Workplace impact of artificial intelligence

From Wikipedia, the free encyclopedia

https://en.wikipedia.org/wiki/Workplace_impact_of_artificial_intelligence 

AI-enabled wearable sensor networks may improve worker safety and health through access to real-time, personalized data, but also presents psychosocial hazards such as micromanagement, a perception of surveillance, and information security concerns.

The impact of artificial intelligence on workers includes both applications to improve worker safety and health, and potential hazards that must be controlled.

One potential application is using AI to eliminate hazards by removing humans from hazardous situations that involve risk of stress, overwork, or musculoskeletal injuries. Predictive analytics may also be used to identify conditions that may lead to hazards such as fatigue, repetitive strain injuries, or toxic substance exposure, leading to earlier interventions. Another is to streamline workplace safety and health workflows through automating repetitive tasks, enhancing safety training programs through virtual reality, or detecting and reporting near misses.

When used in the workplace, AI also presents the possibility of new hazards. These may arise from machine learning techniques leading to unpredictable behavior and inscrutability in their decision-making, or from cybersecurity and information privacy issues. Many hazards of AI are psychosocial due to its potential to cause changes in work organization. These include changes in the skills required of workers, increased monitoring leading to micromanagement, algorithms unintentionally or intentionally mimicking undesirable human biases, and assigning blame for machine errors to the human operator instead. AI may also lead to physical hazards in the form of human–robot collisions, and ergonomic risks of control interfaces and human–machine interactions. Hazard controls include cybersecurity and information privacy measures, communication and transparency with workers about data usage, and limitations on collaborative robots.

From a workplace safety and health perspective, only "weak" or "narrow" AI that is tailored to a specific task is relevant, as there are many examples that are currently in use or expected to come into use in the near future. "Strong" or "general" AI is not expected to be feasible in the near future, and discussion of its risks is within the purview of futurists and philosophers rather than industrial hygienists.

Certain digital technologies are predicted to result in job losses. Starting in the 2020s, the adoption of modern robotics has led to net employment growth. However, many businesses anticipate that automation, or employing robots would result in job losses in the future. This is especially true for companies in Central and Eastern Europe. Other digital technologies, such as platforms or big data, are projected to have a more neutral impact on employment. A large number of tech workers have been laid off starting in 2023; many such job cuts have been attributed to artificial intelligence.

The long-term predicted impact of AI on the workplace remains highly contested. Various academic studies have theorised the impact of AI on the workplace. A 2025 investigation based on users' interactions with Microsoft's AI chatbot, Copilot, identified forty jobs that had high overlaps with the capabilities of AI. The report concluded that these jobs - which included Interpreters and Translators, Historians, Passenger Attendants, Sales Assistants, and Writers - would thus experience significant transformation in the workplace by AI. The report garnered high levels of attention in the media, with some outlets claiming these jobs would become obsolete. However, some of the listed professions criticised the report, suggesting that it had misrepresented their typical workplace activities in order to augment AI's current performance. The historian Chris Campbell argued that the 'report’s methods, deliberately or otherwise, de-skill historians away from a job that requires high-level and deeply human analytical skills to one that is tasked solely with the retention and provision of knowledge. Under that flawed rubric, it is little wonder that historians have a high AI applicability score.

Health and safety applications

In order for any potential AI health and safety application to be adopted, it requires acceptance by both managers and workers. For example, worker acceptance may be diminished by concerns about information privacy, or from a lack of trust and acceptance of the new technology, which may arise from inadequate transparency or training. Alternatively, managers may emphasize increases in economic productivity rather than gains in worker safety and health when implementing AI-based systems.

Eliminating hazardous tasks

Call centers involve significant psychosocial hazards due to surveillance and overwork. AI-enabled chatbots can remove workers from the most basic and repetitive of these tasks.

AI may increase the scope of work tasks where a worker can be removed from a situation that carries risk. In a sense, while traditional automation can replace the functions of a worker's body with a robot, AI effectively replaces the functions of their brain with a computer. Hazards that can be avoided include stress, overwork, musculoskeletal injuries, and boredom.

This can expand the range of affected job sectors into white-collar and service sector jobs such as in medicine, finance, and information technology. As an example, call center workers face extensive health and safety risks due to its repetitive and demanding nature and its high rates of micro-surveillance. AI-enabled chatbots lower the need for humans to perform the most basic call center tasks.

Analytics to reduce risk

The NIOSH lifting equation is calibrated for a typical healthy worker to avoid back injuries, but AI-based methods may instead allow real-time, personalized calculation of risk.

Machine learning is used for people analytics to make predictions about worker behavior to assist management decision-making, such as hiring and performance assessment. These could also be used to improve worker health. The analytics may be based on inputs such as online activities, monitoring of communications, location tracking, and voice analysis and body language analysis of filmed interviews. For example, sentiment analysis may be used to spot fatigue to prevent overwork. Decision support systems have a similar ability to be used to, for example, prevent industrial disasters or make disaster response more efficient.

For manual material handling workers, predictive analytics and artificial intelligence may be used to reduce musculoskeletal injury. Traditional guidelines are based on statistical averages and are geared towards anthropometrically typical humans. The analysis of large amounts of data from wearable sensors may allow real-time, personalized calculation of ergonomic risk and fatigue management, as well as better analysis of the risk associated with specific job roles.

Wearable sensors may also enable earlier intervention against exposure to toxic substances than is possible with area or breathing zone testing on a periodic basis. Furthermore, the large data sets generated could improve workplace health surveillance, risk assessment, and research.

Streamlining safety and health workflows

AI has also been used to attempt to make the workplace safety and health workflow more efficient. One example is coding of workers' compensation claims, which are submitted in a prose narrative form and must manually be assigned standardized codes. AI is being investigated to perform this task faster, more cheaply, and with fewer errors.

AI‐enabled virtual reality systems may be useful for safety training for hazard recognition.

Artificial intelligence may be used to more efficiently detect near misses. Reporting and analysis of near misses are important in reducing accident rates, but they are often underreported because they are not noticed by humans, or are not reported by workers due to social factors.

Hazards

Some machine learning training methods are prone to unpredictabiliy and inscrutability in their decision-making, which can lead to hazards if managers or workers cannot predict or understand an AI-based system's behavior.

There are several broad aspects of AI that may give rise to specific hazards. The risks depend on implementation rather than the mere presence of AI.

Systems using sub-symbolic AI such as machine learning may behave unpredictably and are more prone to inscrutability in their decision-making. This is especially true if a situation is encountered that was not part of the AI's training dataset, and is exacerbated in environments that are less structured. Undesired behavior may also arise from flaws in the system's perception (arising either from within the software or from sensor degradation), knowledge representation and reasoning, or from software bugs. They may arise from improper training, such as a user applying the same algorithm to two problems that do not have the same requirements. Machine learning applied during the design phase may have different implications than that applied at runtime. Systems using symbolic AI are less prone to unpredictable behavior.

The use of AI also increases cybersecurity risks relative to platforms that do not use AI, and information privacy concerns about collected data may pose a hazard to workers.

Psychosocial

Introduction of new AI-enabled technologies may lead to changes in work practices that carry psychosocial hazards such as a need for retraining or fear of technological unemployment.

Psychosocial hazards are those that arise from the way work is designed, organized, and managed, or its economic and social contexts, rather than arising from a physical substance or object. They cause not only psychiatric and psychological outcomes such as occupational burnout, anxiety disorders, and depression, but they can also cause physical injury or illness such as cardiovascular disease or musculoskeletal injury. Many hazards of AI are psychosocial in nature due to its potential to cause changes in work organization, in terms of increasing complexity and interaction between different organizational factors. However, psychosocial risks are often overlooked by designers of advanced manufacturing systems.

Einola and Khoreva explore how different organizational groups perceive and interact with AI technologies. Their research shows that successful AI integration depends on human ownership and contextual understanding. They caution against blind technological optimism and stress the importance of tailoring AI use to specific workplace ecosystems. This perspective reinforces the need for inclusive design and transparent implementation strategies.

Changes in work practices

AI is expected to lead to changes in the skills required of workers, requiring training of existing workers, flexibility, and openness to change. The requirement for combining conventional expertise with computer skills may be challenging for existing workers. Over-reliance on AI tools may lead to deskilling of some professions.

While AI offers convenience and judgement-free interaction, increased reliance—particularly among Generation Z—may reduce interpersonal communication in the workplace and affect social cohesion. As AI becomes a substitute for traditional peer collaboration and mentorship, there is a risk of diminishing opportunities for interpersonal skill development and team-based learning. This shift could contribute to workplace isolation and changes in team dynamics.

Increased monitoring may lead to micromanagement and thus to stress and anxiety. A perception of surveillance may also lead to stress. Controls for these include consultation with worker groups, extensive testing, and attention to introduced bias. Wearable sensors, activity trackers, and augmented reality may also lead to stress from micromanagement, both for assembly line workers and gig workers. Gig workers also lack the legal protections and rights of formal workers.

AI is not merely a technical tool but a transformative force that reshapes workplace structures and decision-making processes. Newell and Marabelli argue that AI alters power dynamics and employee autonomy, requiring a more nuanced understanding of its social and organizational implications. Their study calls for thoughtful integration of AI that considers its broader impact on work culture and human roles.

There is also the risk of people being forced to work at a robot's pace, or to monitor robot performance at nonstandard hours.

Bias

Main article: Algorithmic bias

Algorithms trained on past decisions may mimic undesirable human biases, for example, past discriminatory hiring and firing practices. Information asymmetry between management and workers may lead to stress, if workers do not have access to the data or algorithms that are the basis for decision-making.

In addition to building a model with inadvertently discriminatory features, intentional discrimination may occur through designing metrics that covertly result in discrimination through correlated variables in a non-obvious way.

In complex human‐machine interactions, some approaches to accident analysis may be biased to safeguard a technological system and its developers by assigning blame to the individual human operator instead.

Physical

Automated guided vehicles are examples of cobots currently in common use. Use of AI to operate these robots may affect the risk of physical hazards such as the robot or its moving parts colliding with workers.

Physical hazards in the form of human–robot collisions may arise from robots using AI, especially collaborative robots (cobots). Cobots are intended to operate in close proximity to humans, which makes impossible the common hazard control of isolating the robot using fences or other barriers, which is widely used for traditional industrial robots. Automated guided vehicles are a type of cobot that as of 2019 are in common use, often as forklifts or pallet jacks in warehouses or factories. For cobots, sensor malfunctions or unexpected work environment conditions can lead to unpredictable robot behavior and thus to human–robot collisions.

Self-driving cars are another example of AI-enabled robots. In addition, the ergonomics of control interfaces and human–machine interactions may give rise to hazards.

Hazard controls

AI, in common with other computational technologies, requires cybersecurity measures to stop software breaches and intrusions, as well as information privacy measures. Communication and transparency with workers about data usage is a control for psychosocial hazards arising from security and privacy issues. Proposed best practices for employer‐sponsored worker monitoring programs include using only validated sensor technologies; ensuring voluntary worker participation; ceasing data collection outside the workplace; disclosing all data uses; and ensuring secure data storage.

For industrial cobots equipped with AI‐enabled sensors, the International Organization for Standardization (ISO) recommended: (a) safety‐related monitored stopping controls; (b) human hand guiding of the cobot; (c) speed and separation monitoring controls; and (d) power and force limitations. Networked AI-enabled cobots may share safety improvements with each other. Human oversight is another general hazard control for AI.

Risk management

Both applications and hazards arising from AI can be considered as part of existing frameworks for occupational health and safety risk management. As with all hazards, risk identification is most effective and least costly when done in the design phase.

Workplace health surveillance, the collection and analysis of health data on workers, is challenging for AI because labor data are often reported in aggregate and does not provide breakdowns between different types of work, and is focused on economic data such as wages and employment rates rather than skill content of jobs. Proxies for skill content include educational requirements and classifications of routine versus non-routine, and cognitive versus physical jobs. However, these may still not be specific enough to distinguish specific occupations that have distinct impacts from AI. The United States Department of Labor's Occupational Information Network is an example of a database with a detailed taxonomy of skills. Additionally, data are often reported on a national level, while there is much geographical variation, especially between urban and rural areas.

AI systems in the workplace raise ethical concerns related to privacy, fairness, human dignity, and transparency. According to the OECD, these risks must be addressed through robust governance frameworks and accountability mechanisms. Ethical deployment of AI requires clear policies on data usage, explainability of algorithms, and safeguards against discrimination and surveillance.

Standards and regulation

Main article: Regulation of artificial intelligence

As of 2019, ISO was developing a standard on the use of metrics and dashboards, information displays presenting company metrics for managers, in workplaces. The standard is planned to include guidelines for both gathering data and displaying it in a viewable and useful manner.

In the European Union, the General Data Protection Regulation, while oriented towards consumer data, is also relevant for workplace data collection. Data subjects, including workers, have "the right not to be subject to a decision based solely on automated processing". Other relevant EU directives include the Machinery Directive (2006/42/EC), the Radio Equipment Directive (2014/53/EU), and the General Product Safety Directive (2001/95/EC).

Environmental impact of artificial intelligence

From Wikipedia, the free encyclopedia

https://en.wikipedia.org/wiki/Environmental_impact_of_artificial_intelligence 

Nvidia GB200 die with Blackwell processors, an example of graphics processing units (GPUs) used for AI.

A Google Tensor Processing Unit, an example of application-specific integrated circuits used for AI.

The environmental impact of the design, training, deployment and use of artificial intelligence includes the greenhouse gas emissions from generating electricity for data centres and computing hardware, operational and upstream water use, and material impacts from hardware manufacturing, mining and electronic waste.

Estimating AI's environmental effects can be difficult because results depend on how impacts are measured, including whether accounting includes only model computation or also data-centre overhead, idle capacity, hardware manufacture, and local electricity supply.

As these issues have received greater attention, governments and regulators have increasingly considered data-centre reporting requirements, energy-efficiency standards, and broader transparency measures for AI-related resource use.

Carbon footprint and energy use

AI-related energy use arises at multiple stages, including model training, fine-tuning, inference, storage, networking, and supporting infrastructure such as cooling and power conversion.

Individual level

According to research institute Epoch AI, energy consumption per typical ChatGPT query (0.3 watt-hours) is small compared to the average U.S. household consumption per minute (almost 20 watt-hours).

Published estimates of energy use per AI request vary widely across models, tasks and measurement methods. A benchmark study presented at the 2024 ACM Conference on Fairness, Accountability, and Transparency found substantial differences between task types, with lower energy use for some text tasks and much higher energy use for image generation in the study's test conditions. In that benchmark, simple classification tasks consumed about 0.002–0.007 Wh per prompt on average (about 9% of a smartphone charge for 1,000 prompts), while text generation and text summarisation each used about 0.05 Wh per prompt; image generation averaged 2.91 Wh per prompt, and the least efficient image model in the study used 11.49 Wh per image (roughly equivalent to half a smartphone charge).

First-party measurements in production environments have also been published. A 2025 Google study on Gemini assistant serving reported median per-prompt energy, emissions, and water-use estimates under the authors' accounting framework, while noting that different system boundaries can produce substantially different results. The study reported a median text-prompt estimate of about 0.24 Wh, which is roughly as much energy as watching nine seconds of television. The study also stated that software and infrastructure improvements reduced energy use by a factor of 33 and carbon emissions by a factor of 44 for a typical prompt over one year within the authors' framework.

Researchers at the University of Michigan measured the energy consumption of various Meta Llama 3.1 models released in 2024 and found that smaller language models (8 billion parameters) use about 114 joules (0.03167 Wh) per response, while larger models (405 billion parameters) require up to 6,700 joules (1.861 Wh) per response. This corresponds to the energy needed to run a microwave oven for roughly one-tenth of a second and eight seconds, respectively.

Comparisons between AI systems and human labour for specific tasks have produced mixed results and remain sensitive to assumptions about output quality, workload and system boundaries. A 2024 study in Scientific Reports reported 130 to 2900 times lower estimated carbon emissions for selected AI systems than for human writers and illustrators under its assumptions. A later Scientific Reports paper reported a counterexample for programming tasks under its assumptions, finding 5 to 19 times higher estimated emissions for the evaluated AI system than for human programmers on the benchmark used in that study.

System level

Energy use and efficiency

Fueled by growth in artificial intelligence, data centres' demand for power increased in the 2020s.

 

According to the International Energy Agency data centres are expected to account for a relatively small share of global electricity demand growth by 2030.

 

Efficiency improvement of AI related computer chips, 2008–2023. Index of energy intensity of AI computer chips (2008=100, log scale).

AI electricity intensity depends not only on model architecture but also on hardware and facility efficiency. Data-centre operators commonly report Power usage effectiveness (PUE), which measures the ratio of total facility energy to IT equipment energy; a lower PUE indicates less overhead energy for cooling and other supporting infrastructure.

Operators may also publish metrics and case studies on hardware efficiency, cooling systems and power sourcing. In its 2024 environmental report, Google stated that its 2023 total greenhouse gas emissions increased 13% year over year, primarily because of increased data-centre energy consumption and supply-chain emissions, while also reporting lower PUE than industry averages for its own facilities.

The International Energy Agency has also reported that data centres remain a relatively small share of global electricity use overall, but that their local effects can be much more pronounced because demand is geographically concentrated.

Carbon footprint

At system level, AI contributes to rising electricity demand in data centres and related infrastructure. The International Energy Agency estimated that data centres used about 415 TWh of electricity in 2024, or around 1.5% of global electricity consumption, and projected that data-centre electricity use could rise to about 945 TWh by 2030, with AI identified as the main driver of that growth alongside other digital services.

The carbon footprint of AI systems depends strongly on electricity sources, hardware efficiency, utilisation rates, and what stages are included in the accounting. Training large models can require substantial electricity, while total lifecycle impacts also depend on deployment scale and the amount of inference performed after training.

Early analyses of frontier-model development reported rapid historical growth in training compute for selected systems, although later trends have depended on changes in model design, hardware and efficiency gains.

Accounting methods that include upstream or embodied impacts, such as hardware manufacture and facilities construction, can materially affect estimates of AI-related emissions.

Decisions and strategies by individual companies

Large technology companies have reported that the expansion of AI and cloud infrastructure affects their sustainability targets, electricity demand, and resource use. Google, for example, attributed part of its emissions growth in 2023 to increased data-centre energy consumption and supply-chain emissions in its 2024 environmental report.

Cloud and AI companies have also announced measures intended to reduce environmental impacts, including investment in more efficient hardware, low-carbon electricity procurement, alternative cooling systems, and water stewardship programmes. The extent, comparability, and third-party verification of such disclosures vary between firms and jurisdictions.

Water usage

Data centres can use water directly for cooling and indirectly through the water used in electricity generation, depending on the local energy mix. Public reporting on data-centre water use has often been inconsistent, making comparisons between operators and regions difficult.

To standardise operational reporting, The Green Grid proposed the metric water usage effectiveness (WUE), defined as annual site water use divided by IT equipment energy use. WUE does not by itself measure local water stress, source sustainability, or all upstream water impacts. Studies of AI water use also distinguish between water withdrawal and water consumption.

Research on AI-specific water use has argued that the water footprint of AI systems can be difficult to observe and may vary substantially by location, cooling design, and electricity source. A 2025 Communications of the ACM article summarised methods for estimating AI water footprints and emphasised the distinction between water withdrawal and water consumption.

Li and colleagues estimated that global AI water withdrawal could reach 4.2–6.6 billion cubic metres in 2027 under the scenarios examined in their article. Using GPT-3, released by OpenAI in 2020, as an example, they estimated that training the model in Microsoft's U.S. data centres could consume about 700,000 litres of onsite water and about 5.4 million litres in total when offsite electricity-related water use was included; they also estimated that 10–50 medium-length GPT-3 responses could consume about 500 mL of water, depending on when and where the model was deployed. Published prompt-level estimates have also varied by system and accounting framework: the 2025 Google study on Gemini assistant serving reported a median text-prompt estimate of about 0.26 mL under its framework.

Location can materially affect the significance of data-centre water use. Research on U.S. data centres found that one-fifth of servers' direct water footprint came from moderately to highly water-stressed watersheds, while nearly half of servers were fully or partially powered by plants located in water-stressed regions. A 2025 Reuters report, citing data from Verisk Maplecroft and NatureFinance, said that an average mid-sized data centre uses about 1.4 million litres of water per day for cooling and that Phoenix would experience a 32% increase in annual water stress if currently planned data centres come online.

Water use also occurs upstream in semiconductor fabrication, which relies on large quantities of ultrapure water.

E-waste

Main article: Electronic waste

AI systems depend on specialised computing hardware, and rapid turnover in servers and accelerators may contribute to rising e-waste. According to the Global E-waste Monitor 2024, the world generated an estimated 62 million tonnes of e-waste in 2022, and the total was projected to rise to 82 million tonnes by 2030 under its scenarios. The World Health Organization has also identified e-waste as a growing environmental and public-health issue.

A 2024 study in Nature Computational Science estimated that generative AI could add between 1.2 and 5 million tonnes of e-waste by 2030 under the scenarios examined by the authors. In the study's higher-end scenarios, this would represent up to 12% of projected global e-waste by 2030. The authors also estimated that circular-economy strategies along the generative-AI value chain could reduce AI-related e-waste generation by 16–86%.

Mining

AI hardware depends on complex supply chains for metals, minerals and manufactured components. UNCTAD has reported that the expansion of digital infrastructure increases demand for raw materials and raises environmental and distributional concerns linked to extraction, processing and manufacturing.

Specialised chips used in AI systems can depend on supply chains involving critical minerals and other materials whose extraction and processing may have significant environmental and social effects. These impacts are not unique to AI, but may increase as demand for AI-related hardware grows.

Social impact and environmental justice

The environmental effects of AI-related infrastructure are not distributed evenly. Research on U.S. data centres has found that their environmental footprints vary by region and may intersect with local electricity systems, water availability and existing environmental burdens. In that study, one-fifth of servers' direct water footprint came from moderately to highly water-stressed watersheds, while nearly half of servers were fully or partially powered by plants located in water-stressed regions.

Concerns have also been raised about local air pollution, permitting and grid stress in communities hosting AI-related facilities and associated power infrastructure. In 2025, civil-rights and environmental groups challenged permits connected to an xAI facility in the Memphis area, arguing that air-pollution burdens could fall disproportionately on historically overburdened neighbourhoods. The dispute has been the subject of regulatory and legal proceedings.

Climate solutions

Despite concerns about its environmental footprint, AI has been used in environmental and climate-related applications, including weather forecasting, Earth observation, and optimisation in transport and energy systems.

In weather forecasting, peer-reviewed studies have reported strong results for some AI-based forecasting systems under specific evaluation frameworks. A 2023 Nature paper on Pangu-Weather reported strong medium-range forecasting performance relative to a leading numerical weather prediction system in the study's evaluation. AI has also been used in research on extreme weather and climate-event modelling.

AI has also been proposed for mitigation-oriented optimisation. Google's Green Light project, for example, uses traffic data and machine learning to recommend traffic-signal timing adjustments intended to reduce stop-and-go traffic and associated emissions at intersections.

Whether AI produces net environmental benefits at large scale remains an open question, because outcomes depend on deployment choices, rebound effects, additional infrastructure demand and the extent to which electricity and cooling systems are decarbonised.

Conflict on the use of AI for environmental research

There is ongoing debate over the balance between the possible environmental benefits of AI applications and the environmental costs of scaling AI systems. This includes discussion of transparency, efficiency, rebound effects, and the extent to which AI-related infrastructure growth may offset environmental gains from specific applications.

Policy and regulation

United States

In the United States, proposals have been introduced to study and standardise reporting on AI's environmental impacts. The Artificial Intelligence Environmental Impacts Act of 2024 (S. 3732), introduced in the Senate in February 2024, would require a federal study on the environmental impacts of AI, direct the National Institute of Standards and Technology to convene a consortium on measurement and standards, and establish a voluntary reporting system.

European Union

In the European Union, the Energy Efficiency Directive introduced reporting obligations for large data centres. The European Commission has stated that a European database collects information relevant to the energy performance and water footprint of data centres, and that a delegated regulation sets out the information and key performance indicators for the reporting scheme.

EU member states also maintain national AI strategies, some of which include references to sustainability, energy efficiency, or environmental applications of AI.

France

France's AI strategy documents have discussed AI in relation to ecological transition and environmental applications, including the use of digital infrastructure and data for environmental policy.

Germany

Germany's national AI strategy includes sections on the environmental impacts of AI and on research into energy-efficient and sustainable AI applications.

Italy

Italy's national AI strategy documents include sustainability-related priorities and discuss AI applications in areas such as environment, infrastructure, and sustainable development goals.

Environmental impact of bitcoin

From Wikipedia, the free encyclopedia

https://en.wikipedia.org/wiki/Environmental_impact_of_bitcoin 

Bitcoin mining facility in Quebec, Canada

The environmental impact of bitcoin has been characterized in the literature as significant, particularly due to its energy use, greenhouse gas emissions, and electronic waste. Bitcoin mining, the process by which bitcoins are created and transactions are finalized, is energy-consuming and results in carbon emissions, as 48% of the electricity used in 2025 was generated through fossil fuels while 52% was generated through sustainable energy sources. Moreover, bitcoins are mined on specialized computer hardware resulting in electronic waste. Scholars argue that bitcoin mining could support renewable energy development by utilizing surplus electricity from wind and solar. As of 2025, several empirical studies report an association between higher bitcoin-mining electricity use and worse environmental-sustainability indicators. 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

Electricity consumption of the bitcoin network since 2016 (annualized). The upper and lower bounds 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 scheme and as a potential solution to its environmental issues. Bitcoin advocates oppose such a change, arguing that proof of work is needed to secure the network.

Bitcoin mining's distribution makes it difficult for researchers to identify the location of miners and electricity use. It is therefore difficult to translate energy consumption into carbon emissions. As of 2025, a non-peer-reviewed study by the Cambridge Centre for Alternative Finance (CCAF) estimated that bitcoin consumed 138 TWh (500 PJ) annually, representing 0.5% of the world's electricity consumption and resulting in annual greenhouse gas emissions of 39.8 Mt CO₂, representing 0.08% of global emissions and comparable to Slovakia's emissions.

Bitcoin mining energy mix

Until 2021, most bitcoin mining was done in China. Chinese miners relied 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 mining operations 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.

As of 2025, a CCAF report based on a survey of 49 bitcoin-mining firms (about 48% of network hashrate at the time of data collection) reported their electricity mix as renewables (43%), natural gas (38%), nuclear (10%), and coal (9%). Research by the nonprofit tech company WattTime estimated that US miners consumed 54% fossil fuel-generated power. In 2023, Jamie Coutts, a crypto analyst writing for Bloomberg Terminal, said that renewables represented about half of global bitcoin mining sources.

Environmental effects of electricity use

A study in Scientific Reports found that from 2016 to 2021, each US dollar worth of mined bitcoin caused 35 cents worth of climate damage, compared to 95 for coal, 41 for gasoline, 33 for beef, and 4 for gold mining. A 2025 paper published in Nature Communications found that the 34 largest U.S. bitcoin mines consumed 32.3 TWh of electricity from Aug 2022 to July 2023, 33% more than Los Angeles. Fossil fuel power plants generated 85% of the increased electricity demand from these mines.

The European Securities and Markets Authority and the European Central Bank suggested that using renewable energy for mining may limit the availability of clean energy for the general population.

A 2025 study in Scientific Reports of ten major cryptocurrency-producing countries (2019–2022) found that Bitcoin mining's electricity use was linked to worse environmental sustainability. A larger share of renewables softened but did not eliminate these effects during the study period, and the impact on water use was limited. A 2025 peer-reviewed study in Sustainable Development that used monthly data from 2015–2023 and DARDL/KRLS methods reported an association between higher Bitcoin-mining electricity use and worse environmental sustainability in an SDG-framed measure; the authors characterized this as a risk factor for sustainability goals. A 2025 life-cycle assessment in ACS Sustainable Chemistry & Engineering quantified Bitcoin's carbon, water, and land footprints, concluding that the network's resource consumption poses sustainability challenges and highlighting the need for technological advances and cleaner energy sources.

Proposed mitigation strategies and debate

Reducing the environmental impact of bitcoin is possible by mining only using clean electricity sources. Bitcoin mining representatives argue that their industry creates opportunities for wind and solar companies, leading to a debate on whether bitcoin could be an ESG investment.

According to a 2023 ACS Sustainable Chemistry & Engineering paper, bitcoin mining may offer opportunities to support greenhouse-gas reduction and the renewable-energy transition, by using otherwise-curtailed renewable-energy and acting as a flexible electricity load. 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. Two studies from 2023 and 2024 led by Fengqi You concluded 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 and mitigate climate change. Another 2024 study by Fengqi You published in the Proceedings of the National Academy of Sciences of the United States of America showed that pairing green hydrogen infrastructure with bitcoin mining can accelerate the deployment of solar and wind power capacities. A 2024 study published in Heliyon simulated that a solar-powered bitcoin mining system could achieve a return on investment in 3.5 years compared to 8.1 years for selling electricity to the grid, while preventing 50,000 tons of CO₂ emissions annually. The authors note that proof-of-stake cryptocurrencies cannot provide these incentives.

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 where flaring is prohibited this practice has allowed more oil drills to operate by offsetting costs, delaying fossil fuel phase-out. Commenting on one pilot project with ExxonMobil, political scientist Paasha Mahdavi noted in 2022 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. According to a 2024 paper published in the Journal of Cleaner Production, bitcoin mining can finance methane mitigation of landfill gases.

Comparison to other payment systems

In 2018 Nature Climate Change published a study on projections of Bitcoin growth authored by Camilo Mora and fellow researchers from the University of Hawaiʻi at Mānoa. The paper considered the potential effects on global CO₂ emissions should Bitcoin eventually replace other cashless transactions, finding that the associated energy consumption of Bitcoin usage could potentially produce enough CO₂ emissions to lead to a 2°C increase in global mean average temperature within 30 years under certain assumptions.^[34][35] Several subsequent papers contested the researchers' assumptions. Mora and fellow publishers of the original article defended their paper.

In a 2023 study published in Ecological Economics, researchers from the International Monetary Fund estimated that the global payment system represented about 0.2% of global electricity consumption, comparable to the consumption of Portugal or Bangladesh. For bitcoin, energy used is estimated around 500 kWh 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. Layer 2 solutions, like the Lightning Network, and batching, 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.

OECD notes that a direct comparison between blockchains, which are an infrastructure technology, and the energy consumption of financial sector activity may not be an appropriate comparison.

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, one 2021 study estimated that mining devices had an average lifespan of 1.3 years until they became unprofitable and had to be replaced, resulting in significant electronic waste. This study estimated bitcoin's annual e-waste to be over 30,000 tonnes (comparable to the small IT equipment waste produced by the Netherlands) and each transaction to result in 272 g (9.6 oz) of e-waste. A 2024 systematic review criticized this estimate and argued, based on market sales and IPO data, that bitcoin mining hardware lifespan was closer to 4–5 years. According to the CCAF, e-waste is significantly lower, estimated at 2,300 tonnes in 2024 as 87% of hardware is recycled, sold or repurposed.

Noise pollution

Field measurements around several large U.S. bitcoin mines show steady background sound in nearby residential areas commonly in the mid-30s to low-50s dBA, with higher levels closer to the mining facility. A 2024 consultant study commissioned by Hood County, Texas, measured background levels ranging from 35–53 dBA and recorded a maximum around 59 dBA at two neighborhood locations, while measurements near the site ranged 60–65 dBA. Separately, a 2022 Washington Post investigation that logged ~19,750 one-minute readings outside homes near a North Carolina cryptomine found sound levels above 55 dBA in 98% of readings and above 60 dBA in over 30% of readings. Mitigation approaches reported by operators and consultants include acoustic barriers, equipment enclosures, optimized fan controls, and immersion cooling; however, effectiveness and adoption vary by site.

Water footprint

According to a 2023 non-peer-reviewed commentary, bitcoin's water footprint reached 1,600 gigalitres (5.7×10¹⁰ cu ft) in 2021, due to direct water consumption on site and indirect consumption from electricity generation. The author notes that this water footprint could be mitigated by using immersion cooling and power sources that do not require freshwater such as wind, solar, and thermoelectric power generation with dry cooling.

As of 2025, an investigation by The Texas Observer reported that a bitcoin mining facility in Corpus Christi, Texas, used approximately 127,500 gallons of fresh water per day, based on municipal billing data.

Land footprint

A 2023 study in Earth's Future estimated the global land-use footprint attributable to bitcoin mining in 2020–2021 at 1,870 km² (720 mi²), about 1.4 times the area of Los Angeles.

Health and local air pollution

A 2025 study in Nature Communications found that the demand from 34 large U.S. bitcoin mines increased PM2.5 pollution and exposed about 1.9 million people to ≥0.1 μg/m³ additional PM2.5, sometimes far from the mines. A 2024 review in Environmental Research linked proof-of-work mining to higher air pollution and potential health risks, and calling for mitigation and better data. A 2024 JAMA Viewpoint described potential community hazards from cryptocurrency mining, including air and noise pollution, and recommended protections for vulnerable groups. One 2020 paper found that, in 2018, each US$1 of bitcoin created was associated with about US$0.49 in combined health and climate damages in the United States (US$0.37 in China). A 2024 analysis estimated the climate and health damages from U.S. mining during 2019–2021 exceeded the value of coins generated in many geographic hotspots.

Regulatory responses

China's 2021 bitcoin mining ban was partly motivated by its role in illegal coal mining and environmental concerns.

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. In January 2024, the US Energy Information Administration launched a mandatory survey of cryptocurrency miner energy use but suspended it one month later after it was successfully challenged by miners before the United States District Court for the Western District of Texas.

In Canada, due to high demand from the industry and concerned that their renewable electricity could be better used, the provinces Manitoba and British Columbia paused new connections of bitcoin mining facilities to the hydroelectric grid in late 2022 for 18 months while Hydro-Québec increased prices and capped usage for bitcoin miners.

In October 2022, due to the global energy crisis, the European Commission invited member states to lower the electricity consumption of crypto-asset miners and end tax breaks and other incentives benefiting them.

Green computing

From Wikipedia, the free encyclopedia
https://en.wikipedia.org/wiki/Green_computing

Green computing, green IT (information technology), or Information and Communication Technology Sustainability, is the study and practice of environmentally sustainable computing or IT.

The goals of green computing include optimising energy efficiency during the product's lifecycle; leveraging greener energy sources to power the product and its network; improving the reusability, maintainability, and repairability of the product to extend its lifecycle; improving the recyclability or biodegradability of e-waste to support circular economy ambitions; and aligning the manufacture and use of IT systems with environmental and social goals. Green computing is important for all classes of systems, ranging from handheld systems to large-scale data centers. According to the International Energy Agency, data centres accounted for about 1.5% of global electricity consumption in 2024 (~415 TWh), and under its central scenario, demand could roughly double to ~945 TWh by 2030, with AI workloads a major driver of growth. Sustainable development is a concept that redefines the notion of the general interest by integrating environmental, social, and economic considerations. Many corporate IT departments have green computing initiatives to reduce the environmental effect of their IT operations. Yet it is also clear that the environmental footprint of the sector is significant, estimated at 5-9% of the world's total electricity use and more than 2% of all emissions. Data centers and telecommunications networks will need to become more energy efficient, reuse waste energy, use more renewable energy sources, and use less water for cooling to stay competitive. In the European Union, policy efforts and industry initiatives aim for climate-neutral data centers by 2030.

The carbon emissions associated with manufacturing devices and network infrastructures is also a key factor.

Green computing can involve complex trade-offs. It can be useful to distinguish between IT for environmental sustainability and the environmental sustainability of IT. Although green IT focuses on the environmental sustainability of IT, in practice these two aspects are often interconnected. For example, launching an online shopping platform may increase the carbon footprint of a company's own IT operations, while at the same time helping customers to purchase products remotely, without requiring them to drive, in turn reducing greenhouse gas emission related to travel. The company might be able to take credit for these decarbonisation benefits under its Scope 3 emissions reporting, which includes emissions from across the entire value chain.

Origins

Energy Star logo

In 1992, the U.S. Environmental Protection Agency launched Energy Star, a voluntary labeling program that is designed to promote and recognize the energy efficiency in monitors, climate control equipment, and other technologies. This resulted in the widespread adoption of sleep mode among consumer electronics. Concurrently, the Swedish organization TCO Development launched the TCO Certified program to promote low magnetic and electrical emissions from CRT-based computer displays; this program was later expanded to include criteria on energy consumption, ergonomics, and the use of hazardous materials in construction.

Regulations and industry initiatives

In 2009 the Organisation for Economic Co-operation and Development (OECD) published a survey of over 90 government and industry initiatives on "Green ICTs" (Information and Communication Technologies), the environment and climate change. The report concluded that initiatives tended to concentrate on the greening ICTs themselves, rather than on their actual implementation to reduce global warming and environmental degradation. In general, only 20% of initiatives had measurable targets, with government programs tending to include targets more frequently than business associations.

Government

Many governmental agencies have continued to implement standards and regulations that encourage green computing. The Energy Star program was revised in October 2006 to include stricter efficiency requirements for computer equipment, along with a tiered ranking system for approved products.

By 2008, 26 US states established statewide recycling programs for obsolete computers and consumer electronics equipment. The statutes either impose an "advance recovery fee" for each unit sold at retail or require the manufacturers to reclaim the equipment at disposal.

In 2010, the American Recovery and Reinvestment Act (ARRA) was signed into legislation by President Obama. The bill allocated over $90 billion to be invested in green initiatives (renewable energy, smart grids, energy efficiency, etc.) In January 2010, the U.S. Energy Department granted $47 million of the ARRA money towards projects to improve the energy efficiency of data centers. The projects provided research to optimize data center hardware and software, improve power supply chain, and data center cooling technologies.

Green Digital Governance

Green digital governance refers to the use of information and communication technology (ICT) to support environmentally sustainable policies and practices. It describes a strategy with which an organisation strives to align its information and communications technology with sustainability goals. This can include using digital tools and platforms to monitor and regulate environmental impact, as well as promoting the development and use of clean and renewable energy sources in the technology sector. The goal of green digital governance is to reduce the carbon footprint of the digital economy and to support the transition to a more sustainable and resilient society.

Both the green and the digital transitions are on the agenda for most European countries, as well as the EU as a whole. Documents and goals such as the European Green Deal and the Sustainable Development Goals, fit for 55, Digital Europe and others have begun the transitions. These two transitions often contradict each other, as digital technologies have substantial environmental footprints that go against the targets of the green transition.

The European Union sees digitalisation and the adoption of ICT (Information and Communications Technology) solutions as an important tool for creating greener solutions, while also acknowledging that in order to achieve the desired positive environmental impact, the tools themselves must be environmentally sustainable. The green transition may accelerate innovation and adoption of digital solutions offering the ICT sector new opportunities for becoming more competitive. The synergy created as a result of the green transition and digitalisation brings social, economic and environmental benefits, which is a goal of environmentally friendly digital governments and the creation of green ICT solutions in general.

The digital component is expected to also be used to reach the ambitions of the European Green Deal and Sustainable Development Goals. As powerful enablers for the sustainability transition, digital solutions can advance the circular economy, support the decarbonisation of all sectors and reduce the environmental and social footprint of products placed on the EU market. For example, key sectors such as precision agriculture, transport and energy can benefit from digital solutions in pursuing the sustainability objectives of the European Green Deal.

E-government services can provide solutions to the environmental problem. The possibility for a citizen to fully request and get a service online would render, in addition to cost savings for the public authorities and increased citizen satisfaction, reductions of carbon emissions and paper consumption.

Industry

• iMasons Climate Accord Founded in 2022, the (ICA) is a historic cooperative of companies committed to reducing carbon in digital infrastructure materials, products, and power.
• Climate Savers Computing Initiative (CSCI) is an effort to reduce the electric power consumption of PCs in active and inactive states. The CSCI provides a catalog of green products from its member organizations, and information for reducing PC power consumption. It was started on June 12, 2007. The name stems from the World Wildlife Fund's Climate Savers program, which began in 1999. The WWF is a member of the Computing Initiative.
• The Green Electronics Council offers the Electronic Product Environmental Assessment Tool (EPEAT) to assist in the purchase of "greener" computing systems. The Council evaluates computing equipment on 51 criteria – 23 required and 28 optional - that measure a product's efficiency and sustainability attributes. Products are rated Gold, Silver, or Bronze, depending on how many optional criteria they meet. On January 24, 2007, President George W. Bush issued Executive Order 13423, which requires all United States Federal agencies to use EPEAT when purchasing computer systems.
• The Green Grid is a global consortium dedicated to advancing energy efficiency in data centers and business computing ecosystems. It was founded in February 2007 by several key companies in the industry – AMD, APC, Dell, HP, IBM, Intel, Microsoft, Rackable Systems, SprayCool (purchased in 2010 by Parker), Sun Microsystems and VMware. The Green Grid has since grown to hundreds of members, including end-users and government organizations focused on improving data center infrastructure efficiency (DCIE).
• The Green500 list rates supercomputers by energy efficiency (megaflops/watt), encouraging a focus on efficiency rather than absolute performance.
• Green Comm Challenge is an organization that promotes the development of energy conservation technology and practices in the field of ICT.
• The Transaction Processing Performance Council (TPC) Energy specification augments existing TPC benchmarks by allowing optional publications of energy metrics alongside performance results.
• SPECpower is the first industry standard benchmark that measures power consumption in relation to performance for server-class computers. Other benchmarks which measure energy efficiency include SPECweb, SPECvirt, and VMmark.

Approaches

Modern IT systems rely on a complicated mix of people, networks, and hardware; as such, a green computing initiative ideally covers these areas. A solution may also need to address end user satisfaction, management restructuring, regulatory compliance, and return on investment (ROI). There are also fiscal motivations for companies to take control of their own power consumption; "of the power management tools available, one of the most powerful may still be simple, plain, common sense."

Product longevity

Gartner maintains that the PC manufacturing process accounts for 70% of the natural resources used in the life cycle of a PC. In 2011, Fujitsu released a life-cycle assessment (LCA) of a desktop that show that manufacturing and end of life accounts for the majority of this desktop's ecological footprint. Therefore, the biggest contribution to green computing usually is to prolong the equipment's lifetime. A recent life-cycle assessment comparing a desktop and a laptop for a four-year use case with similar performance found total carbon footprints of 679.1 kg CO2e for the desktop versus 286.1 kg CO2e for the laptop; for both systems, manufacturing was the largest contributor, followed by the use phase.

Another report from Gartner recommends to "Look for product longevity, including upgradability and modularity." For instance, manufacturing a new PC makes a far bigger ecological footprint than manufacturing a new RAM module to upgrade an existing one.

Data center design

Data center facilities are heavy consumers of energy, accounting for between 1.1% and 1.5% of the world's total energy use in 2010. The U.S. Department of Energy estimates that data center facilities consume up to 100 to 200 times more energy than standard office buildings.

Energy efficient data center design should address all of the energy use aspects included in a data center: from the IT equipment to the HVAC (Heating, ventilation and air conditioning) equipment to the actual location, configuration and construction of the building.

The U.S. Department of Energy specifies five primary areas on which to focus energy efficient data center design best practices:

• Information technology (IT) systems
• Environmental conditions
• Air management
• Cooling systems
• Electrical systems

Additional energy efficient design opportunities specified by the U.S. Department of Energy include on-site electrical generation and recycling of waste heat.

Energy efficient data center design should help to better use a data center's space, and increase performance and efficiency.

Software and deployment optimization

Algorithmic efficiency

Main article: Algorithmic efficiency

Further information: Analysis of algorithms

The efficiency of algorithms affects the amount of computer resources required for any given computing function and there are many efficiency trade-offs in writing programs. Algorithm changes, such as switching from a slow (e.g. linear) search algorithm to a fast (e.g. hashed or indexed) search algorithm can reduce resource usage for a given task from substantial to close to zero. In 2009, a study by a physicist at Harvard estimated that the average Google search released 7 grams of carbon dioxide (CO₂). However, Google disputed this figure, arguing that a typical search produced only 0.2 grams of CO₂. Similarly, the environmental footprint of distributed computing is heavily dependent on the algorithmic efficiency of its underlying consensus mechanisms. Mathematical consumption models evaluating Sybil attack resistance schemes indicate that ledger architectures utilizing directed acyclic graphs (DAG) to achieve consensus via virtual voting present lower energy consumption per transaction when compared to traditional proof-of-work systems and standard proof-of-stake blockchains.

Similarly, the environmental footprint of distributed computing is heavily dependent on the algorithmic efficiency of its underlying consensus mechanisms. Mathematical consumption models evaluating Sybil attack resistance schemes indicate that ledger architectures utilizing directed acyclic graphs (DAG) to achieve consensus via virtual voting present lower energy consumption per transaction when compared to traditional proof-of-work systems and standard proof-of-stake blockchains.

Resource allocation

Main article: Resource allocation

Algorithms can also be used to route data to data centers where electricity is less expensive. Researchers from MIT, Carnegie Mellon University, and Akamai have tested an energy allocation algorithm that routes traffic to the location with the lowest energy costs. The researchers project up to 40 percent savings on energy costs if their proposed algorithm were to be deployed. However, this approach does not actually reduce the amount of energy being used; it reduces only the cost to the company using it. Nonetheless, a similar strategy could be used to direct traffic to rely on energy that is produced in a more environmentally friendly or efficient way. A similar approach has also been used to cut energy usage by routing traffic away from data centers experiencing warm weather; this allows computers to be shut down to avoid using air conditioning.

Larger server centers are sometimes located where energy and land are inexpensive and readily available. Local availability of renewable energy, climate that allows outside air to be used for cooling, or locating them where the heat they produce may be used for other purposes could be factors in green siting decisions.

Approaches to actually reduce the energy consumption of network devices by proper network/device management techniques have been surveyed Bianzino, et al. The authors grouped the approaches into 4 main strategies, namely (i) Adaptive Link Rate (ALR), (ii) Interface Proxying, (iii) Energy Aware Infrastructure, and (iv) Maximum Energy Aware Applications.

Virtualizing

Main article: Platform virtualization

See also: Comparison of platform virtualization software

Computer virtualization refers to the abstraction of computer resources, such as the process of running two or more logical computer systems on one set of physical hardware. The concept originated with the IBM mainframe operating systems of the 1960s, and was commercialized for x86-compatible computers, and other computer systems, in the 1990s. With virtualization, a system administrator can combine several formerly physical systems as virtual machines on one powerful system, thereby conserving resources by removing need for some of the original hardware and reducing power and cooling consumption. Virtualization can assist in distributing work so that servers are either busy or put in a low-power sleep state. Several commercial companies and open-source projects now offer software packages to enable a transition to virtual computing. Intel Corporation and AMD have also built proprietary virtualization enhancements to the x86 instruction set into each of their CPU product lines, in order to facilitate virtual computing.

New virtual technologies, such as operating system-level virtualization can also be used to reduce energy consumption. These technologies make a more efficient use of resources, thus reducing energy consumption by design. Also, the consolidation of virtualized technologies is more efficient than the one done in virtual machines, so more services can be deployed in the same physical machine, reducing the amount of hardware needed.

Terminal servers

Main article: Terminal server

Terminal servers have also been used in green computing. When using the system, users at a terminal connect to a central server; all of the actual computing is done on the server, but the end user experiences the system operating as if it were on the terminal. These can be combined with thin clients, which use up to 1/8 the amount of energy of a normal workstation, resulting in a decrease of energy costs and consumption. There has been an increase in using terminal services with thin clients to create virtual labs. Examples of terminal server software include Terminal Services for Windows and the Linux Terminal Server Project (LTSP) for the Linux operating system. Software-based remote desktop clients such as Windows Remote Desktop and RealVNC can provide similar thin-client functions when run on low power hardware that connects to a server.

Data Compression

Main article: Data compression

Data compression, which involves using fewer bits to encode information, may also be used in green computing depending on the structure of the data. Since it is highly data specific, data compression strategies may result in using more energy or resources than necessary in some cases. However, choosing a well-suited compression algorithm for the dataset can yield greater power efficiency and reduce network and storage requirements. There is a tradeoff between compression ratio and energy consumption. Deciding whether or not this is worthwhile depends on the dataset's compressibility. Compression improves energy efficiency for data with a compression ratio much less than roughly 0.3, and hurts for data with higher compression ratios.

Power management

Main article: Power management

The Advanced Configuration and Power Interface (ACPI), an open industry standard, allows an operating system to directly control the power-saving aspects of its underlying hardware. This allows a system to automatically turn off components such as monitors and hard drives after set periods of inactivity. In addition, a system may hibernate, when most components (including the CPU and the system RAM) are turned off. ACPI is a successor to an earlier Intel-Microsoft standard called Advanced Power Management, which allows a computer's BIOS to control power management functions.

Some programs allow the user to manually adjust the voltages supplied to the CPU, which reduces both the amount of heat produced and electricity consumed. This process is called undervolting. Some CPUs can automatically undervolt the processor, depending on the workload; this technology is called "SpeedStep" on Intel processors, "PowerNow!"/"Cool'n'Quiet" on AMD chips, LongHaul on VIA CPUs, and LongRun with Transmeta processors.

Data center power

Data centers, which have been criticized for their extraordinarily high energy demand, are a primary focus for proponents of green computing. According to a Greenpeace study, data centers represent 21% of the electricity consumed by the IT sector, which is about 382 billion kWh a year.

Data centers can potentially improve their energy and space efficiency through techniques such as storage consolidation and virtualization. Many organizations are aiming to eliminate underused servers, resulting in lower energy usage. The U.S. federal government set a minimum 10% reduction target for data center energy usage by 2011. With the aid of a self-styled ultra-efficient evaporative cooling technology. Google Inc. claims to have reduced its energy consumption to 50% of the industry average.

Cryptocurrency mining, particularly for proof-of-work currencies like Bitcoin, also uses significant amounts of energy globally. Advocates have argued that cryptocurrency can help to drive investment in green energy.

Operating system support

Microsoft Windows has included limited PC power management features since Windows 95. These initially provided for stand-by (suspend-to-RAM) and a monitor low power state. Further iterations of Windows added hibernate (suspend-to-disk) and support for the ACPI standard. Windows 2000 was the first NT-based operating system to include power management. This required major changes to the underlying operating system architecture and a new hardware driver model. Windows 2000 also introduced Group Policy, a technology that allowed administrators to centrally configure most Windows features. However, power management was not one of those features. This is probably because the power management settings design relied upon a connected set of per-user and per-machine binary registry values, effectively leaving it up to each user to configure their own power management settings.

This approach, which is not compatible with Windows Group Policy, was repeated in Windows XP. The reasons for this design decision by Microsoft are not known, and it has resulted in heavy criticism. Microsoft significantly improved this in Windows Vista by redesigning the power management system to allow basic configuration by Group Policy. The support offered is limited to a single per-computer policy. Windows 7 retains these limitations but includes refinements for timer coalescing, processor power management, and display panel brightness. The most significant change in Windows 7 is in the user experience. The prominence of the default High Performance power plan has been reduced with the aim of encouraging users to save power.

Third-party PC power management software for adds features beyond those built-in to the Windows operating system. Most products offer Active Directory integration and per-user/per-machine settings with the more advanced offering multiple power plans, scheduled power plans, anti-insomnia features and enterprise power usage reporting.

Linux systems started to provide laptop-optimized power-management in 2005, with power-management options being mainstream since 2009.

Power supply

Desktop computer power supplies are in general 70–75% efficient, dissipating the remaining energy as heat. A certification program called 80 Plus certifies PSUs that are at least 80% efficient; typically these models are drop-in replacements for older, less efficient PSUs of the same form factor. As of July 20, 2007, all new Energy Star 4.0-certified desktop PSUs must be at least 80% efficient.

Storage

Smaller form factor (e.g., 2.5 inch) hard disk drives often consume less power per gigabyte than physically larger drives. Unlike hard disk drives, solid-state drives store data in flash memory or DRAM. With no moving parts, power consumption may be reduced somewhat for low-capacity flash-based devices.

As hard drive prices have fallen, storage farms have tended to increase in capacity to make more data available online. This includes archival and backup data that would formerly have been saved on tape or other offline storage. The increase in online storage has increased power consumption. Reducing the power consumed by large storage arrays, while still providing the benefits of online storage, is a subject of ongoing research.

Video card

A fast GPU may be the largest power consumer in a computer.

Energy-efficient display options include:

• No video card – use a shared terminal, shared thin client, or desktop sharing software if display is required.
• Use motherboard video output – typically low 3D performance and low power.
• Select a GPU based on low idle power, average wattage, or performance per watt.

Display

Unlike other display technologies, electronic paper does not use any power while displaying an image. CRT monitors typically use more power than LCD monitors. They also contain significant amounts of lead. LCD monitors typically use a cold-cathode fluorescent bulb to provide light for the display. Most newer displays use an array of light-emitting diodes (LEDs) in place of the fluorescent bulb, which further reduces the amount of electricity used by the display. Fluorescent back-lights also contain mercury, whereas LED back-lights do not.

A light-on-dark color scheme, also called dark mode, is a color scheme that requires less energy to display on new display technologies, such as OLED. This positively impacts battery life and energy consumption. While an OLED will consume around 40% of the power of an LCD displaying an image that is primarily black, it can use more than three times as much power to display an image with a white background, such as a document or web site. This can lead to reduced battery life and increased energy use, unless a light-on-dark color scheme is used. A 2018 article in Popular Science suggests that "Dark mode is easier on the eyes and battery" and displaying white on full brightness uses roughly six times as much power as pure black on a Google Pixel, which has an OLED display. Apple's iOS 13 and iPadOS 13 both feature a light-on dark mode, which would allow third-party developers to implement their own dark themes. Google's Android 10 features a system-level dark mode.

Materials recycling

Main articles: Electronic waste, computer recycling, and Waste Electrical and Electronic Equipment Directive

Recycling computing equipment can keep harmful materials such as lead, mercury, and hexavalent chromium out of landfills, and can replace equipment that otherwise would need to be manufactured, saving further energy and emissions. Computer systems that have outlived their original function can be re-purposed, or donated to various charities and non-profit organizations. However, many charities have recently imposed minimum system requirements for donated equipment. Additionally, parts from outdated systems may be salvaged and recycled through certain retail outlets and municipal or private recycling centers. Computing supplies, such as printer cartridges, paper, and batteries may be recycled as well.

A drawback to many of these schemes is that computers gathered through recycling drives are often shipped to developing countries where environmental standards are less strict than in North America and Europe. The Silicon Valley Toxics Coalition has estimated that 80% of the post-consumer e-waste collected for recycling is shipped abroad to countries such as China and India.

In 2011, the collection rate of e-waste remained low, even in the most ecology-responsible countries like France. In the U.S., e-waste collection was at a 14% annual rate between electronic equipment sold and e-waste collected for 2006 to 2009.

The recycling of old computers raises a privacy issue. The old storage devices still hold private information, such as emails, passwords, and credit card numbers, which can be recovered simply by using software available freely on the Internet. Deletion of a file does not actually remove the file from the hard drive. Before recycling a computer, users should remove the hard drive, or hard drives if there is more than one, and physically destroy it or store it somewhere safe. There are some authorized hardware recycling companies to whom the computer may be given for recycling, and they typically sign a non-disclosure agreement.

Cloud computing

Main article: Cloud computing

Cloud computing may help to address two major ICT challenges related to green computing – energy usage and embodied carbon. Hyperscale data centers such as those operated by AWS, Azure, and GCP can benefit from economies of scale, and virtualization, dynamic provisioning environment, multi-tenancy and green data center approaches can enable more efficient resource allocation. Organizations may be able to reduce their direct energy consumption and carbon emissions by up to 30% and 90% respectively by moving certain on-premises applications into the public cloud.

However, critics point to shortcomings in the carbon tracking and management tools provided by major cloud providers. GreenOps, also known as DevGreenOps, DevSusOps or DevSustainableOps, is emerging as a framework to include sustainability into cloud management. Carbon-aware computing and grid-aware computing can form part of a GreenOps approach. This includes techniques like demand shifting, which means moving computational workloads to locations or times of day with cleaner energy in the grid. Demand shaping is a similar technique, which focuses on adjusting workloads according to the amount of clean energy currently available.

Edge computing

Main article: Edge computing

New technologies such as edge and fog computing are a solution to reducing energy consumption. These technologies allow redistributing computation near its use, thus reducing energy costs in the network. Furthermore, having smaller data centers, the energy used in operations such as refrigerating and maintenance is reduced.

Remote work

Remote work using teleconference and telepresence technologies is often implemented in green computing initiatives. The advantages include increased worker satisfaction, reduction of greenhouse gas emissions related to travel, and increased profit margins as a result of lower overhead costs for office space, heat, lighting, etc. The average annual energy consumption for U.S. office buildings is over 23 kilowatt hours per square foot, with heat, air conditioning and lighting accounting for 70% of all energy consumed. Other related initiatives, such as Hoteling, reduce the square footage per employee as workers reserve space only when needed. Many types of jobs, such as sales, consulting, and field service, integrate well with this technique.

Voice over IP (VoIP) reduces the telephony wiring infrastructure by sharing the existing Ethernet copper. VoIP and phone extension mobility also made hot desking more practical. Wi-Fi consume 4 to 10 times less energy than 4G.

Telecommunication network devices energy indices

In 2013 ICT energy consumption, in the US and worldwide, was estimated respectively at 9.4% and 5.3% of the total electricity produced. The energy consumption of ICTs is today significant even when compared with other industries. Some studies have tried to identify the key energy indices that allow a relevant comparison between different devices (network elements). This analysis was focused on how to optimise device and network consumption for carrier telecommunication by itself. The target was to allow an immediate perception of the relationship between the network technology and the environmental effect. These studies are at the start and further research will be necessary.

Supercomputers

The Green500 list was first announced on November 15, 2007, at SC|07. As a complement to the TOP500, the listing of the Green500 began a new era where supercomputers can be compared by performance-per-watt. As of 2019, two Japanese supercomputers topped the Green500 energy efficiency ranking with performance exceeding 16 GFLOPS/watt, and two IBM AC922 systems followed with performance exceeding 15 GFLOPS/watt.

Education and certification

Green computing programs

Degree and postgraduate programs provide training in a range of information technology concentrations along with sustainable strategies to educate students on how to build and maintain systems while reducing its harm to the environment. The Australian National University (ANU) offers "ICT Sustainability" as part of its information technology and engineering masters programs. Athabasca University offers a similar course "Green ICT Strategies", adapted from the ANU course notes by Tom Worthington. In the UK, Leeds Beckett University offers an MSc Sustainable Computing program in both full- and part-time access modes.

Green computing certifications

Some certifications demonstrate that an individual has specific green computing knowledge, including:

• Green Computing Initiative – GCI offers the Certified Green Computing User Specialist (CGCUS), Certified Green Computing Architect (CGCA) and Certified Green Computing Professional (CGCP) certifications.
• Information Systems Examination Board (ISEB) Foundation Certificate in Green IT is appropriate for showing an overall understanding and awareness of green computing and where its implementation can be beneficial.
• Singapore Infocomm Technology Federation (SiTF) Singapore Certified Green IT Professional is an industry endorsed professional level certification offered with SiTF authorized training partners. Certification requires completion of a four-day instructor-led core course, plus a one-day elective from an authorized vendor.
• Australian Computer Society (ACS) The ACS offers a certificate for "Green Technology Strategies" as part of the Computer Professional Education Program (CPEP). Award of a certificate requires completion of a 12-week e-learning course designed by Tom Worthington, with written assignments.

Ratings

Since 2010, Greenpeace has maintained a list of ratings of prominent technology companies in several countries based on how clean the energy used by that company is, ranging from A (the best) to F (the worst).

ICT and energy demand

Digitalization has brought additional energy consumption; energy-increasing effects have been greater than the energy-reducing effects. Four energy consumption increasing effects are:

1. Direct effect – Strong increases of (technical) energy efficiency in ICT are countered by the growth of the sector.
2. Efficiency and rebound effects – Rebound effects are high for ICT and increased productivity often leads to new behaviors that are more energy intensive.
3. Economic growth – Positive effect of digitalization on economic growth.
4. Sectoral change – Growth of ICT services tends not to replace, but come on top of existing services.