For the last 10 years, I have consulted for grain growing interests, providing information about past and potential future trends in growing season weather that might impact crop yields.
Their primary interest is the U.S. corn belt, particularly the 12 Midwest states (Iowa, Illinois, Indiana, Ohio, Kansas, Nebraska, Missouri, Oklahoma, the Dakotas, Minnesota, and Michigan) which produce most of the U.S. corn and soybean crop.
Contrary to popular perception, the U.S. Midwest has seen little long-term summer warming. For precipitation, the slight drying predicted by climate models in response to human greenhouse gas emissions has not occurred; if anything, precipitation has increased.
Corn yield trends continue on a technologically-driven upward trajectory, totally obscuring any potential negative impact of “climate change.”
What Period of Time Should We Examine to Test Global Warming Claims?
Based on the observations, “global warming” did not really begin until the late 1970s. Prior to that time, anthropogenic greenhouse gas emissions had not yet increased by much at all, and natural climate variability dominated the observational record (and some say it still does).
Furthermore, uncertainties regarding the cooling effects of sulfate aerosol pollution make any model predictions before the 1970-80s suspect since modelers simply adjusted the aerosol cooling effect in their models to match the temperature observations, which showed little if any warming before that time which could be reasonably attributed to greenhouse gas emissions.
This is why I am emphasizing the last 50 years (1970-2019). This is the period where we should have seen the strongest warming, and as greenhouse-gas emissions continue to increase, it is the period of most interest to help determine just how much faith we should put in model predictions for changes in national energy policies.
In other words, quantitative testing of the greenhouse warming theory should be during a period when the signal of that warming is expected to be the greatest.
50 Years of Predictions vs. Observations
Now that the new CMIP6 climate model experiment data are becoming available, we can begin to get some idea of how those models are shaping up against observations and the previous (CMIP5) model predictions.
The following analysis includes the available model output at the KNMI Climate Explorer website. The temperature observations come from the statewide data at NOAA’s Climate at a Glance website.
For the Midwest U.S. in the summer (June-July-August) we see that there has been almost no statistically significant warming in the last 50 years, whereas the CMIP6 models appear to be producing even more warming than the CMIP5 models did.
Fifty years (1970-2019) of U.S. corn-belt-summer (JJA) warming since 1970 from observations (blue); the previous CMIP5 climate models (42 model avg., green); and the new CMIP6 climate models (13 model avg., red). The three times series have been vertically aligned so their trend lines coincide in the first year (1970), which is the most meaningful way to quantify the long-term warming since 1970.
The observed 50-year trend is only 0.086 C/decade (barely significant at the 1-sigma level), while the CMIP5 average model trend is 4X as large at 0.343 C/decade, and the CMIP6 trend is 5.7X as large at 0.495 C/decade.
While the CMIP6 trend will change somewhat as more models are added, it is consistent with the report that the CMIP6 models are producing more average warming than their CMIP5 predecessors.
I am showing the average of the available models rather than individual models because it is the average of the models which guide the UN IPCC reports and thus energy policy.
It is disingenuous for some to claim that “not all IPCC models disagree with the observations,” as if that is some sort of vindication of all the models. It is not.
If there are one or two models that agree the best with observations, why isn’t the IPCC just using those to write its reports? Hmmm?
What I find particularly troubling is that climate modelers are increasingly deaf to what observations tell us. How can the CMIP5 models (let alone the newer CMIP6 models) be used to guide U.S. energy policy when there is such a huge discrepancy between the models and the observations?
I realize this is just one season (summer) in one region (the U.S. Midwest), but it is immensely important. The U.S. is the world leader in the production of corn (which is used for feed, food, and fuel) and behind only Brazil in soybean production.
Blatantly false claims (e.g. here) of an observed change in the Midwest climate have fed the popular opinion that U.S. crops are already feeling the negative effects of human-caused climate change, despite the facts.
This is just one example of many that the news media have been complicit in the destruction of the rational climate debate, which is now extending to outright censoring of alternative climate views on not only social media but also in mainstream news sources like Forbes that disappeared environmentalist Michael Shellenberger’s op-ed in which he confessed he no longer believes in a “climate crisis.”
Corn and sun image by SplitShire from Pixabay
Roy W. Spencer received his Ph.D. in meteorology at the University of Wisconsin-Madison in 1981. Dr. Spencer’s first popular book on global warming, Climate Confusion (Encounter Books), is now available at Amazon.com and BarnesAndNoble.com.
Read more at Dr. Roy’s Blog
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