Any analysis on the climate impact of a data center should consider resource utilization and energy efficiency, in addition to power mix. Carbon emissions are a factor of three things: the number of servers running, the total energy required to power each server, and the carbon intensity of energy sources used to power these servers. A recent blog post by Jeff Barr outlines why using fewer servers and powering them more efficiently is at least as important to reducing the carbon impact of a company’s data center as its power mix.
A typical large-scale cloud provider achieves approximately 65% server utilization rates versus 15% on-premises, which means when companies move to the cloud, they typically provision fewer than ¼ of the servers than they would on-premises.1 In addition, a typical on-premises data center is 29% less efficient in their use of power compared to a typical large-scale cloud provider that uses world-class facility designs, cooling systems, and workload-optimized equipment.2 Adding these together (fewer servers used plus more power efficient servers), customers only need 16% of the power as compared to on-premises infrastructure. This represents an 84% reduction in the amount of power required.
This massive improvement in energy efficiency drives a huge reduction in climate impact because less energy consumed means fewer carbon emissions. The climate impact improvements get even better when you factor in that the average corporate data center has a dirtier power mix than the typical large-scale cloud provider. Large-scale cloud providers (AWS included) use a power mix that is 28% less carbon intense than the global average.3
Combining the fraction of energy required with a less carbon-intense power mix, customers can end up with a reduction in carbon emissions of 88% by moving to the cloud and AWS.
Read more here.
We’ve made a lot of progress on this commitment. At the end of 2016, more than 40% of the power consumed by our global infrastructure came from renewable energy sources, and we set a goal to be powered by 50% renewable energy by the end of 2017.
Amazon Wind Farm US Central is a 100 megawatt wind farm in Paulding county, Ohio. The wind farm went into operation in December 2016 and is expected to generate approximately 320,000 megawatt hours of wind energy annually - or enough to power more than 29,000 US homes in a year4. Click here to watch the video.
Amazon Wind Farm US Central 2 is a 189 megawatt wind farm in Hardin County, Ohio. The wind farm is expected to generate over 580,000 megawatt hours of wind energy annually - or enough to power approximately 53,000 US homes4 each year.
Amazon Wind Farm US East is a 208 megawatt wind farm in Perquimans and Pasquotank counties, North Carolina. The wind farm went into operation in December 2016 and is expected to generate approximately 670,000 megawatt hours of wind energy annually - or enough to power more than 61,000 US homes4 in a year. Amazon Wind Farm US East is the first utility-scale wind farm in the state of North Carolina.
Amazon Solar Farm US East is an 80 megawatt solar farm in Accomack County, Virginia. The solar farm went into operation in October 2016 and is expected to generate approximately 170,000 megawatt hours of solar power annually – or enough to power approximately 15,000 US homes4 in a year. Click here to watch the video.
Amazon Solar Farm US East 2, Amazon Solar Farm US East 3, Amazon Solar Farm US East 4, and Amazon Solar Farm US East 5 are four individual facilities, each with a capacity of 20 megawatts, located in New Kent, Buckingham, Sussex, and Powhatan counties in Virginia. These solar farms are expected to start generating a total of more than 190,000 megawatt hours of solar power annually by the end of 2017 – or enough to power over 17,000 US homes4 in a year.
Amazon Solar Farm US East 6 is a 100 megawatt facility in Southampton County, Virginia. The solar farm is expected to start generating approximately 210,000 megawatt hours of solar power annually by the end of 2017 – or enough to power over 19,000 US homes4 in a year.
Amazon Wind Farm Fowler Ridge is a 150 megawatt wind farm in Benton County, Indiana. The wind farm went into operation in January 2016 and is expected to generate approximately 500,000 megawatt hours of wind power annually – or enough to power approximately 46,000 US homes4 in a year. Click here to watch the video.
These ten renewable energy projects will deliver a total of 2.6 million MWh of energy annually onto the electric grid powering AWS data centers located in the AWS US East (Ohio) and AWS US East (N. Virginia) Regions. The electricity produced from these projects is enough to power the equivalent of over 240,000 U.S. homes annually, which is approximately the size of the city of Portland, Oregon.5
AWS announced five new solar farms across the Commonwealth of Virginia - these solar farms join the company’s existing project, Amazon Solar Farm US East, which went into production in October 2016. Amazon worked with developers Virginia Solar LLC and Community Energy Solar on the projects, and will further collaborate with an affiliate of Dominion Resources, Inc. to own and operate the solar farms. Read the press release here.
AWS and Dominion Virginia Power join forces on a landmark renewable energy delivery deal. With this, Dominion Virginia Power will manage and integrate the energy produced from various Amazon wind and solar farm projects onto the grid that serves AWS datacenters. Read the Rocky Mountain Institute blog here for more details.
Amazon joined Apple, Google, and Microsoft in filing an Amicus Brief that supports the continued implementation of the U.S. Environmental Protection Agency’s Clean Power Plan (CPP) and discusses the technology industry’s growing desire for affordable renewable energy across the U.S. Read the brief here. Read ACORE's perspective on the brief here.
AWS announced a 4.8 megawatt hour pilot of Tesla’s energy storage batteries in its US West (Northern California) Region. Batteries are important for both data center reliability and as enablers for the efficient application of renewable power. They help bridge the gap between intermittent production, from sources like wind, and the data center’s constant power demands. For more information, please see the Tesla press kit here.
Amazon announced that it has joined the American Council on Renewable Energy (ACORE) and will participate in the U.S. Partnership for Renewable Energy Finance (US PREF) to increase its work with state and federal policymakers and other stakeholders to enable more renewable energy opportunities for cloud providers. For more information, please see the ACORE blog post here.
AWS shared its long-term commitment to achieve 100 percent renewable energy usage for the global AWS infrastructure footprint.
AWS began its journey to carbon neutrality in 2011 when it opened its first carbon-neutral region. Today, AWS offers four separate carbon-neutral regions for customers to utilize (Canada coming soon); and in doing so, we hope to do our part to help tip the scales in the environment's favor.
1 Source: NRDC 2014 “Data Center Efficiency Assessment” report
2 Source: Power Usage Effectiveness (PUE) of on-premises data centers from 2014 Uptime Institute study and PUE of cloud data centers from Google and Facebook public disclosures plus AWS internal data, all of which show PUEs under 1.2
3 Source: AWS average power mix carbon intensity of 393 grams/kWh for June 2015 and 2014 Global Energy Mix data from the International Energy Agency for on-premises assumptions
4 In 2012, the average annual electricity consumption for a U.S. residential utility customer was 10,837 kWh, an average of 903 kilowatt hours (kWh) per month
5 Source: Dividing the population of Portland, Oregon (632,309 in 2015) by the average number of persons per household between 2010-2014 (2.63 according to the US Census), you get 240,421 homes.