Guest Post by Erl Happ
The subject of this post is climate change in the place where I live. The climate has changed in the last sixty years and there is a widespread notion that man is at fault. It’s on the edge of a big desert. Much of the land is salty and the clearing of native vegetation has brought more salt to the surface. There is less rain. Looks like desertification is in process. Many well meaning people point the finger at farmers and we have a ban on the clearing of further native vegetation and a very active forest preservation movement.
In a report at: http://insciences.org/article.php?article_id=8586 we have a description of a paper published in the Journal of Climate, May 2010.
“CSIRO statistician Dr Yun Li and climate physicists Professor Jianping Li and Juan Feng from the Chinese Academy of Sciences remark that since the mid-1970s south-west Western Australia has seen a 15-20 per cent decrease in average winter rainfall, from 323 mm in 1925-1976 to 276 mm from 1976-2003.
South-west WA – a vast area which includes Perth, the Margaret River wine region and the West Australian wheat belt – receives most of its annual rainfall during winter from passing cold fronts and storms. However, since the mid-1970s, the number of storms in the region have decreased leading to less rainfall with the drier conditions being exacerbated due to more high pressure systems entering the area.
Modelling suggests a decrease in mean annual rainfall of 7 per cent and a 14 per cent reduction in surface water runoff in the period 2021 to 2050 relative to the period 1961 to 1990. If current climate trends continue, south-west WA will potentially experience 80 per cent more drought-months by 2070.”
The alarm has also been sounded in relation to sea levels. The increase in sea level on the west coast has been 8 mm per year, about four times that on the east coast. See: http://www.watoday.com.au/environment/sea-levels-could-rise-a-metre-by-2100-20110523-1ezf0.html
Is this just a case of what Leif Svalgaard calls ‘confirmation bias’, namely that ‘you misconstrue to see what you wish’. Is the Commonwealth Scientific and Industrial Research Organization simply projecting on the basis of past experience and a misunderstanding of the science? Is this what is to be expected from a research organization (CSIRO, NASA) funded out of the public purse? Is the notion that this part of the globe is on the way to perdition supportable?
Analysis
The past can be a guide to the future if it informs us as to how the system works. The analysis that follows is based upon observation of historical change. Secondly it is based on an understanding of the elementary laws of gas behavior. Thirdly it is informed by farmers perception that form usually follows function.
All data from http://www.esrl.noaa.gov/psd/cgi-bin/data/timeseries/timeseries1.pl
A full screen version of each figure can be seen by simply clicking on that figure.
Figure 1 Sea level pressure by latitude in 1948-57 and 2001-2010. Mb
Since 1948 the global atmosphere has shifted north.
Figure 2 Change in sea level pressure by latitude Mb.
The loss of air pressure at 60-90° south is matched by an increase elsewhere but most particularly at 30-40° south in the latitude of the winds that bring rain to the South West of Western Australia. This is where the fronts should appear. In a ‘front’ air of Antarctic origin lifts moist air of tropical origin causing rain.
Figure 3 Pressure differential between source and sink latitudes for the planetary winds Mb.
The loss of pressure at 60-70° south and the gain at 30-40° south enhances the pressure differential driving the westerly winds with the effect of:
· Enhancing the flow of the circumpolar current, driving water northwards along the western coasts of the southern continents and raising sea levels as it does so and indeed across the global ocean to the north. Sea level falls in the Southern Ocean, the largest expanse of ocean world-wide.
· Reducing the northward penetration of the polar lows that form on the margins of Antarctica that are responsible for frontal rainfall as they meet humid tropical air traveling southwards.
Figure 4
Figure 4 shows the temperature at 10hPa in the polar stratosphere over Antarctica. A dramatic stepwise increase in the winter minimum temperature occurred in 1976-79. Mid 1976 marks the transition from the weak solar cycle 20 to the very active cycle 21. A coincidence?
Figure 5 Change in surface pressure and 10hPa temperature in the region of the southern annular mode of inter-annual climate variation driven by the coupled circulation of stratosphere and troposphere over Antarctica.
In Figure 5 above, we see a seasonal bias to pressure loss and temperature gain. The temperature of the upper stratosphere (brown) increased between June and March. It is in July and August that the most severe pressure loss is recorded and temperature gain peaks the month after. July and August are months for peak rainfall in Western Australia.
Figure 6 Relationship between sea level pressure near Antarctica vis-a-vis the Indian Ocean to the south-west of Western Australia
We see that the episodic loss of atmospheric pressure at 60-70° south is associated with an increase in atmospheric pressure in the Indian Ocean to the south east of Western Australia.
The bigger picture: ENSO
At latitude 60-70° south, ozone is driven into the troposphere by the coupled circulation of the stratosphere and the troposphere over Antarctica. The pattern of pressure anomalies is described as the Southern Annular Mode (SAM) and can be tracked using the Antarctic Oscillation Index (AOI). This phenomenon lies behind the change evident in figures 1 and 2. Notice the decline in Antarctic pressure evident in the brown line in figure 6. The loss of atmospheric pressure over Antarctica relates directly to temperature change in the stratosphere. If the temperature of the upper stratosphere increases it is because there is more ozone in circulation. In consequence atmospheric pressure must fall at 60-70° south.
There is a circularity in the phenomenon. Temperature changes in the stratosphere primarily in response to a change in pressure affecting the rate of feed of NOx from the mesosphere via the night jet. So, a change in pressure raises ozone levels, pressure falls further as the atmosphere warms in response to the presence of ozone, so the night jet is affected and ozone levels increase again, so pressure must fall at 60-70°south. The circulation is so strong and persistent that it produces the lowest atmospheric pressures seen on the entire planet and acts like a bellows shifting the atmosphere to and from Antarctica and indeed all latitudes south of 50° south.
It is plain that the increase in sea level atmospheric pressure in the region to the south and west of Western Australia is due to atmospheric processes causing pressure loss in Antarctica. Loss off pressure indicates a shift in atmospheric mass. The latitude 30-40°south gains atmospheric mass as part of this process.
Figure 7 Southern Oscillation index and sea level pressure in the Indian Ocean to the south-west of Western Australia
In figure 7 we see an interesting relationship between the Southern Oscillation Index (inverted) and sea level pressure to the south-west of Western Australia. Now, remember that the SOI records the changing relationship between surface pressure in a couple of small towns in the Pacific. This change in pressure relations happens to coincide with the warming and cooling of the Pacific and the tropics generally. This is like the canary in the coal mine. The pressure change here represents a sample, and a very tiny sample at that, of the state of the global atmosphere. The SOI is really a relic of 19th Century climate science. I don’t mean to slight Mr Walker, we actually need more like him. He was a big picture man working with very little data.
Notice the stepwise increase in the SOI after 1978, plainly associated with the stepwise increase in stratospheric temperature in Antarctica. Observe the slow recovery in the SOI over the next forty years. In 2011 the SOI has set a new peak (a trough in this graph because the SOI is inverted) in relation to the entire record since 1948. This is La Nina territory. Plainly sea level pressure off Western Australia is due for a fall. When it falls, rainfall will recover and sea level will decline.
Thinking Thinking
This post shows a strong link between Antarctic surface pressure, the ENSO phenomenon, Western Australia rainfall and the level of the sea in relation to the land.
If we are to understand these phenomena we must understand the drivers of Antarctic surface pressure. There is nothing internal to the climate system that can account for what appears to be a 120 year swing in Antarctic surface pressure and the strength of the Westerly winds in the southern hemisphere. As I have illustrated at: http://wattsupwiththat.com/2011/08/20/the-character-of-climate-change-part-3/ cloud cover and sea surface temperature is driven by changes in surface pressure at 60-70° south latitude. Leif Svalgaard tells me that this is a well understood phenomenon. Strangely, I have never seen it explained in print. Perhaps he misconstrued what I was saying. It happens.
If you want to find the place where the stone falls into the water, look for the splash. Examine the ripples spreading out from that point. In the climate pond the biggest splash is in Antarctica. Look again at figure 1 and figure 8 below.
Figure 8 Temperature in the Antarctic stratosphere at 80-90°south
Where in Antarctica is the biggest splash and the associated ripples? The biggest splash is at the top of the stratosphere where the night jet introduces oxides of nitrogen from the mesosphere. Why do the ripples exhibit a less spiky, more organic form at the bottom of the stratosphere than at the top? It’s because of the influence of the coupled circulation that modulates ozone and temperature. It has least influence at the top of the stratosphere where the night jet rules supreme.
Now just in case you have been told that heating of the stratosphere is associated with ‘Planetary Waves’ or ‘tropical convection’ that might be considered to be internal to the system, consider figure 8 but also 9 and 10, the latter showing monthly temperature anomalies as a departure from the 1948-2011 average.
Figure 9 Monthly anomalies at various pressure levels in the Antarctic Stratosphere at 80-90°S 2008-2011
Figure 10 Monthly anomalies at various pressure levels in the Antarctic stratosphere at 80-90°S in 1948-50
It is plain that the temperature of the stratosphere changes first and to the greatest extent at the highest altitude and that change propagates downward. It also appears that temperature at 10hPa tends to jump in November as the Arctic circulation cuts in, the cooling of the Arctic atmosphere and the warming of the Antarctic atmosphere robbing Antarctica of atmospheric mass. The atmosphere is one big pond. The Antarctic represents the strongest circulation. In general you can expect the Antarctic to be deterministic, but here we see the Arctic saying its piece.
And the $64,000 question? What causes the jerks in atmospheric pressure that initiate the transfer of mass from Antarctica and to a lesser extent from the Arctic? We know that the coupled circulation amplifies the process. But what starts it off? This is the question to be resolved if we are to understand and predict climate change. Who do we know that should be able to tell us about the importance of plasma and electromagnetic influences 0n the location of the atmosphere?
And here is a $6 question? Why is there less ozone in the southern stratosphere than in the northern stratosphere? Is it partly because it is continually being wasted into the troposphere and attacked by oxides of nitrogen from the mesosphere? Has anyone ever suggested that?
Conclusion
To take this post back to where it started, we can say that the decline in rainfall and increase in sea surface temperature in the south-west of Western Australia is plainly reversible. There is no reason to imagine that the trend of the last forty years should continue.
The sky will not fall.
Discover more from Watts Up With That?
Subscribe to get the latest posts sent to your email.
Thanks, Erl.
A few points though:
i) The Antarctic shows a slow decline in stratospheric temperatures from the late 70s to date during active cycles 21 to 23 and a slow rise over the period to the late 70s when the sun was a little less active during cycle 20 so that is consistent with my proposal. I agree that the discontinuity in the late 70s requires an explanation but that could be the result of an internal system shift in energy transfer distribution.
ii) I don’t agree that the positions of the jets are inconsequential. The surface pressure distribution is a key indicator of the rate at which energy is being transferred from surface to space and from equator to poles by non radiative means.
iii) I don’t think any part of what I say is a figment of my imagination. Some points that I make are a little speculative but only because no one has a proper handle on the processes going on in the upper atmosphere.However the observations that I refer to are what they are regardless.
iv) I don’t regard the polar vortex as the same as the polar front. The polar front is merely the boundary of the polar vortex at the surface. I agree that the Antarctic region is more influential overall than the Arctic region.
v) I agree that the flux in global cloud cover is critical. I don’t agree that the mechanism I propose is unclear. Poleward jets are seen to be more zonal jets with shorter lines of interaction between air masses and larger cloud free descending air masses in the air circulation cells either side of the equator. That results in less global cloudiness when the system is warming and more not less energy getting into the global oceans. The poleward shift of the jets is indeed a system response but it is a response capable of negating the additional energy being received into the system by accelerating the rate of energy transfer to space. The opposite during a cooling period when the jets are more equatorward.
We are not far apart in the way that we are looking at the system but in order to match observations I have had to conclude that certain features of the system are of opposite sign to that generally proposed. I accept that that puts me out on a limb in certain respects and I await more observations to resolve the issues one way or another. Suffice it to say that I think there are bigger problems in the observations for the conventional viewpoint than for the viewpoint that I propose.
The main difference between us is that you seem to share the conventional view that an active sun should warm the stratosphere globally and an inactive sun allow it to cool. For the reasons set out in my article I cannot see that to be the case in light of actual observations.
I think the point of balance of energy flux in the vertical structure of the atmosphere is at about 45km (the stratopause approximately) where Joanna Haigh notes that from 2004 to 2007 the sign of the atmospheric ozone response to the solar changes became the opposite of what was expected (more ozone at a time of inactive sun rather than less). We need to wait and see what has happened since 2007 in the regions above 45km.