Carbon footprint explained

A carbon footprint (or greenhouse gas footprint) is a calculated value or index that makes it possible to compare the total amount of greenhouse gases that an activity, product, company or country adds to the atmosphere. Carbon footprints are usually reported in tonnes of emissions (CO₂-equivalent) per unit of comparison. Such units can be for example tonnes CO₂-eq per year, per kilogram of protein for consumption, per kilometer travelled, per piece of clothing and so forth. A product's carbon footprint includes the emissions for the entire life cycle. These run from the production along the supply chain to its final consumption and disposal.

Similarly, an organization's carbon footprint includes the direct as well as the indirect emissions that it causes. The Greenhouse Gas Protocol (for carbon accounting of organizations) calls these Scope 1, 2 and 3 emissions. There are several methodologies and online tools to calculate the carbon footprint. They depend on whether the focus is on a country, organization, product or individual person. For example, the carbon footprint of a product could help consumers decide which product to buy if they want to be climate aware. For climate change mitigation activities, the carbon footprint can help distinguish those economic activities with a high footprint from those with a low footprint. So the carbon footprint concept allows everyone to make comparisons between the climate impacts of individuals, products, companies and countries. It also helps people devise strategies and priorities for reducing the carbon footprint.

The carbon dioxide equivalent (CO₂eq) emissions per unit of comparison is a suitable way to express a carbon footprint. This sums up all the greenhouse gas emissions. It includes all greenhouse gases, not just carbon dioxide. And it looks at emissions from economic activities, events, organizations and services.^[1] In some definitions, only the carbon dioxide emissions are taken into account. These do not include other greenhouse gases, such as methane and nitrous oxide.^[2]

Various methods to calculate the carbon footprint exist, and these may differ somewhat for different entities. For organizations it is common practice to use the Greenhouse Gas Protocol. It includes three carbon emission scopes. Scope 1 refers to direct carbon emissions. Scope 2 and 3 refer to indirect carbon emissions. Scope 3 emissions are those indirect emissions that result from the activities of an organization but come from sources which they do not own or control.^[3]

For countries it is common to use consumption-based emissions accounting to calculate their carbon footprint for a given year. Consumption-based accounting using input-output analysis backed by super-computing makes it possible to analyse global supply chains. Countries also prepare national GHG inventories for the UNFCCC. The GHG emissions listed in those national inventories are only from activities in the country itself. This approach is called territorial-based accounting or production-based accounting. It does not take into account production of goods and services imported on behalf of residents. Consumption-based accounting does reflect emissions from goods and services imported from other countries. Consumption-based accounting is therefore more comprehensive. This comprehensive carbon footprint reporting including Scope 3 emissions deals with gaps in current systems. Countries' GHG inventories for the UNFCCC do not include international transport.^[4] Comprehensive carbon footprint reporting looks at the final demand for emissions, to where the consumption of the goods and services takes place.^[5]

Definition

A formal definition of carbon footprint is as follows: "A measure of the total amount of carbon dioxide (CO₂) and methane (CH₄) emissions of a defined population, system or activity, considering all relevant sources, sinks and storage within the spatial and temporal boundary of the population, system or activity of interest. Calculated as carbon dioxide equivalent using the relevant 100-year global warming potential (GWP100)."^[6]

Scientists report carbon footprints in terms of equivalents of tonnes of CO₂ emissions (CO₂-equivalent). They may report them per year, per person, per kilogram of protein, per kilometer travelled, and so on.

In the definition of carbon footprint, some scientists include only CO_2. But more commonly they include several of the notable greenhouse gases. They can compare various greenhouse gases by using carbon dioxide equivalents over a relevant time scale, like 100 years. Some organizations use the term greenhouse gas footprint or climate footprint^[7] to emphasize that all greenhouse gases are included, not just carbon dioxide.

The Greenhouse Gas Protocol includes all of the most important greenhouse gases. "The standard covers the accounting and reporting of seven greenhouse gases covered by the Kyoto Protocol – carbon dioxide (CO₂), methane (CH₄), nitrous oxide (N₂O), hydrofluorocarbons (HFCs), perfluorocarbons (PCFs), sulfur hexafluoride (SF₆) and nitrogen trifluoride (NF₃)."^[8]

In comparison, the IPCC definition of carbon footprint in 2022 covers only carbon dioxide. It defines the carbon footprint as the "measure of the exclusive total amount of emissions of carbon dioxide (CO₂) that is directly and indirectly caused by an activity or is accumulated over the lifecycle stages of a product." The IPCC report's authors adopted the same definition that had been proposed in 2007 in the UK.^[9] That publication included only carbon dioxide in the definition of carbon footprint. It justified this with the argument that other greenhouse gases were more difficult to quantify. This is because of their differing global warming potentials. They also stated that an inclusion of all greenhouse gases would make the carbon footprint indicator less practical. But there are disadvantages to this approach. One disadvantage of not including methane is that some products or sectors that have a high methane footprint such as livestock^[10] appear less harmful for the climate than they actually are.^[11]

Types of greenhouse gas emissions

See also: Carbon accounting. The greenhouse gas protocol is a set of standards for tracking greenhouse gas emissions.^[12] The standards divide emissions into three scopes (Scope 1, 2 and 3) within the value chain.^[13] Greenhouse gas emissions caused directly by the organization such as by burning fossil fuels are referred to as Scope 1. Emissions caused indirectly by an organization, such as by purchasing secondary energy sources like electricity, heat, cooling or steam are called Scope 2. Lastly, indirect emissions associated with upstream or downstream processes are called Scope 3.

Direct carbon emissions (Scope 1)

Direct or Scope 1 carbon emissions come from sources on the site that is producing a product or delivering a service.^{[14] [15]} An example for industry would be the emissions from burning a fuel on site. On the individual level, emissions from personal vehicles or gas-burning stoves are Scope 1.

Indirect carbon emissions (Scope 2)

Indirect carbon emissions are emissions from sources upstream or downstream from the process being studied. They are also known as Scope 2 or Scope 3 emissions.

Scope 2 emissions are the indirect emissions related to purchasing electricity, heat, or steam used on site. Examples of upstream carbon emissions include transportation of materials and fuels, any energy used outside of the production facility, and waste produced outside the production facility.^[16] Examples of downstream carbon emissions include any end-of-life process or treatments, product and waste transportation, and emissions associated with selling the product.^[17] The GHG Protocol says it is important to calculate upstream and downstream emissions. There could be some double counting. This is because upstream emissions of one person's consumption patterns could be someone else's downstream emissions

Other indirect carbon emissions (Scope 3)

Scope 3 emissions are all other indirect emissions derived from the activities of an organization. But they are from sources they do not own or control. The GHG Protocol's Corporate Value Chain (Scope 3) Accounting and Reporting Standard allows companies to assess their entire value chain emissions impact and identify where to focus reduction activities.^[18]

Scope 3 emission sources include emissions from suppliers and product users. These are also known as the value chain. Transportation of good, and other indirect emissions are also part of this scope. In 2022 about 30% of US companies reported Scope 3 emissions.^[19] The International Sustainability Standards Board is developing a recommendation to include Scope 3 emissions in all GHG reporting.^[20]

Purpose and strengths

See also: Carbon accounting. The current rise in global average temperature is more rapid than previous changes. It is primarily caused by humans burning fossil fuels.^{[21] [22]} The increase in greenhouse gases in the atmosphere is also due to deforestation and agricultural and industrial practices. These include cement production. The two most notable greenhouse gases are carbon dioxide and methane.^[23] Greenhouse gas emissions, and hence humanity's carbon footprint, have been increasing during the 21st century.^[24] The Paris Agreement aims to reduce greenhouse gas emissions enough to limit the rise in global temperature to no more than 1.5 °C above pre-industrial levels.^{[25] [26]}

The carbon footprint concept makes comparisons between the climate impacts of individuals, products, companies and countries. A carbon footprint label on products could enable consumers to choose products with a lower carbon footprint if they want to help limit climate change. For meat products for example, such a label could make it clear that beef has a higher carbon footprint than chicken.

Understanding the size of an organization's carbon footprint makes it possible to devise a strategy to reduce it. For most businesses the vast majority of  emissions do not come from activities on site, known as Scope 1, or from energy supplied to the organization, known as Scope 2. Instead they come from Scope 3 emissions. They come from the extended upstream and downstream supply chain.^{[27] [28]} Therefore ignoring Scope 3 emissions makes it impossible to detect all emissions of importance. This will limit options for mitigation.^[29] Large companies in sectors such as clothing or automobiles would need to examine more than 100,000 supply chain pathways to fully report their carbon footprints.^[30]

The importance of displacement of carbon emissions has been known for some years. Scientists also call this carbon leakage.^[31] The idea of carbon footprint addresses concerns of carbon leakage which the Paris Agreement does not cover. Carbon leakage occurs when importing countries outsource production to exporting countries. The outsourcing countries are often rich countries while the exporters are often low-income countries.^[32] The displacement of impacts is typically from developed to developing countries. Countries can make it appear that their GHG emissions are falling by moving dirty industries abroad. But when you look at their emissions from a consumption perspective they could be increasing.^{[33] [34]}

Carbon leakage and the related international trade have a range of environmental impacts. These include increased air pollution, water scarcity,^[35] biodiversity loss,^[36] raw material usage,^[37] and energy depletion.^[38]

Scholars have argued in favour of using both consumption-based and production-based accounting. This helps establish shared producer and consumer responsibility.^[39] Currently countries report on their annual GHG inventory to the UNFCCC based on their territorial emissions. This is known as the territorial-based approach or production-based approach.^{[40] [41]} Including consumption-based calculations in the UNFCCC reporting requirements would help close loopholes by addressing the challenge of carbon leakage.^[42]

The Paris Agreement currently does not require countries to include in their national totals the GHG emissions associated with international transport. These emissions are reported separately. They are not subject to the limitation and reduction commitments of Annex 1 Parties under the Climate Convention and Kyoto Protocol. The carbon footprint methodology includes GHG emissions associated with international transport. This means it assigns emissions caused by international trade to the importing country.

Underlying concepts for calculations

The calculation of the carbon footprint of a product, service or sector requires expert knowledge and careful examination of what is to be included. Carbon footprints can be calculated at different scales. They can apply to whole countries, cities,^[43] neighborhoods and also sectors, companies and products.^[44] Several free online carbon footprint calculators exist to calculate personal carbon footprints.^{[45] [46]}

Software such as the "Scope 3 Evaluator" can help companies report emissions throughout their value chain.^[47] The software tools can help consultants and researchers to model global sustainability footprints. In each situation there are a number of questions that need to be answered. These include which activities are linked to which emissions, and which proportion should be attributed to which company. Software is essential for company management. But there is a need for new ways of enterprise resource planning to improve corporate sustainability performance.^[48]

To achieve 95% carbon footprint coverage, it would be necessary to assess 12 million individual supply-chain contributions. This is based on analyzing 12 sectoral case studies.^[49] The Scope 3 calculations can be made easier using input-output analysis. This is a technique originally developed by Nobel Prize-winning economist Wassily Leontief.

Consumption-based emission accounting based on input-output analysis

Consumption-based emission accounting traces the impacts of demand for goods and services along the global supply chain to the end-consumer. It is also called consumption-based carbon accounting. In contrast, a production-based approach to calculating GHG emissions is not a carbon footprint analysis. This approach is also called a territorial-based approach. The production-based approach includes only impacts physically produced in the country in question.^[50] Consumption-based accounting redistributes the emissions from production-based accounting. It considers that emissions in another country are necessary for the home country's consumption bundle.

Consumer-based accounting is based on input-output analysis. It is used at the highest levels for any economic research question related to environmental or social impacts.^[51] Analysis of global supply chains is possible using consumption-based accounting with input-output analysis assisted by super-computing capacity.

Leontief created Input-output analysis (IO) to demonstrate the relationship between consumption and production in an economy. It incorporates the entire supply chain. It uses input-output tables from countries' national accounts. It also uses international data such as UN Comtrade and Eurostat. Input-output analysis has been extended globally to multi-regional input-output analysis (MRIO). Innovations and technology enabling the analysis of billions of supply chains made this possible. Standards set by the United Nations underpin this analysis.^[52] The analysis enables a Structural Path Analysis. This scans and ranks the top supply chain nodes and paths. It conveniently lists hotspots for urgent action. Input-output analysis has increased in popularity because of its ability to examine global value chains.^{[53] [54]}

Combination with life cycle analysis (LCA)

Life cycle assessment (LCA) is a methodology for assessing all environmental impacts associated with the life cycle of a commercial product, process, or service. It is not limited to the greenhouse gas emissions. It is also called life cycle analysis. It includes water pollution, air pollution, ecotoxicity and similar types of pollution. Some widely recognized procedures for LCA are included in the ISO 14000 series of environmental management standards. A standard called ISO 14040:2006 provides the framework for conducting an LCA study.^[55] ISO 14060 family of standards provides further sophisticated tools. These are used to quantify, monitor, report and validate or verify GHG emissions and removals.

Greenhouse gas product life cycle assessments can also comply with specifications such as Publicly Available Specification (PAS) 2050 and the GHG Protocol Life Cycle Accounting and Reporting Standard.^{[56] [57]}

An advantage of LCA is the high level of detail that can be obtained on-site or by liaising with suppliers. However, LCA has been hampered by the artificial construction of a boundary after which no further impacts of upstream suppliers are considered. This can introduce significant truncation errors. LCA has been combined with input-output analysis. This enables on-site detailed knowledge to be incorporated. IO connects to global economic databases to incorporate the entire supply chain.^[58]

Problems

Shifting responsibility from corporations to individuals

Critics argue that the original aim of promoting the personal carbon footprint concept was to shift responsibility away from corporations and institutions and on to personal lifestyle choices.^{[59] [60]} The fossil fuel company BP ran a large advertising campaign for the personal carbon footprint in 2005 which helped popularize this concept. This strategy, employed by many major fossil fuel companies, has been criticized for trying to shift the blame for negative consequences of those industries on to individual choices.^[61]

Geoffrey Supran and Naomi Oreskes of Harvard University examined this question. They argued that concepts such as carbon footprints "hamstring us, and they put blinders on us, to the systemic nature of the climate crisis and the importance of taking collective action to address the problem".^{[62] [63]}

Relationship with other environmental impacts

A focus on carbon footprints can lead people to ignore or even exacerbate other related environmental issues of concern. These include biodiversity loss, ecotoxicity and habitat destruction. It may not be easy to measure these other human impacts on the environment with a single indicator like the carbon footprint. Consumers may think that the carbon footprint is a proxy for environmental impact. In many cases this is not correct.^[64] There can even be trade-offs between reducing the carbon footprint and environmental protection goals. One example is the use of biofuel. Biofuel is a renewable energy source and can reduce the carbon footprint of energy supply. But it can also pose ecological challenges during its production. This is because it is often produced in monocultures with ample use of fertilizers and pesticides. Another example is offshore wind parks. These could have unintended impacts on marine ecosystems.

The carbon footprint analysis solely focuses on greenhouse gas emissions, unlike a life-cycle assessment which is much broader and looks at all environmental impacts. Therefore, it is useful to stress in communication activities that the carbon footprint is just one in a family of indicators (e.g. ecological footprint, water footprint, land footprints and material footprints), and should not be looked at in isolation.^[65] In fact, the carbon footprint can be treated as one component of the ecological footprint.^[66]

The "Sustainable Consumption and Production Hotspot Analysis Tool" (SCP-HAT) is a suitable tool to put carbon footprint analysis into a wider perspective. It includes a number of socio-economic and environmental indicators.^{[67] [68]} It offers calculations that are either consumption-based, following the carbon footprint approach, or production-based. The database of the SCP-HAT tool is underpinned by input-output analysis. This means it includes Scope 3 emissions. The IO methodology is also governed by UN standards. It is based on input-output tables of countries' national accounts and international trade data such as UN Comtrade.^[69] Therefore it is comparable worldwide.

Differing boundaries for calculations

The term carbon footprint has been applied to limited calculations that do not include Scope 3 emissions or the entire supply chain. This can lead to claims of misleading customers with regards to the real carbon footprints of companies or products.

Reported values

See also: Greenhouse gas emissions.

By products

The Carbon Trust has worked with UK manufacturers to produce "thousands of carbon footprint assessments". As of 2014 the Carbon Trust state they have measured 28,000 certifiable product carbon footprints.^[70]

Food

Plant-based foods tend to have a lower carbon footprint than meat and dairy. In many cases a much smaller footprint. This holds true when comparing the footprint of foods in terms of their weight, protein content or calories. The protein output of peas and beef provides an example. Producing 100 grams of protein from peas emits just 0.4 kilograms of carbon dioxide equivalents (CO₂eq). To get the same amount of protein from beef, emissions would be nearly 90 times higher, at 35 kgCO₂eq. Only a small fraction of the carbon footprint of food comes from transport and packaging. Most of it comes from processes on the farm, or from land use change. This means the choice of what to eat has a larger potential to reduce carbon footprint than how far the food has traveled, or how much packaging it is wrapped in.

By sector

The IPCC Sixth Assessment Report found that global GHG emissions have continued to rise across all sectors. Global consumption was the main cause. The most rapid growth was in transport and industry.^[71] A key driver of global carbon emissions is affluence. The IPCC noted that the wealthiest 10% in the world contribute between about one third to one half (36%–45%) of global GHG emissions. Researcheres have previously found that affluence is the key driver of carbon emissions. It has a bigger impact than population growth. And it counters the effects of technological developments. Continued economic growth mirrors the increasing trend in material extraction and GHG emissions.^[72] “Industrial emissions have been growing faster since 2000 than emissions in any other sector, driven by increased basic materials extraction and production,” the IPCC said.^[73]

Transport

Notes and References

1. Web site: What is a carbon footprint . 2023-05-28 . www.conservation.org.
2. IPCC, 2022: Annex I: Glossary [van Diemen, R., J.B.R. Matthews, V. Möller, J.S. Fuglestvedt, V. Masson-Delmotte, C. Méndez, A. Reisinger, S. Semenov (eds)]. In IPCC, 2022: Climate Change 2022: Mitigation of Climate Change. Contribution of Working Group III to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change [P.R. Shukla, J. Skea, R. Slade, A. Al Khourdajie, R. van Diemen, D. McCollum, M. Pathak, S. Some, P. Vyas, R. Fradera, M. Belkacemi, A. Hasija, G. Lisboa, S. Luz, J. Malley, (eds.)]. Cambridge University Press, Cambridge, UK and New York, NY, USA.
3. Green Element Ltd., What is the Difference Between Scope 1, 2 and 3 Emissions?, published 2 November 2018, accessed 11 November 2020
4. Web site: Emissions from fuels used for international aviation and maritime transport . 2023-06-11 . unfccc.int.
5. Tukker . Arnold . Pollitt . Hector . Henkemans . Maurits . 2020-04-22 . Consumption-based carbon accounting: sense and sensibility . Climate Policy . en . 20 . sup1 . S1–S13 . 10.1080/14693062.2020.1728208 . 2020CliPo..20S...1T . 214525354 . 1469-3062. 1887/3135062 . free .
6. Wright . L. . Kemp, S. . Williams, I. . 2011 . 'Carbon footprinting': towards a universally accepted definition . Carbon Management . 2 . 1 . 61–72 . 10.4155/CMT.10.39 . 154004878 . free. 2011CarM....2...61W .
7. Wright . Laurence A . Kemp . Simon . Williams . Ian . 2011 . 'Carbon footprinting': towards a universally accepted definition . Carbon Management . en . 2 . 1 . 61–72 . 10.4155/cmt.10.39 . 1758-3004 . 154004878 . free . 2011CarM....2...61W .
8. Web site: Corporate Standard Greenhouse Gas Protocol . live . https://web.archive.org/web/20220729200224/https://ghgprotocol.org/corporate-standard . 29 July 2022 . 29 July 2022.
9. Wiedmann, T. and Minx, J. (2008). A Definition of 'Carbon Footprint' . In: C. C. Pertsova, Ecological Economics Research Trends: Chapter 1, pp. 1-11, Nova Science Publishers, Hauppauge NY, USA.
10. Ritchie . Hannah . Roser . Max . Rosado . Pablo . 2020-05-11 . CO₂ and Greenhouse Gas Emissions . Our World in Data.
11. Web site: How New Zealand is reducing methane emissions from farming . 2024-02-10 . www.bbc.com.
12. Web site: Greenhouse Gas Protocol . live . https://web.archive.org/web/20201222020458/https://ghgprotocol.org/ . 22 December 2020 . 25 February 2019.
13. Web site: Streamlined Energy And Carbon Reporting Guidance UK . 2020-07-16 . LongevityIntelligen . en.
14. Web site: Product Life Cycle Accounting and Reporting Standard . live . https://web.archive.org/web/20190225223919/https://ghgprotocol.org/sites/default/files/standards/ . 2019-02-25 . GHG Protocol.
15. Book: Bellassen, Valentin . Accounting for Carbon Monitoring, Reporting and Verifying Emissions in the Climate Economy . Cambridge University Press . 2015 . 9781316162262 . 6.
16. Web site: Scope 2 Calculation Guidance . live . https://web.archive.org/web/20201021072905/https://ghgprotocol.org/sites/default/files/ghgp/Scope3_Calculation_Guidance.pdf . 21 October 2020 . 25 February 2019 . GHG Protocol.
17. Web site: EPA, OA . US . 2015-12-23 . Overview of Greenhouse Gases US EPA . live . https://web.archive.org/web/20160812082641/https://www.epa.gov/ghgemissions/overview-greenhouse-gases . 12 August 2016 . 2017-11-01 . US EPA . en.
18. Web site: Corporate Value Chain (Scope 3) Standard Greenhouse Gas Protocol . live . https://web.archive.org/web/20211209194835/https://ghgprotocol.org/standards/scope-3-standard . 9 December 2021 . 2021-12-09 . ghgprotocol.org.
19. Web site: Bokern . D. . March 9, 2022 . Reported Emission Footprints: The Challenge is Real . 2023-01-22 . MSCI . en-US.
20. Web site: Molé . P. . 2022-11-01 . ISSB Votes to Include Scope 3 Greenhouse Gas (GHG) Emission Disclosures in Updates to Draft Standards . 2023-01-22 . VelocityEHS . en-US.
21. Lynas . Mark . Houlton . Benjamin Z. . Perry . Simon . 19 October 2021 . Greater than 99% consensus on human caused climate change in the peer-reviewed scientific literature . . 16 . 11 . 114005 . 2021ERL....16k4005L . 10.1088/1748-9326/ac2966 . 239032360 . free.
22. Allen, M.R., O.P. Dube, W. Solecki, F. Aragón-Durand, W. Cramer, S. Humphreys, M. Kainuma, J. Kala, N. Mahowald, Y. Mulugetta, R. Perez, M.Wairiu, and K. Zickfeld, 2018: Chapter 1: Framing and Context. In: Global Warming of 1.5°C. An IPCC Special Report on the impacts of global warming of 1.5°C above pre-industrial levels and related global greenhouse gas emission pathways, in the context of strengthening the global response to the threat of climate change, sustainable development, and efforts to eradicate poverty [Masson-Delmotte, V., P. Zhai, H.-O. Pörtner, D. Roberts, J. Skea, P.R. Shukla, A. Pirani, W. Moufouma-Okia, C. Péan, R. Pidcock, S. Connors, J.B.R. Matthews, Y. Chen, X. Zhou, M.I. Gomis, E. Lonnoy, T. Maycock, M. Tignor, and T. Waterfield (eds.)]. Cambridge University Press, Cambridge, UK and New York, NY, USA, pp. 49-92. .
23. Web site: 18 September 2020 . . Ritchie . Hannah . Sector by sector: where do global greenhouse gas emissions come from? . Our World in Data . 28 October 2020.
24. Book: European Commission. Joint Research Centre. . CO2 emissions of all world countries :JRC/IEA/PBL 2022 report. . 2022 . Publications Office . 9789276558026 . LU . 10.2760/730164.
25. Web site: UNFCCC . The Paris Agreement . live . https://web.archive.org/web/20210319205057/https://unfccc.int/process-and-meetings/the-paris-agreement/the-paris-agreement . 19 March 2021 . 18 September 2021 . unfccc.int.
26. Web site: Schleussner . Carl-Friedrich . The Paris Agreement – the 1.5 °C Temperature Goal . 2022-01-29 . Climate Analytics . en.
27. Web site: 2022-09-20 . What is the difference between Scope 1, 2 and 3 emissions, and what are companies doing to cut all three? . 2023-05-28 . World Economic Forum . en.
28. Web site: Lenzen . Manfred . Murray . Joy . 2009 . Input into Greenhouse Gas Protocol Technical Working Group discussion on sectoral value chain mapping of emissions by purchased categories . May 28, 2023.
29. Lenzen . M . Treloar . G . 2002-02-01 . Embodied energy in buildings: wood versus concrete—reply to Börjesson and Gustavsson . Energy Policy . en . 30 . 3 . 249–255 . 10.1016/S0301-4215(01)00142-2 . 2002EnPol..30..249L . 0301-4215.
30. Web site: Vivienne Reiner, Arunima Malik, Manfred Lenzen . 2022-02-24 . Google and Amazon misled about their carbon footprint. But what about the rest of us? . 2023-05-28 . The Canberra Times . en-AU.
31. Wiedmann . Thomas . Lenzen . Manfred . 2018 . Environmental and social footprints of international trade . Nature Geoscience . en . 11 . 5 . 314–321 . 10.1038/s41561-018-0113-9 . 2018NatGe..11..314W . 134496973 . 1752-0894. 1959.4/unsworks_50533 . free .
32. News: Reiner . Vivienne . Malik . Arunima . October 13, 2021 . Carbon 'footprinting' could accurately measure countries' emissions . news.com.au . 7 July 2023.
33. News: 2008-07-31 . UK in 'delusion' over emissions . en-GB . 2023-06-19.
34. Wiedmann, T., Wood, R., Lenzen, M., Minx, J., Guan, D. and Barrett, J. (2007) Development of an Embedded Carbon Emissions Indicator – Producing a Time Series of Input-Output Tables and Embedded Carbon Dioxide Emissions for the UK by Using a MRIO Data Optimisation System, Report to the UK Department for Environment, Food and Rural Affairs by Stockholm Environment Institute at the University of York and Centre for Integrated Sustainability Analysis at the University of Sydney, June 2008. Defra, London, UK
35. Lenzen . Manfred . Moran . Daniel . Bhaduri . Anik . Kanemoto . Keiichiro . Bekchanov . Maksud . Geschke . Arne . Foran . Barney . 2013-10-01 . International trade of scarce water . Ecological Economics . en . 94 . 78–85 . 10.1016/j.ecolecon.2013.06.018 . 2013EcoEc..94...78L . 0921-8009.
36. Lenzen . M. . Moran . D. . Kanemoto . K. . Foran . B. . Lobefaro . L. . Geschke . A. . June 2012 . International trade drives biodiversity threats in developing nations . Nature . en . 486 . 7401 . 109–112 . 10.1038/nature11145 . 22678290 . 2012Natur.486..109L . 1119021 . 1476-4687.
37. Wiedmann . Thomas O. . Schandl . Heinz . Lenzen . Manfred . Moran . Daniel . Suh . Sangwon . West . James . Kanemoto . Keiichiro . 2015-05-19 . The material footprint of nations . Proceedings of the National Academy of Sciences . en . 112 . 20 . 6271–6276 . 10.1073/pnas.1220362110 . 0027-8424 . 4443380 . 24003158 . free . 2015PNAS..112.6271W .
38. Lan . Jun . Malik . Arunima . Lenzen . Manfred . McBain . Darian . Kanemoto . Keiichiro . 2016-02-01 . A structural decomposition analysis of global energy footprints . Applied Energy . en . 163 . 436–451 . 10.1016/j.apenergy.2015.10.178 . 2016ApEn..163..436L . 0306-2619.
39. Lenzen . Manfred . Murray . Joy . Sack . Fabian . Wiedmann . Thomas . 2007 . Shared producer and consumer responsibility — Theory and practice . Ecological Economics . en . 61 . 1 . 27–42 . 10.1016/j.ecolecon.2006.05.018.
40. Eggleston, S., Buendia, L., Miwa, K., Ngara, T., & Tanabe, K. (Eds.). (2006). 2006 IPCC guidelines for national greenhouse gas inventories (Vol. 5). Hayama, Japan: Institute for Global Environmental Strategies.
41. Web site: How do CO2 emissions compare when we adjust for trade? . 2023-07-07 . Our World in Data. Text was copied from this source, which is available under a Creative Commons Attribution 4.0 International License
42. Kanemoto . K. . Moran . D. . Lenzen . M. . Geschke . A. . 2014 . International trade undermines national emission reduction targets: New evidence from air pollution . Global Environmental Change . en . 24 . 52–59 . 10.1016/j.gloenvcha.2013.09.008 . 2014GEC....24...52K . 0959-3780.
43. Wiedmann . Thomas . Chen . Guangwu . Owen . Anne . Lenzen . Manfred . Doust . Michael . Barrett . John . Steele . Kristian . 2021 . Three-scope carbon emission inventories of global cities . Journal of Industrial Ecology . en . 25 . 3 . 735–750 . 10.1111/jiec.13063 . 2021JInEc..25..735W . 224842866 . 1088-1980. 1959.4/unsworks_73064 . free .
44. Web site: ((Department for Business, Energy & Industrial Strategy)) . 25 June 2020 . UK local authority carbon dioxide emissions estimates 2018 . live . https://web.archive.org/web/20210126205847/https://assets.publishing.service.gov.uk/government/uploads/system/uploads/attachment_data/file/894785/2005-18-local-authority-co2-emissions-statistical-release.pdf . 26 January 2021 . 13 April 2021 . GOV.UK.
45. Web site: My Carbon Plan - Carbon Footprint Calculator, which provides a calculator using ONS data in the UK. mycarbonplan.org. 2020-04-04. 27 July 2020. https://web.archive.org/web/20200727073303/https://www.mycarbonplan.org/measure-carbon-footprint-calculator. live.
46. Web site: CO2List.org which shows CO2 coming from common products and activities. co2list.org. 2019-10-04. 3 October 2019. https://web.archive.org/web/20191003010424/http://www.co2list.org/. live.
47. Web site: Scope 3 Evaluator GHG Protocol . 2023-06-11 . ghgprotocol.org.
48. Hack . Stefan . Berg . Christian . 2014-07-02 . The Potential of IT for Corporate Sustainability . Sustainability . en . 6 . 7 . 4163–4180 . 10.3390/su6074163 . 2071-1050 . free .
49. Web site: Pain-free scope 3. Input into Greenhouse Gas Protocol Technical Working Group discussion on sectoral value chain mapping of emissions by purchased categories . June 11, 2023.
50. Dietzenbacher . Erik . Cazcarro . Ignacio . Arto . Iñaki . 2020 . Towards a more effective climate policy on international trade . Nature Communications . en . 11 . 1 . 1130 . 10.1038/s41467-020-14837-5 . 2041-1723 . 7048780 . 32111849 . free. 2020NatCo..11.1130D . Text was copied from this source, which is available under a Creative Commons Attribution 4.0 International License
51. Malik . Arunima . McBain . Darian . Wiedmann . Thomas O. . Lenzen . Manfred . Murray . Joy . 2019 . Advancements in Input-Output Models and Indicators for Consumption-Based Accounting . Journal of Industrial Ecology . en . 23 . 2 . 300–312 . 10.1111/jiec.12771 . 2019JInEc..23..300M . 158533390 . 1088-1980.
52. Book: Division, UN Statistics . Handbook of input-output table compilation and analysis . 1999 . en.
53. Web site: World Trade Organization - Global Value Chains . 2023-06-05 . www.wto.org . en.
54. Book: http://dx.doi.org/10.4337/9781786430816 . Recent Developments in Input–Output Analysis . Elgar Research Reviews in Economics . 2020-07-31 . Dietzenbacher . Erik . 10.4337/9781786430816 . Lahr . Michael L. . Lenzen . Manfred . 9781786430809 . 225409688 .
55. Web site: 12 August 2014 . Environmental management -- Life cycle assessment -- Principles and framework . live . https://web.archive.org/web/20190226045810/https://www.iso.org/standard/37456.html . 26 February 2019 . 25 February 2019 . International Organization for Standardization.
56. http://shop.bsigroup.com/en/forms/PASs/PAS-2050 "PAS 2050:2011 Specification for the assessment of the life cycle greenhouse gas emissions of goods and services"
57. http://www.ghgprotocol.org/standards/product-standard "Product Life Cycle Accounting and Reporting Standard"
58. Lenzen . Manfred . 2000 . Errors in Conventional and Input-Output—based Life—Cycle Inventories . Journal of Industrial Ecology . en . 4 . 4 . 127–148 . 10.1162/10881980052541981 . 2000JInEc...4..127L . 154022052 . 1088-1980.
59. Web site: Kaufman . Mark . 13 July 2020 . The devious fossil fuel propaganda we all use . live . https://web.archive.org/web/20200917005055/https://mashable.com/feature/carbon-footprint-pr-campaign-sham/ . 17 September 2020 . 2020-09-17 . . en.
60. Turner . James Morton . 2014 . Counting Carbon: The Politics of Carbon Footprints and Climate Governance from the Individual to the Global . Global Environmental Politics . en . 14 . 1 . 59–78 . 10.1162/GLEP_a_00214 . 1526-3800 . 15886043.
61. Westervelt . Amy . Amy Westervelt . 2021-05-14 . Big Oil Is Trying to Make Climate Change Your Problem to Solve. Don't Let Them . live . https://web.archive.org/web/20210621192628/https://www.rollingstone.com/politics/politics-news/climate-change-exxonmobil-harvard-study-1169682/ . 21 June 2021 . 2021-06-13 . Rolling Stone . en-US.
62. News: Leber . Rebecca . 13 May 2021 . ExxonMobil wants you to feel responsible for climate change so it doesn't have to . live . https://web.archive.org/web/20230325073105/https://www.vox.com/22429551/climate-change-crisis-exxonmobil-harvard-study . 25 March 2023 . 25 March 2023 . Vox.
63. Supran . Geoffrey . Oreskes . Naomi . May 2021 . Rhetoric and frame analysis of ExxonMobil's climate change communications . One Earth . 4 . 5 . 696–719 . 2021OEart...4..696S . 10.1016/j.oneear.2021.04.014 . 2590-3322 . 236343941 . free.
64. Book: Berg, Christian . Sustainable action: overcoming the barriers . 2020 . 978-0-429-57873-1 . Abingdon, Oxon . 1124780147.
65. Fang . K. . Heijungs, R. . De Snoo, G.R. . 2014 . Theoretical exploration for the combination of the ecological, energy, carbon, and water footprints: Overview of a footprint family . Ecological Indicators . 36 . 508–518 . 10.1016/j.ecolind.2013.08.017. 2014EcInd..36..508F .
66. Wiedmann . Thomas . Barrett . John . 2010 . A Review of the Ecological Footprint Indicator—Perceptions and Methods . Sustainability . en . 2 . 6 . 1645–1693 . 10.3390/su2061645 . 2071-1050 . free .
67. Web site: SCP Hotspots Analysis . 2023-06-05 . en-US.
68. Piñero, P., Sevenster, M., Lutter, S., Giljum, S. (2021). Technical documentation of the Sustainable Consumption and Production Hotspots Analysis Tool (SCPHAT) version 2.0. Commissioned by UN Life Cycle Initiative, One Planet Network, and UN International Resource Panel. Paris.
69. Web site: UN Comtrade . 2023-06-19 . comtradeplus.un.org.
70. Web site: Footprint measurement . dead . https://web.archive.org/web/20141223225009/http://www.carbontrust.com/client-services/footprinting/footprint-measurement . 23 December 2014 . 14 August 2012 . The Carbon Trust.
71. Web site: 2022 . IPCC 6th Assessment Report. WG III. Mitigation of Climate Change. Chapter 2 Emissions Trends and Drivers pp. 215-294 . June 11, 2023 . 218.
72. Wiedmann . Thomas . Lenzen . Manfred . Keyßer . Lorenz T. . Steinberger . Julia K. . 2020-06-19 . Scientists' warning on affluence . Nature Communications . en . 11 . 1 . 3107 . 10.1038/s41467-020-16941-y . 2041-1723 . 7305220 . 32561753. 2020NatCo..11.3107W .
73. Web site: IPCC 6th Assessment Report. WG III. Full Report. 2029p. . June 11, 2023 . 1163.