that The Russians have a climate model that works. Wonder if it is open sourced? If anyone knows, or knows how to get a copy, let me know! It would save a lot of time trying to make one that works from the crap that doesn’t…

The Cooling Rains

Reblogged from Watts Up With That:

Guest Post by Willis Eschenbach

I took another ramble through the Tropical Rainfall Measurement Mission (TRMM) satellite-measured rainfall data. Figure 1 shows a Pacific-centered and an Atlantic-centered view of the average rainfall from the end of 1997 to the start of 2015 as measured by the TRMM satellite.

Figure 1. Average rainfall, meters per year, on a 1° latitude by 1° longitude basis. The area covered by the satellite data, forty degrees north and south of the Equator, is just under 2/3 of the globe. The blue areas by the Equator mark the InterTropical Convergence Zone (ITCZ). The two black horizontal dashed lines mark the Tropics of Cancer and Capricorn, the lines showing how far north and south the sun travels each year (23.45°, for those interested).

There’s lots of interesting stuff in those two graphs. I was surprised by how much of the planet in general, and the ocean in particular, are bright red, meaning they get less than half a meter (20″) of rain per year.

I was also intrigued by how narrowly the rainfall is concentrated at the average Inter-Tropical Convergence Zone (ITCZ). The ITCZ is where the two great global hemispheres of the atmospheric circulation meet near the Equator. In the Pacific and Atlantic on average the ITCZ is just above the Equator, and in the Indian Ocean, it’s just below the Equator. However, that’s just on average. Sometimes in the Pacific, the ITCZ is below the Equator. You can see kind of a mirror image as a light orange horizontal area just below the Equator.

Here’s an idealized view of the global circulation. On the left-hand edge of the globe, I’ve drawn a cross section through the atmosphere, showing the circulation of the great atmospheric cells.

Figure 2. Generalized overview of planetary atmospheric circulation. At the ITCZ along the Equator, tall thunderstorms take warm surface air, strip out the moisture as rain, and drive the warm dry air vertically. This warm dry air eventually subsides somewhere around 25-30°N and 25-30S of the Equator, creating the global desert belts at around those latitudes.

The ITCZ is shown in cross-section at the left edge of the globe in Figure 2. You can see the general tropical circulation. Surface air in both hemispheres moves towards the Equator. It is warmed there and rises. This thermal circulation is greatly sped up by air driven vertically at high rates of speed through the tall thunderstorm towers. These thunderstorms form all along the ITCZ. These thunderstorms provide much of the mechanical energy that drives the atmospheric circulation of the Hadley cells.

With all of that as prologue, here’s what I looked at. I got to thinking, was there a trend in the rainfall? Is it getting wetter or drier? So I looked at that using the TRMM data. Figure 3 shows the annual change in rainfall, in millimeters per year, on a 1° latitude by 1° longitude basis.

Figure 3. Annual change in the rainfall, 1° latitude x 1° longitude gridcells.

I note that the increase in rain is greater on the ocean vs land, is greatest at the ITCZ, and is generally greater in the tropics.

Why is this overall trend in rainfall of interest? It gives us a way to calculate how much this cools the surface. Remember the old saying, what comes down must go up … or perhaps it’s the other way around, same thing. If it rains an extra millimeter of water, somewhere it must have evaporated an extra millimeter of water.

And in the same way that our bodies are cooled by evaporation, the surface of the planet is also cooled by evaporation.

Now, we note above that on average, the increase is 1.33 millimeters of water per year. Metric is nice because volume and size are related. Here’s a great example.

One millimeter of rain falling on one square meter of the surface is one liter of water which is one kilo of water. Nice, huh?

So the extra 1.33 millimeters of rain per year is equal to 1.33 extra liters of water evaporated per square meter of surface area.

Next, how much energy does it take to evaporate that extra 1.33 liters of water per square meter so it can come down as rain? The calculations are in the endnotes. It turns out that this 1.33 extra liters per year represents an additional cooling of a tenth of a watt per square meter (0.10 W/m2).

And how does this compare to the warming from increased longwave radiation due to the additional CO2? Well, again, the calculations are in the endnotes. The answer is, per the IPCC calculations, CO2 alone over the period gave a yearly increase in downwelling radiation of ~ 0.03 W/m2. Generally, they double that number to allow for other greenhouse gases (GHGs), so for purposes of discussion, we’ll call it 0.06 W/m2 per year.

So over the period of this record, we have increased evaporative cooling of 0.10 W/m2 per year, and we have increased radiative warming from GHGs of 0.06 W/m2 per year.

Which means that over that period and that area at least, the calculated increase in warming radiation from GHGs was more than counterbalanced by the observed increase in surface cooling from increased evaporation.

Regards to all,

w.

As usual: please quote the exact words you are discussing so we can all understand exactly what and who you are replying to.

Additional Cooling

Finally, note that this calculation is only evaporative cooling. There are other cooling mechanisms at work that are related to rainstorms. These include:

• Increased cloud albedo reflecting hundreds of watts/square meter of sunshine back to space

• Moving surface air to the upper troposphere where it is above most GHGs and freer to cool to space.

• Increased ocean surface albedo from whitecaps, foam, and spume.

• Cold rain falling from a layer of the troposphere that is much cooler than the surface.

• Rain re-evaporating as it falls to cool the atmosphere

• Cold wind entrained by the rain blowing outwards at surface level to cool surrounding areas

• Dry descending air between rain cells and thunderstorms allowing increased longwave radiation to space.

Between all of these, they form a very strong temperature regulating mechanism that prevents overheating of the planet.

Calculation of energy required to evaporate 1.33 liters of water.

#latent heat evaporation joules/kg @ salinity 35 psu, temperature 24°C

> latevap = gsw_latentheat_evap_t( 35, 24 ) ; latevap

[1] 2441369

# joules/yr/m2 required to evaporate 1.33 liters/yr/m2

> evapj = latevap * 1.33 ; evapj

[1] 3247021

# convert joules/yr/m2 to W/m2

> evapwm2 = evapj / secsperyear ; evapwm2

[1] 0.1028941

Note: the exact answer varies dependent on seawater temperature, salinity, and density. These only make a difference of a couple percent (say 0.1043 vs 0.1028941). I’ve used average values.

Calculation of downwelling radiation change from CO2 increase.

#starting CO2 ppmv Dec 1997

> thestart = as.double( coshort[1] ) ; thestart

[1] 364.38

#ending CO2 ppmv Mar 2015

> theend = as.double( last( coshort )) ; theend

[1] 401.54

# longwave increase, W/m2 per year over 17 years 4 months

> 3.7 * log( theend / thestart, 2)/17.33

[1] 0.0299117

Fake climate science and scientists

Reblogged from Watts Up With That:

Alarmists game the system to enrich and empower themselves, and hurt everyone else

by Paul Driessen

The multi-colored placard in front of a $2-million home in North Center Chicago proudly proclaimed, “In this house we believe: No human is illegal” – and “Science is real” (plus a few other liberal mantras).

I knew right away where the owners stood on climate change, and other hot-button political issues. They would likely tolerate no dissension or debate on “settled” climate science or any of the other topics.

But they have it exactly backward on the science issue. Real science is not belief – or consensus, 97% or otherwise. Real science constantly asks questions, expresses skepticism, reexamines hypotheses and evidence. If debate, skepticism and empirical evidence are prohibited – it’s pseudo-science, at best.

Real science – and real scientists – seek to understand natural phenomena and processes. They pose hypotheses that they think best explain what they have witnessed, then test them against actual evidence, observations and experimental data. If the hypotheses (and predictions based on them) are borne out by their subsequent findings, the hypotheses become theories, rules, laws of nature – at least until someone finds new evidence that pokes holes in their assessments, or devises better explanations.

Real science does not involve simply declaring that you “believe” something, It’s not immutable doctrine. It doesn’t claim “science is real” – or demand that a particular scientific explanation be carved in stone. Earth-centric concepts gave way to a sun-centered solar system. Miasma disease beliefs surrendered to the germ theory. The certainty that continents are locked in place was replaced by plate tectonics (and the realization that you can’t stop continental drift, any more than you stop climate change).

Real scientists often employ computers to analyze data more quickly and accurately, depict or model complex natural systems, or forecast future events or conditions. But they test their models against real-world evidence. If the models, observations and predictions don’t match up, real scientists modify or discard the models, and the hypotheses behind them. They engage in robust discussion and debate.

They don’t let models or hypotheses become substitutes for real-world evidence and observations. They don’t alter or “homogenize” raw or historic data to make it look like the models actually work. They don’t hide their data and computer algorithms (AlGoreRythms?), restrict peer review to closed circles of like-minded colleagues who protect one another’s reputations and funding, claim “the debate is over,” or try to silence anyone who dares to ask inconvenient questions or find fault with their claims and models. They don’t concoct hockey stick temperature graphs that can be replicated by plugging in random numbers.

In the realm contemplated by the Chicago yard sign, we ought to be doing all we can to understand Earth’s highly complex, largely chaotic, frequently changing climate system – all we can to figure out how the sun and other powerful forces interact with each other. Only in that way can we accurately predict future climate changes, prepare for them, and not waste money and resources chasing goblins.

But instead, we have people in white lab coats masquerading as real scientists. They’re doing what I just explained true scientists don’t do. They also ignore fluctuations in solar energy output and numerous other powerful, interconnected natural forces that have driven climate change throughout Earth’s history. They look only (or 97% of the time) at carbon dioxide as the principle or sole driving force behind current and future climate changes – and blame every weather event, fire and walrus death on manmade CO2.

Even worse, they let their biases drive their research and use their pseudo-science to justify demands that we eliminate all fossil fuel use, and all carbon dioxide and methane emissions, by little more than a decade from now. Otherwise, they claim, we will bring unprecedented cataclysms to people and planet.

Not surprisingly, their bad behavior is applauded, funded and employed by politicians, environmentalists, journalists, celebrities, corporate executives, billionaires and others who have their own axes to grind, their own egos to inflate – and their intense desire to profit from climate alarmism and pseudo-science.

Worst of all, while they get rich and famous, their immoral actions impoverish billions and kill millions, by depriving them of the affordable, reliable fossil fuel energy that powers modern societies.

And still these slippery characters endlessly repeat the tired trope that they “believe in science” – and anyone who doesn’t agree to “keep fossil fuels in the ground” to stop climate change is a “science denier.”

When these folks and the yard sign crowd brandish the term “science,” political analyst Robert Tracinski suggests, it is primarily to “provide a badge of tribal identity” – while ironically demonstrating that they have no real understanding of or interest in “the guiding principles of actual science.”

Genuine climate scientist (and former chair of the School of Earth and Atmospheric Sciences at the Georgia Institute of Technology) Dr. Judith Curry echoes Tracinski. Politicians like Senator Elizabeth Warren use “science” as a way of “declaring belief in a proposition which is outside their knowledge and which they do not understand…. The purpose of the trope is to bypass any meaningful discussion of these separate questions, rolling them all into one package deal – and one political party ticket,” she explains.

The ultimate purpose of all this, of course, is to silence the dissenting voices of evidence- and reality-based climate science, block creation of a Presidential Committee on Climate Science, and ensure that the only debate is over which actions to take first to end fossil fuel use … and upend modern economies.

The last thing fake/alarmist climate scientists want is a full-throated debate with real climate scientists – a debate that forces them to defend their doomsday assertions, methodologies, data manipulation … and claims that solar and other powerful natural forces are minuscule or irrelevant compared to manmade carbon dioxide that constitutes less that 0.02% of Earth’s atmosphere (natural CO2 adds another 0.02%).

Thankfully, there are many reasons for hope. For recognizing that we do not face a climate crisis, much less threats to our very existence. For realizing there is no need to subject ourselves to punitive carbon taxes or the misery, poverty, deprivation, disease and death that banning fossil fuels would cause.

Between the peak of the great global cooling scare in 1975 until around 1998, atmospheric carbon dioxide levels and temperatures did rise in rough conjunction. But then temperatures mostly flat-lined, while CO2 levels kept climbing. Now actual average global temperatures are already 1 degree F below the Garbage In-Garbage Out computer model predictions. Other alarmist forecasts are also out of touch with reality.

Instead of fearing rising CO2, we should thank it for making crop, forest and grassland plants grow faster and better, benefitting nature and humanity – especially in conjunction with slightly warmer temperatures that extend growing seasons, expand arable land and increase crop production.

The rate of sea level rise has not changed for over a century – and much of what alarmists attribute to climate change and rising seas is actually due to land subsidence and other factors.

Weather is not becoming more extreme. In fact, Harvey was the first Category 3-5 hurricane to make US landfall in a record 12 years – and the number of violent F3 to F5 tornadoes has fallen from an average of 56 per year from 1950 to 1985 to only 34 per year since then.

Human ingenuity and adaptability have enabled humans to survive and thrive in all sorts of climates, even during our far more primitive past. Allowed to use our brains, fossil fuels and technologies, we will deal just fine with whatever climate changes might confront us in the future. (Of course, another nature-driven Pleistocene-style glacier pulling 400 feet of water out of our oceans and crushing Northern Hemisphere forests and cities under mile-high walls of ice truly would be an existential threat to life as we know it.)

So if NYC Mayor Bill De Blasio and other egotistical grand-standing politicians and fake climate scientists want to ban fossil fuels, glass-and-steel buildings, cows and even hotdogs – in the name of preventing “dangerous manmade climate change” – let them impose their schemes on themselves and their own families. The rest of us are tired of being made guinea pigs in their fake-science experiments.

Paul Driessen is senior policy advisor for the Committee For A Constructive Tomorrow (CFACT) and author of articles and books on energy, environmental and human rights issues.

Emperor Penguins “Wiped Out”

NOT A LOT OF PEOPLE KNOW THAT

By Paul Homewood

image

Thousands of emperor penguin chicks drowned when the sea-ice on which they were being raised was destroyed in severe weather.

The catastrophe occurred in 2016 in Antarctica’s Weddell Sea.

Scientists say the colony at the edge of the Brunt Ice Shelf has collapsed with adult birds showing no sign of trying to re-establish the population.

And it would probably be pointless for them to try as a giant iceberg is about to disrupt the site.

The dramatic loss of the young emperor birds is reported by a team from the British Antarctic Survey (BAS).

Drs Peter Fretwell and Phil Trathan noticed the disappearance of the so-called Halley Bay colony in satellite pictures.

It is possible even from 800km up to spot the animals’ excrement, or guano, on the white ice and then to estimate the likely size of any gathering.

But the Brunt population, which had sustained…

View original post 850 more words

Basic Science: 4 Keys to Melt Fears About Ice Sheets Melting

Reblogged from Watts Up With That:

William Ward, April 18, 2019


[HiFast BLUF:  Here’s the author’s summary/bottom line up front.] Despite the overwhelming number of popular news reports to the contrary, studies of ice sheets melting over the past century show remarkable ice stability. Using the proper scientific perspective, analysis of ice-melt rates and ice-mass losses show the ice sheets will take hundreds of thousands of years to melt, assuming the next glacial period doesn’t start first. An application of basic physics shows that for every 1 °C of atmospheric heat exchanged with the ice sheets we get a maximum 0.4 inches of SLR and a correspondingly cooler atmosphere. Over the 20th century, we observed a worst-case 4:1 ratio of consumed heat to retained atmospheric heat. It is proposed that this ratio can be used to assess potential ice-melt related SLR for a hypothetical atmospheric temperature increase scenario over the current century. Using a reasonable range for all of the variables we can estimate an SLR of between 1.4 – 6.4 inches, but our current observations support the rise being toward the lower end of that range.

The atmosphere and oceans do not show the increase in energy necessary to cause catastrophic SLR from rapidly melting ice. Humankind does not possess the technology to melt a significant amount of ice because the energy required is enormous and only nature can meter out this energy over very long periods. With the proper scientific perspective about the amount of energy required to melt ice, it should be much more difficult for Climate Alarmists to scare the public with scenarios not supported by basic science.


 

The world is drowning in articles about catastrophic sea level rise (SLR), reminding us that if the ice sheets melt, 260 feet of water will flood our coastal cities. We know that sea level today is 20-30 feet lower than it was at the end of the last interglacial period 120,000 years ago. We also know that sea level has risen 430 feet since the end of the last glacial maximum 22,000 years ago. Research shows this rise was not monotonic but oscillatory, and during periods over the past 10,000 years, sea level has been several meters higher than today. So, evidence supports the possibility of higher sea levels, but does the evidence support the possibility of catastrophic sea level rise from rapidly melting ice?

In this paper, basic science is used to show that catastrophic SLR from melting ice cannot happen naturally over a short period. Additionally, humankind does not possess the capability to melt a large amount of ice quickly even through our most advanced technology. This news should relieve the public, which is routinely deceived by reporting that misrepresents the facts. The public is susceptible to unnecessary alarmism when melt rates and ice-melt masses are presented without perspective and juxtaposed against claims that scientists are worried. This paper uses the same facts but places them in perspective to show that catastrophic risks do not exist.

Ice Sheets Melting: Deceptive Reporting

The growing alarm over melting ice sheets is directly attributable to deceptive reporting. The sheer number of reports inundates the public with an incessant message of angst. A single scientific study can be the source for headlines in hundreds of news articles. With social media repeating the news and the subsequent chorus of lectures from celebrities and politicians, we find ourselves in the deafening echo chamber of Climate Alarmism. However, it is a mistake to assume the real risks are proportional to the frequency or intensity of the message.

The primary problem is that the news writers do not have the scientific background to report on the subject responsibly, and therefore they routinely corrupt and distort the facts. Take for example an article in Smithsonian dated September 1, 2016, entitled “Melting Glaciers Are Wreaking Havoc on Earth’s Crust.” The first two sentences of the article read:

“You’ve no doubt by now been inundated with the threat of global sea level rise. At the current estimated rate of one-tenth of an inch each year, sea level rise could cause large swaths of cities like New York, Galveston and Norfolk to disappear underwater in the next 20 years.”

A sea level rise rate of one-tenth of an inch per year yields 2 inches of SLR in 20 years. Topographical maps show the lowest elevations of these cities are more than ten feet above sea level. No portion of these cities will disappear underwater from 2 inches of SLR.

The news writers seem obligated to pepper the facts with their own opinions such as “… climate change is real, undeniable and caused by humans.” It is often difficult for the reader to discern the facts from the opinions. However, even the facts become troubling because they consist of numbers without the perspective to understand their significance and are wrapped in existential angst. Consider the following excerpt from a June 13, 2018 article in the Washington Post, entitled “Antarctic ice loss has tripled in a decade. If that continues, we are in serious trouble.”

“Antarctica’s ice sheet is melting at a rapidly increasing rate, now pouring more than 200 billion tons of ice into the ocean annually and raising sea levels a half-millimeter every year, a team of 80 scientists reported… The melt rate in Antarctica has tripled in the past decade, the study concluded. If the acceleration continues, some of scientists’ worst fears about rising oceans could be realized, leaving low-lying cities and communities with less time to prepare than they had hoped.”

As reported, the reader assumes a melt rate that has tripled must be dire, and billions of tons of melting ice must be extreme. However, this perception changes if the facts are analyzed to provide perspective. An analysis shows that the original annual melt rate of 1.3 parts-per-million (ppm) has increased to nearly 4 ppm over 26 years. The news writer failed to inform us of these facts which provide perspective. The new melt rate is analogous to losing 4 dollars out of 1 million dollars. Losing slightly less than 4 parts in 1 million each year means that it will take over 250,000 years to melt entirely. No natural process is static, so we should expect variation over time. Most change is cyclical. Sometimes the ice is increasing and sometimes it is decreasing. The average person’s body mass fluctuates by 20,000 to 40,000 ppm each day. By comparison, Antarctica varying by 1-4 ppm over a year should be considered rock-solid stability in the natural world.

Ice Sheets Melting: What Happened Over the Past Century

Antarctica holds 91% of the world’s land ice, Greenland 8%, and the remaining 1% is spread over the rest of the world. Therefore, by understanding what is happening to the ice sheets in Antarctica and Greenland, we understand what is happening to 99% of the world’s land ice.

NASA is a good source for research about what is happening in Antarctica. However, two NASA agencies have recently published studies with conflicting conclusions. The Goddard Space Flight Center recently published research concluding Antarctica is not contributing to SLR. According to the study, snow accumulation exceeded ice melting, resulting in a 0.5-inch sea level reduction since 1900. Contrarily, the Jet Propulsion Laboratory (JPL) reports that the rate of Ice loss from Antarctica has tripled since 2012 and contributed 0.3 inches to SLR between 1992 and 2017. To cover the worst-case scenario, we can analyze the JPL study and provide the perspective to understand their results.

Over 26 years, Antarctica’s average annual mass loss was less than 0.00040% of its total. If Antarctica were a 220 lb man, his mass loss each year would be 0.4 grams or about eight tears. (Eight human tears weigh about 0.4 g.) At this alarming rate that makes our most elite climate scientists worried, it would take 250,185 years to melt all of the ice. It would take over 1,000 years of melting to yield 12 inches of SLR from Antarctica if we ignore natural variability and the cyclical nature of ice volume and assume the melt rate continues uninterrupted.

The best information we have about Greenland comes from a study in the journal Nature, estimating Greenland’s ice losses between 1900 – 2010. Using current ice volume estimates from USGS, we calculate the ice mass in 2010 was between 99.5% – 99.8% of what it was in 1900. Ice melt from Greenland in the 111 years contributed 0.6 – 1.3 inches to SLR. It would take over 1,300 years of melting to yield 12 inches of SLR from Greenland if we ignore natural variability and the cyclical nature of ice volume and assume the melt rate continues uninterrupted.

The average annual inland temperature in Antarctica is -57 °C and most coastal stations average -5 °C to -15 °C. The much talked about Western Antarctica averages several degrees below 0 °C. Southern Greenland does experience summer temperatures above 0 °C and seasonal melting. Northern Greenland stays below 0 °C even in the summer months, and the average annual inland temperatures are -20 °C to -30 °C. The temperatures in Greenland and Antarctica are not warm enough to support significant rapid ice melt. In the past century, we have 1 °C of retained atmospheric heat, and enough heat exchanged with ice in Greenland and Antarctica to raise sea level by 0.9 – 1.6 inches. Despite all of the reports in the media to the contrary, we have no real observations of any ice melt crisis. The past 111 years have been remarkable because of ice stability – not because of ice melting. We are 19 years into the 21st century with no evidence supporting an outcome much different from the 20th century.

Ice Sheets Melting: The Process

The lifecycle of an ice sheet begins as snow. Snow falls in the higher elevations and over time it compacts and becomes ice. The ice thickness in Antarctica is over 12,000 feet in the center of the continent and over 9,000 feet over most of East Antarctica. The force of gravity initiates a thousand-year journey where the ice flows from its heights back to the sea. At the end of this journey, when its weight can no longer be supported by the sea, it “calves” and becomes an iceberg. Some icebergs can float around Antarctica for over 30 years before fully melting. So, young ice is born inland from snow, and old ice dies near the coast from seasonal melting or after drifting for years as an iceberg. This process is the natural cycle of ice and not one which should create panic. During some periods we have more snow accumulating than ice melting, such as the period between 1300 CE and 1850 CE, known as the “Little Ice Age.” During other periods we have more ice melting than snow accumulating, such as the Medieval Warm Period and our present time.

In our present time, sunlight alone is insufficient to cause significant changes to ice sheet mass. Sunlight must act in concert with other effects such as cloud cover, water vapor and other “greenhouse” gasses such as CO2. Regardless of the mechanisms, the Earth system must do two things to melt more ice: 1) retain more heat energy and 2) via the atmosphere, transport this heat to the poles and transfer it to the ice. Additional heat energy in the system cannot melt ice unless this transport and transfer happen.

Ice Sheets Melting: Conservation of Energy

A 2007 study by Shepherd and Wingham published in Science shows the current melt rate from Greenland and Antarctica contribute 0.014 inches to SLR each year. For perspective, the thickness of 3 human hairs is greater than 0.014 inches. The results align reasonably well with the other studies mentioned. Despite the minuscule amount of actual SLR from melting ice, NOAA and the IPCC provide 21st century SLR projections that range from a few inches to several meters. The wide range of uncertainty leads to angst about catastrophe; however, the use of basic science allows us to provide reasonable bounds to the possibilities.

Before the start of the American Revolution, Scottish scientist Joseph Black (and others) solved the mysteries of specific heat and latent heat, which gives us the relationship between heat energy, changing states of matter (solid/liquid) and change of temperature. Equations 1 and 2 give us the mathematical relationships for specific heat and latent heat respectively:

(1) E = mc∆T

(2) E = mL

Where E is thermal energy (Joules), m is the mass (kg), c is the “specific heat” constant (J/kg/°C), ∆T is the change in temperature (°C), and L is the latent heat constant (J/kg). Specific heat is the amount of heat energy that we must add (or remove) from a specified mass to increase (or decrease) the temperature of that mass by 1 °C. Latent heat is the thermal energy released or absorbed during a constant temperature phase change. If we know the mass of the ice, water or atmosphere, it is easy to calculate the amount of energy it takes to change its temperature, melt it or freeze it.

Understanding that energy is conserved when melting ice, the equations above can be used to calculate the temperature effects that must be observed in the oceans or atmosphere to support an ice melt scenario. We can provide reasonable bounds and reduce the uncertainty.

See the reference section at the end of the paper for all sources and calculations.

Key #1: Importance of the Latent Heat of Fusion

It is essential to understand the latent heat of fusion because of the enormous amount of heat energy that is required to change the state of H2O from solid to liquid. Figure 1 shows the specific heat and phase change diagram for water. The blue line shows the temperature of water in °C (y-axis) plotted against the change in thermal energy in kJ/kg (x-axis). It shows how temperature and energy are related as we go from cold solid ice to boiling liquid water. The average annual inland temperature of Greenland is -25 °C and this is the reason for Point 1 on the line. If we start at Point 1 and progress to Point 2, this shows how much heat energy must be added to change the temperature of 1kg of ice from -25 °C to 0 °C. It is important to note that at Point 2, the ice is still 100% solid at 0 °C.

Figure 1: Water Phase/Specific Heat Diagram

The diagram reveals something interesting about the behavior of water. As we progress from Point 2 to Point 3, the water undergoes a phase change from solid to liquid. There is no temperature change as the ice becomes liquid water; however, a large amount of heat energy must be added. The energy that must be added to change the phase of water from solid to liquid is the latent heat of fusion. For melting ice, temperature alone does not inform us about what is happening to the system. To assess ice melting, we must understand the net change of energy. Whether we melt 1kg of ice or the entire ice sheet in Greenland, using Equations 1 and 2, we can easily calculate the energy required to do so. Going from Point 1 to Point 3 requires 3.86×105 Joules of energy for each kg of ice mass warmed and melted. For simplicity, we call this quantity of energy “E.”

Figure 1 also shows what happens as we move from Point 3 (0 °C liquid seawater) to Point 4 (seawater starting to boil at 100 °C). It takes a measure of energy “E” to move between Points 3 and 4, just as it does to move between Points 1 and 3. Therefore, as shown in Table 1, the energy required to melt the ice is equivalent to the energy required to heat the meltwater to a boil at 100 °C. (Note: the fresh water from the ice is assumed to flow to the oceans.)

Energy to melt 1kg of polar ice from -25 °C to 0 °C water <– Is Equal To –> Energy to raise the temperature of 1kg of seawater from 0 °C to 100 °C

Table 1: Relating Energy Between Polar Ice Melt and Boiling Water

Key #2: Total Energy Required to Melt the Ice Sheets

Using Equations 1 and 2, we calculate that the total heat energy required to melt the ice sheets entirely is 1.32×1025 J. This value can be given perspective by calculating the increase in ocean water temperature that would result from adding 1.32×1025 J of heat. We know that deep ocean water below the thermocline is very stable in temperature between 0-3 °C. 90% of the ocean water mass is below the thermocline. The thermocline and surface layer above contains the ocean water that responds to changes in atmospheric heat, whether that be from seasonal changes or climate changes. Therefore, if we constrain the 1.32×1025 J of heat energy to the upper 10% of the ocean mass, we calculate the temperature increase would be 25.6 °C, assuming equal heat distribution for simplicity of analysis. This increase would make the surface temperature of equatorial ocean water close to 55 °C, similar to a cup of hot coffee. Polar seas would be perfect for swimming at nearly 25 °C. According to NOAA, over the past 50 years, the average ocean surface temperature has increased approximately 0.25 °C.

Another way to give perspective is to calculate the increase in atmospheric temperature that would result from adding 1.32×1025 J of heat to the atmosphere. First, we must understand some related facts about the atmosphere. Heat energy must be transported by the atmosphere to the polar regions, or no ice can melt. However, the atmosphere’s capacity to store heat energy is extremely low compared to the energy required to melt all of the ice. The ice sheets contain more than 900 times the thermal energy below 0 °C as the atmosphere contains above 0 °C, and therefore the atmospheric heat energy must be replenished continuously to sustain ice melting. Melting polar ice with heat from the atmosphere is analogous to filling a bathtub with a thimble. The low specific heat of air is one reason the atmosphere lacks heat carrying capacity. The other reason is its low mass.

Figure 2 shows the vertical profile of the Earth’s atmosphere. The red line in Figure 2 shows the temperature of the atmosphere in °C (x-axis) plotted against the altitude in km (y-axis). 75% of the mass of the atmosphere is contained in the Troposphere, where all life (outside of the oceans) exists on Earth. Figure 2 reveals that most of the atmosphere is far too cold to melt ice. We can ignore the Upper Thermosphere as the mass of atmosphere contained in that layer is negligibly small. Only the Lower Troposphere below 2.5 km altitude contains air at a warm enough temperature to melt ice. (See the region of the graph enclosed in the yellow oval.) 35% of the atmospheric mass exists below 2.5 km, and the average temperature is ~ 8 °C.

Figure 2: Vertical Profile of Earth’s Atmosphere

Using Equation 1 with E = 1.32×1025 J, the mass of the atmosphere below 2.5 km and solving for ∆T, we can calculate what the temperature of the air below 2.5 km would be if it contained the energy required to melt all of the ice. The atmospheric temperature would have to be 7,300 °C, which is 1,522 °C hotter than the surface of the sun. Life on Earth would be in jeopardy from the increased atmospheric heat long before all of the ice melted. While there are no plausible thermodynamic pathways to heat the Earth’s atmosphere to such temperatures, the calculations of energy required are accurate. According to NASA, the global average temperature over the past 50 years has increased approximately 0.6 °C.

Key #3: SLR From Incremental Atmospheric Heat Exchange with Ice Sheets

It is said, “you can’t have your cake and eat it too.” Similarly, you can’t have atmospheric heat and melt with it too. If the ice consumes heat, then the atmosphere cools. If the atmosphere retains its heat, then no ice melts. So, let’s examine some scenarios where we trade energy from the atmosphere with ice to see how much corresponding SLR we can get.

Using Equation 1, we can determine the change in energy for a 1 °C temperature decrease in the atmosphere below 2.5km. We can then apply this energy to the ice, assume maximum melting volume and translate that to SLR. For every 1 °C of atmospheric energy transferred to the ice, we get 0.4 inches of SLR. Some IPCC scenarios project a 4 °C rise in “global average temperature” in the 21st century, due to increased atmospheric CO2. An increase in temperature does not melt any additional ice unless the heat is transferred to the ice. If 4 °C of energy from the atmosphere is transferred to the ice, we get a corresponding 1.7 inches of SLR and an atmosphere that is 4 °C cooler. If we transfer all of the energy in the atmosphere above 0 °C to the ice, then we get 3.4 inches of SLR and a world where the entire atmosphere is at or below 0 °C. The global average temperature would be 6 °C less than the coldest experienced during the depth of a glacial period.

To raise sea level by 12 inches would require the atmosphere to heat up by 28 °C before exchanging that energy with the ice. As we would experience it, the atmosphere would have to heat up by some incremental value, then exchange that incremental value of energy with the ice, thus cooling the atmosphere, and then repeat this process until the 28 °C of atmospheric heat is consumed.

Key #4: Maximum Ice Melt Potential from Technology

Keys #1-3 don’t offer much to support the possibility of large quantities of ice being melted rapidly by natural causes. The next obvious question is, can humankind generate enough heat with our most advanced technology to melt a significant amount of ice rapidly?

The power of the atom is one of the most awesome powers humankind has harnessed. There are 8,400 operational nuclear warheads in the world’s nuclear arsenal, with a total yield of 2,425 Megatons of TNT. It is interesting to note that the energy contained in this nuclear arsenal is over 800 times the equivalent explosive power used in World War II. It is said that there are enough nuclear weapons to destroy the world a hundred times over. So, perhaps this is enough energy to melt the ice sheets entirely. For this exercise, we assume the nuclear weapons release their energy slowly – only fast enough to melt ice and no faster. For maximum melting, we evenly distribute all of the weapons in the ice. However, when we convert 2,425 MT to Joules, we get a number that is far below the energy required to melt all of the ice. The SLR we could get by using all of the world’s nuclear weapons for melting ice would be 0.002 inches. For reference, the diameter of a human hair is 2.5 times thicker than this. If we want all of the ice to melt, we need to duplicate each weapon more than 1,300,000 times. So, it looks like our current arsenal of nuclear weapons is no match for the ice.

What other sources of power does humankind have that could be used to melt a significant amount of ice? The annual global energy production of electric power is 25 petawatt-hours (25×1015 Whr) or 9×1019 Joules. If we could, through some advanced technology, transfer all electric energy generated over one year to heaters buried in the ice, and do this with no transmission or distribution losses, then how much ice could we melt? The answer is 0.02 inches of SLR (equivalent to 4 human hair diameters). This scenario would require that humans not use any electric power for that entire year, for anything other than melting ice. Humanity would have to forego the benefits of electric power for over 146,000 years to melt all of the ice, assuming static conditions in the ice.

Ice Sheets Melting: Analysis

Since 1900 we have 1 °C of retained atmospheric heat, and enough heat consumed by the ice sheets to produce 0.9 – 1.6 inches of SLR. From Key #3 we learned 1.7 inches of SLR results from trading 4 °C of atmospheric heat for ice melting. Therefore, as a worst-case approximation, if there had been no net ice melt since 1900, the atmosphere would have heated by approximately 5 °C. We can conclude that ice melting consumed 4 °C of heat, leaving the atmosphere with 1 °C of retained heat. We observed a 4:1 ratio of consumed heat to retained heat in the 20th century, worst case. For the best-case approximation, we use the lower estimate of 0.9 inches of SLR, which yields a 2:1 ratio of consumed heat to retained heat over the same period. In one of the more extreme scenarios, the IPCC climate model projects 4 °C of atmospheric temperature rise in the 21st century. For a 4 °C rise scenario, using the worst-case ratio of consumed to retained heat, we can estimate a 6.4 inch SLR over that period. In a more moderate scenario, the IPCC projects a 1.5 °C temperature rise. For a 1.5 °C rise, using the best-case ratio of consumed to retained heat, we can estimate an SLR of 1.4 inches. Unfortunately, none of the climate models have been able to predict the climate accurately, and none of them backtest successfully. We are one-fifth of the way through the 21st century and do not appear to be on course for the IPCC’s worst-case temperature projections. Therefore, it is reasonable to assume the results for the 21st century will likely be very similar to the 20th century, with 1-2 inches of SLR.

Detailed analysis of the claimed Earth energy imbalance is beyond the scope of this paper. The analysis presented here exposes the effects that must occur from an imbalance that leads to catastrophic melting. The ice must absorb large quantities of heat energy for sustained periods. Therefore, inland temperatures over Antarctica and Greenland would need to be maintained well above 0 °C for significant portions of the year. Atmospheric heat lost to the ice would need to be continually replenished to perpetuate the process. The oceans store heat energy, but the large mass of the oceans with the high specific heat of seawater blunts the possible effects from that energy. The energy that would raise the first 2.5 km of atmospheric air by 1 °C would raise the first 1,000 feet of seawater by only 0.0035 °C. The 2nd law of thermodynamics requires a temperature difference to transfer heat energy. Small increases in ocean temperature cannot lead to large movements of heat energy to an already warmer atmosphere. Finally, the system must transport more heat energy to the polar regions. In reality, the Earth maintains a very large temperature gradient between the equator and the poles. Our observations do not show gradient changes that would support significant additional heat transport. Without the increased energy storage and transport, and sustained polar temperatures well above freezing, catastrophic ice melt scenarios are not possible.

Ice Sheets Melting: Summary

Despite the overwhelming number of popular news reports to the contrary, studies of ice sheets melting over the past century show remarkable ice stability. Using the proper scientific perspective, analysis of ice-melt rates and ice-mass losses show the ice sheets will take hundreds of thousands of years to melt, assuming the next glacial period doesn’t start first. An application of basic physics shows that for every 1 °C of atmospheric heat exchanged with the ice sheets we get a maximum 0.4 inches of SLR and a correspondingly cooler atmosphere. Over the 20th century, we observed a worst-case 4:1 ratio of consumed heat to retained atmospheric heat. It is proposed that this ratio can be used to assess potential ice-melt related SLR for a hypothetical atmospheric temperature increase scenario over the current century. Using a reasonable range for all of the variables we can estimate an SLR of between 1.4 – 6.4 inches, but our current observations support the rise being toward the lower end of that range.

The atmosphere and oceans do not show the increase in energy necessary to cause catastrophic SLR from rapidly melting ice. Humankind does not possess the technology to melt a significant amount of ice because the energy required is enormous and only nature can meter out this energy over very long periods. With the proper scientific perspective about the amount of energy required to melt ice, it should be much more difficult for Climate Alarmists to scare the public with scenarios not supported by basic science.

References

NASA Study: Mass Gains of Antarctic Ice Sheet Greater than Losses: https://www.nasa.gov/feature/goddard/nasa-study-mass-gains-of-antarctic-ice-sheet-greater-than-losses

Ramp-up in Antarctic ice loss speeds sea level rise: https://climate.nasa.gov/news/2749/ramp-up-in-antarctic-ice-loss-speeds-sea-level-rise/?fbclid=IwAR2Vnkbxxa-NTU_v0lRUUGGDffMs4Q6BGvHX-KHzcHM7-q2B7IO59wCEiQc

Sea Level and Climate (Fact Sheet 002-00): https://pubs.usgs.gov/fs/fs2-00/

Spatial and temporal distribution of mass loss from the Greenland Ice Sheet since AD 1900: https://www.nature.com/articles/nature16183

Recent Sea-Level Contributions of the Antarctic and Greenland Ice Sheets: http://science.sciencemag.org/content/315/5818/1529

All of the constants and calculations are provided in the associated Excel file located here: https://wattsupwiththat.com/wp-content/uploads/2019/04/Ice-Atmosphere-Ocean-Energy-20190407-1-1.xlsx

Inconvenient stumps

Reblogged from Watts Up With That:

Climate alarmists tell us that the Earth has never been warmer, and that we can tell by looking at tree rings, treelines, and other proxy indicators of climate.

Climate scientists claim the warmth is unprecedented.

We’ve been told it is warming so fast, we have only 12 years left!

Yet nature seems to not be paying attention to such pronouncements, as this discovery shows.

This photo shows a tree stump of White Spruce that was radiocarbon dated at 5000 years old. It was located 100 km north of the current tree line in extreme Northwest Canada.

The area is now frozen tundra, but it was once warm enough to support significant tree growth like this.

If climate was this warm in the past, how did that happen before we started using the fossil fuels that supposedly made our current climate unprecedentedly warm?

A simple demo of order and chaos; Climate Models are not so simple

Here’s a fascinating example of oscillating systems.

In this demonstration 15 independent cyclic systems with different periods begin in phase, then watch how the total system departs from being in phase to apparent chaos to split phases and so on.

Now consider this demonstration as a model for all the contributors, big and small, to Earth’s climate–certainly more than the 15 billiard balls depicted here. And put the balls on springs of varying elasticity (permitting varying periods). And then allow the balls to hit each other (adding the third dimension to their oscillation and…..energy transfer).

Try to model and predict that!

Predicting heat waves? Look half a world away

Reblogged from Watts Up With That:

[HiFast Note:  This study identifies the Madden-Julian Oscillation (MJO) and correlates one of its phases to California heat waves.  Nothing really new here.  Joe Bastardi has been talking about the MJO for many years.]

charles the moderator /

When thunderstorms brew over the tropics, California heat wave soon to follow

University of California – Davis

An orchard of young trees withstands drought in California's Central Valley in 2014. The ability to predict heat waves in the Central Valley could help better prepare and protect crops and people from the impacts. Credit UC Davis

An orchard of young trees withstands drought in California’s Central Valley in 2014. The ability to predict heat waves in the Central Valley could help better prepare and protect crops and people from the impacts. Credit UC Davis

When heavy rain falls over the Indian Ocean and Southeast Asia and the eastern Pacific Ocean, it is a good indicator that temperatures in central California will reach 100°F in four to 16 days, according to a collaborative research team from the University of California, Davis, and the Asia-Pacific Economic Cooperation (APEC) Climate Center in Busan, South Korea.

The results were published in Advances in Atmospheric Sciences on April 12.

FROM PREDICTION TO PROTECTION

Heat waves are common in the Central California Valley, a 50-mile-wide oval of land that runs 450 miles from just north of Los Angeles up to Redding. The valley is home to half of the nation’s tree fruit and nut crops, as well as extensive dairy production, and heat waves can wreak havoc on agricultural production. The dairy industry had a heat wave-induced economic loss of about $1 billion in 2006, for instance. The ability to predict heat waves and understand what causes them could inform protective measures against damage.

“We want to know more about how extreme events are created,” said Richard Grotjahn, corresponding author on the paper and professor in the UC Davis Department of Land, Air and Water Resources. “We know that such patterns in winter are sometimes linked with areas of the tropics where thunderstorms are enhanced. We wondered if there might be similar links during summer for those heat waves.”

The scientists analyzed the heat wave data from June through September from 1979 to 2010. The data were collected by 15 National Climatic Data Centers stations located throughout the Valley. From these data, the researchers identified 24 heat waves. They compared these instances to the phases of a large, traveling atmospheric circulation pattern called the Madden-Julian Oscillation, or MJO.

The MJO manifests as heavy rain that migrates across the tropical Indian and then Pacific Oceans, and researchers have shown that it influences winter weather patterns.

TROPICAL RAINFALL AND CALIFORNIA

“It’s well known that tropical rainfall, such as the MJO, has effects beyond the tropics,” said Yun-Young Lee of the APEC Climate Center in Busan, South Korea, the paper’s first author. “So a question comes to mind: Is hot weather in the Central California Valley partly attributable to tropical rainfall?”

Lee and Grotjahn found that, yes, enhanced rainfall in the tropics preceded each heat wave in specific and relatively predictable patterns. They also found that hot weather in the valley is most common after more intense MJO activity in the eastern Pacific Ocean, and next most common after strong MJO activity in the Indian Ocean.

“The more we know about such associations to large-scale weather patterns and remote links, the better we can assess climate model simulations and therefore better assess simulations of future climate scenarios,” Grotjahn said.

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This work was supported by the National Science Foundation, the National Aeronautics and Space Administration, the Department of Energy Office of Science, the United States Department of Agriculture’s National Institute of Food and Agriculture, and the APEC Climate Center in the Republic of Korea.