Bitcoin Mining is intentionally designed to be resource-intensive and difficult so that the number of blocks found each day by miners remains steady over time, producing a controlled finite monetary supply. Individual blocks must contain a proof-of-work to be considered valid. This proof-of-work (PoW) is verified by other Bitcoin nodes each time they receive a block. Bitcoin uses a PoW function to protect against double-spending, which also makes Bitcoin's ledger immutable.
This bizarre process might not seem like it would need that much electricity—and in the early years, it didn’t. When he first started in 2012, Carlson was mining bitcoin on his gaming computer, and even when he built his first real dedicated mining rig, that machine used maybe 1,200 watts—about as much as a hairdryer or a microwave oven. Even with Seattle’s electricity prices, Carlson was spending around $2 per bitcoin, which was then selling for around $12. In fact, Carlson was making such a nice profit that he began to dream about running a bunch of servers and making some serious money. He wasn’t alone. Across the expanding bitcoin universe, lots of miners were thinking about scaling up, turning their basements and spare bedrooms into jury-rigged data centers. But most of these people were thinking small, like maybe 10 kilowatts, about what four normal households might use. Carlson’s idea was to leapfrog the basement phase and go right to a commercial-scale bitcoin mine that was huge: 1,000 kilowatts. “I started to have this dream, that I was posting on online forums, ‘I think I could build the first megawatt-scale mine.’”
In the meantime, the basin’s miners are at full steam ahead. Salcido says he’ll have 42 megawatts running by the end of the year and 150 megawatts by 2020. Carlson says his next step after his current build-out of 60 megawatts will be “in the hundreds” of megawatts. Over the next five years, his company plans to raise $5 billion in capital to build 2,000 megawatts—two gigawatts—of additional mining capacity. But that won’t all be in the basin, he says. Carlson says he and others will soon be scaling up so rapidly that, for farsighted miners, the Mid-Columbia Basin effectively is already maxed out, in part because the counties simply can’t build out power lines and infrastructure fast enough. “So we have to go site hunting across the US & Canada,” Carlson told me in a text. “I’m on my way to Quebec on Monday.” As in oil or gold, prospectors never stop—they just move on.
More important, Nakamoto built the system to make the blocks themselves more difficult to mine as more computer power flows into the network. That is, as more miners join, or as existing miners buy more servers, or as the servers themselves get faster, the bitcoin network automatically adjusts the solution criteria so that finding those passwords requires proportionately more random guesses, and thus more computing power. These adjustments occur every 10 to 14 days, and are programmed to ensure that bitcoin blocks are mined no faster than one roughly every 10 minutes. The presumed rationale is that by forcing miners to commit more computing power, Nakamoto was making miners more invested in the long-term survival of the network.