Annex A.1 describes the seventeen emission trading systems and tradeable performance standards for which coverage and permit prices were estimated in 2015: The Alberta Specified Gas Emitters Regulation and the Quebec Cap-and-Trade System in Canada, the seven Chinese pilot systems (Beijing, Chongqing, Guangdong, Hubei, Shanghai, Shenzhen, Tianjin), the European Union Emissions Trading System, the systems in Saitama and Tokyo (Japan), Korea, New Zealand, Switzerland, and the California Cap-and-Trade Program as well as the Regional Greenhouse Gas Initiative in the United States. Annex A.2 shows results on ETS and tradeable performance standard coverage by sector and permit prices. Annex A.3 lists the system-specific adjustment and assumptions for the calculations.

Table A.1 summarises the main features of the seventeen emissions trading systems and tradeable performance standards that were operational in 2015. These carbon pricing systems are included in the estimation of effective carbon rates as presented in Chapter 3 on carbon pricing developments. Regarding recent carbon pricing trends (Chapter 2) Table 2.1 lists all new carbon pricing systems, which have become operational since 2016 or are expected to become operational soon, and are included in the forward-looking estimates of Chapter 2.

Table A.2 shows the shares of emissions covered by ETS and tradeable performance standards across sectors for all countries and regions included in this report in which emitters could trade permits in 2015. For subnational trading systems, the emissions covered by the ETS and tradeable performance standards are given as shares of national emissions. The last column lists the price of tradeable emission permits in 2015 EUR per tonne of CO₂.

Results presented in Table A.2 are based on the general estimation methodology described in OECD (2016[5]). In addition, the following specific adjustments and assumptions apply for the different emissions trading systems.

Canada prices carbon emissions through tradeable permits at the Provincial level. In 2015, the Quebec Cap-and-Trade System and the Alberta Specified Gas Emitters Regulation, put a price on carbon emissions through tradeable permits.

A.3.1.1. Alberta

Verified emissions for the Alberta Specified Gas Emitters Regulation, a tradeable performance standard, were not available for 2015 at the time of writing. Hence, emission coverage is estimated using 2015 facility-level data on greenhouse gas emissions, differentiated by gas, as published by the Government of Canada (2017[6]). Based on this data, the following system-specific adjustments and assumptions are made:

• The matching of facilities to the six Effective Carbon Rate (ECR) sectors is based on the North American Industry Classification System (NAICS) as reported in the dataset (Government of Canada, 2017[6]).

• Process emissions are excluded using data from the Canadian Greenhouse Gas Emissions Inventory (Environment Canada, 2017[7]).

• The price associated with the Specified Gas Emitters Regulation (SGER) for 2015 is assumed to be CAD 15 per tonne CO_2, which corresponds to the permit price emitters had to pay to Alberta’s Climate Change and Emissions Management Fund for compliance obligations they could not meet in a more cost-effective way (make improvements at their facility to reduce emissions; use emission performance credits generated at facilities that achieve more than the required reductions; purchase Alberta-based carbon offset credits).

A.3.1.4. Quebec

Data on emissions subject to the Quebec Cap-and-Trade System in 2015 is from Quebec’s Ministry of Sustainable Development, Environment and the Fight against Climate Change (Gouvernement du Québec, 2017[8]). The dataset reports the verified greenhouse gas emissions in 2015 of all facilities and fuel suppliers subject to the system. In addition, the following ETS-specific adjustments and assumptions are made:

• Matching of facilities to the six sectors discussed in the main body of the report is based on the North American Industry Classification System (NAICS) as in the previous edition of Effective Carbon Rates (OECD, 2016[5]).

• Non-CO₂ emissions are removed based on facility-reported emissions data, which is differentiated by gas (Government of Canada, 2017[6]).

• Process emissions are excluded and fuel suppliers included combining the verified emissions dataset with provincial-level data contained in the Canadian Greenhouse Gas Emissions Inventory (Environment Canada, 2017[7]).

• The average auction price in 2015 was CAD 15.88 per tonne of CO₂ (average of four auctions, weighted by the number of allowances sold).

The estimation of emissions covered by the Chinese Pilot ETSs follows Li et al. (2015[9]) as outlined in Annex B in OECD (2016[5]). The estimation by Li et al. (2015[9]) follows largely the general estimation methodology as detailed in Annex A in OECD (2016[5]), but deviations occur due to different structures and availability of data. In particular, the following specific adjustments to the general estimation methodology and assumptions are made:

• Industrial process emissions from lime and cement production are excluded from the estimation of the emissions trading systems in Beijing, Chongqing, Guangdong, Shanghai and Shenzhen using a uniform process emission factor (0.57 tonnes CO₂ per tonne of cement) from the literature. Cement and lime production account for 87% of China’s total industrial process emissions in 2005 (UNFCCC, 2015[10]).

• Auto-generation of electricity in China mainly occurs in the aluminium sector (Li, 2015[11]). Because the vast majority of Chinese aluminium is produced outside the area of the seven pilot systems, no adjustment for auto-electricity is made.

• To calculate indirect CO₂ emissions from electricity, an average value for the national carbon intensity of electricity production is used. This implicitly assumes that electricity consumed in different sectors and regions is produced based on the same energy mix.

• In Shanghai, emissions from air transport subject to the ETS are currently allocated to the commercial and residential sector.

• In Shenzhen, 197 public buildings are covered by the Shenzhen ETS, but no information is available to estimate the total sector coverage.

• Prices:

  • Beijing’s average price in 2015 amounts to CNY 41.70 (EUR 6.05) per tonne CO2

  • Chongqing’s average price in 2015 amounts to CNY 24.75 (EUR 3.58) per tonne CO₂

  • Guangdong’s average price in 2015 amounts to CNY 16.38 (EUR 2.37) per tonne CO₂

  • Hubei’s average price in 2015 amounts to CNY 24.84 (EUR 3.60) per tonne CO₂

  • Shanghai’s average price in 2015 amounts to CNY 23.65 (EUR 3.42) per tonne CO₂

  • Shenzhen’s average price in 2015 amounts to CNY 37.55 (EUR 5.44) per tonne CO₂

  • Tianjin’s average price in 2015 amounts to CNY 22.02 (EUR 3.19) per tonne CO₂

• To determine the price signal sent by ETS in China, an average price from all pilot systems was calculated for each sector, weighted by the proportion of covered emissions from each system in that sector. Price information is based on market prices from the emission exchanges in 2015, see PMR (2015[12]), PMR (2015[13]), and PMR (2015[14]).

• The weighted effective average price in China amounts to CNY 22.82 (EUR 3.30) in the industry sector, CNY 26.71 (i.e. EUR 3.87) in the commercial and residential sector, CNY 22.08 (i.e. EUR 3.20) in the electricity sector.1

Data on verified emissions from more than 11 000 installations, and their corresponding economic activity classification, is from the European Commission (2017[15]). In addition, the following specific assumptions are made:

• The Statistical Classification of Economic Activities in the European Community (NACE) classifies economic activities into 615 economic classes. Where available, NACE codes are used to match emissions from installations to Effective Carbon Rate (ECR) sectors.2 If no NACE code is available installations are matched to ECR sectors codes using a compulsory activity code, that derives from the list of activities included in the EU ETS shown above. For electricity generation and heat generation installations, there is only one common activity code. To distinguish between emissions from electricity and heat generation from installations with no NACE code but a common activity code two steps are undertaken. First, a ratio of emissions from electricity generation installations to heat generation installations is built based on information from installations for which a NACE code is available. Second emissions from electricity and heat generation from installations with no NACE code but a common activity code, are attributed to electricity and heat generation according to the ratio calculated in the first step.

• The electricity sector is covered at close to 100% in most countries, given that even small fossil fuel power plants (>= 20 MW capacity) have to take part in the ETS. For some countries coverage was initially estimated to exceed 100% in the electricity sector. This is a consequence of initially allocating all emissions from electricity generation under the ETS to the electricity sector, even though some of these emissions result from auto-electricity generation in the industry sector. NACE and activity codes only specify the main activity of an installation. A power plant owned by an industrial company that produces electricity for its own production, but at the same time also for the grid maybe coded simply as a power plant. All its emissions would then be coded as emissions from the electricity sector, even though some are from auto-electricity generation in the industry sector. Knowing that the coverage of the electricity sector cannot be above 100% and that the rules on inclusion of power plants onto the ETS imply close to 100% coverage of the electricity sector any emissions in excess of 100% coverage of the electricity sector are called overflow emissions and separated from the electricity sector. These overflow emissions are then allocated to the industry sector, given that they result from auto-generation of electricity in the industry sector.

• With respect to aviation, commercial flights within the EEA area are covered by the EU ETS as described above. The Taxing Energy Use database only takes emission from domestic flights into account. For that reasons it is assumed that all regularly scheduled domestic flights are covered by the EU ETS, which are 97% of all flights within the EEA according to a study for the European Aviation Safety Agency (EASA, 2009[16]).

• The average allowance price of all auctions in 2015 was EUR 7.60 per tonne of CO₂ (European Energy Exchange, 2015[17]).

A.3.4.1. Tokyo

Emissions by sector from are from the Tokyo Metropolitan Government (TMG, 2017[18]). In addition, the following country-specific assumptions are made:

• The share of indirect emissions from electricity use, i.e. emission from electricity bought from an electricity provider, in total emissions is calculated for each sector using Tokyo’s greenhouse gas inventory (TMG, 2017[19]). Thereby it is assumed that the share of indirect emissions from electricity use in total emissions is the same for covered and non-covered facilities in a given sector.

• 2015 emissions under the cap are currently not available by economic subsector. For this reason subsector data from the latest year available, i.e. 2010, are scaled to 2015 by the difference of aggregate emissions under the cap from 2010 to 2015.

• The detailed subsector data for 2010 has only been published as preliminary data. Meanwhile official data show higher aggregate emissions for 2010 than the preliminary data does. The preliminary by subsector data is therefore scaled to match the official aggregate data for 2010.

• According to Jin (2017[20]) one excess reduction credit traded between JPY 1080 and JPY 1550. One excess reduction credit allows emitting one tonne CO₂ (TMG, 2012[21]). For the calculation of effective carbon rates a central estimate of JPY 1320 per tonne CO₂ for 2015 is assumed.

A.3.4.2 Saitama

Emissions by sector from are from the Saitama Prefectural Government (SPG, 2017[22]). In addition, the following country-specific assumptions are made:

• The share of indirect emissions from electricity use, i.e. emission from electricity bought from an electricity provider, in total emissions is calculated for each sector using Saitama’s greenhouse gas inventory (SPG, 2017[23]). Thereby it is assumed that the share of indirect emissions from electricity use in total emissions is the same for covered and non-covered facilities for a given sector.

• The Saitama ETS is linked with the Tokyo ETS via SME credits. Therefore it is assumed that the credit price from Tokyo also applies to Saitama. According to Jin (2017[20]) one excess reduction credit traded between JPY 1080 and JPY 1550. One excess reduction credit allows emitting one tonne CO₂ (TMG, 2012[21]). For the calculation of effective carbon rates a central estimate of JPY 1320 per tonne CO₂ for 2015 is assumed.

The Korean Ministry of Environment provided aggregated sector data on verified carbon dioxide emissions covered by the Korean emissions trading system in 2015. In addition, the following ETS-specific assumptions and adjustments are made:

• Industrial process emissions are retrieved from the UNFCCC as submitted by the Korean authorities.

• Non-GHG emissions had been excluded from the aggregated data provided by the Ministry of Environment. Hence no adjustment for non-GHG emissions was necessary.

• It is assumed that biomass is covered by the system, but that its emissions factor is equal to zero.

• The average permit price was KRW 11230 per tonne of CO₂ in 2015 according to data provided by the Korean Ministry of Environment.

The coverage of the New Zealand ETS is estimated differently than for the other ETS. Given that the New Zealand ETS is an upstream ETS, applying to fuels (whether imported or produced) rather than to users, coverage is estimated by calculating which proportion of each fuel type is subject to the ETS. The proportion of ETS coverage for emissions from each fuel is assumed to apply uniformly to all users of that fuel. To calculate coverage at the user level, total covered emissions from fuels used by each user are then divided by the total emissions for that user. Data on total covered emissions by user by calendar year are published by the New Zealand Environmental Protection Agency. In addition, the following assumptions are made:

• CO₂ emissions occur from energy use occur primarily through liquid fossil fuel combustion and in the stationary energy sector. Consequently, non-energy related emissions (e.g. industrial processes or agriculture) have been excluded from the estimation.

• The data retrieved from the New Zealand Environmental Protection Agency lists emissions from industrial processes separately from emissions from energy use, allowing exclusion of industrial process emissions from the estimation.

• It is assumed that ETS participants fully pass ETS costs on to end users.

• The average price of New Zealand Units (NZUs) is used, to reflect the fact that 97% of surrendered permits in 2015 were NZUs (49% Forestry NZUs; 48% Other NZUs) (New Zealand Environmental Protection Agency, 2015[24]). From 1 June 2015, only NZUs and New Zealand-based assigned amount units (NZAAUs) are eligible to meet the NZ ETS obligations (New Zealand Ministry for the Environment , 2016[25]).

• The rate of permits is halved because one permit is surrendered for every two tonnes of CO₂ emissions. The average permit price has been calculated as half the average NZU price for 2015: EUR 2.12 per tonne CO₂, or NZD 3.38 per tonne CO₂ (Carbonnews, 2018[26]). This one-for-two transition measure is gradually phased out over three years starting January 1, 2017 (New Zealand Ministry for the Environment, 2016[27]).

A list of ETS installations, as well as surrendered emissions by facility and year, are taken from the website of the Swiss Emissions Trading Registry (2018[28]). Covered facilities are matched to sectors based on information provided by Swiss Federal Office for the Environment for the previous edition of this report (OECD, 2016[5]). In addition, the following country-specific adjustments and assumptions are made:

• Installation-level data on non-CO₂ emission are retrieved from the Swiss Pollutant Registry (Swiss Federal Office for the Environment, 2017[29]) and deducted from verified ETS emissions.

• Process emissions as declared by Switzerland to the UNFCCC (Swiss Federal Office for the Environment, 2017[30]) are deducted from the industry sectors with process emissions.

• The weighted average of the three allowance auctions of 2015 is applied as the permit price.

• The 2015 emission permit price amounts to CHF 11.68 per tonne of CO₂.

To determine the price signal sent by emissions trading systems in the USA an average auction price from RGGI and the California system was calculated for all sectors, weighted by the proportion of emissions subject to each system in that sector.

The weighted average auction price in the USA in 2015 amounts to USD 12.33 in the industry sector, USD 9.07 in electricity and USD 12.44 in all other sectors.

A.3.8.1. RGGI

Data on verified emissions of facilities covered by system is obtained from RGGI reports on annual emissions (RGGI, 2017[31]). In addition, the following system-specific adjustments and assumptions are made:

• All emissions are attributed to the main industrial sector of the facility as specified by the North American Industry Classification System (NAICS). The NAICS codes of all facilities is obtained from the Energy Information Agency (EIA, 2017[32]).

• The average auction clearing price in 2015 was USD 6.11 per tonne CO₂ (RGGI, 2017[33]).

A.3.8.2. California

Data on greenhouse gas emissions subject to a compliance obligation in the Cap-and-Trade Program are published at the facility level by the Californian Air Resource Board (ARB) in the “Annual Summary of GHG Mandatory Reporting” (California ARB, 2017[34]). Based on this data the following system-specific adjustments and assumptions are made:

• The matching of facilities to the six Effective Carbon Rate (ECR) sectors is based on the North American Industry Classification System (NAICS). NAICS codes are reported for all facilities in California ARB (2017[34]). In specific cases, activity codes, as reported in California ARB, (2017[34]), have been used to refine the match.

• Emissions from fuel suppliers have been attributed to the six sectors based on the following main assumptions: first, the transport sector is fully covered from transportation fuel suppliers, and second, the remaining fuel supplier emissions are allocated to all other sectors at a constant share.

• Non-CO₂ and industrial process emissions are excluded based on information from the California Greenhouse Gas Emission Inventory (California ARB, 2017[35]).

• The average auction price in 2015 was USD 12.44 per tonne CO₂ (California ARB, 2017[36]).

[36] California ARB (2017), California Cap and Trade Program – Summary of Joint Auction Settlement Prices and Results, https://www.arb.ca.gov/cc/capandtrade/auction/results_summary.pdf (accessed on 08 December 2017).

[35] California ARB (2017), California's Greenhouse Gas Inventory by IPCC Category, https://www.arb.ca.gov/cc/inventory/data/tables/ghg_inventory_by_ipcc_all_00-15.xlsx (accessed on 15 December 2017).

[34] California ARB (2017), GHG Data - California Air Resources Board - State of California, https://www.arb.ca.gov/cc/reporting/ghg-rep/reported-data/2015-ghg-emissions-2017-11-06.xlsx (accessed on 06 December 2017).

[26] Carbonnews (2018), OMF NZ Market Report Archive, http://www.carbonnews.co.nz/tagarchive.asp?tag=OMF+NZ+Market+Report (accessed on 27 March 2018).

[16] EASA (2009), SAVE - Study on Aviation and Economic Modelling, Final Report, European Aviation Safety Agency, Cologne.

[32] EIA (2017), Form EIA-860 detailed data for 2015, http://www.eia.gov/electricity/data/eia860/ (accessed on 18 December 2017).

[7] Environment Canada (2017), National Inventory Report 1990-2015: Greenhouse Gas Sources and Sinks in Canada, http://donnees.ec.gc.ca/data/substances/monitor/national-and-provincial-territorial-greenhouse-gas-emission-tables/?l.

[15] European Commission (2017), Union Registry: Compliance data for 2016, European Commission, Brussels, https://ec.europa.eu/clima/policies/ets/registry_en#tab-0-1 (accessed on 23 March 2018).

[17] European Energy Exchange (2015), Emission Spot Primary Market Auction Report 2015, European Energy Exchange, Leipzig, https://www.eex.com/de/marktdaten/umweltprodukte/auktionsmarkt/european-emission-allowances-auction/european-emission-allowances-auction-download (accessed on 23 March 2018).

[8] Gouvernement du Québec (2017), Émissions de gaz à effet de serre déclarées et vérifiées des établissements visés par le RSPEDE, http://www.mddelcc.gouv.qc.ca/changements/carbone/documentation.htm.

[1] Gouvernement du Québec (2017), “Regulation respecting a cap-and-trade system for greenhouse gas emission allowances”.

[6] Government of Canada (2017), Facility-reported greenhouse gas data, https://www.canada.ca/en/environment-climate-change/services/climate-change/greenhouse-gas-emissions/facility-reporting/data.html.

[20] Jin, Z. (2017), Current Status of Emission Trading Schemes (ETSs) in Japan, China and South Korea, Presentation at ISAP 2017.

[9] Li, J. (2015), Integrating Cap and Trade into Taxing Energy Use: Interim Report for China, report prepared for the OECD.

[11] Li, J. (2015), Personal Communication.

[3] New Zealand Emissions Trading Register (2018), Public information and reports, https://www.eur.govt.nz/Authentication/Logon.aspx?ReturnUrl=%2fdefault.aspx (accessed on 27 March 2018).

[24] New Zealand Environmental Protection Agency (2015), Facts and figures 2015.

[27] New Zealand Ministry for the Environment (2016), Phase out of the one-for-two transitional measure from the New Zealand Emissions Trading Scheme.

[25] New Zealand Ministry for the Environment (2016), The New Zealand Emissions Trading Scheme Evaluation 2016, http://www.mfe.govt.nz..

[5] OECD (2016), Effective Carbon Rates: Pricing CO2 through Taxes and Emissions Trading Systems, OECD Publishing, Paris, http://dx.doi.org/10.1787/9789264260115-en.

[12] PMR (2015), “China Carbon Market Monitor”, The PMR China Carbon Market Monitor 1.

[13] PMR (2015), “China Carbon Market Monitor”, The PMR China Carbon Market Monitor 2.

[14] PMR (2015), “China Carbon Market Monitor”, The PMR China Carbon Market Monitor 3.

[31] RGGI (2017), Reports: Annual Emissions – Facility Level View, https://rggi-coats.org/eats/rggi/index.cfm?hc=ISkwICAK (accessed on 18 December 2017).

[33] RGGI (2017), Transaction Price Report, https://rggi-coats.org/eats/rggi/index.cfm?hc=ISkwICAK (accessed on 18 December 2017).

[4] RGGI (2008), Regional greenhouse gas initiative model rule: 12/31/08 with corrections,, Regional Greenhouse Gas Initiative, New York.

[22] SPG (2017), Saitama 2015 Emission Data, http://www.pref.saitama.lg.jp/a0502/sakugen.html (accessed on 31 January 2018).

[23] SPG (2017), Saitama Prefecture Greenhouse Gas Emission Inventory 2015, Saitama Prefecture Environment Department, Saitama.

[28] Swiss Emissions Trading Registry (2018), Public information, https://www.emissionsregistry.admin.ch.

[2] Swiss Federal Council (2012), Ordinance on the Reduction of CO2 Emissions.

[29] Swiss Federal Office for the Environment (2017), Swiss Pollutant Release and Transfer Register, http://www.ubst.bafu.admin.ch/opendata/UBD0001.ods.

[30] Swiss Federal Office for the Environment (2017), “Switzerland’s Greenhouse Gas Inventory 1990–2015”, https://www.bafu.admin.ch/dam/bafu/en/dokumente/klima/klima-climatereporting/switzerland_s_most_recent_national_inventory_report.pdf.download.pdf/Switzerland's%20National%20Inventory%20Report%202017%20(GHG%20inventory%201990-2015).pdf.

[19] TMG (2017), Final Energy Consumption and Greenhouse Gas Emissions in Tokyo, Tokyo Muncipal Government, Bureau of Environment.

[18] TMG (2017), Results of the Tokyo Cap-and-Trade Program for the First Fiscal Year of Second Compliance Period, Tokyo Municipal Government, Bureau of Environment.

[21] TMG (2012), Total reduction obligations and emissions trading scheme. Assessment of transaction prices., Tokyo Municipal Government, Bureau of Environment.

[10] UNFCCC (2015), Submitted National Communications from non-Annex I Parties: Second National Communication on Climate Change of The People’s Republic of China, http://unfccc.int/resource/docs/natc/chnnc2e.pdf (accessed on 06 October 2015).