Cryptocurrency

Small digression electricity + bitcoin. Sounds conclusive:

Bitcoin consumes a lot of electricity. But this does not mean that the cryptocurrency is destroying the climate. After all, Bitcoin’s ecological footprint is probably much smaller than one might think at first glance.

Recently, economist Alex de Vries published a paper on “Bitcoin’s Growing Energy Problem” in the scientific journal Joule. Vries, who works at the consulting firm PricewaterhouseCoopers, has been studying Bitcoin’s power consumption for some time. On his website Digiconomist, he plots this with the Bitcoin electricity index.

According to Vries’ paper, Bitcoin miners currently consume at least 2.55 gigawatts, but more likely about 7.67 gigawatts. This means that Bitcoin could consume almost as much electricity as Austria (8.2 gigawatts). This value is, of course, a scandal that finds an echo in the German media. For example, T3N, Die Zeit and the Süddeutsche Zeitung have reported on the paper. Spiegel Online carries an interview with de Vries, in which he even calls for “an international agreement, preferably under the leadership of the UN” to get a grip on the energy consumption of mining.

Is mining really that bad? How reliable are de Vries’ values? Is Bitcoin threatening to undo the successes of the energy transition, as Der Spiegel asked back in late 2017? Or is reality once again a bit more complicated?

In the following, we will try to bring a little clarity to these questions.

No matter how you calculate it - it’s a lot
Let’s start with how to measure Bitcoin’s power consumption. The very largest portion of power consumption goes back to the miners competing to append a new block to the blockchain. How much they consume is hard to figure out.

We do know what Bitcoin’s hashrate is - about 35 million terahashes, which means that all the miners combined perform about 35 trillion hash operations per second. But we don’t know what devices are used to generate them. Is it the modern, energy-efficient antminers S9? What share do older generation miners make up? Are there even graphics cards connected? Power consumption depends in an extreme way on what devices are used. And this we do not know.

If you start with the hashrate, you can at best calculate a minimum value: Take a current miner - the Antminer S9 - and pretend that the entire mining network consists solely of it. An S9 generates 13 terahash with a power consumption of 1300 watts. This would require about 2.7 million Antminer S9s to raise the hashrate of Bitcoin, giving us a power consumption of 3.5 gigawatts. This would be, as I said, a lower bound that can be multiplied by any estimated value (x1.5; x2; …).

De Vries, on the other hand, starts his estimate at the other end: with revenues. He assumes that miners will produce hashpower until they make only a marginal profit. He then estimates how much money they invest in mining, what portion of that goes into electricity, and what prices the miners pay. He assumes a 60 percent share of electricity and an electricity price of 5 U.S. cents per kilowatt hour.

Using these values, de Vries concludes that Bitcoin consumes at least 2.55,

but probably closer to 7.67 gigawatts. The Bitcoin Energy Consumption Index on its website translates this value (7.67 gigawatts) into an annual consumption of 69 terawatt hours. That’s about as much as six to eight decent nuclear power plants produce and more than the country of Czech Republic consumes.

Of course, one can doubt de Vries’ method. But as we have seen, even an optimistic minimum estimate based on Antminer’s S9 power consumption lands at 3.5 gigawatts. This makes it relatively likely that de Vries’ values are relatively correct. What is often radically wrong, on the other hand, is the interpretation of this result.

Cheap electricity is mostly green electricity
At first glance, this doesn’t sound good at all. We’re replacing incandescent bulbs with LED lights, building refrigerators and washing machines that use less and less electricity, and putting up thousands of wind turbines - and then along comes Bitcoin, suddenly consuming 69 terawatt hours a year. Is the cryptocurrency ruining everything with that? Was the energy transition and all the electricity saving for nothing?

Such questions are obvious, but they are wrong, because they compare things that cannot be compared. Because there is no direct relationship between the amount of electricity produced and the ecological footprint.

A simple comparison: If someone lives near coal-fired power plants, say in the Rhineland, he will pollute the environment with every kilowatt hour he consumes. If he lights up with an LED lamp for one hour a day, he causes more environmental damage than if someone wastes renewable energy, such as when the Icelandic capital Reykjavik heats its sidewalks in winter with energy from geothermal energy. It’s not how much that matters, but where from. It is better to waste electricity from renewable sources than to save electricity from coal power.

Of course, with Bitcoin, we don’t know where the miners are located or what electricity they use. The only thing we do know is that miners go where the electricity is cheap. While other industries are more tied to location and dependent on a mix of cost factors, miners are highly mobile and understand the cost of electricity as by far the most important competitive factor. There may be no industry that is as attracted to low electricity prices.

Countries with strikingly low electricity costs include Sweden, Finland and Canada, according to Statista. What these three countries have in common is that they have a relatively high proportion of renewable energies, primarily hydropower. In Canada, according to a study by the Fraunhofer Institute, electricity prices are lowest in the province of Quebec. Quebec has one of the world’s highest shares of electricity from hydropower - and is considered a miner’s paradise.

The situation is similar in Sweden, Norway, Finland, the U.S. and, most notably, Iceland: electricity is cheapest where it can be generated most easily and with a surplus. This usually doesn’t mean building a coal-fired or nuclear power plant - both of which are usually only competitive with government subsidies, once you add in the follow-up costs - but using natural conditions to tap energy. This is true even in Germany, where wind power is now the cheapest way to create new electricity capacity. Internationally, of course

hydroelectric and geothermal power are still much cheaper, so it is reasonable to assume that a large part of Bitcoin’s hashrate comes from these environmentally friendly types of energy.

At this point, one could make a not entirely far-fetched assumption: that Bitcoin’s biological footprint, despite its huge energy consumption, is better than that of a Rhineland industrial area. After all, German electricity is often not only expensive, but also dirty.

Cheap coal power as a result of the wrong policies.
We’ll stick with this argument, but let it slide in a roughly different direction.

Bitcoin miners inevitably settle in locations where electricity is cheap. Any type of electricity that sells at prices below 5 or 6 dollar cents is eligible for miners. In most cases, such power comes from hydroelectric or geothermal sources, as it is relatively easy and inexpensive to generate and scale if the natural conditions are met. In many northern countries or provinces, there is a surplus of clean energy that is skimmed by miners. The environmental footprint of such mining farms is zero. An LED light in a southern German household causes more damage.

When mining is profitable, it means that there is an oversupply of electricity in a region: that a generator is willing and able to produce more electricity than citizens and businesses consume. It means that a region either produces an extreme amount of electricity but has no businesses that consume it - such as in Iceland or Quebec in Canada - , or that industry in the area is idle, such as in the so-called Rust Belt in the northeastern U.S., but the energy infrastructure has not yet been sufficiently deconstructed.

In most cases, the waste takes place before the miners settle. If there is indeed a nuclear or coal-fired power plant somewhere that is running without any demand driving electricity prices to prohibitive levels for mining, that in itself should be an environmental scandal. Today, when a government expands or maintains non-renewable power generation on a scale for which the market has no need, it sets serious economic-environmental disincentives. Miners exploit these, but usually also correct them relatively quickly.

Venezuela, for example, subsidized electricity generation to the point that the country had some of the cheapest rates in the world. This attracted miners in droves, some of whom used old - i.e., extremely inefficient - equipment to profitably generate Bitcoins. As a result, electricity became increasingly scarce locally, and when a mining farm once even caused a blackout in an entire neighborhood, the government intervened and had the farm shut down.

Similarly, in China, miners had spread to wherever the government’s planned economy provided abundant power for new industrial sites. In some cases, miners reaped the rewards of planning mistakes, such as setting up asic farms in ghost towns with large power plants, but in others they siphoned off electricity needed by other industries.

needed by other industries. As soon as the miners come into conflict with the “real” industry’s hunger for electricity, the government intervenes here as well. The result is that more and more Chinese miners are moving their machines to places where renewable electricity is cheap and in surplus in large quantities.

So under normal circumstances, misaligned incentives usually correct themselves. Sometimes, however, it probably still happens that a region or government creates or maintains excess capacity from coal or nuclear power. In this case, in the very worst case, the miners prevent such overcapacity from being removed due to lack of demand.

Such a grievance is fairly easy to eradicate. All the government has to do is what goes without saying for a modern, ecologically oriented energy policy: Ensure that electricity from non-sustainable production is more expensive than renewable energy. If this were the standard, bitcoin mining could not be environmentally harmful at all.

Translated with www.DeepL.com/Translator (free version)