Guest essay by David Archibald
There is now consensus that the Sun has now entered a quiet period. The first paper from the solar physics community predicting the current quiet period was Schatten and Tobiska’s 2003 paper “Solar Activity Heading for a Maunder Minimum?”. To date, Solar Cycle 24 has shown similar maximum SSN amplitudes to that of Solar Cycle 5, the first half of the Dalton Minimum:
Figure 1: Solar Cycle 24 relative to the Dalton Minimum
But what comes beyond that? Predicting the amplitude of Solar Cycle 24 was big business in the solar physics community with a total of 75 forecasts. There is only one forecast of the amplitude of Solar Cycle 25 to date. That forecast is Livingstone and Penn’s prediction of a maximum amplitude of seven. The first forecast, by Libby and Pandolfi, of the current quiet period is now over 40 years old. The fact that Libby and Pandolfi’s prediction got the detail of temperature changes to date right gives great credibility to it. Written in 1979, they forecast a warming trend for the rest of the 20th century followed by a cold snap that might well last throughout the first half of the 21st century. Specifically, Dr Libby is quoted by the Los Angeles Times as saying,
“we see a warming trend (by about a quarter of 1 degree Fahrenheit) globally to around the year 2000. And then it will get really cold – if we believe our projections. This has to be tested.” How cold? “Easily one or two degrees,” she replied, “and maybe even three or four degrees.”
The Libby and Pandolfi forecast was based on isotope ratios in tree rings and dates from a time before the corruption of tree ring science.
One commercial consequence of lower solar activity is that satellites will last longer in their orbits. Another is that agricultural production in the mid-latitudes will be affected. One of the most productive agricultural regions on the planet is the Corn Belt of the United States. Modern corn hybrids are tuned around maximizing the yield from the growing conditions experienced in the Corn Belt over the last 30 years with Growing Degree Days (GDD) to maturity ranging from 2200 to 2700. GDD is calculated from the day of planting by adding the maximum and minimum daily temperature in Fahrenheit, dividing by two and then subtracting 50 to produce the result. If the overnight minimum is less than 50°F, 50°F is used. The maximum is capped at 86°F as corn plants don’t grow any faster above that temperature. Daily temperature records for the Corn Belt start about 1900. The following graph shows the accumulation of GDDs for the periods 1901 – 1910 and 2001 – 2010 for Whitestown just northeast of Indianapolis in the southeast end of the Corn Belt:
Figure 2: Cumulative GDD for Whitestown, Indiana 1901 – 1910 and 2001 – 2010
The graph assumes a common planting date of 27th April. The blue lines are the years 1901 – 1910 and the red lines are the years 2001 – 2010. They all stop on the date of first frost. Most of the growing seasons last decade had plenty of heat to get to maturity with up to 1,000 GDD in excess of the requirement at 2,500 GDD. A century before, the margin of safety was far less. Normal first frost for Whitestown is 10th October. A century ago the earliest frost was five weeks before that on 3rd September, 1908. Similarly, in the latter period the earliest date to get to 2,500 GDD was 15th August. In the earlier period the last date to get to 2,500 GDD was almost six weeks later at 28th September.
Farmers can adjust the type of crop they grow to suit their climatic expectations. Yield is directly proportional to GDD though as shown by the following graphic of corn and soybeans:
Figure 3: Yield relative to GDD (CHU) for Corn and Soybeans Source: Andy Bootsma, 2002: Potential Impacts of Climate Change on Eastern Canada
If a farmer plants a 2,200 GDD corn crop in the expectation of a cool or short season and the season turns out to have been capable of growing a 2,500 GDD, then he has foregone about 12% of the value of the later maturing variety. If he plants a 2,500 GDD variety and the season falls short though, most of the value of the crop will be lost. Wheat and barley require about 1,600 GDD and 1,400 GDD respectively. The highest wheat yield in Indiana in 2012 was 74 bushels/acre whereas the highest corn yield was 159 bushels/acre. Another factor in predicting grain output is the ability to switch to winter wheat in which a crop is planted in early September, germinates and then lies dormant under the snow blanket until the following spring.
A study in the 1980s of the effect of lower temperatures on Canadian wheat production found that a 1°C decrease would reduce the frost-free period by 15 days and that a 2°C decrease would not allow the crop to ripen before the first frost. Canadian wheat farmers have assured me though that they could switch to winter wheat and have a higher yield. In Manitoba, for example, the yield might be 71 bushels per acre for winter wheat compared to 51 bushels per acre for spring wheat. Growing winter wheat is riskier than spring wheat in that a hard frost before the first snow could kill the crop.
A further complication in trying to determine what the coming decline in temperature will do to grain production is that the area of the Corn Belt approximates to the region that was scraped flat by the Laurentide ice sheet. After the Wisconsin Glacier receded, the glaciated soils of the Midwest that are primarily north of Interstate 70 were covered with several feet of wind-blown loess deposits that came from the Great Plains that lie east of the Rockies. In Northern Illinois for example, in an area north of I-80, six to eight feet of loess deposits overlie glacier till. These soils are all primarily silt loam, silty clay loam, clay loam and clay. The water holding capacity of these soils are about 2 inches per foot. The counties in the Corn Belt with the highest productivity have deep fertile soils. Most of these soils were covered with prairie grass that over time raised the organic matter levels to between 2% and 5%. The resulting biological activity that developed in these soils made them very productive. These counties are also watered by natural rainfall that results from the Gulf of Mexico Pump. As the weather fronts move from west to east across the Rockies, we have the Great Plains that are mostly arid, but by the time the fronts reach eastern Nebraska, the moisture from the Gulf of Mexico is sucked north by the counter-clockwise flow of air that rotates around the low pressure fronts and drops the rain on the Midwest when it hits the cooler air from the north. Therefore the Corn Belt has the optimum combination of soil type, temperature and moisture. As growing conditions shift south, the soil types won’t be as good.
Friis-Christianson and Lassen theory enables us to predict temperature for a solar cycle if we know the length of the solar cycle preceding it. Thus Solheim et al have been able to predict that the average global temperature over Solar Cycle 24 will be 0.9°C lower than it was over Solar Cycle 23. Polar amplification also plays a part such that Svalbard, for example, in winter will experience a 6°C decline in temperature. Work on temperature records in the northeast United States suggest that the temperature decline in prospect for the Corn Belt is 2.0°C for Solar Cycle 24.
We can cross-check this expectation against modelled historic Total Solar Irradiance (TSI) data. Lean et al produced a reconstruction of TSI back to 1610. That is shown in Figure 4 following. Also shown is Livingstone and Penn’s prediction for Solar Cycle 25 amplitude converted to TSI by scaling against the Maunder Minimum. Shaviv in 2008 found empirically that a 1 watt/m2 change in TSI was associated with (as opposed to cause directly) in a 0.6°C change in global average temperature. A fall in solar activity to levels reached in the Dalton Minimum, as per Lean’s data, would result in a decline of global temperature of 1.2°C, a little more than what Solheim’s group is projecting. Solar Cycle 4, the cycle preceding the Dalton Minimum, was 13.6 years long, about a year longer than Solar Cycle 23. Libby and Pandolfi’s prediction of a temperature decline of up to 4°F translates to 2.2°C. Through TSI, this would require a fall of 3.7 watts/m2 which is greater than the range in Lean’s modelled data for the period since 1610. This may mean that Libby and Pandolfi are correct and Lean’s model needs adjusting.
Figure 4: Projecting the decline in Total Solar Irradiance
Working through the effect on GDDs, a return to TSI conditions of the Dalton Minimum can be expected to reduce US corn production by perhaps 20% to 25%. This equates to the increase in corn production over the last ten years from mandated ethanol. US grain and soybean production of about 500 million tonnes per annum is sufficient to feed 1.2 billion vegetarians. The amine profile of wheat can be approximated by a diet of 70% corn and 30% soybeans, otherwise those things are fed to animals at about a 25% protein conversion efficiency. Corn and soybeans would be the diet of involuntary vegetarianism. The rest of the world does not have the luxury of US agriculture’s latent productivity.
Figure 5: US Corn and Wheat Prices 1784 to 2013
Figure 5 shows the effect of the low temperatures of the Dalton Minimum on corn and wheat prices in the United States. The absolute peak was associated with the eruption of Mt Tambora. Also evident is the period of high and volatile prices associated with the cold temperatures of the mid-19th century.
Figure 6: Major wheat exporting countries
A return to the climatic conditions of the Dalton Minimum is likely to take Russia, Kazakhstan and the European Union out of the export market. The other countries will have some reduction in wheat available for export. Colder is also drier and thus a number of major grain producers such as India and China, currently largely self-sufficient, will experience shortfalls from their requirements.
Figure 6: Imports and exports of grain by continent
Figure 6 above shows net exports of grain by continent with the Arab countries as a separate region. Those countries are the biggest grain importing block on the planet. Soybeans are not included in this graphic. China has become the major soybean importer at 60 million tonnes per annum. In terms of protein content, that equates to about 180 million tonnes of wheat per annum. The Chinese convert those soybeans to animal protein in the form of pig meat.
Countries in the Middle East North Africa (MENA) region have been in the news recently. Further detail on their import dependency is shown in Figure 6 following.
Figure 6: MENA region domestic and imported grain by country
In Figure 6, the population size of each country is shown by the size of the bar. The blue component of the bar shows how much of each country’s grain requirement is grown domestically and the red component denotes the imported share. Countries are shown from west to east as per the map. A proportion of the Egyptian population already suffers from malnutrition. A current wheat prices, it costs about $1 per day to keep someone fed in terms of bulk grain. The oil exporting countries in the graphic can afford to feed their populations, with some countries feeding others as well. Saudi Arabia has been keeping Yemen above water and more recently took on Egypt too.
Figure 7: An animal model of population growth and collapse
All the countries of the MENA region have seen their populations grow to well in excess of their inherent carrying capacity. A combination of deteriorating climate and ongoing world population growth can be reasonably expected to cause a spike in grain prices to levels last seen in the 19th century. It is also possible that sufficient grain may not be available at any price in some regions. Populations models from the animal kingdom provide some guidance as to how events might unfold. A good example is the snowshoe hare and lynx of North America. The snowshoe hare population collapses to less than 10% of its peak on a roughly ten year cycle, followed by the lynx. Taking the example of Egypt, the current population is twice the level that can be supported by its grain production. If the food supply to that country falls below the minimum required to maintain public order, then the distribution system for diesel and fertiliser will break down and domestic grain production would also be affected.
The starving populations of Egyptian cities will fan out into the countryside and consume whatever they can chew which will include the seed grain. That will ensure that domestic grain production will collapse. The population of Egypt might fall to 10% of its carrying capacity which would be 5% of its current level. Any starvation in the MENA region is likely to trigger panic buying by other governments in the region and beyond with consequent effects on established trade patterns.
UPDATE:
The Excel spreadsheet for the Whitestown data used in this essay is here Whitestown-all-years (.xlsx file)
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We now have tremendous ability to modify the characteristics of plants by direct genetic modification, instead of the slow trial and error process of selective breeding.
While cooler conditions probably could not be entirely compensated for, developing cold resistance could be the next growth area for plant research.
ian005 says:
September 8, 2013 at 1:16 pm
True. Sometimes people just starve in place. That happened in the Irish potato famine. The last major starvation event was in the 1967 drought in India with 1 million dead. And the Chinese were able to starve 45 million people to death in the Great Leap Forward and hold society together. One the other hand the Swiss ate their domestic animals in 1816 and started chewing on leather. Will the Egyptians go quietly into that good night? No, I think they will eat their seed grain.
In respect of Figure 7, the relationship can be given by Lotka–Volterra equation like this:
http://en.wikipedia.org/wiki/Lotka%E2%80%93Volterra_equation
dx/dt = x(alpha – beta y)
dy/dt = – y(gamma – delta x)
The question is a lag between the peaks. In other words, how much time do we have before the system breaks down?
David Archibald says:
September 8, 2013 at 2:53 pm
Absolutely not. Post it up in public for everyone to see, along with the details on the origin of the data itself, or it ain’t science.
w.
Gary Pearse says:
September 8, 2013 at 3:06 pm
And just what do you imagine that they are planting in Canada, Gary … hot weather strains?
w.
David Archibald says:
September 8, 2013 at 3:23 pm
David Archibald says:
September 8, 2013 at 3:26 pm
David. I fear that you’re the one who needs more rigor. The corn yield in Canada is 83,611 Hg/Ha, and that of the US is 77,442 Hg/Ha (source FAO).
Or take another example. The wheat yield in the US is 31,140 Hg/Ha, and that of Ireland is 63,061 Hg/Ha.
In other words, things are nowhere near as simple as you imagine them to be, and your claim that cold automatically equals less production is totally contradicted by the actual yield data.
w.
I believe all the problems discussed in the article are basically political not physical. Sunspots have very little affect on the body politic.
Kip Hansen says:
September 8, 2013 at 3:15 pm
Involuntary vegetarianism will keep the circus going for a bit longer. Animal protein will get a lot more expensive. But a large proportion of the planet currently spends about half their income on food. What happens when the price goes up? As for thinking and planning, the EPA is currently trying to shut down the US coal industry on the basis of voodoo science. That is one thing – the Obama administration promised it and they are delivering on their promise. But where is the clamor against it? In this country, the major airline, Qantas, two years ago shut down many flights because they saw a wisp of dust in the air from a volcano 20,000 km away in Chile. It is one thing for government departments to be run by arts graduates with no life experience, it is another for a major commercial enterprise to harm its customers and shareholders because of voodoo. These people can’t have played outside as children. There will not be any thinking and planning. There will only be reaction to events. Clumsy and stupid reaction to unexpected events, such as the climate returning to its normal condition.
Some papers for/against the impact of solar cycles on food prices.
Influence of Solar Activity on State of Wheat Market in Medieval EnglandA. Pustilnik, Gregory Yom Din
Possible Space Weather Influence on the Earth Wheat Markets
On Possible Influence of Space Weather on Agricultural Markets: Necessary Conditions and Probable Scenariosm, L. Pustil’nik and G. Yom Din
On the insignificance of Herschel’s sunspot correlation Jeffrey J. Love
Willis Eschenbach says:
September 8, 2013 at 3:59 pm
Corn growing conditions in Canada are more favourable than those in the US? Think, Willis, think.
2 points
1. GDD isn’t the limiting factor in some important wheat producing areas. Rather it’s soil moisture. Here in Western Australia, a cooler climate would result in increased yields. In addition, there are large areas that are currently not used for agriculture which could be brought into production in a cooler and wetter climate.
2. Like Doug Proctor, my main concern is a large volcanic eruption at the wrong time. Over timescales of years to decades I have no doubt we could adapt to cooling. Although with short term problems in the MENA, and with ample cheap energy.
IMO the triple whammy of artificially high energy costs, climate cooling, and a volcanic eruption is likely what will get us into serious food supply trouble.
“””””……Henry Clark says:
September 8, 2013 at 12:54 pm
george e. smith says:
September 8, 2013 at 12:29 pm
“The amplitude of the annual cycling for the modern warm period, is clearly significantly higher than the amplitude during the earlier period in the 1850 to 1910 period. yet the value differs by about 1 w/m^2; less than 0.1%”
Figure 4 in this article incorrectly states 1 W/m^2 per 0.6 degrees Celsius while strangely attributing that particular number to Dr. Nir Shaviv. …….”””””
Henry, Nothing you wrote has anything to do with the fact that the annual cycle in TSI, due simply to the variation in the sun earth distance, should have an amplitude that is proportional to the mean TSI value, which is only 0.1% different between the 1850-1910 period, and the modern warm period, yet the graph shows much more amplitude difference than that; maybe 50 times as much amplitude difference.
Finland & Estonian Famines 1695-97
Lack of stored food can rapidly result in famine.
Finland lost about 30% of its population and Estonia about 20% in the Great Famine of 1695-97.
Neumann, J.; Lindgrén, S. (1979). “Great Historical Events That Were Significantly Affected by the Weather: 4, <a href=The Great Famines in Finland and Estonia 1695–97″. Bulletin of the American Meteorological Society 60 (7): pp775–787. doi:10.1175/1520-0477(1979)0602.0.CO;2. ISSN 1520-0477.
David,
Here’s a link to the original paper
Libby, L. M. & L. J. Pandolfi. (1974) Temperature Dependence of Isotope Ratios in Tree Rings. Proc. Nat. Acad. Sci. USA Vol. 71, No. 6, pp. 2482-2486.
While steel grain bins are ubiquitous in North America, some countries can suffer losses of harvested crop exceeding 50% in population boom years for rats, mice, or other vermin.
Improving storage thus offers another method of ensuring food supplies even if the crops themselves are less productive.
Interesting article, but just as the earth is much more adaptive to factors affecting global temperatures, the human population is also very creative and adaptive in times of crisis. There will not be a massive food problem like you are suggesting here (unless all the governments in the world take over the food production systems, then we are doomed). The capitalistic system will provide us with all the food we need. Remember there are many millions of acres in South America that could be put into production if the incentive was there. And this is only one of the many changes that could result in more food production. If you scare too many people the elites will try to take over just like they are trying for global warming.
I’ll just be happy if we go back to 1970s temps. That should shut the AGWers up for good and completely end this nonsense.
(Simpleton alert)
We have better transportation now than back when people starved to death due to the climate. If the Vikings had the transportation available to them that we have now, they might still be here.
The grain belt moves south, so what? We can still move the foodstuffs where they need to go.
If I have to eat grass-fed animals instead of grain-fed animals, I will still be fed.
If these “projections” do have some validity, ramp up CO2 production world-wide so the plant matter has a better chance.
I really wish people would stop complaining about Ethanol production. It’s not that bad. If you have ever seen the crappy grain that gets delivered to those plants that produce ethanol, you might not wish to eat grain yourself. It comes from the bottom of the pile and filled with bugs and dirt. They clean it up, get some energy out of it and then feed it to livestock that tastes really good.
This is just more fear-mongering. IMHO.
A few thoughts from a guy who has lived in Manitoba for more than four decades. Farmers know that the two most important dates are the last frost in spring and the first frost in fall. For the last two decades Canada Agriculture has worked hard on developing “85 day corn”. Only because of price has corn acreage expanded greatly in the last few years. Yes, we do have 85 day corn- it took a lot of sequential breeding. The GDD are still important, but primarily to beat the frost. Any change that may occur regarding cooling probably can be accommodated by Canadian seed. However, we don’t have 75 day corn, so Canada would drop out of the corn production.
Crop options are wider than most folks think. We have short and long season Canola, a wide variety of barley and wheat, and even some short season specialty crops. In the long term, precipitation is a greater determinant of yield than temperature. Our water situation is always a matter of too much or too little- with too little being the biggest problem. Last and first frost, however, can trump all other factors. A few hundred GDDs after a first frost are useless.
http://3.bp.blogspot.com/_zkLPSWe75rc/TTIIxnWgnfI/AAAAAAAAAHo/FAj5IINeqLw/s1600/Corn%2Bpile%2Bat%2Bgrain%2Belevator.JPG
David:
You cited a number of events – Irish potato famine, Indian famine of 1967 (which undoubtedly was one of the events driving Ehrlich’s views in the early 1970s), and the Chinese GLF fiasco. In the latter case, the famine was driven by political, not solar or climactic, events – rather like the Ukrainian famine of 1932-34, where the Soviets’ collectivization policies included deliberate starvation of an unwilling populace. The issue for India in 1967 was infrastructure related and political mismanagement of a crisis, as much as it was absolute lack of food. Can climatically-driven food shortages cause political collapse or drive societal change? Yes, of course: Fernand Braudel and the Annales School of historical analysis consider the events of the longue durée as the essential ingredients driving societal change. Is it inevitable? No. Likely? Hard to say and certainly hard to predict. Your final paragraph, to me, smacked of alarmism and nothing more. Unfortunately, it puts you squarely in the company of Ehrlich (and Hansen, and other fellow travelers). It detracts from the analysis, rather than adds to it. It is speculation (rather wildly expressed, at that) and nothing more.
I have worked with these issues for decades including all the issues discussed here. I have even studied the correlations with sunspots and Lynx cycles. (the pattern relates to the 11 year solar cycle (8 to 14 year variance).
http://drtimball.com/2011/tipping-points-are-natural-environmentalists-exploit-them/
The big issue and in my opinion the big mistake made in this article is the pattern of food production is not a function of temperature, except in extreme years like 1816, the “year with no summer.” The critical issue for world food production is the pattern of precipitation in the middle latitudes (35 to 60° latitude). That is a ‘wet’ and ‘dry’ cycle with the only variance being the intensity of the dry cycles.
Beyond the incorrect focus on temperature as a determinant of yields there is the assumption that a solar cycle will manifest in all climate data for the entire globe.
The pattern of crop yields in the middle latitudes are determined by the precipitation pattern which is coincident with the 22 year sunspot cycle. This was identified years ago and was the underpinning, although he didn’t know about the connection, for the Kondratieff Cycle
http://www.angelfire.com/or/truthfinder/index22.html
I have published about the relationship between the 22 year cycle and the drought sequence.
“Climatic Change, Droughts and Their Social Impact: Central Canada, 1811-20, a classic example.” In C.R.Harington (ed) The Year Without a Summer? World Climate in 1816. 1992, National Museum of Natural Sciences, Canadian Museum of Nature, Ottawa
I also identified how the droughts alternate between ‘cold’ droughts with only slightly elevated temperatures, lower precipitation and moderate wind increases, and ‘hot’ droughts with high temperatures, low precipitation and very strong winds. These hot droughts correlate with the Kondratieff Cycle.
The IPCC has the world focussed on CO2 and temperature – it is time to recognize the importance of H2O and precipitation.
Tim Ball says:
September 8, 2013 at 7:32 pm
You are correct to emphasize drought rather than temperature. Well do I recall the severe drought year of 1977 in the Pacific Northwest, not equaled since, although 2001 came closest. All was made clear to me in 1997 with the discovery of the PDO.
I already was as sure as I could be that CACA was utter nonsense, but discovery of the Pacific & Atlantic oscillations clinched it for me.
Thanks David, good work. You show a small rise in Australian exports which I think is correct. It should be noted that much of this export grain currently goes to the middle east. Its often aussie wheat that’s milled in Cairo. Thus the rise in export from Australia may help a little in the middle east. The catch is the profitability of the Australian farmers and the stability of the subsidies in the middle east itself. I’m not expecting much reform in the middle east politically and while, with capitalisation their farming could be much more productive, again thats not likely. Islam’s ban on interest bearing loans cripples its rural capitalisation.
One item of good news is that we are seeing new crops, some of which are well suited to changed climate and land that is normaly not arrible. Nupa, Distichlis palmeri, has been bred up in stocks as a UN responce to sea level rise. Since sea level rise is a no show the seed stock of Nupa could be retasked in area’s of high salt risk, Its a Halophyte grain that can be irrigated with sea water in most latitudes. A significant yeald could be possible in the Delta and on the desert coasts feeding egypt, etc. The choice would be famine or a new crop. Both the Dalton and Maunder minimum are periods of new crop experimentation in many parts of the world. We need to push that solition again.
@David Archibald
David,
Why do you have to use the term ‘consensus’ to describe the current low solar activity? Does anyone currently deny that SC24 is the smallest observed solar cycle in 100 years?
Observation trumps prediction, so who cares what Schatten predicted in 2003? And why do you keep using that fake “SIDC data” (in Figure 1) to prove that SC24 resembles SC5? (Leif pointed out the same error to you in July, but you still keep claiming it is “SIDC data”: http://wattsupwiththat.com/2013/07/28/solar-cycle-24-update-2/#comment-1373256)
Actually, SC24 most closely resembles SC14 (looking at the real SIDC data):
http://www.solen.info/solar/cycl5.html
http://www.solen.info/solar/cycl14.html
http://www.solen.info/solar/images/cycles23_24.png
But there was no cooling in 1902-1913, was there? So perhaps your motive in mentioning SC5 and the Maunder and Dalton periods, was to link your argument to the historical fact that these solar minima also coincided with cooler temperatures.
But this might give the false impression that there is some kind of ‘consensus’ that the current low solar activity will also lead to lower temperatures. The truth is that there is no consensus that this historical cooling was caused by low solar activity. Yes, it is being actively debated and investigated. But no one has a convincing explanation of this historical correlation of cooling and low solar magnetic activity.
So please get your facts straight, and quit trying to use alarmist tactics to persuade us that there will be too much cooling.
😐