Data centres and data transmission networks

Tracking Clean Energy Progress

On track

As the world becomes increasingly digitalised, data centres and data transmission networks are emerging as an important source of energy demand, each accounting for about 1% of global electricity demand. Despite exponential growth in demand for these services, huge strides in energy efficiency have helped to limit electricity demand growth. Sustained efforts by the ICT industry to improve energy efficiency, as well as government policies to promote best practices, will be critical to keep energy demand in check over the coming decades.

George Kamiya
Lead author

Global trends in internet traffic, data centre workloads, and data centre energy use

	Internet traffic	Data centre workloads	Data centre energy use
2015	100	100	100
2016	138	133	102
2017	182	168	102
2018	237	206	104
2019	312	239	101
2020	404	274	100
2021	519	313	100
{"chart":{"type":"line","height":"45%"},"plotOptions":{"series":{"marker":{"enabled":false},"showInLegend":true}},"tooltip":{"valueSuffix":" (2015 = 100)"},"yAxis":{"title":{"text":"Index (2015 = 100)"},"min":0}}

Back to Buildings sector | TCEP overview 🕐 Last updated Monday, May 27, 2019

Tracking progress

Global internet traffic has tripled since 2015, and is expected to further double by 2022 to 4.2 zettabytes per year (4.2 trillion gigabytes) (Cisco, 2015; 2018; 2019). The number of mobile internet users is expected to increase from 3.6 billion in 2018 to 5 billion by 2025, while the number of Internet of Things (IoT) connections is expected to triple from 7.5 billion in 2018 to over 25 billion by 2025 (GSM Association, 2019).

These trends are driving exponential growth in demand for data centre and network services.

Data centres

Most of the world’s Internet Protocol (IP) traffic goes through data centres. Greater connectivity is therefore driving up demand for data centre services and energy use (mostly electricity), with multiplying effects: for every bit of data that travels the network from data centre to end users, another 5 bits of data are transmitted within and among data centres (Cisco, 2016).

Global data centre electricity demand in 2018 was an estimated 198 TWh, or almost 1% of global final demand for electricity (Masanet et al., 2018).

Based on current trends in the efficiency of hardware and data centre infrastructure, global data centre energy demand is projected to decrease slightly to 191 TWh in 2021 (Cisco, 2018; Masanet et al., 2018; Shehabi et al., 2016). This is despite a projected 80% increase in data centre traffic and 50% increase in data centre workloads over the next three years (Cisco, 2018).

Global data centre energy demand by end use and data centre type

Despite rapid growth in data centre traffic and workloads, global data centre electricity demand appears to be on track to remain flat in coming years, thanks to efficiency improvements and a shift to hyperscale data centres.

	Servers	Storage	Network	Infrastructure*
2015	88.4	14.2	3.7	84.3
2016	90.5	19.4	3.6	81.7
2017	96.6	17.2	3.9	77.3
2018	101.7	18.2	4.0	73.8
2019	104.0	16.6	4.0	67.2
2020	105.9	17.5	3.9	62.8
2021	109.1	19.2	3.9	58.6
{"chart":{"type":"area","height":"45%"},"plotOptions":{"series":{"stacking":"normal","marker":{"enabled":false}}},"legend":{"reversed":true},"tooltip":{"valueSuffix":" TWh"},"xAxis":{},"yAxis":{"title":{"text":"TWh"},"reversedStacks":false,"max":200},"series":[{"colorIndex":5},{"colorIndex":6},{"colorIndex":7},{"colorIndex":8}]}
	Traditional	Cloud (non-hyperscale)	Hyperscale
2015	97.6	62.0	31.1
2016	83.7	70.3	41.2
2017	70.1	75.1	49.8
2018	60.6	76.3	60.9
2019	50.4	71.7	69.7
2020	41.0	72.9	76.2
2021	32.6	71.6	86.6
{"chart":{"type":"area","height":"45%"},"plotOptions":{"series":{"stacking":"normal","marker":{"enabled":false}}},"legend":{"reversed":true},"tooltip":{"valueSuffix":" TWh"},"xAxis":{},"yAxis":{"title":{"text":""},"reversedStacks":false,"max":200},"series":[{"colorIndex":1},{"colorIndex":3},{"colorIndex":2}]}

Note: * Data centre infrastructure refers to energy consumed by non-IT equipment such as cooling and lighting.

Source: Masanet et al. (2018)

Strong growth in demand for data centre services continues to be offset by continued improvements in the efficiency of servers, storage devices, network switches and data centre infrastructure, as well as a shift to much greater shares of cloud and hyperscale data centres. Hyperscale data centres are very efficient, large-scale cloud data centres that run at high capacity, owing in part to virtualisation software that enables data centre operators to deliver higher work output with fewer servers.

The shift away from small, inefficient data centres towards much larger cloud and hyperscale data centres is evident in the shrinking share of data centre infrastructure in total energy demand, given the very low power usage effectiveness (PUE) of large data centres. PUE is a measure of how efficiently a data centre uses energy; the very best hyperscale data centres can have PUE values of around 1.1 (meaning 0.1 kWh used for cooling/power provision for every 1 kWh used for IT equipment).

The nascent IT infrastructure for blockchain and cryptocurrencies is evolving rapidly, and its implications for data centre electricity use are not yet well understood.

Early estimates suggest that the electricity used by Bitcoin miners – one prominent example of emerging blockchain IT infrastructure – may currently amount to around 0.1‑0.3% of global electricity consumption. However, as blockchain applications grow, understanding and managing its energy use implications may become increasingly important for energy analysts and policy makers.

Data transmission networks

Data networks consumed around 260 TWh globally in 2018, or about 1.1% of total global electricity demand, with mobile networks accounting for two-thirds.

In the near term, the range of possible energy outcomes is wide, hinging largely on data demand growth and the pace of further efficiency improvements.

In a moderate efficiency-improvement scenario of 10% per year (a conservative estimate based on historical improvements), electricity demand could rise nearly 10% to around 280 TWh in 2021.

In contrast, under a high efficiency-improvement scenario of 20% per year (based on rates achieved in well-managed networks with high capacity utilisation), demand could drop by 25% to about 190 TWh.

This range of potential outcomes highlights the importance of policy to drive further efficiency gains.

Electricity use by internet data transmission networks

The prospects for future electricity demand from data transmission networks hinge critically on the pace of efficiency improvements.

	Fixed	Mobile
2015	74	118
2018	89	172
2021 - Moderate efficiency improvement	111	169
2021 - High efficiency improvement	78	118
{"chart":{"type":"column","height":"45%"},"xAxis":{"type":"category"},"plotOptions":{"column":{"borderWidth":0,"stacking":"normal"},"series":{"events":{"legendItemClick":"function () { return false; }"}}},"tooltip":{"enabled":false},"yAxis":{"reversedStacks":false,"min":0,"max":400,"title":{"text":"TWh"}},"series":[{"colorIndex": 4},{"id":"fixed","colorIndex": 5},{"type":"errorbar","linkedTo":"fixed","data":[[131,253],[178,344],[190,370],[133,259]]}]}

Several trends are shaping the future of data network electricity use. Global IP traffic increased nearly threefold during 2014‑18, and similar growth is projected for 2018‑22. The nature of data transmission is changing rapidly, with traffic from wireless and mobile devices expected to account for more than 70% of total IP traffic by 2022, up from around half in 2018.

This shift towards greater use of mobile networks may also have significant implications for the energy use of data transmission networks, given the considerably higher electricity intensities (kWh/GB) of mobile networks compared with fixed-line networks at current traffic rates.

While the latest mobile telecommunications technologies are much less energy-intensive than older technologies (e.g. 4G can be more than 50 times more energy efficient than 2G), their higher speeds may allow for greater usage and traffic volumes.

Despite strong growth in data demand and shifts to mobile transmission, data transmission network technologies are rapidly becoming more efficient: fixed-line network energy intensity has halved every two years since 2000 in developed countries (Aslan et al., 2017), and mobile-access network energy efficiency has been improving 10‑20% annually in recent years (Fehske et al., 2011).

Mobile networks are shifting rapidly away from older networks towards more efficient 4G (and eventually 5G). By 2022, 4G and 5G are expected to carry a combined 83% of mobile traffic, compared with less than 1% for 2G (Cisco, 2019).

Demand for data centre and network services is expected to continue to grow strongly, but how this affects energy use will continue to be determined largely by the pace of energy efficiency gains.

Government policies, as well as action and commitments by data centre and network operators, will be essential to driving further efficiency improvements to moderate overall ICT energy use.

Incentives and guidance for efficient data centre operations

With data demand growth expected to be strongest in the Asia-Pacific region and North America, continued efforts to make data centres and networks in these regions more efficient is critical. Huang and Masanet (2015) offer a summary of best practices and how to calculate savings for incentives programmes.

Policies for more efficient data transmission networks

Governments and network operators could be instrumental in implementing policies and programmes to improve the energy efficiency of data transmission networks.

Actions could include accelerating the phase-out of energy-intensive legacy networks, implementing network device energy efficiency standards, improving metrics and incentives for efficient network operations, and supporting international technology protocols.

Better national data systems

Improving data collection on ICT and their energy-use characteristics can help inform energy analysis and policy making.

For example, the US Energy Information Administration collects data on connected devices in homes (RECS) and commercial buildings (CBECS), as well as on servers in data centres (CBECS).

Voluntary agreements with companies and industries

Companies and industries could agree to voluntary efficiency and CO2 emissions targets.

For example, the European Union and the United States have adopted voluntary agreements with companies to improve the efficiency of connected set-top boxes. Verizon has announced public efficiency goals for its network operations, for which it annually publishes indicators (kWh/GB) and progress.

Innovation gaps

Demand for data centre and data transmission network services is expected to continue to grow strongly over the next decade. Innovation will be critical to ensuring that energy efficiency gains continue to keep overall energy demand in check.

Accelerating energy efficiency of mobile networks

Global internet protocol (IP) traffic is increasing rapidly, and is expected to triple by 2022. This traffic is increasingly shifting to wireless and mobile: wireless and mobile devices expected to account for more than 70% of traffic by 2022, up from around half in 2018.

This shift toward greater use of mobile networks may have significant implications for energy use, given the considerably higher electricity intensities (kWh/GB) of mobile networks compared with fixed-line networks at current traffic rates.

Read more about this innovation gap →

Applying artificial intelligence in data centres

Demand for data centre services is expected to continue to grow strongly after 2020, and data centre energy use will continue to be largely determined by the pace of energy efficiency gains. While the continued shift to efficient cloud and hyperscale data centres will reduce the energy intensity of data centre services, applying artificial intelligence (AI) and machine learning to tap further efficiency gains may become increasingly important.

Read more about this innovation gap →

Additional resources


  1. Aslan, J. et al. (2017), "Electricity Intensity of Internet Data Transmission: Untangling the Estimates", Journal of Industrial Ecology, ,
  2. Cisco (2015), "The History and Future of Internet Traffic", ,
  3. Cisco (2016), "Cisco Global Cloud Index 2015-2020 - Cisco Knowledge Network Session", .
  4. Cisco (2018), Cisco Global Cloud Index: Forecast and Methodology, 2016–2021., ,
  5. Cisco (2019), Cisco Visual Networking Index : Global Mobile Data Traffic Forecast Update , 2017 – 2022., ,
  6. Fehske, A. et al. (2011), "The global footprint of mobile communications: The ecological and economic perspective", IEEE Communications Magazine, Vol. 49/8, pp. 55–62,
  7. GSM Association (2019), The Mobile Economy, ,
  8. Huang, R. and Masanet, E. (2015), "Data Center IT Efficiency Measures", The Uniform Methods Project: Methods for Determining Energy Efficiency Savings for Specific Measures, ,
  9. Masanet, E. R. et al. (2018), Global Data Center Energy Use: Distribution, Composition, and Near-Term Outlook, Evanston, IL.
  10. Shehabi, A. et al. (2016), United States Data Center Energy Usage Report, Berkeley, California,


Eric Masanet, Northwestern University