Climate Modeling: Settled Science Or Fool’s Errand?

Climate Modeling: Settled Science Or Fool’s Errand?
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Climate Modeling: Settled Science Or Fool’s Errand?

Play Quizzes 4

I don’t know if you’ve had a chance to read Daniel Sarewitz’s recent piece Saving Science in the New Atlantis, but it is causing all sorts of ripples across the scientific community, and deserves even more attention from both scientists and policy makers. I interviewed Sarewitz for RealClear Radio Hour this weekend, and I would like to dig into one of the many issues we discussed, and that is the misuse of climate models.

But first, a little background.

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Climate Modeling

The differences in the way scientists and engineers use mathematics can have profound political consequences.Like the quip about England and America often misattributed to George Bernard Shaw, science and engineering are two professions divided by a common language. That language, of course, is mathematics, a symbolic abstraction through which we can describe, explain, and sometimes transform the natural world. That purpose matters because the differences in the way scientists and engineers use mathematics can have profound political consequences when those calculations drift too far from observable reality.

When mathematics jumped from paper to computers, elegance was turbocharged with brute force. This allowed scientists and engineers to develop computer models that simulated physical phenomena. Eventually, some of these simulation models became good enough that “what if” experiments could be conducted more rapidly and conveniently on a computer than by performing physical experiments. Propelled by Moore’s Law , improvements in computing delivered billions of calculations per second, and the most advanced simulation models took on breathtaking levels of sophistication.

Engineering, Tech-Based

In the engineering world, we got semiconductor physics models that attempted to simulate the behavior of integrated circuits. In the beginning, these models were very crude, and the circuits were correspondingly simple. But the integrated circuits slowly co-evolved with the tools used to design them in a tight feedback loop, creating a cycle that eventually yielded models that could flawlessly predict the behavior of electrons traversing single atomic layers of material.

Whenever the models made predictions that deviated from measured results – sometimes ruining a batch of chips – the model parameters got adjusted. This was often done with the help of scientists whose research followed technological developments, as engineers asked them to help figure out what went wrong. Companies that got that process right thrived. Those that didn’t went out of business. For the rest of us, this ongoing process meant better, faster, cheaper gadgets, as the transistor radios of yore evolved into today’s powerful smartphones.

Science, Funding-Based

In the science world, we have climate models that attempt to simulate the combined behavior of the Sun, along with the Earth’s atmosphere, ocean, cloud, and biosphere, as one giant integrated system. In the beginning, these models were very crude, and the United Nations Intergovernmental Panel on Climate Change unequivocally stated that “the climate system is a coupled non-linear chaotic system, and therefore the long-term prediction of future climate states is not possible.” But that didn’t stop environmental activists from using these models to make alarming predictions of runaway global warming decades in the future.

The only feedback loop that informed scientific development was the funding feedback loop.It was the perfect advocacy narrative, because the models were never used to build anything, and could not easily be tested. One could hardly ask engineers to whip up a batch of planets with varying levels of carbon dioxide (CO2) to see whether the model parameters reflected reality. So the only feedback loop that informed scientific development was the funding feedback loop , as pleasing the funding agencies became paramount. When funding became politicized, climate change became a partisan political cudgel. Scientists who made alarming forecasts thrived, while those who didn’t were forced to seek greener pastures. For the rest of us, it’s meant an intractable, toxically polarized political controversy that is roiling major segments of our economy.

Meanwhile, published estimates of climate sensitivity – the critical parameter driving the models – have been trending ever-downward as time has proven old alarming climate forecasts spectacularly wrong. And scientists who want to test technologies to cool the planet, like spraying reflective particles into the atmosphere, know that after all the billions spent, the models still aren’t anywhere near good enough to predict the consequences of such interventions.

Which brings us back to Daniel Sarewitz , Co-Director of the Consortium for Science, Policy, and Outcomes at Arizona State University. Sarewitz, who was trained as an earth scientist, is terrified that “science is trapped in a self-destructive vortex” that is endangering both science and democracy. In his blockbuster analysis mentioned above, he nails his thesis to the laboratory door, challenging Big Science to get its act together. Politicizing science, he argues, leads to debates about science being substituted for debates about politics. So we end up fighting over unverifiable forecasts about what might happen in the future, rather than wrestling with the complex tradeoffs that attend political decisions on what we should – or could – do about carbon emissions under all the potential future scenarios.

But rather than get discouraged, Sarewitz believes there is a way out of this conundrum. His advice is, “Technology unites while science divides.” He recommends that science “abdicate its protected political status and embrace both its limits and its accountability to the rest of society.” Despite calling long-range climate forecasting “a fool’s errand,” he thinks dumping too much CO2 in the atmosphere will make anthropogenic global warming a long term problem that will eventually require the decarbonization of our energy industries. But he sees this as a process taking many decades, one that can be best addressed not with politicized science, but by letting adaptation, innovation, wealth creation, and economic growth lead the way.

You can listen to a podcast of our complete RealClear Radio Hour interview here .

Bill Frezza

Bill Frezza

Bill Frezza is a fellow at the Competitive Enterprise Institute and the host of RealClear Radio Hour.

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  1. Whereas I do find this an interesting article, and interview, it misses out on the other 2 debates raging in the scholarly literature on climate change. Which probably explains why few have heard one whit about them. The second involves a lively discussion of just how long should the Holocene interglacial last? The 3rd is far more interesting and is summed up by Ruddiman’s (2003) Early Anthropogenic Hypothesis:

    “The possible explanation as to why we are still in an interglacial relates to the early anthropogenic hypothesis of Ruddiman (2003, 2005). According to that hypothesis, the anomalous increase of CO2 and CH4 concentrations in the atmosphere as observed in mid- to late Holocene ice-cores results from anthropogenic deforestation and rice irrigation, which started in the early Neolithic at 8000 and 5000 yr BP, respectively. Ruddiman proposes that these early human greenhouse gas emissions prevented the inception of an overdue glacial that otherwise would have already started.”

    Muller and Pross (2007)

    This may seem counter-intuitive at first, but this simply cannot be had both ways. Either CO2/CH4/etc. can prevent glacial inception, or they cannot. It is just that simple.

    we study the questions why we still live in an interglacial world and when we
    should expect the end of the Holocene under natural conditions (no
    anthropogenic influence) or under anthropogenic perturbations (also referred to
    as “Anthropocene”), questions which attracted considerable interest
    in recent years. It was argued that without earlier anthropogenic activity we
    would live already in glacial world (Ruddiman’s hypothesis). Tzedakis et al.
    (Nature Geoscience, 2012), using MIS 19 as the best analogy in terms of the
    orbital parameters for the Holocene, suggested that the new glacial inception
    would start within the next 1500 years, assuming natural CO2 level of 240 ppm.
    However, 240 ppm is much lower than preindustrial CO2 level and CO2
    concentrations during several most recent interglacials (starting from MIS 11).
    Here, using the comprehensive Earth system model of intermediate complexity
    CLIMBER-2, carefully calibrated for the simulations of the past eight glacial
    cycles, we show that (i) although climate conditions during late Holocene were
    very close to the bifurcation transition to the glacial climate state (Calov
    and Ganopolski, Geophys. Res. Lett., 2005), it is very unlikely that under
    pre-industrial CO2 level (280 ppm) glacial inception would occur within the
    next several thousand years; (ii) it is likely that the current interglacial,
    even without anthropogenic CO2 emission, would be the longest interglacial
    during the past million years; (iii) current CO2 level makes new glacial
    inception virtually impossible within the next 50,000 years; (iv) in agreement
    with earlier result of Archer and Ganopolski (Geochem. Geophys. Geosyst., 2007)
    based on a conceptual model of glacial cycles, we found that consumption of a
    large portion of available fossil fuel could postpone the next glacial
    inception by hundreds of thousand years.”

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