{"id":264499,"date":"2023-06-29T13:34:27","date_gmt":"2023-06-29T11:34:27","guid":{"rendered":"https:\/\/climatescience.press\/?p=264499"},"modified":"2023-06-29T13:34:30","modified_gmt":"2023-06-29T11:34:30","slug":"physics-is-why-renewables-cant-power-modern-economies","status":"publish","type":"post","link":"https:\/\/climatescience.press\/?p=264499","title":{"rendered":"Physics Is Why Renewables Can\u2019t Power Modern Economies"},"content":{"rendered":"\n
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From Heartland Daily News<\/strong><\/em><\/a><\/p>\n\n\n\n

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To understand why wind and solar power, even with battery backup, will not be sufficient in the near future to supply the electric power needs of any modern industrial economy, much less an economy the size of the United States, one must first understand how the electric power system works.<\/p>\n\n\n\n

Note: I\u2019m not talking about costs. Although the media regularly reports demonstrably false claims that wind and solar power are cheaper than traditional power sources such as coal, natural gas, hydroelectric, and nuclear, that\u2019s not the issue I\u2019m addressing today.<\/p>\n\n\n\n

I\u2019m simply discussing the physics and real-world possibility of the electric power system in the United States going net zero by 2030, 2035, 2050 or whatever random date one might project is necessary to prevent global average temperatures from exceeding the also completely random 1.5\u2103 to 2\u2103 rise commonly assumed to be the trigger for a climate disaster.<\/p>\n\n\n\n

The engineers that designed modern power systems understood these realities and applied them as they developed the well-functioning systems in America and Europe that have driven economic growth for a century now. However, engineering truths are now being ignored by politicians hoping to score points with green voters. Reality matters, folks, and as wind and solar have increasingly displaced coal, the number of blackouts and brownouts across the nation has increased dramatically<\/a>, more than doubling in the past six years alone<\/a>. This is not a coincidence or a result of climate change.<\/p>\n\n\n\n

A large-scale power grid consists of two segments: baseload power and peaking power. Baseload power is the minimum amount of energy needed for normal daily operations, which requires a fairly constant flow of power. Coal, nuclear, hydro, and to a lesser but growing extent natural gas have satisfied the country\u2019s baseload for the past century because they operate full-time, providing a steady flow of power.<\/p>\n\n\n\n

Peaking power is the additional power needed when the system is faced with unusual amounts of demand, as in July and August in Texas or Arizona, when air conditioner use soars, and in December and January in Minnesota or North Dakota, when the furnaces kick in. Natural gas has commonly served to provide peaking power because it can be cycled on and off quickly, as needed.<\/p>\n\n\n\n

Neither wind nor solar can be relied upon for either baseload or peaking power. Wind turbines generate power only when the wind blows between certain speeds, and the power they generate fluctuates constantly as wind gusts vary. Solar provides no power at night or when solar panels are covered by snow or ice, and only reduced power on cloudy days, during storms, or when dirty. Battery backup, the power source that is supposed to fill the gaps when wind and solar are not producing electricity or are producing less than what is in demand, will not exist in the needed capacities for decades to come, if ever. There simply aren\u2019t enough batteries, not enough being built, and not enough of the needed materials to build them being mined and refined, to change that anytime soon.<\/p>\n\n\n\n

It is true that new technologies are being developed, such as new types of batteries and technologies to allow geothermal power to become more widespread, but they are years away from commercial practicality. They won\u2019t make substantial additions to the electric power system on the short timelines demanded by net zero advocates.<\/p>\n\n\n\n

These realities mean every megawatt of wind and solar added to the electric grid requires a megawatt of backup from traditional sources to run constantly at less-than-peak levels as spinning reserve, to regulate the flow of fluctuating power delivered to the grid from turbines and solar panels when they are operating and to take up the slack during periods when either or both sources of weather-dependent power are not operating.<\/p>\n\n\n\n

Despite these realities, Democrats and climate warriors at the federal level and in the states are shutting down necessary baseload and peaking power sources as fast as they can.<\/p>\n\n\n\n

The electric grid was built up over 80 years or more. To reduce carbon dioxide emissions (which are in fact beneficial to the environment), climate scolds are demanding the impossible, to replace fossil fuels with renewable power plants in just seven, 12, or for some unusually patient alarmists, 27 years.<\/p>\n\n\n\n

To meet current electric power needs, estimates are millions of wind turbines would have to be erected, millions of solar panels installed, and billions of battery packs stored in millions of homes or at tens of thousands of centralized battery farms that would have to be built. Wind turbines would have to cover one-third of the continental United States, or solar panels would probably have to cover more than 20 percent of the countryside, just to meet current demand<\/em>.<\/p>\n\n\n\n

We would also have to erect thousands of additional electric towers, string thousands of additional miles of transmission lines, and build thousands of new transformer stations to get the power from the locations where the wind blows and sun shines regularly\u2014which is where the wind and solar farms will have to be built, of course\u2014to the cities and towns where the power is needed. That will have a devastating impact on wildlife and wilderness.<\/p>\n\n\n\n

Of course, that\u2019s just to meet the current demand for electric power. The U.S. population is growing, the economy is growing, and because of Biden administration regulations limiting natural gas appliances and vehicles powered by internal combustion engines, more people will be plugging in more electric vehicles, more electric stoves, more electric furnaces, more electric water heaters, etc., so demand for electricity is going to grow dramatically, meaning we will need even more turbines, panels, batteries, and transmission lines than estimated.<\/p>\n\n\n\n

How big a task is the net zero transformation? On September 30, 2019, Roger Pielke Jr. calculated reaching net zero globally by 2050 would require bringing online the equivalent of three new large nuclear power plants every two days, beginning on October 1, 2019 and going on through January 1, 2050. Alternatively, hitting net zero by 2050 would require the deployment of approximately 1,500 new wind turbines covering 300 square miles of land each day from October 1, 2019 through January 1, 2050, Pielke calculated. The United States\u2019 contribution would require one new large nuclear power plant deployed every six days or the equivalent of 1,000 wind turbines every six days, Pielke reported. Simultaneously, countries around the world would have to retire an equivalent amount of fossil fuel power along the same timelines.<\/p>\n\n\n\n

In case no one has noticed, the United States hasn\u2019t opened even a single new power plant since Pielke wrote, and although hundreds of new turbines have been erected since 2019, nowhere near the 218,000 turbines required over the 1,308 days between October 1, 2019 and May 1, 2023 have been built. And although in America some large fossil fuel power plants have been shuttered, some have also been added, so the pace of required emissions reductions in the United States, much less across the world where new coal and gas plants are being brought online at a breakneck pace, is far from being met. That means the necessary pace of power plant closures and openings of new zero-emitting power sources is steeper now than when Pielke produced his analysis three and a half years ago.<\/p>\n\n\n\n

And that\u2019s to hit net zero by 2050. To meet the much more ambitious target of net zero by 2030, as some are demanding, the United States would have had to begin deploying the equivalent of one new nuclear plant or 1,000 wind turbines every other day, starting back in 2019.<\/p>\n\n\n\n

Proponents of net zero admit the technological transformation required is akin to a wartime effort. If net zero is to be accomplished, all manufacturing will have to be directed away from whatever products we build now and diverted to the production of millions of wind turbines, solar panels, electric vehicles, batteries, transmission towers and power lines, rail tracks, cars, battery packs, heat pumps, and associated technologies for the net zero economy. The government will have to conscript all factories, and by extension their workers, into a warlike net zero crusade against chimeric climate change. It would all be for naught, moreover, because global greenhouse gas emissions would continue to rise to power economic growth in developing countries that are not foolish enough to impose fossil fuel restrictions on themselves.<\/p>\n\n\n\n

Energy analyst Mark Mills refers to the green energy transition demanded by climate alarmists as an exercise in \u201cmagical thinking,\u201d and he\u2019s right. In one article Mills provided 41 \u201cinconvenient truths\u201d about the new energy revolution. Here are some examples:<\/p>\n\n\n\n