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Environmental impact of bitcoin

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File:Argo Blockchain Helios Facility.jpg
Bitcoin mining facility in Texas.

The environmental effects of bitcoin are significant. Bitcoin mining, the process by which bitcoins are created and transactions are finalized, is energy-consuming and results in carbon emissions as about half of the electricity used is generated through fossil fuels. As of 2022, bitcoin mining is estimated to be responsible for 0.2% of world greenhouse gas emissions, and to represent 0.4% of global electricity consumption. Moreover, bitcoins are mined on specialized computer hardware with a short lifespan, resulting in electronic waste. The amount of electrical energy and e-waste generated by bitcoin mining is often compared with countries like Greece or the Netherlands. Bitcoin's environmental impact has attracted the attention of regulators, leading to incentives or restrictions in various jurisdictions.

Greenhouse gas emissions

Mining as an electricity-intensive process

Bitcoin electricity consumption
Electricity consumption of the bitcoin network since 2016 (annualized) and comparison with the electricity consumption of various countries in 2019. The upper and lower bounds (grey traces) are based on worst-case and best-case scenario assumptions, respectively. The red trace indicates an intermediate best-guess estimate.

Bitcoin mining is a highly electricity-intensive proof-of-work process. Miners run dedicated software to compete against each other and be the first to solve the current 10 minute block, yielding them a reward in bitcoins. A transition to the proof-of-stake protocol, which has better energy efficiency, has been described as a sustainable alternative to bitcoin's proof-of-work scheme and as a potential solution to its environmental issues.

Bitcoin mining's distribution makes it difficult for researchers to identify miners's location and electricity use and therefore to translate energy consumption into carbon emissions. As of 2022, the Cambridge Centre for Alternative Finance (CCAF) estimates that bitcoin consumes 95.5 TWh (344 PJ) annually, representing 0.4% of the world's electricity consumption, ranking bitcoin mining between Belgium and the Netherlands in terms of electricity consumption. According to a 2022 estimate published in Joule, bitcoin mining may result in annual carbon emission of 65 Mt CO2, representing 0.2% of global emissions, which is comparable to the level of emissions of Greece.

Bitcoin mining energy mix

Until 2021, most bitcoin mining was done in China. Chinese miners would rely on cheap coal power in Xinjiang and Inner Mongolia during late autumn, winter and spring, migrating to regions with overcapacities in low-cost hydropower (like Sichuan and Yunnan) between May and October. After China banned bitcoin mining in June 2021, its miners moved to other countries. By August 2021, mining was concentrated in the U.S. (35%), Kazakhstan (18%), and Russia (11%) instead. The shift from coal resources in China to coal resources in Kazakhstan increased bitcoin's carbon footprint as Kazakhstani coal plants use hard coal, which has the highest carbon content of all coal types. Despite the ban, covert mining operations gradually came back to China, reaching 21% of global hashrate as of 2022.

Reducing the environmental impact of bitcoin is possible by mining only using clean electricity sources. As of 2021, according to The New York Times, bitcoin's use of renewables ranged from 40% to 75%. As of 2023, according to Bloomberg Intelligence, renewables represent about half of global bitcoin mining sources. Still, experts and government authorities, such as the European Securities and Markets Authority and the European Central Bank, have suggested that using renewable energy for mining may limit the availability of clean energy for the general population.

According to a 2023 ACS Sustainable Chemistry & Engineering article, directing the surplus energy from power stations that utilize intermittent renewable energy sources (e.g., wind power and solar power) to bitcoin mining could reduce curtailment, hedge electricity price risk, help resolve instability in the electrical grid, and increase the profitability of renewable energy infrastructure—therefore accelerating the transition to sustainable energy; this would decrease bitcoin's carbon footprint. Another 2023 study published in the same journal showed that mining bitcoin off-grid during the precommercial phase (when a wind or solar farm is generating electricity but not yet integrated into the grid) could bring additional profits and therefore support renewable energy development. A 2023 review published in Resource and Energy Economics also concluded that bitcoin mining could increase renewable capacity but that it might increase carbon emissions and that mining bitcoin to provide demand response largely mitigated its environmental impact. Conversely, bitcoin mining may also incentivize the recommissioning of fossil fuel plants. For instance, Greenidge Generation, a closed coal-fired power plant in New York State, was converted into natural gas in 2017 and started mining bitcoin in 2020 to monetize off-peak periods. Such impact is difficult to quantify.

Methane emissions

See also: Routine flaring § Alternatives

Bitcoin has been mined via electricity generated through the combustion of associated petroleum gas (APG), which is a methane-rich byproduct of crude oil drilling that is sometimes flared or released into the atmosphere. Methane is a greenhouse gas with a global warming potential 28 to 36 times greater than CO2. By converting more of the methane to CO2 than flaring alone would, using APG generators reduces the APG's contribution to the greenhouse effect, but this practice still harms the environment. In places such as Colorado where flaring is prohibited this practice has allowed more oil drills to operate by offsetting costs, which further delays fossil fuel phase-out. Commenting on one pilot project with ExxonMobil, political scientist Paasha Mahdavi notes that this process could potentially allow oil companies to report lower emissions by selling gas leaks, shifting responsibility to buyers and avoiding a real reduction commitment.

Comparison to other payment systems

One 2021 study by cryptocurrency investment firm Galaxy Digital claimed that bitcoin mining used less than half the energy of the banking system. In a 2023 study published in Ecological Economics, researchers from the International Monetary Fund estimate that the global payment system represented about 0.2% of global electricity consumption, comparable to the consumption of Portugal or Bangladesh. Citing the Galaxy Digital report, the authors note that the energy consumption of the entire banking sector is larger as banks offer more services than just payments. Besides energy consumption, they note that the carbon intensity of the energy used matters.

Energy used is estimated around 500 kilowatt-hours per transaction, compared to 0.001 kWh for credit cards (not including consumption from the merchant's bank, which receives the payment). However, bitcoin's energy expenditure is not directly linked to the number of transactions and this estimate does not take into account layer 2 solutions, like the Lightning Network, and batching, which allow bitcoin to process more payments than the number of on-chain transactions suggests. For instance, in 2022, bitcoin processed 100 million transactions per year, representing 250 million payments.

In September 2022, a study in Scientific Reports found that from 2016 to 2021, each US dollar worth of mined bitcoin market value caused 35 cents worth of climate damage, compared to 95 for coal, 41 for gasoline, 33 for beef, and 4 for gold mining.

Electronic waste

For broader coverage of this topic, see Electronic waste § Cryptocurrency e-waste.
The total active mining equipment in the bitcoin network and the related electronic waste generation, from July 2014 to July 2021.

Bitcoins are usually mined on specialized computing hardware, called application-specific integrated circuits, with no alternative use beyond bitcoin mining. Due to the consistent increase of the bitcoin network's hashrate, mining devices are estimated to have an average lifespan of 1.3 years until they become unprofitable and need to be replaced, resulting in significant electronic waste. As of 2021, bitcoin's annual e-waste was estimated to be over 30,000 tonnes, which is comparable to the small IT equipment waste produced by the Netherlands, while each bitcoin transaction was estimated to result in 272 g (9.6 oz) of e-waste.

Regulatory responses

In September 2022, the US Office of Science and Technology Policy highlighted the need for increased transparency about electricity usage, greenhouse gas emissions, and e-waste. In November 2022, the US Environmental Protection Agency confirmed working on the climate impacts of cryptocurrency mining. In the US, New York State banned new fossil fuel mining plants with a two-year moratorium, citing environmental concerns, while Iowa, Kentucky, Montana, Pennsylvania, Rhode Island, Texas, and Wyoming encourage bitcoin mining with tax breaks. Texas incentives aim to cut methane emissions from flared gas using bitcoin mining.

References

  1. ^ Huang, Jon; O'Neill, Claire; Tabuchi, Hiroko (3 September 2021). "Bitcoin Uses More Electricity Than Many Countries. How Is That Possible?". The New York Times. ISSN 0362-4331.
  2. ^ de Vries et al. 2022, p. 499.
  3. ^ Messina, Irene (31 August 2023). "Bitcoin electricity consumption: an improved assessment". Cambridge Judge Business School. Retrieved 7 September 2023.
  4. ^ de Vries, Alex; Stoll, Christian (December 2021). "Bitcoin's growing e-waste problem". Resources, Conservation and Recycling. 175: 105901. doi:10.1016/j.resconrec.2021.105901. ISSN 0921-3449. S2CID 240585651.
  5. ^ Stoll, Christian; Klaaßen, Lena; Gallersdörfer, Ulrich; Neumüller, Alexander (June 2023). Climate Impacts of Bitcoin Mining in the U.S. (Report). Working Paper Series. MIT Center for Energy and Environmental Policy Research.
  6. ^ Wendl, Moritz; Doan, My Hanh; Sassen, Remmer (15 January 2023). "The environmental impact of cryptocurrencies using proof of work and proof of stake consensus algorithms: A systematic review". Journal of Environmental Management. 326 (Pt A): 116530. doi:10.1016/j.jenvman.2022.116530. ISSN 0301-4797. PMID 36372031. S2CID 253476551.
  7. ^ de Vries et al. 2022, p. 498.
  8. de Vries et al. 2022, Data S1.
  9. Akhtar, Tanzeel; Shukla, Sidhartha (17 May 2022). "China Makes a Comeback in Bitcoin Mining Despite Government Ban". Bloomberg News.
  10. de Vries et al. 2022, pp. 501–502.
  11. Chawaga, Peter (14 September 2023). "Elon Musk said Tesla would resume bitcoin payments now that it has crossed this threshold". TheStreet.
  12. Szalay, Eva (19 January 2022). "EU should ban energy-intensive mode of crypto mining, regulator says". Financial Times.
  13. Gschossmann, Isabella; van der Kraaij, Anton; Benoit, Pierre-Loïc; Rocher, Emmanuel (11 July 2022). "Mining the environment – is climate risk priced into crypto-assets?". Macroprudential Bulletin (18). European Central Bank.
  14. ^ Velický, Matěj (27 February 2023). "Renewable Energy Transition Facilitated by Bitcoin". ACS Sustainable Chemistry & Engineering. 11 (8): 3160–3169. doi:10.1021/acssuschemeng.2c06077. ISSN 2168-0485. S2CID 256788823.
  15. Lal, Apoorv; Zhu, Jesse; You, Fengqi (13 November 2023). "From Mining to Mitigation: How Bitcoin Can Support Renewable Energy Development and Climate Action". ACS Sustainable Chemistry & Engineering. 11 (45): 16330–16340. doi:10.1021/acssuschemeng.3c05445. ISSN 2168-0485. S2CID 264574360.
  16. Bruno, August; Weber, Paige; Yates, Andrew J. (August 2023). "Can Bitcoin mining increase renewable electricity capacity?". Resource and Energy Economics. 74: 101376. doi:10.1016/j.reseneeco.2023.101376. ISSN 0928-7655.
  17. ^ Corbet, Shaen; Yarovaya, Larisa (24 August 2020). "The environmental effects of cryptocurrencies". In Corbet, Shaen; Urquhart, Andrew; Yarovaya, Larisa (eds.). Cryptocurrency and Blockchain Technology. De Gruyter. p. 154. doi:10.1515/9783110660807-009. ISBN 978-3-11-066080-7. S2CID 240881482.
  18. Lorenzato, Gianni; Tordo, Silvana; Howells, Huw Martyn; Berg, Berend van den (20 May 2022). Financing Solutions to Reduce Natural Gas Flaring and Methane Emissions. World Bank. pp. 98–104. ISBN 978-1-4648-1850-9.
  19. Calma, Justine (4 April 2022). "Why fossil fuel companies see green in Bitcoin mining projects / And why it's risky business". The Verge.
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  21. ^ Agur, Itai; Lavayssière, Xavier; Villegas Bauer, Germán; Deodoro, Jose; Martinez Peria, Soledad; Sandri, Damiano; Tourpe, Hervé (October 2023). "Lessons from crypto assets for the design of energy efficient digital currencies". Ecological Economics. 212: 107888. doi:10.1016/j.ecolecon.2023.107888.
  22. Heinonen, Henri T.; Semenov, Alexander; Veijalainen, Jari; Hamalainen, Timo (14 July 2022). "A Survey on Technologies Which Make Bitcoin Greener or More Justified". IEEE Access. 10: 74792–74814. Bibcode:2022IEEEA..1074792H. doi:10.1109/ACCESS.2022.3190891. S2CID 250580065.
  23. Jones, Benjamin A.; Goodkind, Andrew L.; Berrens, Robert P. (29 September 2022). "Economic estimation of Bitcoin mining's climate damages demonstrates closer resemblance to digital crude than digital gold". Scientific Reports. 12 (1): 14512. Bibcode:2022NatSR..1214512J. doi:10.1038/s41598-022-18686-8. ISSN 2045-2322. PMC 9522801. PMID 36175441.
  24. OSTP (8 September 2022), Climate and Energy Implications of Crypto-Assets in the United States (PDF), White House Office of Science and Technology Policy
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  26. ^ Bologna, Michael J. "Texas Offers New Tax Benefit to Attract Bitcoin Miners". Bloomberg Tax.

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