Sustainability and the Internet (SUSTAIN) RG M. Knodel
Internet-Draft CDT
Intended status: Informational C. Adams
Expires: 7 January 2027 M. Thorne
Green Web Foundation
6 July 2026
Impacts of the Internet on the Environment, Beyond Carbon
draft-knodel-beyond-carbon-01
Abstract
The global internet is comprised of vast interconnected networks
spanning nearly every surface of planet and sky that, together with
user devices, consumes energy and emits greenhouse gases. The true
scale and proposed mitigations of the carbon footprint of the
internet are the subject of important research. The internet also
requires the depletion of other natural resources beyond carbon,
namely land, water, electromagnetic spectrum and minerals.
Electronic waste contributes in particularly acute ways to
environmental pollution. This document surveys the impacts of the
internet on the environment and includes, but goes beyond, energy use
and carbon footprint to look at the consumption of natural resources
and environmental waste.
About This Document
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Status of This Memo
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 2
2. The Internet's Environmental Impacts . . . . . . . . . . . . 4
2.1. Carbon . . . . . . . . . . . . . . . . . . . . . . . . . 4
2.2. Natural resources . . . . . . . . . . . . . . . . . . . . 5
2.2.1. Land . . . . . . . . . . . . . . . . . . . . . . . . 5
2.2.2. Animals and other ecosystems . . . . . . . . . . . . 6
2.2.3. Water . . . . . . . . . . . . . . . . . . . . . . . . 6
2.2.4. Electromagnetic spectrum . . . . . . . . . . . . . . 7
2.2.5. Minerals . . . . . . . . . . . . . . . . . . . . . . 7
2.3. Waste . . . . . . . . . . . . . . . . . . . . . . . . . . 8
3. Guiding Principles . . . . . . . . . . . . . . . . . . . . . 8
4. Conclusions . . . . . . . . . . . . . . . . . . . . . . . . . 9
5. Security Considerations . . . . . . . . . . . . . . . . . . . 9
6. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 10
7. Informative References . . . . . . . . . . . . . . . . . . . 10
Appendix A. Acknowledgments . . . . . . . . . . . . . . . . . . 13
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 13
1. Introduction
The internet is the biggest machine we've ever created, extending
from the depths of the ocean all the way to low earth orbit.
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Much research has been invested in understanding environmental
impacts. Research such as the ‘United Nations (UN) Digital Economy
Report: Shaping an environmentally sustainable and inclusive digital
future’ examines the true scale and proposed mitigations of the
carbon footprint of the internet [UN]. Related research by the World
Health Organisation primer on the health impacts of e-Waste details
the harms incurred when the majority of e-waste is processed [WHO].
Standardized methodologies also exist for conducting these
assessments, such as Recommendation L.1410 from the International
Telecommunication Union's Telecommunication Standardization Sector
(ITU-T) for life cycle assessments of information and communication
technology (ICT) goods, networks, and services [L1410].
This document originated in discussions at the 2022 Internet
Architecture Board (IAB) Workshop on Environmental Impact of Internet
Applications and Systems [RFC9547].
This document aims to briefly categorize a complete survey of
environmental impacts due to a global internet operating at scale.
It is the expectation that these impacts are persistent and some will
have few to no mitigations, even given a very long arc of innovation
and scientific advancement. That is because each of these impacts
are intimately tied to the physical limits of our planet, which are
far more finite than our imaginations are capacious [Jansen].
It is, however, of utmost importance to confront and understand the
planet's limitations and the ways in which internet growth pushes up
against them.
A 'climate justice' approach to building internet architecture not
only reduces the internet’s own environmental impact but reduces
overall environmental impacts of our society. [Manojlovic]
Environmental, Social, and Governance (ESG) frameworks are a related
but distinct lens through which the impacts of internet
infrastructure are increasingly assessed. In practice, however, ESG
analysis of the technology sector tends to reduce to a tension
between mining, for the battery and mineral inputs of the energy
transition, and energy, from nonrenewable sources -- a reductionist
frame relative to the fuller set of impacts surveyed in this document
[WhiteCaseESG]. Nonetheless, addressing these impacts is also
increasingly a business imperative: customers increasingly demand it,
and regulation increasingly requires it, as with the EU's Corporate
Sustainability Reporting Directive [CSRD] and Energy Efficiency
Directive [EED].
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This document summarizes the most promising mitigations in the
context of internet networking. We further suggest a principled
approach to guide understanding the problem space and taking
measurable action. Our proposed approach aims for technical
excellence, is informed by prior implementation and testing,
documents clearly and concisely; and is open and fair in its
assessments.
2. The Internet's Environmental Impacts
This section is arranged in three sub-sections: 2.1. Carbon, 2.2.
Natural Resources and 2.3. Waste. In the first section, of course
carbon is a natural resource but in this document we rely on the vast
research and documentation elsewhere to discuss the consumption of
energy and its emissions in the form of greenhouse gas. Land, water,
electromagnetic spectrum and minerals are all finite, non-renewable
resources that are consumed by internet infrastructure and these
impacts are explained in depth with citations. Lastly waste is
discussed as its own very consequential impact on the pollution of
the rest of the environment, living and nonliving.
2.1. Carbon
Carbon footprint is a concept that takes into consideration emissions
and global warming and the ozone layer. The projected impacts, and
mitigations of global warming are extensively detailed in the
Intergovernmental Panel on Climate Change’s sixth assessment [IPCC].
Progress on allowing the ozone layer to recover since the 1980s is at
risk of being undone as a result of the deployment of low-earth orbit
constellation satellites [Ferreira].
A primary driver of the carbon emissions of internet infrastructure
stems from the energy sources powering it. Not only is it often
powered by non-renewable energy sources [IEA], but the amount of
energy used is increasing faster than efficiency gains can offset
[UptimeInstitute].
In addition, the chip and semiconductor sector has a significant
environmental footprint [StandEarth], as do other emerging digital
technologies, notably artificial intelligence (AI) [SmithAdams]. The
packaging and global transport of network equipment and end user
devices is a further, often overlooked, source of carbon emissions.
Energy consumption is the unequal distribution of and limitations on
use of carbon energy for various purposes. The share of global
carbon emissions is unevenly distributed across countries, but also
within countries across income levels [Oxfam].
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2.2. Natural resources
Natural resources such as land, water, minerals and electromagnetic
spectrum are all impacted by increased digitalisation and the growth
of the internet. The Earth-system-science framework defines nine
"planetary boundaries": climate change, novel entities (such as
chemical pollution and plastics), stratospheric ozone depletion,
atmospheric aerosol loading, ocean acidification, biogeochemical
flows of nitrogen and phosphorus, freshwater use, land-system change,
and biosphere integrity. Six of these -- climate change, novel
entities, biogeochemical flows, freshwater use, land-system change,
and biosphere integrity -- have already been transgressed, suggesting
that Earth is now well outside of the safe operating space for
humanity [Richardson].
These resources raise two distinct kinds of scarcity. Some are
finite in total quantity because they are non-renewable, raising the
question of whether there is enough to go around at all. Others
raise a related but orthogonal issue of capacity, which is space-time
dependent: whether there is enough to go around at a specific place
and time, a question of equitable distribution and usage rather than
total abundance.
2.2.1. Land
Internet infrastructure now occupies every physical domain: space,
including deep space; the ground beneath our feet; and the sea, down
to the sea bed.
New work is beginning at the IETF to define an IP protocol stack for
deep space communications, extending internet infrastructure beyond
Earth orbit entirely [I-D.many-deepspace-ip-architecture].
On the ground, internet infrastructure is often strategically placed
geographically and geopolitically. While the Earth's crust is finite
in total (a background abundance constraint), the more immediate
impact is one of capacity: a given site, once occupied by internet
infrastructure, cannot simultaneously be used by other humans.
Data centers themselves form a distinct land-use ecology, reshaping
the geography, water tables, and energy grids of the regions that
host them [Hogan].
Two broad approaches to data center governance have emerged. One is
centered on market efficiency, intellectual property protection, and
continued growth, often citing competitive advantages such as
favorable climate or existing infrastructure. The other treats land,
water, and energy as scarce resources rather than assuming their
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abundance, and argues for centring people and planet over profit and
capital [JansenCath]. Product-level standards, such as the European
Union's (EU) ecodesign requirements for servers and data storage
products, offer a standards-based lever that could help
operationalize this latter approach in law, constraining resource use
and waste regardless of ownership model [EcodesignServers].
At sea, undersea internet cables and related infrastructure disrupt
the sea bed. Furthermore untouched areas of the deep sea are being
proposed for mining instead of reusing minerals already in
circulation [Dutzik]. In addition, undersea internet cables face
growing risk from extreme weather and sea level rise affecting the
coastal infrastructure they depend on [Durairajan].
2.2.2. Animals and other ecosystems
This scarcity of land also affects animals and other ecosystems. The
Intergovernmental Science-Policy Platform on Biodiversity and
Ecosystem Services (IPBES) Global Assessment Report on Biodiversity
and Ecosystem Services in 2019 provided a IPCC-like basis for policy
and decision making, evaluating 15000 scientific publications, from
145 authors from 40 countries. It found 82% of wild mammal biomass
had been lost in the last 50 years, and called for transformative
changes to avoid further biodiversity loss. [IPBES]
A "handprint" is a concept developed in contrast to footprint, to
quantify the positive environmental impact of a technology, product,
or organization. Footprint and handprint are calculated
independently, with footprint minimized and handprint maximized; a
positive handprint should not be treated as compensating for a
negative footprint, as doing so risks greenwashing
[ITUSG5Biodiversity].
2.2.3. Water
Water is used extensively throughout the digital technology sector,
particularly within data centers for cooling, for mineral extraction
and production, and for chip and semiconductor manufacturing
[Mytton]. Water is renewable at a global scale, so the primary issue
is one of capacity rather than abundance: whether enough is available
in a specific place at a specific time. Water use continues to
increase, driven primarily by more advanced AI and cloud computing
needs, and often places strain on water resources in the communities
surrounding data centers, an effect compounded where non-renewable
groundwater aquifers -- themselves an abundance-constrained resource
-- are drawn down faster than they can recharge. Many data centers,
chip fabs, and other digital infrastructure are being built in
already water-stressed areas such as Spain and the U.S. state of
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Arizona. Chip fabrication is particularly water-intensive: Taiwan's
semiconductor fabs alone consume tens of thousands of cubic meters of
water per day, competing directly with agricultural and municipal
supply during droughts [Roussilhe].
This limits the availability of water for other human, animal, and
ecosystem needs at that same place and time [Manojlovic].
2.2.4. Electromagnetic spectrum
Electromagnetic spectrum is not consumed or depleted by use, and the
same frequencies can be reused in different places or at different
times. Its scarcity is therefore a matter of capacity rather than
abundance: access to specific frequencies at a specific place and
time continues to be allocated disproportionately to large companies
and wealthier countries, despite ITU commitments to more equitable
allocation.
2.2.5. Minerals
Minerals are the clearest case of an abundance-constrained resource
in this document: once a deposit is extracted and consumed, it cannot
be replenished on any human timescale. Mineral extraction depletes
finite resources.
Extraction requires significant water use.
It scars and degrades the Earth's crust.
It destroys habitats.
Extraction processes are toxic at the point of extraction.
This limits the availability of land for other uses.
Manufacturing network equipment and end user devices from these
minerals carries its own environmental footprint, separate from the
impacts of extraction itself.
Global mineral extraction, processing, and refining also carries
significant human rights impacts, including the use of forced labor
for minerals sourced from conflict zones [MetalsGreenEurope].
Despite minerals being finite resources, demand for them continues to
grow rapidly as new digital and energy technologies depend on them
[WorldBankMinerals].
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2.3. Waste
In the air -- pollution from fossil fuels, burning e-waste.
On earth -- sanitation, landfills, polluting soil, limiting use of
space, ecosystem disruption, as documented at e-waste processing
sites such as Agbogbloshie, Ghana [Akese]. This waste also poisons
water: toxic leachate from landfills and informal e-waste processing
sites contaminates groundwater and waterways relied on by surrounding
communities.
In the sea -- undersea cables, mineral extraction byproducts, e-waste
shipping, pollution.
In space -- debris, crowding the sky scape, congestion, limit of use.
Only a small fraction of e-waste is formally collected and recycled:
22.3% globally in 2022, with e-waste generation growing nearly five
times faster than documented recycling. Recycling rates also vary
sharply by region, from 42.8% in Europe to less than 1% in African
countries [GEM2024].
3. Guiding Principles
As the practice of digital sustainability is still in development, we
suggest the following principles to guide IETF’s approach to the
topic, building on prior proposals for a sustainability stack for
Internet architecture [King]. These principles are designed to be
more enduring concepts that can inform solutions even as the
technical specifics of those solutions evolve with the field.
* Open and fair: Claims about environmental impacts must be publicly
verifiable, such as linking to publicly available evidence and
allowing third party auditing. Publicly verifiable evidence
contributes to higher confidence in the measurements and
facilitates independent monitoring and assessment as well as
ensures fairer participation and competition, as in mandatory
public reporting regimes such as the EU's data center
sustainability indicators [EED].
* Timely: Where possible, move towards real-time information about
impacts over an annual cadence or slower cadence. More timely
data enables more responsiveness and a higher resolution of
understanding, as called for in ongoing work on green networking
metrics and management [I-D.cx-opsawg-green-metrics] [RFC9845].
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* Within planetary boundaries: Treat the carrying capacity of the
planet, as determined by the best available science, as a
constraint to work within. There is a safe operating capacity of
the planet, that when breached represents a critical risk to
people and ecosystems we are part of, causing avoidable harm.
* Demand and supply can both be levers: Reducing demand for
resources is also a valid and important approach in addition to
providing supply more efficiently, including by applying Internet
architecture principles to energy systems directly [Nordman].
* Backwards compatibility: The maintenance of existing protocols and
backwards compatibility in protocol design, as opposed to new
protocol stacks such as "Green IP", reduces the need to
manufacture new networking hardware and end user devices.
* Full-stack integration: Sustainability should be integrated
throughout the stack, from software design and refurbished
hardware procurement to grid-aware computing and the choice of
hosting providers powered by renewable energy.
* Sustainable procurement: Sustainable and rights-respecting
procurement practices should be prioritized and embedded
throughout an organization.
* Sustainability by design: Sustainability should be embedded from
the start of a project or protocol's design, not added as an
afterthought.
* Data sharing: Sharing data about resource consumption improves
reporting and transparency and helps create measurable benchmarks.
4. Conclusions
Key mitigations include reducing extraction, improving architectural
efficiency to reduce cooling needs, and distributing resources more
equitably. Data localisation choices also affect environmental
impact. Backwards compatibility and protocol maintenance can serve
as antidotes to premature hardware obsolescence, sometimes termed
"Green IP". The rapid growth of computationally-intensive
applications, such as large language models, is a significant new
driver of this resource demand [Bender].
5. Security Considerations
There are no security considerations for this document.
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6. IANA Considerations
This document has no IANA actions.
7. Informative References
[Akese] Akese, G. A., "Electronic Waste (e-Waste) Science and
Advocacy at Agbogbloshie: The Making and Effects of the
World's Largest e-Waste Dump", 2019,
.
[Bender] Bender, E. M., "On the Dangers of Stochastic Parrots: Can
Language Models Be Too Big?", 2021,
.
[CSRD] European Union, "Directive (EU) 2022/2464 as Regards
Corporate Sustainability Reporting", 2022,
.
[Durairajan]
Durairajan, R., Barford, C., and P. Barford, "Lights Out:
Climate Change Risk to Internet Infrastructure", 2018,
.
[Dutzik] Dutzik, T., "We Don’t Need Deep-Sea Mining", 2024,
.
[EcodesignServers]
European Commission, "Commission Regulation (EU) 2019/424
Laying Down Ecodesign Requirements for Servers and Data
Storage Products", 2019,
.
[EED] European Union, "Directive (EU) 2023/1791 on Energy
Efficiency (recast)", 2023,
.
[Ferreira] P., F. J., "Potential Ozone Depletion From Satellite
Demise During Atmospheric Reentry in the Era of Mega-
Constellations", 2024,
.
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[GEM2024] International Telecommunication Union and United Nations
Institute for Training and Research, "The Global E-waste
Monitor 2024", 2024, .
[Hogan] Hogan, M., "Big Data Ecologies", 2018,
.
[IEA] International Energy Agency, "Data Centres and Data
Transmission Networks", 2024, .
[IPBES] IPBES, "Summary for Policymakers of the Global Assessment
Report on Biodiversity and Ecosystem Services", 2019,
.
[IPCC] Calvin, "International Panel on Climate Change Synthesis
Report 2023", 2023, .
[ITUSG5Biodiversity]
ITU-T Study Group 5, "ITU-T Study Group 5, Question 9/5:
L.Biodiversity_footprint and L.Biodiversity_opportunities
(Work in Progress)", 2026,
.
[Jansen] Jansen, F., "The problem is growth", 2023,
.
[JansenCath]
Jansen, F. and C. Cath, "Down with Data Centres:
Developing Critical Policy", 2024,
.
[King] King, M., Krishnan, S., Pignataro, C., Thubert, P., and E.
Voit, "On Principles for a Sustainability Stack", 2022,
.
[L1410] ITU-T Study Group 5, "Methodology for Environmental Life
Cycle Assessments of Information and Communication
Technology Goods, Networks and Services", 2024,
.
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[Manojlovic]
Manojlovic, V., "Internet Infrastructure and Climate
Justice", 2022, .
[MetalsGreenEurope]
Green European Foundation, "Metals for a Green and Digital
Europe: An Agenda for Action", 2021,
.
[Mytton] Mytton, D., "Data Centre Water Consumption", 2021,
.
[Nordman] Nordman, B., "Applying Internet Architecture to Energy
Systems", 2022, .
[Oxfam] Khalfan, A., "Climate Equality, A planet for the 99
percent", 2023, .
[Richardson]
Richardson, K., "Earth beyond six of nine planetary
boundaries", 2023,
.
[Roussilhe]
Roussilhe, G., "Water and Microchips: The Climatic and
Industrial Future of Taiwan", 2021,
.
[SmithAdams]
Smith, H. and C. Adams, "Thinking About Using AI? Here's
What You Can and (Probably) Can't Change About Its
Environmental Impact", 2024,
.
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[StandEarth]
Stand.earth, "Clean Clicks or Dirty Chips? Despite
Commitments to 100% Renewable Energy, U.S. Semiconductor
Expansion Driving Demand for Dirty Energy", 2024,
.
[UN] United Nations, "Digital Economy Report 2024.", 2024,
.
[UptimeInstitute]
Bashroush, R. and A. Lawrence, "Beyond PUE: Tackling IT's
Wasted Terawatts", 2020,
.
[WhiteCaseESG]
Wright, O., Weisberg, A., and T. Ferguson, "Taking ESG
Seriously: The Crucial Role of Mining Investors in the
Energy Transition", 2021, .
[WHO] World Health Organization, "Electronic Waste (e-Waste)",
n.d., .
[WorldBankMinerals]
Hund, K., "Minerals for Climate Action: The Mineral
Intensity of the Clean Energy Transition", 2020,
.
Appendix A. Acknowledgments
The authors would like to thank Michael Oghia and Emile Stephan for
their detailed reviews and suggested additions to this document.
Authors' Addresses
Mallory Knodel
CDT
Email: mknodel@cdt.org
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Chris Adams
Green Web Foundation
Email: chris@greenweb.org
Michelle Thorne
Green Web Foundation
Email: michelle@thegreenwebfoundation.org
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