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9 200 C,F6 Perfluoroethane

7 000 C 3F, Perfluoropropane

7 000 C4F10 Perfluorobutane

8 700 c-C4F, Perfluorocyclobutane

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List of tables

Page

Energy Table 1 Sectoral Report for Energy ................................................................................................... 31 - 32 Sectoral Background Data for Energy Table 1.A(a) Fuel Combustion Activities - Sectoral Approach ......................................................... 33 - 36 Table 1.A(b) CO2 from Fuel Combustion Activities - Reference Approach ......................... 37 Table 1.A(c) Comparison of CO2 Emissions from Fuel Combustion ................................... 38 Table 1.A(d) Feedstocks and Non-Energy Use of Fuels .................................................................... 39 Table 1.B.1 Fugitive Emissions from Solid Fuels ............................................................................. 40 Table 1.B.2 Fugitive Emissions from Oil, Natural Gas and Other Sources ....................................... 41 Table 1.C International Bunkers and Multilateral Operations ........................................................... 42 Industrial Processes Table 2(I) Sectoral Report for Industrial Processses .......................................................................... 43 - 44 Sectoral Background Data for Industrial Processes Table 2(I).A-G Emissions of CO2 , CH4 and N2O .............................................................. 45 - 46 Table 2(II) Sectoral Report for Industrial Processes – Emissions of HFCs, PFCs and SF6 ........................................................................................................ 47 - 48 Table 2(II).C, E Metal Production, Production of Halocarbons and SF6 ............................. 49 Table 2(II).F Consumption of Halocarbons and SF6 .......................................................................... 50 - 51 Solvent and Other Product Use Table 3 Sectoral Report for Solvent and Other Product Use ............................................................. 52 Table 3.A-D Sectoral Background Data for Solvent and Other Product Use .................................... 53 Agriculture Table 4 Sectoral Report for Agriculture ............................................................................................. 54 - 55 Sectoral Background Data for Agriculture Table 4.A Enteric Fermentation ......................................................................................................... 56 Table 4.B(a) CH4 Emissions from Manure Management .................................................... 57 Table 4.B(b) N2O Emissions from Manure Management .................................................... 58 Table 4.C Rice Cultivation ................................................................................................................ 59 Table 4.D Agricultural Soils .............................................................................................................. 60 Table 4.E Prescribed Burning of Savannas ........................................................................................ 61 Table 4.F Field Burning of Agricultural Residues ............................................................................. 62 Land-Use Change and Forestry Table 5 Sectoral Report for Land-Use Change and Forestry ............................................................. 63 Sectoral Background Data for Land-Use Change and Forestry Table 5.A Changes in Forest and Other Woody Biomass Stocks ...................................................... 64 Table 5.B Forest and Grassland Conversion ...................................................................................... 65 Table 5.C Abandonment of Managed Lands ..................................................................................... 66 Table 5.D CO2 Emissions and Removals from Soil ............................................................ 67 Waste Table 6 Sectoral Report for Waste ..................................................................................................... 68 Sectoral Background Data for Waste Table 6.A Solid Waste Disposal ........................................................................................................ 69 Table 6.C Waste Incineration ............................................................................................................. 69 Table 6.B Waste-water Handling ....................................................................................................... 70


Summary Tables Summary 1.A Summary Report for National Greenhouse Gas Inventories (IPCC Table 7A) ................................................................................................................................ 71 - 73 Summary 1.B Short Summary Report for National Greenhouse Gas Inventories (IPCC Table 7B) ................................................................................................................................ 74 Summary 2 Summary Report for CO2 Equivalent Emissions .............................................. 75 Summary 3 Summary Report for Methods and Emission Factors Used ............................................ 76 - 77 Other Tables Table 7 Summary Overview for Key Sources ................................................................................... 78 Table 8(a) Recalculation - Recalculated Data .................................................................................... 79 - 80 Table 8(b) Recalculation - Explanatory Information ......................................................................... 81 Table 9(a) Completeness - Information on Notation Keys ................................................................ 82 Table 9(b) Completeness - Information on Additional Greenhouse Gases ........................................ 83 Table 10 Emissions Trends (CO2) ...................................................................................... 84 Table 10 Emissions Trends (CH4) ...................................................................................... 85 Table 10 Emissions Trends (N2O) ...................................................................................... 86 Table 10 Emissions Trends (HFCs, PFCs and SF6) ............................................................. 87 Table 10 Emissions Trends (Summary) .............................................................................. 88 Explanatory note: In order to avoid changes to the layout of the complex tables of the common reporting format, the tables have not been translated. The common reporting format is a standardized format to be used by Annex I Parties for electronic reporting of estimates of greenhouse gas emissions and removals and any other relevant information. Due to technical limitations, the layout of the printed version of the CRF in this document (e.g., size of tables and fonts) cannot be standardized. The list of tables in this document follows the order of tables in the electronic version of the CRF.

Common Reporting Format for the provision of inventory information by Annex I Parties to the UNFCCC.

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TABLE 1 SECTORAL REPORT FOR ENERGY Country

(Sheet 1 of 2) Year

Submission

GREENHOUSE GAS SOURCE AND SINK CATEGORIES CO2 CH4 N2O NOX CO NMVOC SO2

(Gg)

Total Energy

A. Fuel Combustion Activities (Sectoral Approach)

1. Energy Industries

a. Public Electricity and Heat Production

b. Petroleum Refining

c. Manufacture of Solid Fuels and Other Energy Industries

2. Manufacturing Industries and Construction

a. Iron and Steel

b. Non-Ferrous Metals

c. Chemicals

d. Pulp, Paper and Print

e. Food Processing, Beverages and Tobacco

f. Other (as specified in table 1.A(a) sheet 2)

3. Transport

a. Civil Aviation

b. Road Transportation

c. Railways

d. Navigation

e. Other Transportation (as specified in table 1.A(a) sheet 3)


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TABLE 1 SECTORAL REPORT FOR ENERGY Country (Sheet 2 of 2) Year

Submission GREENHOUSE GAS SOURCE AND SINK CATEGORIES CO2 CH4 N2O NOX CO NMVOC SO2

(Gg)

4. Other Sectors a. Commercial/Institutional b. Residential c. Agriculture/Forestry/Fisheries

5. Other (as specified in table 1.A(a) sheet 4) a. Stationary b. Mobile

B. Fugitive Emissions from Fuels 1. Solid Fuels

a. Coal Mining and Handling b. Solid Fuel Transformation c. Other (as specified in table 1.B.1)

2. Oil and Natural Gas a. Oil b. Natural Gas c. Venting and Flaring

Venting Flaring

d. Other (as specified in table 1.B.2) Memo Items: (1) International Bunkers

Aviation Marine

Multilateral Operations CO2 Emissions from Biomass

(1) Countries are asked to report emissions from international aviation and marine bunkers and multilateral operations, as well as CO2 emissions from biomass, under Memo Items. These emissions should not be included in the national total emissions from the energy sector. Amounts of biomass used as fuel are included in the national energy consumption but the corresponding CO2 emissions are not included in the national total as it is assumed that the biomass is produced in a sustainable manner. If the biomass is harvested at an unsustainable rate, net CO2 emissions are accounted for as a loss of biomass stocks in the land-use change and forestry sector.

Documentation Box: Parties should provide detailed explanations on the energy sector in Chapter 3: Energy (CRF sector 1) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table.


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TABLE 1.A(a) SECTORAL BACKGROUND DATA FOR ENERGY Country

Fuel Combustion Activities - Sectoral Approach Year

(Sheet 1 of 4) Submission

GREENHOUSE GAS SOURCE AND SINK CATEGORIES

AGGREGATE ACTIVITY DATA IMPLIED EMISSION FACTORS (2) EMISSIONS

Consumption CO2 CH4 N2O CO2 CH4 N2O (TJ) NCV/GCV(1

) (t/TJ) (kg/TJ) (Gg)

1.A. Fuel Combustion Liquid Fuels Solid Fuels Gaseous Fuels Biomass (3) Other Fuels

1.A.1. Energy Industries Liquid Fuels Solid Fuels Gaseous Fuels Biomass (3) Other Fuels

a. Public Electricity and Heat Production Liquid Fuels Solid Fuels Gaseous Fuels Biomass (3) Other Fuels

b. Petroleum Refining Liquid Fuels Solid Fuels Gaseous Fuels Biomass (3) Other Fuels

c. Manufacture of Solid Fuels and Other Energy Industries Liquid Fuels Solid Fuels Gaseous Fuels Biomass (3) Other Fuels

Note: All footnotes for this table are given at the end of the table on sheet 4.

Note: For the coverage of fuel categories, refer to the IPCC Guidelines (Volume 1. Reporting Instructions - Common Reporting Framework, section 1.2, p. 1.19). If some derived gases (e.g. gas works, gas, coke oven gas, blast furnace gas) are considered, Parties should provide information on the allocation of these derived gases under the above fuel categories (liquid, solid, gaseous, biomass and other fuels) in the NIR (see also documentation box at the end of sheet 4 of this table).


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TABLE 1.A(a) SECTORAL BACKGROUND DATA FOR ENERGY Country

Fuel Combustion Activities - Sectoral Approach Year

(Sheet 2 of 4)

Submission


AGGREGATE ACTIVITY DATA IMPLIED EMISSION FACTORS (2) EMISSIONS

Consumption CO2 CH4 N2O CO2 CH4 N2O (TJ) NCV/GCV(1) (t/TJ) (kg/TJ) (Gg) 1.A.2 Manufacturing Industries and Construction

Liquid Fuels Solid Fuels Gaseous Fuels Biomass (3) Other Fuels

a. Iron and Steel Liquid Fuels Solid Fuels Gaseous Fuels Biomass (3) Other Fuels

b. Non-Ferrous Metals Liquid Fuels Solid Fuels Gaseous Fuels Biomass (3) Other Fuels

c. Chemicals Liquid Fuels Solid Fuels Gaseous Fuels Biomass (3) Other Fuels

d. Pulp, Paper and Print Liquid Fuels Solid Fuels Gaseous Fuels Biomass (3) Other Fuels

e. Food Processing, Beverages and Tobacco Liquid Fuels Solid Fuels Gaseous Fuels Biomass (3) Other Fuels

f. Other (please specify ) (4)




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TABLE 1.A(a) SECTORAL BACKGROUND DATA FOR ENERGY Country Fuel Combustion Activities - Sectoral Approach Year (Sheet 3 of 4) Submission

GREENHOUSE GAS SOURCE AND SINK CATEGORIES AGGREGATE ACTIVITY DATA IMPLIED EMISSION FACTORS (2) EMISSIONS

Consumption CO2 CH4 N2O CO2 CH4 N2O (TJ) NCV/GCV(1) (t/TJ) (kg/TJ) (Gg) 1.A.3 Transport

Liquid Fuels Solid Fuels Gaseous Fuels Biomass Other Fuels (3)

a. Civil Aviation Aviation Gasoline Jet Kerosene

b. Road Transportation Gasoline Diesel Oil Liquefied Petroleum Gases (LPG) Other Liquid Fuels (please specify)

Gaseous Fuels Biomass (3) Other Fuels (please specify)

c. Railways

Liquid Fuels Solid Fuels Gaseous Fuels Other Fuels (please specify)

d. Navigation

Residual Oil (Residual Fuel Oil) Gas/Diesel Oil Gasoline Other Liquid Fuels (please specify)

Solid Fuels Gaseous Fuels Other Fuels (please specify)

e. Other Transportation (please specify) (5)




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TABLE 1.A(a) SECTORAL BACKGROUND DATA FOR ENERGY Country Fuel Combustion Activities - Sectoral Approach Year (Sheet 4 of 4) Submission

GREENHOUSE GAS SOURCE AND SINK CATEGORIES AGGREGATE ACTIVITY DATA IMPLIED EMISSION FACTORS (2) EMISSIONS

Consumption CO2 CH4 N2O CO2 CH4 N2O (TJ) NCV/GCV(1) (t/TJ) (kg/TJ) (Gg)

1.A.4 Other Sectors Liquid Fuels Solid Fuels Gaseous Fuels Biomass (3) Other Fuels

a. Commercial/Institutional Liquid Fuels Solid Fuels Gaseous Fuels Biomass (3) Other Fuels

b. Residential Liquid Fuels Solid Fuels Gaseous Fuels Biomass (3) Other Fuels

c. Agriculture/Forestry/Fisheries Liquid Fuels Solid Fuels Gaseous Fuels Biomass (3) Other Fuels

1.A.5 Other (Not specified elsewhere)(6)

a. Stationary(please specify) (7)


b. Mobile (please specify) (8)


(1) If activity data are calculated using net calorific values (NCV) as specified by the IPCC Guidelines, write NCV in this column. If gross calorific values (GCV) are used, write GCV in this column.

(2) Accurate estimation of CH4 and N2O emissions depends on combustion conditions, technology and emission control policy, as well as on fuel characteristics. Therefore, caution should be used when comparing the implied emission factors across countries. (3) Although carbon dioxide emissions from biomass are reported in this table, they will not be included in the total CO2 emissions from fuel combustion. The value for total CO2 from biomass is recorded in Table1 sheet 2 under the Memo Items. (4) Use this cell to list all activities covered under "f. Other". (5) Use this cell to list all activities covered under "e. Other transportation". (6) Include military fuel use under this category. (7) Use this cell to list activities covered under "1.A.5.a Other - stationary". (8) Use this cell to list activities covered under "1.A.5.b Other - mobile".

Documentation Box: • Parties should provide detailed explanations on the fuel combustion sub-sector in the corresponding part of Chapter 3: Energy (CRF sub-sector 1.A) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table. • If estimates are based on GCV, use this documentation box to provide reference to the relevant section of the NIR where the information necessary to allow the calculation of the activity data based on NCV can be found.

• If some derived gases (e.g. gas works gas, coke oven gas, blast furnace gas) are considered, use this documentation box to provide a reference to the relevant section of the NIR containing the information on the allocation of these derived gases under the above fuel categories (liquid, soild, gaseous, biomass and other fuels).


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TABLE 1.A(b) SECTORAL BACKGROUND DATA FOR ENERGY Country CO2 from Fuel Combustion Activities - Reference Approach (IPCC Worksheet 1-1) Year (Sheet 1 of 1) Submission FUEL TYPES Unit Production Imports Exports International Stock change Apparent Conversion NCV/GCV (1) Apparent Carbon emission Carbon Carbon Net carbon Fraction of Actual CO2 bunkers consumption factor consumptio

n factor content stored emissions carbon emissions

(TJ/Unit) (TJ) (t C/TJ) (Gg C) (Gg C) (Gg C) oxidized (Gg CO2) Liquid Primary Crude Oil Fossil Fuels Orimulsion Natural Gas Liquids Secondary Gasoline

Fuels Jet Kerosene Other Kerosene Shale Oil Gas / Diesel Oil Residual Fuel Oil Liquefied Petroleum Gas

(LPG)

Ethane Naphtha Bitumen Lubricants Petroleum Coke Refinery Feedstocks Other Oil

Other Liquid Fossil

Liquid Fossil Totals Solid Primary Anthracite (2) Fossil Fuels Coking Coal

Other Bituminous Coal Sub-bituminous Coal Lignite Oil Shale Peat Secondary BKB(3) and Patent Fuel Fuels Coke Oven/Gas Coke

Other Solid Fossil

Solid Fossil Totals

Gaseous Fossil Natural Gas (Dry) Other Gaseous Fossil

Gaseous Fossil Totals Total Biomass total

Solid Biomass Liquid Biomass Gas Biomass

(1) To convert quantities in previous columns to energy units, use net calorific values (NCV) and write NCV in this column. If gross calorific values (GCV) are used, write GCV in this column.

(2) If data for Anthracite are not available separately, include with Other Bituminous Coal. (3) BKB: Brown coal/peat briquettes.

Documentation Box:

Parties should provide detailed explanations on the fuel combustion sub-sector, including information related to CO2 from the Reference approach, in the corresponding part of Chapter 3: Energy (CRF sub-sector 1.A) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table.


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TABLE 1.A(c) COMPARISON OF CO2 EMISSIONS FROM FUEL COMBUSTION Country (Sheet 1 of 1) Year

Submission FUEL TYPES REFERENCE APPROACH SECTORAL APPROACH (1) DIFFERENCE (2) CO2 Energy CO2 Energy CO2

Apparent energy consumption (3)

Apparent energy consumption (excluding

non-energy use and feedstocks) (4)

emissions consumption emissions consumption emissions

(PJ) (PJ) (Gg) (PJ) (Gg) (%) (%) Liquid Fuels (excluding international bunkers)

Solid Fuels (excluding international bunkers) (5)

Gaseous Fuels Other (5)

Total (5)

(1) "Sectoral approach" is used to indicate the approach (if different from the Reference approach) used by the Party to estimate CO2 emissions from fuel combustion as reported in table 1.A(a), sheets 1-4. (2) Difference in CO2 emissions estimated by the Reference approach (RA) and the Sectoral approach (SA) (difference = 100% x ((RA-SA)/SA)). For calculating the difference in energy consumption between the two approaches, data as reported in the column "Apparent energy consumption (excluding non-energy use and feedstocks)" are used for the Reference approach. (3) Apparent energy consumption data shown in this column are as in table 1.A(b). (4) For the purposes of comparing apparent energy consumption from the Reference approach with energy consumption from the Sectoral approach, Parties should, in this column, subtract from the apparent energy consumption (Reference approach) the energy content corresponding to the fuel quantities used as feedstocks and/or for non-energy purposes, in accordance with the accounting of energy use in the Sectoral approach. (5) Emissions from biomass are not included. Note: The Reporting Instructions of the Revised 1996 IPCC Guidelines for National Greenhouse Gas Inventories require that estimates of CO2 emissions from fuel combustion, derived using a detailed Sectoral approach, be compared to those from the Reference approach (Worksheet 1-1 of the IPCC Guidelines, Volume 2, Workbook). This comparison is to assist in verifying the Sectoral data.

Documentation Box: • Parties should provide detailed explanations on the fuel combustion sub-sector, including information related to the comparison of CO2 emissions calculated using the Sectoral approach with those calculated using the Reference approach, in the corresponding part of Chapter 3: Energy (CRF sub-sector 1.A) of the NIR. Use this documentation box to provide references to the relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table. • If the CO2 emission estimates from the two approaches differ by more than 2 per cent, Parties should briefly explain the cause of this difference in this documentation box and provide a reference to the relevant section of the NIR where this difference is explained in more detail.


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TABLE 1.A(d) SECTORAL BACKGROUND DATA FOR ENERGY Country

Feedstocks and Non-Energy Use of Fuels Year


Additional information (a)

FUEL TYPE ACTIVITY DATA AND RELATED INFORMATION IMPLIED EMISSION FACTOR

ESTIMATE CO2 not emitted Subtracted from energy sector

Fuel quantity Fraction of carbon stored Carbon emission factor

Carbon stored in non-energy use of

fuels

(specify source category) (TJ) (t C/TJ) (Gg C) (Gg CO2)

Naphtha (1) Lubricants Bitumen Coal Oils and Tars (from Coking Coal) Natural Gas(1) Gas/Diesel Oil (1) LPG (1) Ethane (1) Other (please specify)

Total Total amount of C and CO2 from feedstocks and non-energy use of fuels that is included as emitted CO2 in the Reference approach

(1) Enter data for those fuels that are used as feedstocks (fuel used as raw materials for manufacture of products such as plastics or fertilizers) or for other non-energy use (fuels not used as fuel or transformed into another fuel (e.g. bitumen for road construction, lubricants)).

(a) The fuel lines continue from the table to the left.

Documentation box: A fraction of energy carriers is stored in such products as plastics or asphalt. The non-stored fraction of the carbon in the energy carrier or product is oxidized, resulting in carbon dioxide emissions, either during use of the energy carriers in the industrial production (e.g. fertilizer production), or during use of the products (e.g. solvents, lubricants), or in both (e.g. monomers). To report associated emissions, use the above table, filling in an extra table, as shown below.

Associated CO2 emissions Allocated under

(Gg) (Specify source category, e.g. Waste Incineration)

• Parties should provide detailed explanations on the fuel combustion sub-sector, including information related to feedstocks, in the corresponding part of Chapter 3: Energy (CRF sub-sector 1.A) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table. • The above table is consistent with the IPCC Guidelines. Parties that take into account the emissions associated with the use and disposal of these feedstocks could continue to use their methodology, but should indicate this in this documentation box and provide a reference to the relevant section of the NIR where further explanation can be found.


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TABLE 1.B.1 SECTORAL BACKGROUND DATA FOR ENERGY Country Fugitive Emissions from Solid Fuels Year (Sheet 1 of 1) Submission

GREENHOUSE GAS SOURCE AND ACTIVITY DATA IMPLIED EMISSION FACTORS EMISSIONS SINK CATEGORIES Amount of fuel produced CH4 (1) CO2 CH4 CO2

Recovery/Flaring (2) Emissions (3) (Mt) (kg/t) (Gg)

1. B. 1. a. Coal Mining and Handling i. Underground Mines(4)

Mining Activities Post-Mining Activities

ii. Surface Mines(4) Mining Activities Post-Mining Activities

1. B. 1. b. Solid Fuel Transformation 1. B. 1. c. Other (please specify)(5)

(1) The IEFs for CH4 are estimated on the basis of gross emissions as follows: (CH4 emissions + amounts of CH4 flared/recovered) / activity data.

(2) Amounts of CH4 drained (recovered), utilized or flared. (3) Final CH4 emissions after subtracting the amounts of CH4 utilized or recovered. (4) In accordance with the IPCC Guidelines, emissions from Mining Activities and Post-Mining Activities are calculated using the activity data of the amount of fuel produced for Underground Mines and Surface Mines.

(5) This category is to be used for reporting any other solid fuel-related activities resulting in fugitive emissions, such as emissions from abandoned mines and waste piles.

Note: There are no clear references to the coverage of 1.B.1.b. and 1.B.1.c. in the IPCC Guidelines. Make sure that the emissions entered here are not reported elsewhere. If they are reported under another source category, indicate this by using notation key IE and making the necessary reference in Table 9 (completeness). Documentation box: • Parties should provide detailed explanations on the fugitive emissions from source category 1.B.1 Solid fuels, in the corresponding part of Chapter 3: Energy (CRF source category 1.B.1) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table. • Regarding data on the amount of fuel produced entered in the above table, specify in this documentation box whether the fuel amount is based on the run-of-mine (ROM) production or on the saleable production. • If entries are made for "Recovery/Flaring", indicate in this documentation box whether CH4 is flared or recovered and provide a reference to the section in the NIR where further details on recovery/flaring can be found. • If estimates are reported under 1.B.1.b. and 1.B.1.c., use this documentation box to provide information regarding activities covered under these categories and to provide a reference to the section in the NIR where the background information can be found.


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TABLE 1.B.2 SECTORAL BACKGROUND DATA FOR ENERGY Country

Fugitive Emissions from Oil, Natural Gas and Other Sources Year


GREENHOUSE GAS SOURCE AND ACTIVITY DATA (1) IMPLIED EMISSION FACTORS EMISSIONS SINK CATEGORIES Description (1) Unit (1) Value CO2 CH4 N2O CO2 CH4 N2O (kg/unit) (2) (Gg) 1. B. 2. a. Oil (3)

I. Exploration (e.g. number of wells drilled)

ii. Production(4) (e.g. PJ of oil produced) iii. Transport (e.g. PJ oil loaded in

tankers)

iv. Refining / Storage (e.g. PJ oil refined) v. Distribution of Oil Products (e.g. PJ oil refined) vi. Other 1. B. 2. b. Natural Gas

i. Exploration ii. Production (4) / Processing (e.g. PJ gas produced) iii. Transmission (e.g. PJ gas consumed) iv. Distribution (e.g. PJ gas consumed)

v. Other Leakage (e.g. PJ gas consumed) at industrial plants and power stations in residential and commercial sectors 1. B. 2. c. Venting (5) i. Oil (e.g. PJ oil produced) ii. Gas (e.g. PJ gas produced) iii. Combined Flaring i. Oil (e.g. PJ gas consumption) ii. Gas (e.g. PJ gas consumption) iii. Combined 1.B.2.d. Other (please specify)(6)

(1) Specify the activity data used in the Description column (see examples). Specify the unit of the activity data in the Unit column using one of the following units: PJ, Tg, 10^6 m^3, 10^6 bbl/yr, km, number of sources (e.g. wells). (2) The unit of the implied emission factor will depend on the unit of the activity data used, and is therefore not specified in this column. (3) Use the category also to cover emissions from combined oil and gas production fields. Natural gas processing and distribution from these fields should be included under 1.B.2.b.ii and 1.B.2.b.iv, respectively. (4) If using default emission factors, these categories will include emissions from production other than venting and flaring. (5) If using default emission factors, emissions from Venting and Flaring from all oil and gas production should be accounted for under Venting. (6) For example, fugitive CO2 emissions from production of geothermal power could be reported here. Documentation box: • Parties should provide detailed explanations on the fugitive emissions from source category 1.B.2 Oil and natural gas, in the corresponding part of Chapter 3: Energy (CRF source category 1.B.2) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table. • Regarding data on the amount of fuel produced entered in this table, specify in this documentation box whether the fuel amount is based on the raw material production or on the saleable production. Note cases where more than one type of activity data is used to estimate emissions. • Venting and Flaring: Parties using the IPCC software could report venting and flaring emissions together, indicating this in this documentation box.

• If estimates are reported under "1.B.2.d Other", use this documentation box to provide information regarding activities covered under this category and to provide a reference to the section in the NIR where background information can be found.


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TABLE 1.C SECTORAL BACKGROUND DATA FOR ENERGY Country

International Bunkers and Multilateral Operations Year


Additional information GREENHOUSE GAS SOURCE ACTIVITY DATA IMPLIED EMISSION FACTORS EMISSIONS Fuel Distribution (a) (per cent) AND SINK CATEGORIES Consumption CO2 CH4 N2O CO2 CH4 N2O consumption Domestic International (TJ) (t/TJ) (Gg) Aviation

Aviation Bunkers Marine Jet Kerosene Gasoline Marine Bunkers Gasoline Gas/Diesel Oil

(a) For calculating the allocation of fuel consumption, the sums of fuel consumption for domestic navigation and aviation (Table 1.A(a)) and for international bunkers (Table 1.C) are used.

Residual Fuel Oil Lubricants Coal Other (please specify) Multilateral Operations (1) (1) Parties may choose to report or not report the activity data and implied emission factors for multilateral operations consistent with the principle of confidentiality stated in the UNFCCC reporting guidelines.

In any case, Parties should report the emissions from multilateral operations, where available, under the Memo Items section of the Summary tables and in the Sectoral report table for energy.

Note: In accordance with the IPCC Guidelines, international aviation and marine bunker fuel emissions from fuel sold to ships or aircraft engaged in international transport should be excluded from national totals and reported separately for information purposes only.

Documentation box: • Parties should provide detailed explanations on the fuel combustion sub-sector, including international bunker fuels, in the corresponding part of Chapter 3: Energy (CRF sub-sector 1.A) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table. • Provide in this documentation box a brief explanation on how the consumption of international marine and aviation bunker fuels was estimated and separated from domestic consumption, and include a reference to the section of the NIR where the explanation is provided in more detail.


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TABLE 2(I) SECTORAL REPORT FOR INDUSTRIAL PROCESSES Country (Sheet 1 of 2) Year

Submission

GREENHOUSE GAS SOURCE AND CO2 CH4 N2O HFCs(1) PFCs(1) SF6 NOx CO NMVOC SO2

SINK CATEGORIES P A P A P A (Gg) CO2 equivalent (Gg) (Gg)

Total Industrial Processes A. Mineral Products

1. Cement Production 2. Lime Production 3. Limestone and Dolomite Use 4. Soda Ash Production and Use 5. Asphalt Roofing 6. Road Paving with Asphalt 7. Other (as specified in table 2(I)A-G)

B. Chemical Industry 1. Ammonia Production 2. Nitric Acid Production 3. Adipic Acid Production 4. Carbide Production 5. Other (as specified in table 2(I)A-G)

C. Metal Production 1. Iron and Steel Production 2. Ferroalloys Production 3. Aluminium Production 4. SF6 Used in Aluminium and Magnesium Foundries 5. Other (as specified in table 2(I)A-G)

P = Potential emissions based on Tier 1 approach of the IPCC Guidelines. A = Actual emissions based on Tier 2 approach of the IPCC Guidelines. This applies only to source categories where methods exist for both tiers.

(1) The emissions of HFCs and PFCs are to be expressed as CO2 equivalent emissions. Data on disaggregated emissions of HFCs and PFCs are to be provided in Table 2(II).


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TABLE 2(I) SECTORAL REPORT FOR INDUSTRIAL PROCESSES Country (Sheet 2 of 2) Year

Submission

GREENHOUSE GAS SOURCE AND CO2 CH4 N2O HFCs(1) PFCs(1) SF6 NOx CO NMVOC SO2

SINK CATEGORIES P A P A P A (Gg) CO2 equivalent (Gg) (Gg)

D. Other Production 1. Pulp and Paper 2. Food and Drink(2)

E. Production of Halocarbons and SF6 1. By-product Emissions

Production of HCFC-22 Other

2. Fugitive Emissions 3. Other (as specified in table 2(II))

F. Consumption of Halocarbons and SF6 1. Refrigeration and Air Conditioning Equipment 2. Foam Blowing 3. Fire Extinguishers 4. Aerosols/ Metered Dose Inhalers 5. Solvents 6. Other applications using ODS(3) substitutes 7. Semiconductor Manufacture 8. Electrical Equipment 9. Other (as specified in table 2(II)

G. Other (as specified in tables 2(I).A-G and 2(II))

P = Potential emissions based on Tier 1 approach of the IPCC Guidelines. A = Actual emissions based on Tier 2 approach of the IPCC Guidelines. This applies only to source categories where methods exist for both tiers.

(1) The emissions of HFCs and PFCs are to be expressed as CO2 equivalent emissions. Data on disaggregated emissions of HFCs and PFCs are to be provided in Table 2(II). (2) CO2 from Food and Drink Production (e.g. gasification of water) can be of biogenic or non-biogenic origin. Only information on CO2 emissions of non-biogenic origin should be reported. (3) ODS: ozone-depleting substances.

Documentation box: Parties should provide detailed explanations on the industrial processes sector in Chapter 4: Industrial processes (CRF sector 2) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table.


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TABLE 2(I).A-G SECTORAL BACKGROUND DATA FOR INDUSTRIAL PROCESSES Country

Emissions of CO2, CH4 and N2O Year


ACTIVITY DATA IMPLIED EMISSION FACTORS (2) EMISSIONS GREENHOUSE GAS SOURCE AND SINK CATEGORIES Production/Consumption quantity CO2 CH4 N2O CO2 CH4 N2O Emissions(3) Recovery(4) Emissions(3) Recovery(4) Emissions(3) Recovery(4)

Description (1) (kt) (t/t) (Gg)

A. Mineral Products

1. Cement Production (e.g. cement or clinker production)

2. Lime Production

3. Limestone and Dolomite Use

4. Soda Ash

Soda Ash Production

Soda Ash Use

5. Asphalt Roofing

6. Road Paving with Asphalt

7. Other (please specify)

Glass Production

B. Chemical Industry 1. Ammonia Production (5)

2. Nitric Acid Production

3. Adipic Acid Production

4. Carbide Production

Silicon Carbide

Calcium Carbide


Carbon Black

Ethylene

Dichloroethylene

Styrene

Methanol

(1) Where the IPCC Guidelines provide options for activity data, e.g. cement production or clinker production for estimating the emissions from Cement Production, specify the activity data used (as shown in the example in parenthesis) in order to make the choice of emission factor more transparent and to facilitate comparisons of implied emission factors. (2) The implied emission factors (IEF) are estimated on the basis of gross emissions as follows: IEF = (emissions plus amounts recovered, oxidized, destroyed or transformed) / activity data. (3) Final emissions are to be reported (after subtracting the amounts of emission recovery, oxidation, destruction or transformation). (4) Amounts of emission recovery, oxidation, destruction or transformation. (5) To avoid double counting, make offsetting deductions for fuel consumption (e.g. natural gas) in Ammonia Production, first for feedstock use of the fuel, and then for a sequestering use of the feedstock.


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TABLE 2(I).A-G SECTORAL BACKGROUND DATA FOR INDUSTRIAL PROCESSES Country

Emissions of CO2, CH4 and N2O Year


GREENHOUSE GAS SOURCE AND ACTIVITY DATA IMPLIED EMISSION FACTORS (2) EMISSIONS SINK CATEGORIES Production/Consumption quantity CO2 CH4 N2O CO2 CH4 N2O Emissions(3) Recovery(4) Emissions(3) Recovery(4) Emissions(3) Recovery(4)

Description (1) (kt) (t/t) (Gg)

C. Metal Production 1. Iron and Steel Production

Steel Pig Iron Sinter Coke Other (please specify)

2. Ferroalloys Production 3. Aluminium Production 4. SF6 Used in Aluminium and Magnesium Foundries


D. Other Production 1. Pulp and Paper 2. Food and Drink

G. Other (please specify) (1) Where the IPCC Guidelines provide options for activity data, e.g. cement production or clinker production for estimating the emissions from Cement Production, specify the activity data used (as shown in the example in parenthesis) in order to make the choice of emission factor more transparent and to facilitate comparisons of implied emission factors. (2) The implied emission factors (IEF) are estimated on the basis of gross emissions as follows: IEF = (emissions + amounts recovered, oxidized, destroyed or transformed) / activity data. (3) Final emissions are to be reported (after subtracting the amounts of emission recovery, oxidation, destruction or transformation). (4) Amounts of emission recovery, oxidation, destruction or transformation. Documentation box: • Parties should provide detailed explanations on the industrial processes sector in Chapter 4: Industrial processes (CRF sector 2) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table. • In relation to metal production, more specific information (e.g. data on virgin and recycled steel production) could be provided in this documentation box, or in the NIR, together with a reference to the relevant section. • Confidentiality: Where only aggregate figures for activity data are provided, e.g. due to reasons of confidentiality, a note indicating this should be provided in this documentation box.


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TABLE 2(II) SECTORAL REPORT FOR INDUSTRIAL PROCESSES - EMISSIONS OF HFCs, PFCs AND SF6 Country

(Sheet 1 of 2) Year Submission


HF

C-2

3

HF

C-3

2

HF

C-4

1

HF

C-4

3-10

mee

HF

C-1

25

HF

C-1

34

HF

C-1

34a

HF

C-1

52a

HF

C-1

43

HF

C-1

43a

HF

C-2

27ea

HF

C-2

36fa

HF

C-2

45ca

Un

spec

ifie

d

mix

of

list

ed

HF

Cs (

1)

Tot

al H

FC

s

CF

4

C2F

6

C 3

F8

C4F

10

c-C

4F

8

C5F

12

C6F

14

Un

spec

ifie

d

mix

of

list

ed

PF

Cs

(1)

Tot

al P

FC

s

SF

6

(t)(2)

CO2 equivalent

(Gg) (t)(2)

CO2 equivalent

(Gg) (t)(2)

Total Actual Emissions of Halocarbons (by chemical) and SF6

C. Metal Production Aluminium Production SF6 Used in Aluminium Foundries SF6 Used in Magnesium Foundries


Production of HCFC-22 Other

2. Fugitive Emissions 3. Other (as specified in table (II).C,E)

F(a). Consumption of Halocarbons and SF6 (actual emissions - Tier 2)

1. Refrigeration and Air Conditioning Equipment

2. Foam Blowing 3. Fire Extinguishers 4. Aerosols/Metered Dose Inhalers 5. Solvents 6. Other applications using ODS(3) substitutes

7. Semiconductor Manufacture 8. Electrical Equipment 9. Other (as specified in table 2(II)F)

G. Other (please specify)

Note: 1. All footnotes for this table are given at the end of the table on sheet 2.

2. Gases with GWP values not yet agreed upon by the Conference of the Parties should be reported in Table 9(b).


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TABLE 2(II) SECTORAL REPORT FOR INDUSTRIAL PROCESSES - EMISSIONS OF HFCs, PFCs AND SF6 Country (Sheet 2 of 2) Year

Submission


HF

C-2

3

HF

C-3

2

HF

C-4

1

HF

C-4

3-10

mee

HF

C-1

25

HF

C-1

34

HF

C-1

34a

HF

C-1

52a

HF

C-1

43

HF

C-1

43a

HF

C-2

27ea

HF

C-2

36fa

HF

C-2

45ca

Un

spec

ifie

d

mix

of

list

ed

HF

Cs

(1)

Tot

al H

FC

s

CF

4

C2F

6

C 3

F8

C4F

10

c-C

4F8

C5F

12

C6F

14

Un

spec

ifie

d

mix

of

list

ed

PF

Cs (

1)

Tot

al P

FC

s

SF

6

(t)(2) CO2 equivalent (Gg) (t)(2) CO2 equivalent

(Gg) (t)(2)

F(p). Total Potential Emissions of Halocarbons (by chemical) and SF6

(4) Production(5) Import: In bulk In products (6) Export: In bulk In products (6) Destroyed amount

GWP values used 11700 650 150 1300 2800 1000 1300 140 300 3800 2900 6300 560 6500 9200 7000 7000 8700 7500 7400 23900

Total Actual Emissions (7) (CO2 equivalent (Gg))

C. Metal Production E. Production of Halocarbons and SF6 F(a). Consumption of Halocarbons and SF6 G. Other

Ratio of Potential/Actual Emissions from Consumption of Halocarbons and SF6

Actual emissions - F(a) (Gg CO2 eq.) Potential emissions - F(p) (8) (Gg CO2 eq.) Potential/Actual emissions ratio (1) In accordance with the UNFCCC reporting guidelines, HFC and PFC emissions should be reported for each relevant chemical. However, if it is not possible to report values for each chemical (i.e. mixtures, confidential data, lack of disaggregation), these columns could be used for reporting aggregate figures for HFCs and PFCs, respectively. Note that the unit used for these columns is Gg of CO2 equivalent. (2) Note that the units used in this table differ from those used in the rest of the Sectoral report tables, i.e. t instead of Gg. (3) ODS: ozone-depleting substances (4) Potential emissions of each chemical of halocarbons and SF6 estimated using Tier 1a or Tier 1b of the IPCC Guidelines (Volume 3. Reference Manual, pp. 2.47-2.50). Where potential emission estimates are available in a disaggregated manner for the source categories F.1 to F.9, these should be reported in the NIR and a reference should be provided in the documentation box. Use table Summary 3 to indicate whether Tier 1a or Tier 1b was used. (5) Production refers to production of new chemicals. Recycled substances could be included here, but avoid double counting of emissions. An indication as to whether recycled substances are included should be provided in the documentation box to this table. (6) Relevant only for Tier 1b. (7) Total actual emissions equal the sum of the actual emissions of each halocarbon and SF6 from the source categories 2.C, 2.E, 2.F and 2.G as reported in sheet 1 of this table multiplied by the corresponding GWP values. (8) Potential emissions of each halocarbon and SF6 taken from row F(p) multiplied by the corresponding GWP values. Note: As stated in the UNFCCC reporting guidelines, Parties should report actual emissions of HFCs, PFCs and SF6, where data are available, providing disaggregated data by chemical and source category in units of mass and in CO2 equivalent. Parties reporting actual emissions should also report potential emissions for the sources where the concept of potential emissions applies, for reasons of transparency and comparability. Gases with GWP values not yet agreed upon by the COP should be reported in Table 9 (b). Documentation box: • Parties should provide detailed explanations on the industrial processes sector in Chapter 4: Industrial processes (CRF sector 2) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table. • If estimates are reported under "2.G Other", use this documentation box to provide information regarding activities covered under this category and to provide reference to the section in the NIR where background information can be found.


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TABLE 2(II). C, E SECTORAL BACKGROUND DATA FOR INDUSTRIAL PROCESSES Country

Metal Production; Production of Halocarbons and SF6 Year



IMPLIED EMISSION FACTORS(2) EMISSIONS

CF4 C2F6 SF6 CF4 C2F6 SF6

ACTIVITY DATA

Emissions(3) Recovery(4) Emissions(3) Recovery(4) Emissions(3) Recovery(4)

Description (1) (t) (kg/t) (t)

C. PFCs and SF6 from Metal Production PFCs from Aluminium Production SF6 used in Aluminium and Magnesium Foundries

Aluminium Foundries (SF6 consumption) Magnesium Foundries (SF6 consumption)


IMPLIED EMISSION FACTORS(2) EMISSIONS

HFC-23 SF6

HFCs/PFCs (as specified)

HFC-23 SF6 HFCs/PFCs

ACTIVITY DATA

Emissions(3) Recovery(4) Emissions(3) Recovery(4) (specify

chemical) Emissions(3) Recovery(4)

Description (1) (t) (kg/t) (t)


Production of HCFC-22 Other (specify activity)

2. Fugitive Emissions (please specify activity)

3. Other (please specify activity)

(1) Specify the activity data used as shown in the examples within parentheses. (2) The implied emission factors (IEFs) are estimated on the basis of gross emissions as follows: IEF = (emissions + amounts recovered, oxidized, destroyed or transformed) / activity data. (3) Final emissions are to be reported (after subtracting the amounts of emission recovery, oxidation, destruction or transformation). (4) Amounts of emission recovery, oxidation, destruction or transformation.

Documentation box: • Parties should provide detailed explanations on the industrial processes sector in Chapter 4: Industrial processes (CRF sector 2) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table. • Where only aggregate figures for activity data are provided, e.g. due to reasons of confidentiality (see footnote 1 to table 2(II)), a note indicating this should be provided in this documentation box. • Where applying Tier 1b (for source category 2.C), Tier 2 (for source category 2.E) and country-specific methods, specify any other relevant activity data used in this documentation box, including a reference to the section of the NIR where more detailed information can be found. • Use this documentation box for providing clarification on emission recovery, oxidation, destruction and/or transformation, and provide a reference to the section of the NIR where more detailed information can be found.


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TABLE 2(II).F SECTORAL BACKGROUND DATA FOR INDUSTRIAL PROCESSES Country

Consumption of Halocarbons and SF6 Year


GREENHOUSE GAS SOURCE IMPLIED EMISSION FACTORS EMISSIONS

AND SINK CATEGORIES

ACTIVITY DATA Amount of fluid

Filled into new manufactured

products

In operating systems (average annual

stocks)

Remaining in products at decommissioning

Product manufacturing factor

Product life factor Disposal loss

factor From

manufacturing From stocks From disposal

(t) (% per annum) (t)

1. Refrigeration(1)

Air Conditioning Equipment

Domestic Refrigeration (Specify chemical)(1)

Commercial Refrigeration

Transport Refrigeration

Industrial Refrigeration

Stationary Air-Conditioning

Mobile Air-Conditioning

2. Foam Blowing(1)

Hard Foam

Soft Foam

(1) Under each of the listed source categories, specify the chemical consumed (e.g. HFC-32) as indicated under category Domestic Refrigeration; use one row per chemical. Note: This table provides for reporting of the activity data and emission factors used to calculate actual emissions from consumption of halocarbons and SF6 using the "bottom-up approach" (based on the total stock of equipment and estimated emission rates from this equipment). Some Parties may prefer to estimate actual emissions following the alternative "top-down approach" (based on annual sales of equipment and/or gas). Those Parties should provide the activity data used in the current format and any other relevant information needed to understand the content of the table in the documentation box at the end of sheet 2 to this table, including a reference to the section of the NIR where further details can be found. Those Parties should provide the following data in the NIR:

1. the amount of fluid used to fill new products, 2. the amount of fluid used to service existing products, 3. the amount of fluid originally used to fill retiring products (the total nameplate capacity of retiring products), 4. the product lifetime, and 5. the growth rate of product sales, if this has been used to calculate the amount of fluid originally used to fill retiring products.

In the NIR, Parties may provide alternative formats for reporting equivalent information with a similar level of detail.


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TABLE 2(II).F SECTORAL BACKGROUND DATA FOR INDUSTRIAL PROCESSES Country

Consumption of Halocarbons and SF6 Year


GREENHOUSE GAS SOURCE IMPLIED EMISSION FACTORS EMISSIONS AND SINK CATEGORIES

ACTIVITY DATA Amount of fluid

Filled into new manufactured

products

In operating systems (average annual

stocks)

Remaining in products at decommissioning

Product manufacturing

factor

Product life factor

Disposal loss factor

From manufacturing

From stocks From disposal

(t) (% per annum) (t)

3. Fire Extinguishers Specify chemical)(1)

4, Aerosols (1) Metered Dose Inhalers Other

5. Solvents (1)

6. Other applications using ODS(2) substitutes (1)

7. Semiconductors (1)

8. Electric Equipment(1)

9. Other (please specify)(1)

(1) Under each of the listed source categories, specify the chemical consumed (e.g. HFC-32) as indicated under category Fire Extinguishers; use one row per chemical. (2) ODS: ozone-depleting substances.

Documentation box: • Parties should provide detailed explanations on the industrial processes sector in Chapter 4: Industrial processes (CRF sector 2) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table. • Where only aggregate figures for activity data are provided, e.g. due to reasons of confidentiality (see footnote 1 to table 2(II)), a note indicating this should be provided in this documentation box. • With regard to data on the amounts of fluid that remained in retired products at decommissioning, use this documentation box to provide a reference to the section of the NIR where information on the amount of the chemical recovered (recovery efficiency) and other relevant information used in the emission estimation can be found. • Parties that estimate their actual emissions following the alternative top-down approach might not be able to report emissions using this table. As indicated in the note to sheet 1 of this table, Parties should in these cases, in the NIR, provide alternative formats for reporting equivalent information with a similar level of detail. References to the relevant section of the NIR should be provided in this documentation box.


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TABLE 3 SECTORAL REPORT FOR SOLVENT AND OTHER PRODUCT USE Country

(Sheet 1 of 1) Year Submission


CO2 N2O NMVOC

(Gg)

Total Solvent and Other Product Use A. Paint Application B. Degreasing and Dry Cleaning C. Chemical Products, Manufacture and Processing D. Other

1. Use of N2O for Anaesthesia 2. N2O from Fire Extinguishers 3. N2O from Aerosol Cans 4. Other Use of N2O 5. Other (as specified in table 3.A-D)

Note: The quantity of carbon released in the form of NMVOCs should be accounted for in both the NMVOC and the CO2 columns. Note that these quantites of NMVOCs should be converted into CO2 equivalent emissions before being added to the CO2 amounts in the CO2 column. Documentation box: • Parties should provide detailed explanations on the solvent and other product use sector in Chapter 5: Solvent and other product use (CRF sector 3) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table. • The IPCC Guidelines do not provide methodologies for the calculation of emissions of N2O from Solvent and Other Product Use. If reporting such data, Parties should provide additional information (activity data and emission factors) used to derive these estimates in the NIR, and provide in this documentation box a reference to the section of the NIR where this information can be found.


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TABLE 3.A-D SECTORAL BACKGROUND DATA FOR SOLVENT AND OTHER PRODUCT USE Country

(Sheet 1 of 1) Year

Submission

GREENHOUSE GAS SOURCE AND SINK CATEGORIES ACTIVITY DATA IMPLIED EMISSION FACTORS (1) CO2 N2O

Description (kt) (t/t) (t/t)

A. Paint Application B. Degreasing and Dry Cleaning C. Chemical Products, Manufacture and Processing D. Other

1. Use of N2O for Anaesthesia 2. N2O from Fire Extinguishers 3. N2O from Aerosol Cans 4. Other Use of N2O 5. Other (please specify)(2)

(1) The implied emission factors will not be calculated until the corresponding emission estimates are entered directly into Table 3. (2) Some probable sources to be reported under "other" are listed in this table. Complement the list with other relevant sources, as appropriate.

Documentation box: Parties should provide detailed explanations on the solvent and other product use sector in Chapter 5: Solvent and other product use (CRF sector 3) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table.


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TABLE 4 SECTORAL REPORT FOR AGRICULTURE Country

(Sheet 1 of 2) Year

Submission

GREENHOUSE GAS SOURCE AND CH4 N2O NOx CO NMVOC SINK CATEGORIES (Gg)

Total Agriculture A. Enteric Fermentation

1. Cattle (1) Option A:

Dairy Cattle Non-Dairy Cattle

Option B: Mature Dairy Cattle Mature Non-Dairy Cattle Young Cattle

2. Buffalo 3. Sheep 4. Goats 5. Camels and Llamas 6. Horses 7. Mules and Asses 8. Swine 9. Poultry 10. Other (as specified in table 4.A)

B. Manure Management 1. Cattle (1)

Option A: Dairy Cattle Non-Dairy Cattle


2. Buffalo 3. Sheep 4. Goats 5. Camels and Llamas 6. Horses 7. Mules and Asses 8. Swine 9. Poultry 10. Other livestock (as specified in table 4.B(a))



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TABLE 4 SECTORAL REPORT FOR AGRICULTURE Country

(Sheet 2 of 2) Year

Submission

GREENHOUSE GAS SOURCE AND CH4 N2O NOx CO NMVOC SINK CATEGORIES (Gg) B. Manure Management (continued)

11. Anaerobic Lagoons 12. Liquid Systems 13. Solid Storage and Dry Lot 14. Other (please specify)

C. Rice Cultivation

1. Irrigated 2. Rainfed 3. Deep Water 4. Other (as specified in table 4.C)

D. Agricultural Soils (2) 1. Direct Soil Emissions 2. Pasture, Range and Paddock Manure(3) 3. Indirect Emissions 4. Other (as specified in table 4.D)

E. Prescribed Burning of Savannas F. Field Burning of Agricultural Residues

1 . Cereals 2. Pulses 3 . Tubers and Roots 4 . Sugar Cane 5 . Other (as specified in table 4.F)

G. Other (please specify)

(1) The sum for cattle would be calculated on the basis of entries made under either option A (dairy and non-dairy cattle) or option B (mature dairy cattle, mature non-dairy cattle and young cattle). (2) See footnote 4 to Summary 1.A of this common reporting format. Parties which choose to report CO2 emissions and removals from agricultural soils under 4.D Agricultural Soils of the sector Agriculture should report the amount (in Gg) of these emissions or removals in table Summary 1.A of the CRF. References to additional information (activity data, emissions factors) reported in the NIR should be provided in the documentation box to table 4.D. In line with the corresponding table in the IPCC Guidelines (i.e. IPCC Sectoral Report for Agriculture), this table does not include provisions for reporting CO2 estimates. (3) Direct N2O emissions from pasture, range and paddock manure are to be reported in the "4.D Agricultural Soils" category. All other N2O emissions from animal manure are to be reported in the "4.B Manure Management" category. See also chapter 4.4 of the IPCC good practice guidance report. Note: The IPCC Guidelines do not provide methodologies for the calculation of CH4 emissions and CH4 and N2O removals from agricultural soils, or CO2 emissions from prescribed burning of savannas and field burning of agricultural residues. Parties that have estimated such emissions should provide, in the NIR, additional information (activity data and emission factors) used to derive these estimates and include a reference to the section of the NIR in the documentation box of the corresponding Sectoral background data tables.

Documentation box: • Parties should provide detailed explanations on the agriculture sector in Chapter 6: Agriculture (CRF sector 4) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table. • If estimates are reported under "4.G Other", use this documentation box to provide information regarding activities covered under this category and to provide reference to the section in the NIR where background information can be found.


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TABLE 4.A SECTORAL BACKGROUND DATA FOR AGRICULTURE Country

Enteric Fermentation Year


Additional information (only for those livestock types for which Ttier 2 was used) (a)


ACTIVITY DATA AND OTHER RELATED INFORMATION IMPLIED EMISSION FACTORS (3)

Other (specify)

Population size (1) Average gross energy intake (GE)

Average CH4 conversion rate (Ym) (2) CH4

Disaggregated list of animals (b)

(1000s) (MJ/head/day) (%) (kg CH4/head/yr) Indicators:

Dairy Cattle

Non-Dairy Cattle

1. Cattle Weight (kg) Option A: Feeding situation (c)

Dairy Cattle (4) Milk yield (kg/day) Non-Dairy Cattle Work (h/day)

Option B: Pregnant (%) Mature Dairy Cattle Digestibility Mature Non-Dairy Cattle of feed (%)

Young Cattle 2. Buffalo (a) See also Tables A-1 and A-2 of the IPCC Guidelines (Volume 3. Reference 3. Sheep Manual, pp. 4.31-4.34). These data are relevant if Parties do not have data on 4. Goats average feed intake. 5. Camels and Llamas (b) Disaggregate to the split actually used. Add columns to the table if necessary. 6. Horses (c) Specify feeding situation as pasture, stall fed, confined, open range, etc. 7. Mules and Asses 8. Swine 9. Poultry 10. Other (please specify) (1) Parties are encouraged to provide detailed livestock population data by animal type and region, if available, in the NIR, and provide reference to the relevant section in the documentation box below. Parties should use the same animal population statistics to estimate CH4 emissions from enteric fermentation, CH4 and N2O from manure management, N2O direct emissions from soil and N2O emissions associated with manure production, as well as emissions from the use of manure as fuel, and sewage-related emissions reported in the waste sector. (2) Ym refers to the fraction of gross energy in feed converted to methane and should be given in per cent in this table. (3) The implied emission factors will not be calculated until the corresponding emission estimates are entered directly into Table 4. (4) Including data on dairy heifers, if available.

Documentation box:

• Parties should provide detailed explanations on the agriculture sector in Chapter 6: Agriculture (CRF sector 4) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table. • Indicate in this documentation box whether the activity data used are one year-estimates or a three-year average.

• Provide a reference to the relevant section in the NIR, in particular with regard to:

(a) disaggregation of livestock population (e.g. according to the classification recommended in the IPCC good practice guidance), including information on whether these data are one-year estimates or a three-year average. (b) parameters relevant to the application of IPCC good practice guidance.


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TABLE 4.B(a) SECTORAL BACKGROUND DATA FOR AGRICULTURE Country CH4 Emissions from Manure Management Year (Sheet 1 of 1) Submission

Additional information (for Tier 2) (a) ACTIVITY DATA AND OTHER RELATED INFORMATION Animal waste management system GREENHOUSE GAS

SOURCE AND SINK CATEGORIES

Population size

Allocation by climate region (1)

Cool Temperate Warm (1000s) (%)

Typical animal mass (average)

(kg)

VS(2) daily excretion (average)

(kg dm/head/day)

CH4 producing potential (Bo)(2)

(average)

(m3 CH4/kg VS)

IMPLIED EMISSION FACTORS (4)

CH4 (kg CH4/head/yr)

An

imal

ca

tego

ry

Ind

icat

or

Cli

mat

e re

gion

An

aero

bi

c la

goon

Liq

uid

sy

stem

Dai

ly

spre

ad

Sol

id

stor

age

Dry

lot

Pas

ture

ra

nge

p

add

ock

Oth

er

1. Cattle Cool Option A: Temperate

Dairy Cattle (3)

Allocation (%)

Warm Non-Dairy Cattle Cool

Option B: Temperate Mature Dairy Cattle D

airy

Cat

tle

MCF(b)

Warm Mature Non-Dairy Cattle Cool Young Cattle Temperate

2. Buffalo

Allocation (%)

Warm 3. Sheep Cool 4. Goats Temperate 5. Camels and Llamas N

on-D

airy

C

attl

e

MCF(b)

Warm 6. Horses Cool 7. Mules and Asses Temperate 8. Swine

Allocation (%)

Warm 9. Poultry Cool 10. Other livestock (please specify)

Temperate

Sw

ine

MCF(b)

Warm Cool (1) Climate regions are defined in terms of annual average temperature as follows: Cool = less than 15°C; Temperate = 15 - 25°C inclusive; and Warm = greater than 25°C (see Table 4.2 of the IPCC Guidelines (Volume 3, Reference Manual, p. 4.8)).

Temperate

Allocation (%) Warm

(2) VS = Volatile Solids; Bo = maximum methane producing capacity for manure IIPCC Guidelines (Volume 3, Reference Manual, p.4.23 and p.4.15); dm = dry matter. Provide average values for VS and Bo where original calculations were made at a more disagregated level of these livestock categories.

Cool

Temperate (3) Including data on dairy heifers, if available.

Oth

er l

ives

tock

(p

leas

e sp

ecif

y)

MCF(b)

Warm (4) The implied emission factors will not be calculated until the corresponding emission estimates are entered directly into Table 4.

(a) The information required in this table may not be directly applicable to country-specific methods developed for MCF calculations. In such cases, information on MCF derivation should be described in the NIR and references to the relevant sections of the NIR should be provided in the documentation box.

(b) MCF = Methane Conversion Factor (IPCC Guidelines, (Volume 3. Reference Manual, p. 4.9)). If another climate region categorization is used, replace the entries in the cells with the climate regions for which the MCFs are specified.

Documentation box:

• Parties should provide detailed explanations on the agriculture sector in Chapter 6: Agriculture (CRF sector 4) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and further details are needed to understand the content of this table. • Indicate in this documentation box whether the activity data used are one-year estimates or a three-year average. • Provide a reference to the relevant section in the NIR, in particular with regard to:

(a) disaggregation of livestock population (e.g. according to the classification recommended in the IPCC good practice guidance), including information on whether these data are one-year estimates or a three-year average. (b) parameters relevant to the application of IPCC good practice guidance;

(c) information on how the MCF are derived, if relevant data could not be provided in the additional information box.


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TABLE 4.B(b) SECTORAL BACKGROUND DATA FOR AGRICULTURE Country

N2O Emissions from Manure Management Year


ACTIVITY DATA AND OTHER RELATED INFORMATION IMPLIED EMISSION FACTORS (1)

AND SINK CATEGORIES Population size

Nitrogen excretion Nitrogen excretion per animal waste management system (AWMS) (kg N/yr) Emission factor per animal waste

management system (1000s) (kg N/head/yr) Anaerobic

lagoon Liquid system Daily spread Solid storage

and dry lot Pasture range and paddock

Other (kg N2O-N/kg N)

Cattle Anaerobic lagoon Option A: Liquid system

Dairy Cattle Solid storage and dry lot Non-Dairy Cattle Other AWMS


Sheep Swine Poultry Other livestock (please specify)

Total per AWMS

(1) The implied emission factor will not be calculated until the emissions are entered directly into Table 4.

Documentation box: • Parties should provide detailed explanations on the agriculture sector in Chapter 6: Agriculture (CRF sector 4) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table. • Indicate in this documentation box whether the activity data used are one-year estimates or a three-year average. • Provide a reference to the relevant section in the NIR, in particular with regard to: (a) disaggregation of livestock population (e.g. according to the classification recommended in the IPCC good practice guidance), including information on whether these data are one-year estimates or a three-year average. (b) information on other AWMS, if reported.


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TABLE 4.C SECTORAL BACKGROUND DATA FOR AGRICULTURE Country

Rice Cultivation Year



ACTIVITY DATA AND OTHER RELATED INFORMATION IMPLIED EMISSION FACTOR (1) EMISSIONS

Harvested area (2) Organic amendments added(3) CH4 CH4 (109 m2/yr) type (t/ha) (g/m2) (Gg)

1. Irrigated Continuously Flooded Intermittently Flooded Single Aeration

Multiple Aeration 2. Rainfed

Flood Prone Drought Prone

3. Deep Water Water Depth 50-100 cm Water Depth > 100 cm

4. Other (please specify) Upland Rice(4)

Total (4)

(1) The implied emission factor implicitly takes account of all relevant corrections for continuously flooded fields without organic amendment, the correction for the organic amendments and the effect of different soil characteristics, if considered in the calculation of methane emissions. (2) Harvested area is the cultivated area multiplied by the number of cropping seasons per year. (3) Specify dry weight or wet weight for organic amendments in the documentation box. (4) These rows are included to allow comparison with international statistics. Methane emissions from upland rice are assumed to be zero.

Documentation box: • Parties should provide detailed explanations on the agriculture sector in Chapter 6: Agriculture (CRF sector 4) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table. • When disaggregating by more than one region within a country, and/or by growing season, provide additional information on disaggregation and related data in the NIR and provide a reference to the relevant section in the NIR. • Where available, provide activity data and scaling factors by soil type and rice cultivar in the NIR.


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TABLE 4.D SECTORAL BACKGROUND DATA FOR AGRICULTURE Country

Agricultural Soils(1) Year


Additional information


ACTIVITY DATA AND OTHER RELATED INFORMATION

IMPLIED EMISSION FACTORS

EMISSIONS Fraction (a)

Description Value

Description Value N2O FracBURN Fraction of crop residue burned

kg N/yr kg N2O-N/kg N (2) (Gg) FracFUEL Fraction of livestock N excretion in excrements burned for fuel

1. Direct Soil Emissions N input to soils FracGASF Fraction of synthetic fertilizer N applied to soils that volatilizes as NH3 and NOx

1. Synthetic Fertilizers Nitrogen input from application of synthetic fertilizers

FracGASM Fraction of livestock N excretion that volatilizes as NH3 and NOx

2. Animal Manure Applied to Soils Nitrogen input from manure applied to soils FracGRAZ Fraction of livestock N excreted and deposited onto soil during grazing

3. N-fixing Crops Nitrogen fixed by N-fixing crops FracLEACH Fraction of N input to soils that is lost through leaching and run-off

4. Crop Residue Nitrogen in crop residues returned to soils FracNCRBF Fraction of total above-ground biomass of N-fixing crop that is N

5. Cultivation of Histosols (2) Area of cultivated organic soils (ha/yr) FracNCRO Fraction of residue dry biomass that is N

6. Other direct emissions (please specify)

FracR Fraction of total above-ground crop biomass that is removed from the field as a crop product

Other fractions (please specify)

2. Pasture, Range and Paddock Manure N excretion on pasture range and paddock

3. Indirect Emissions

1. Atmospheric Deposition Volatized N from fertilizers, animal manures and other

2. Nitrogen Leaching and Run-off N from fertilizers, animal manures and other that is lost through leaching and run-off

(a) Use the definitions for fractions as specified in the IPCC Guidelines (Volume 3. Reference Manual, pp. 4.92 - 4.113) as elaborated by the IPCC good practice guidance (pp 4.54 - 4.74).


(1) See footnote 4 to Summary 1.A. of this common reporting format. Parties that choose to report CO2 emissions and removals from agricultural soils under 4.D. Agricultural Soils category should indicate the amount (in Gg) of these emissions or removals and relevant additional information (activity data, implied emissions factors) in the documentation box. (2) To convert from N2O-N to N2O emissions, multiply by 44/28. Note that for cultivation of Histosols the unit of the IEF is kg N2O-N/ha.

Documentation box: • Parties should provide detailed explanations on the agriculture sector in Chapter 6: Agriculture (CRF sector 4) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table. • Provide a reference to the relevant section in the NIR, in particular with regard to:

(a) Background information on CO2 emissions and removals estimates from agricultural soils, if accounted for under the agriculture sector; (b) Background information on CH4 emissions from agricultural soils, if accounted for under the agriculture sector; (c) Disaggregated values for FracGRAZ according to animal type, and for FracBURN according to crop types; (d) Full list of assumptions and fractions used.


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TABLE 4.E SECTORAL BACKGROUND DATA FOR AGRICULTURE Country

Prescribed Burning of Savannas Year



ACTIVITY DATA AND OTHER RELATED INFORMATION IMPLIED EMISSION FACTORS EMISSIONS

Area of savanna burned

Average above-ground biomass density

Fraction of savanna burned

Biomass burned Nitrogen fraction in

biomass

CH4 N2O CH4 N2O

(k ha/yr) (t dm/ha) (Gg dm) (kg/t dm) (Gg)

(specify ecological zone)


Living Biomass Dead Biomass

Fraction of above-ground biomass

Fraction oxidized

Carbon fraction

Documentation box: Parties should provide detailed explanations on the agriculture sector in Chapter 6: Agriculture (CRF sector 4) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table.


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TABLE 4.F SECTORAL BACKGROUND DATA FOR AGRICULTURE Country

Field Burning of Agricultural Residues Year



ACTIVITY DATA AND OTHER RELATED INFORMATION IMPLIED EMISSION FACTORS

EMISSIONS

Crop production

Residue/ Crop ratio

Dry matter (dm)

fraction of residue

Fraction burned in

fields

Fraction oxidized

Total biomass burned

C fraction of residue

N-C ratio in biomass residues

CH4 N2O CH4 N2O

(t) (Gg dm) (kg/t dm) (Gg)

1. Cereals Wheat Barley Maize Oats Rye Rice Other (please specify)

2. Pulses

Dry bean Peas Soybeans Other (please specify)

3 Tubers and Roots

Potatoes Other (please specify)

4 Sugar Cane 5 Other (please specify)

Documentation box: Parties should provide detailed explanations on the agriculture sector in Chapter 6: Agriculture (CRF sector 4) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table.


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TABLE 5 SECTORAL REPORT FOR LAND-USE CHANGE AND FORESTRY Country

(Sheet 1 of 1) Year

Submission GREENHOUSE GAS SOURCE AND SINK CATEGORIES

CO2 emissions(1) CO2 removals(1) Net CO2 emissions/ removals (1)

CH4 N2O NOx CO

(Gg) Total Land-Use Change and Forestry A. Changes in Forest and Other Woody Biomass Stocks

1. Tropical Forests 2. Temperate Forests 3. Boreal Forests 4. Grasslands/Tundra 5. Other (please specify)

Harvested Wood (2) B. Forest and Grassland Conversion


C. Abandonment of Managed Lands


D. CO2 Emissions and Removals from Soil

Cultivation of Mineral Soils Cultivation of Organic Soils Liming of Agricultural Soils Forest Soils Other (please specify)(3)

E. Other (please specify) (1) Note that according to the IPCC Guidelines, for purposes of reporting, the signs for removals are always (-) and for emissions (+). Net CO2 emissions/removals are calculated as follows: net CO2 = CO2 emissions + CO2 removals. Note that this result is to be reported in table Summary 1.A, where a single number is to be placed in either the CO2 emissions or the CO2 removals column, as appropriate.

(2) Following the IPCC Guidelines, the harvested wood should be reported under Changes in Forest and Other Woody Biomass Stocks (Volume 3. Reference Manual, p.5.17). (3) Include emissions from soils not reported under sections A, B and C.

Note: According to the IPCC Guidelines (Volume 3. Reference Manual, pp. 4.2, 4.87), CO2 emissions from agricultural soils are to be included under Land-use change and forestry (LUCF). At the same time, the Summary Report 7A (Volume 1. Reporting Instructions, Tables.27) allows for reporting CO2 emissions or removals from agricultural soils either in the Agriculture sector, under 4.D Agricultural soils or in the Land-use change and forestry sector under 5.D Emissions and removals from soil. Parties may choose either way to report emissions or removals from this source in the common reporting format, but the way they have chosen to report should be clearly indicated, by providing a brief explanation in the documentation boxes to Table 4D of the agriculture sector. Double-counting of these emissions or removals should be avoided. Parties should include these emissions or removals consistently in Table8(a) (Recalculation - Recalculated data) and Table10 (Emission trends).

Documentation box: • Parties should provide detailed explanations on the land-use change and forestry sector in Chapter 7: Land-use change and forestry (CRF sector 5) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table. • If estimates are reported under "5.E Other", use this documentation box to provide information regarding activities covered under this category and to provide reference to the section in the NIR where background information can be found.


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TABLE 5.A SECTORAL BACKGROUND DATA FOR LAND-USE CHANGE AND FORESTRY Country Changes in Forest and Other Woody Biomass Stocks Year (Sheet 1 of 1) Submission

GREENHOUSE GAS SOURCE AND SINK CATEGORIES ACTIVITY DATA IMPLIED EMISSION

FACTORS ESTIMATES Area of forest/

biomass stocks Average annual growth

rate Implied carbon uptake

factor Carbon uptake increment

(kha) (t dm/ha) (t C/ha) (Gg C) Tropical Plantations Acacia spp.

Eucalyptus spp. Tectona grandis Pinus spp Pinus caribaea Mixed Hardwoods Mixed Fast-Growing

Hardwoods

Mixed Softwoods Other Forests Moist Seasonal Dry Other (specify)

Temperate Plantations Commercial Evergreen Deciduous Other (specify)

Boreal Number of trees Annual growth rate Carbon uptake factor Carbon uptake increment

(1000s of trees) (kt dm/1000 trees) (t C/tree) (Gg C) Non-Forest Trees (specify type)

Total annual growth increment (Gg C) Gg CO2 Amount of biomass removed Carbon emission factor Carbon release (kt dm) (t C/t dm) (Gg C)

Total biomass removed in Commercial Harvest Traditional Fuelwood Consumed Total Other Wood Use

Total Biomass Consumption from Stocks (1) (Gg C) Other Changes in Carbon Stocks (2) (Gg C) Gg CO2

Net annual carbon uptake (+) or release (-) (Gg C) Net CO2 emissions (-) or removals (+) (Gg CO2)

(1) Make sure that the quantity of biomass burned off-site is subtracted from this total. (2) The net annual carbon uptake/release is determined by comparing the annual biomass growth versus annual harvest, including the decay of forest products and slash left during harvest. The IPCC Guidelines recommend default assumption that all carbon removed in wood and other biomass from forests is oxidized in the year of removal. The emissions from decay could be included under Other Changes in Carbon Stocks. Note: Sectoral background data tables on Land-Use Change and Forestry should be filled in only by Parties using the IPCC default methodology. Parties that use country-specific methods and models should report information on them in a transparent manner in the NIR.

Documentation box: Parties should provide detailed explanations on the land-use change and forestry sector in Chapter 7: Land-use change and forestry (CRF sector 5) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table.


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TABLE 5.B SECTORAL BACKGROUND DATA FOR LAND-USE CHANGE AND FORESTRY Country

Forest and Grassland Conversion Year


GREENHOUSE GAS SOURCE ACTIVITY DATA AND OTHER RELATED INFORMATION IMPLIED EMISSION FACTORS EMISSIONS AND SINK CATEGORIES On site and off site burning Decay of above-ground biomass(1)

Burning Burning

On site On site Off site

Quantity of biomass burned Off site

Decay

Decay

Area converted annually

Annual net loss of biomass

On site Off site

Average area

converted

Average annual net loss of biomass

Average quantity of biomass left to

decay

CO2 CH4 N2O CO2 CO2 CO2 CH4 N2O CO2 CO2

Vegetation types (kha) (kt dm) (kt dm) (kt dm) (kha) (t dm/ha) (kt dm) (t/ha) (Gg)

Tropical Wet/Very Moist

Moist, short dry season

Moist, long dry season

Dry

Montane Moist

Montane Dry Tropical Savanna/Grasslands

Temperate Coniferous

Broadleaf

Mixed Broadleaf/ Coniferous

Grasslands

Boreal Mixed Broadleaf/ Coniferous

Coniferous

Forest-Tundra Grasslands/Tundra Other (please specify)

Total

(1) Activity data are by default 10-year averages. Specify the average decay time which is appropriate for the local conditions, if other than 10 years.


Emissions/Removals On site Off site Fractions On site Off site Immediate carbon release from burning Fraction of biomass burned (average) Total On site and Off site (Gg C) Fraction which oxidizes during burning

(average)

Delayed emissions from decay (Gg C) Carbon fraction of above-ground biomass (average)

Total annual carbon release (Gg C) Fraction left to decay (average)

Total annual CO2 emissions (Gg CO2) Nitrogen-carbon ratio

Note: Sectoral background data tables on Land-Use Change and Forestry should be filled in only by Parties using the IPCC default methodology. Parties that use country-specific methods and models should report information on them in a transparent manner in the NIR. Documentation box: Parties should provide detailed explanations on the land-use change and forestry sector in Chapter 7: Land-use change and forestry (CRF sector 5) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table.


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TABLE 5.C SECTORAL BACKGROUND DATA FOR LAND-USE CHANGE AND FORESTRY Country Abandonment of Managed Lands Year (Sheet 1 of 1) Submission

ACTIVITY DATA AND OTHER RELATED INFORMATION IMPLIED EMISSION FACTORS ESTIMATES GREENHOUSE GAS SOURCE

AND SINK CATEGORIES Total area abandoned and regrowing (1)

Annual rate of above-ground biomass growth

Carbon fraction of above-ground biomass

Rate of above-ground biomass carbon uptake

Annual carbon uptake in above-ground biomass

first 20 years >20 years first 20 years >20 years first 20 years >20 years first 20 years >20 years first 20 years >20 years Original natural ecosystems (kha) (kha) (t dm/ha) (t dm/ha) (t C/ha/yr) (t C/ha/yr) (Gg C/yr) (Gg C/yr) Tropical Wet/Very Moist

Moist, short dry season Moist, long dry season Dry Montane Moist Montane Dry

Tropical Savanna/Grasslands Temperate Mixed

Broadleaf/Coniferous

Coniferous Broadleaf

Grasslands Boreal Mixed

Broadleaf/Coniferous

Coniferous Forest-tundra

Grasslands/Tundra Other (please specify)

Total annual carbon uptake (Gg C) Total annual CO2 removal (Gg CO2)

(1) If lands are regenerating to grassland, then the default assumption is that no significant changes in above-ground biomass occur.

Note: Sectoral background data tables on Land-use Change and Forestry should be filled in only by Parties using the IPCC default methodology. Parties that use country-specific methods and models should report information on them in a transparent manner in the NIR.



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TABLE 5.D SECTORAL BACKGROUND DATA FOR LAND-USE CHANGE AND FORESTRY Country

CO2 Emissions and Removals from Soil Year


Additional information Soil type GREENHOUSE GAS SOURCE

AND SINK CATEGORIES ACTIVITY DATA IMPLIED EMISSION

FACTORS ESTIMATES

Average annual rate of soil

carbon uptake/removal Net change in soil carbon in

mineral soils

Hig

h

acti

vity

so

ils

Low

ac

tivi

ty

soil

s

San

dy

Vol

can

ic

Wet

lan

d

(Aq

uic

)

Org

anic

so

il

Land area (Mha)

(Mg C/ha/yr) (Tg C over 20 yr)

Yea

r

Climate (a) Land-use/ management system(a)

percent distribution (%)

Cultivation of Mineral Soils (1) (e.g. tropical, dry) (e.g. savanna) High Activity Soils (e.g. irrigated cropping) Low Activity Soils Sandy Volcanic Wetland (Aquic)

20

yea

rs

pri

or

Other (please specify)

Land area Annual loss rate Carbon emissions from organic soils

(ha) (Mg C/ha/yr) (Mg C/yr)

inv

ento

ry

yea

r

Cultivation of Organic Soils Cool Temperate

Upland Crops (a) These should represent the major types of land management systems per climate region present in the country as well as ecosystem types which were either converted to agriculture (e.g., forest, savanna, grassland) or have been derived from previous agricultural land-use (e.g., abandoned lands, reforested lands). Systems should also reflect differences in soil carbon stocks that can be related to differences in management (IPCC Guidelines, Volume 2. Workbook, Table 5-9, p. 5.26, and Appendix (pp. 5.31 - 5.38)).

Pasture/Forest Warm Temperate

Upland Crops Pasture/Forest

Tropical Upland Crops Pasture/Forest

Total annual amount of lime

Carbon conversion factor Carbon emissions from liming

(Mg) (Mg C) Liming of Agricultural Soils Limestone Ca(CO3) Dolomite CaMg(CO3)2

Total annual net carbon emissions from agriculturally impacted soils (Gg C) Total annual net CO2 emissions from agriculturally impacted soils (Gg CO2)

(1) The information to be reported under Cultivation of Mineral Soils aggregates data per soil type over all land-use/management systems. This refers to land area data and to the emission estimates and implied emissions factors accordingly.

Note: Sectoral background data tables on Land-Use Change and Forestry should be filled in only by Parties using the IPCC default methodology. Parties that use country-specific methods and models should report information on them in a transparent manner in the NIR.



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TABLE 6 SECTORAL REPORT FOR WASTE Country (Sheet 1 of 1) Year

Submission


CO2(1) CH4 N2O NOx CO NMVOC SO2

(Gg) Total Waste A. Solid Waste Disposal on Land

1. Managed Waste Disposal on Land 2. Unmanaged Waste Disposal Sites 3. Other (as specified in table 6.A)

B. Waste Water Handling 1. Industrial Wastewater 2. Domestic and Commercial Waste Water 3. Other (as specified in table 6.B)

C. Waste Incineration D. Other (please specify) (1) CO2 emissions from source categories Solid waste disposal on land and Waste incineration should only be included if they derive from non-biological or inorganic waste sources. Documentation box: • Parties should provide detailed explanations on the waste sector in Chapter 8: Waste (CRF sector 6) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table. • If estimates are reported under "6.D Other", use this documentation box to provide information regarding activities covered under this category and to provide reference to the section in the NIR where background information can be found.


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TABLE 6.A SECTORAL BACKGROUND DATA FOR WASTE Country

Solid Waste Disposal Year





IMPLIED EMISSION FACTOR

EMISSIONS Description Value

Annual MSW at the SWDS MCF DOC degraded CH4 (1) CO2 CH4 CO2

(4) Total population (1000s)(a) Emissions

(2 ) Recovery

(3) Urban population (1000s)(a)

(Gg) % (t /t MSW) (Gg) Waste generation rate (kg/capita/day) 1 Managed Waste Disposal on Land Fraction of MSW disposed to SWDS 2 Unmanaged Waste Disposal Sites Fraction of DOC in MSW

a. Deep (>5 m) CH4 oxidation factor (b) b. Shallow (<5 m) CH4 fraction in landfill gas

3 Other (please specify) CH4 generation rate constant (k) (c) Time lag considered (yr) (c)

MSW - Municipal Solid Waste, SWDS - Solid Waste Disposal Site, MCF - Methane Correction Factor, DOC - Degradable Organic Carbon (IPCC Guidelines (Volume 3. Reference Manual, section 6.2.4)).

MSW includes household waste, yard/garden waste, commercial/market waste and organic industrial solid waste. MSW should not include inorganic industrial waste such as construction or demolition materials.

(a) Specify whether total or urban population is used and the rationale for doing so.

(b) See IPCC Guidelines (Volume 3. Reference Manual, p. 6.9).

(1) The CH4 implied emission factor (IEF) is calculated on the basis of gross CH4 emissions, as follows: IEF = (CH4 emissions + CH4 recovered)/annual MSW at the SWDS. (c) Only for Parties using Tier 2 methods. (2) Actual emissions (after recovery). (3) CH4 recovered and flared or utilized. (4) Under Solid Waste Disposal, CO2 emissions should be reported only when the disposed waste is combusted at the disposal site as a management practice. CO2 emissions from non-biogenic wastes are included in the total emissions, whereas the CO2 emissions from biogenic wastes are not included in the total emissions. TABLE 6.C SECTORAL BACKGROUND DATA FOR WASTE

Waste Incineration

(Sheet 1 of 1)

GREENHOUSE GAS SOURCE AND SINK CATEGORIES ACTIVITY DATA IMPLIED EMISSION FACTOR EMISSIONS Amount of incinerated wastes CO2

CH4 N2O CO2 (1) CH4 N2O

(Gg) (kg/t waste) (Gg) Waste Incineration a. Biogenic (1) b. Other (non-biogenic - please specify) (1), (2) (1) Under Solid Waste Disposal, CO2 emissions should be reported only when the disposed waste is combusted at the disposal site as a management practice. CO2 emissions from non-biogenic wastes are included in the total emissions, while the CO2 emissions from biogenic wastes are not included in the total emissions. (2) Enter under this source category all types of non-biogenic wastes, such as plastics.

Note: Only emissions from waste incineration without energy recovery are to be reported in the waste sector. Emissions from incineration with energy recovery are to be reported in the energy sector, as other fuels (see IPCC good practice guidance, page 5.23).

Documentation box: • Parties should provide detailed explanations on the waste sector in Chapter 8: Waste (CRF sector 6) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table. • Parties that use country-specific models should provide a reference in the documentation box to the relevant section in the NIR where these models are described, and fill in only the relevant cells of tables 6.A and 6.C. • Provide a reference to the relevant section in the NIR, in particular with regard to: (a) A population size (total or urban population) used in the calculations and the rationale for doing so; (b) The composition of landfilled waste; (c) In relation to the amount of incinerated wastes, specify whether the reported data relate to wet or dry matter.


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TABLE 6.B SECTORAL BACKGROUND DATA FOR WASTE Country

Waste Water Handling Year


Additional information GREENHOUSE GAS SOURCE AND SINK CATEGORIES

ACTIVITY DATA AND RELATED INFORMATION(1)

IMPLIED EMISSION FACTOR

EMISSIONS Domestic Industrial

Total organic product CH4 (2) N2O(3) CH4 N2O (3) Total waste water (m3):

Emissions (4) Recovery (5) Treated waste water (%): (Gg DC(1)/yr) (kg/kg DC) (Gg) Waste-water streams: Waste-water output 1. Industrial Waste Water (m3)

DC (kgCOD/m3)

a. Waste Water Industrial waste water b. Sludge Non-ferrous

2. Domestic and Commercial Wastewater

Fertilizers

a. Waste Water Food and beverage b. Sludge Paper and pulp

3. Other (please specify) Organic chemicals (6) Other (specify)

a. Waste Water b. Sludge DC (kg BOD/1000 person/yr)

(6) Domestic and Commercial



IMPLIED EMISSION FACTOR EMISSIONS Other

Population Protein consumption

N fraction N2O N2O

(1000s) (kg/person/yr) (kg N/kg protein)

(kg N2O-N/kg sewage N produced)

(Gg)

N2O from human sewage (3) Handling systems: Industrial waste water

treated

Industrial sludge treated

Domestic waste water

treated

Domestic sludge treated

(%) (%) (%) (%) (1) DC - degradable organic component. DC indicators are COD (Chemical Oxygen Demand) for industrial waste water and BOD (Biochemical Oxygen Demand) for Domestic/Commercial waste water/sludge (IPCC Guidelines (Volume 3. Reference Manual, pp. 6.14, 6.18)).

Aerobic

(2) The CH4 implied emission factor (IEF) is calculated on the basis of gross CH4 emissions, as follows: IEF = (CH4 emissions + CH4 recovered or flared) / total organic product.

Anaerobic

(3) Parties using methods other than those from the IPCC for estimating N2O emissions from human sewage or waste-water treatment should provide aggregate data in this table.

Other (specify)

(4) Actual emissions (after recovery). (5) CH4 recovered and flared or utilized. (6) Use these cells to specify each activity covered under "6.B.3 Other". Note that under each reported activity, data for waste water and sludge are to be reported separately. Documentation box: • Parties should provide detailed explanations on the waste sector in Chapter 8: Waste (CRF sector 6) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and/or further details are needed to understand the content of this table. • Regarding the estimates for N2O from human sewage, specify whether total or urban population is used in the calculations and the rationale for doing so. Provide explanation in the documentation box. • Parties using methods other than those from the IPCC for estimating N2O emissions from human sewage or waste-water treatment should provide, in the NIR, corresponding information on methods, activity data and emission factors used, and should provide a reference to the relevant section of the NIR in this documentation box.


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SUMMARY 1.A SUMMARY REPORT FOR NATIONAL GREENHOUSE GAS INVENTORIES (IPCC TABLE 7A) Country

(Sheet 1 of 3) Year

Submission

GREENHOUSE GAS SOURCE AND CO2 CO2 CH4 N2O HFCs(1) PFCs(1) SF6 NOx CO NMVOC SO2

SINK CATEGORIES emissions removals P A P A P A (Gg) CO2 equivalent (Gg) (Gg)

Total National Emissions and Removals

1. Energy A. Fuel Combustion Reference Approach (2)

Sectoral Approach (2)



3. Transport

4. Other Sectors

5. Other

B. Fugitive Emissions from Fuels

1. Solid Fuels

2. Oil and Natural Gas

2. Industrial Processes A. Mineral Products

B. Chemical Industry

C. Metal Production

D. Other Production (3)

E. Production of Halocarbons and SF6

F. Consumption of Halocarbons and SF6

G. Other

A = Actual emissions based on Tier 2 approach of the IPCC Guidelines. P = Potential emissions based on Tier 1 approach of the IPCC Guidelines.



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SUMMARY 1.A SUMMARY REPORT FOR NATIONAL GREENHOUSE GAS INVENTORIES (IPCC TABLE 7A) Country (Sheet 2 of 3) Year

Submission

GREENHOUSE GAS SOURCE AND CO2 CO2 CH4 N2O HFCs (1) PFCs(1) SF6 NOx CO NMVOC SO2


3. Solvent and Other Product Use

4. Agriculture A. Enteric Fermentation

B. Manure Management

C. Rice Cultivation

D. Agricultural Soils (4), (5) (4), (5)

E. Prescribed Burning of Savannas

F. Field Burning of Agricultural Residues

G. Other

5. Land-Use Change and Forestry (5) (5) A. Changes in Forest and Other Woody Biomass Stocks

(5) (5)

B. Forest and Grassland Conversion (5) (5)

C. Abandonment of Managed Lands (5) (5)

D. CO2 Emissions and Removals from Soil (5) (5)

E. Other (5) (5)

6. Waste A. Solid Waste Disposal on Land (6)

B. Waste-water Handling

C. Waste Incineration (6)

D. Other

7. Other (please specify)(7)



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SUMMARY 1.A SUMMARY REPORT FOR NATIONAL GREENHOUSE GAS INVENTORIES (IPCC TABLE 7A) Country (Sheet 3 of 3) Year

Submission

GREENHOUSE GAS SOURCE AND CO2 CO2 CH4 N2O HFCs PFCs SF6 NOx CO NMVOC SO2 SINK CATEGORIES emissions removals P A P A P A

(Gg) CO2 equivalent (Gg) (Gg)

Memo Items: (8) International Bunkers

Aviation Marine


(1) The emissions of HFCs and PFCs are to be expressed as CO2 equivalent emissions. Data on disaggregated emissions of HFCs and PFCs are to be provided in Table 2(II) of this common reporting format. (2) For verification purposes, countries are asked to report the results of their calculations using the Reference approach and to explain any differences with the Sectoral approach in the documentation box to Table 1.A.(c). For estimating national total emissions, the results from the Sectoral approach should be used, where possible. (3) Other Production includes Pulp and Paper and Food and Drink Production. (4) According to the IPCC Guidelines (Volume 3. Reference Manual, pp. 4.2, 4.87), CO2 emissions from agricultural soils are to be included under Land-use change and forestry (LUCF). At the same time, the Summary Report 7A (Volume 1. Reporting Instructions, Tables.27) allows for reporting CO2 emissions or removals from agricultural soils either in the Agriculture sector, under 4.D Agricultural soils or in the Land-use change and forestry sector under 5.D Emissions and removals from soil. Parties may choose either way to report emissions or removals from this source in the common reporting format, but the way they have chosen to report should be clearly indicated, by providing a brief explanation in the documentation box to Table 4.D of the agriculture sector. Double-counting of these emissions or removals should be avoided. Parties should include these emissions or removals consistently in Table8(a) (Recalculation - Recalculated data) and Table10 (Emission trends). (5) Do not provide an estimate of both CO2 emissions and CO2 removals. "Net" emissions (emissions - removals) of CO2 should be estimated and a single number placed in either the CO2 emissions or CO2 removals column, as appropriate. Note that for the purposes of reporting, the signs for removals are always (-) and for emissions (+). (6) Note that CO2 from source categories Solid waste disposal on land and Waste incineration should only be included if it stems from non-biogenic or inorganic waste streams. Note that only emissions from waste incineration without energy recovery are to be reported in the waste sector, whereas emissions from incineration with energy recovery are to be reported in the energy sector. (7) If reporting any country-specific source category under sector "7. Other", detailed explanations should be provided in Chapter 9: Other (CRF sector 7) of the NIR. (8) Countries are asked to report emissions from international aviation and marine bunkers and multilateral operations, as well as CO2 emissions from biomass, under Memo Items. These emissions should not be included in the national total emissions from the energy sector. Amounts of biomass used as fuel are included in the national energy consumption but the corresponding CO2 emissions are not included in the national total as it is assumed that the biomass is produced in a sustainable manner. If the biomass is harvested at an unsustainable rate, net CO2 emissions are accounted for as a loss of biomass stocks in the land-use change and forestry sector.


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SUMMARY 1.B SHORT SUMMARY REPORT FOR NATIONAL GREENHOUSE GAS INVENTORIES (IPCC TABLE 7B) Country

(Sheet 1 of 1) Year

Submission

GREENHOUSE GAS SOURCE AND CO2 CO2 CH4 N2O HFCs(1) PFCs(1) SF6 NOx CO NMVOC SO2


Total National Emissions and Removals 1. Energy

A. Fuel Combustion Reference Approach(2) Sectoral Approach(2) B. Fugitive Emissions from Fuels

2. Industrial Processes 3. Solvent and Other Product Use 4. Agriculture (3) 5. Land-Use Change and Forestry (4) (4) 6. Waste 7. Other Memo Items: (5) International Bunkers

Aviation Marine


A = Actual emissions based on Tier 2 approach of the IPCC Guidelines.

P = Potential emissions based on Tier 1 approach of the IPCC Guidelines.

(1) The emissions of HFCs and PFCs are to be expressed as CO2 equivalent emissions. Data on disaggregated emissions of HFCs and PFCs are to be provided in Table 2(II) of this common reporting format. (2) For verification purposes, countries are asked to report the results of their calculations using the Reference approach and to explain any differences with the Sectoral approach in the documentation box to Table 1.A.(c). For estimating national total emissions, the result from the Sectoral approach should be used, where possible.

(3) According to the IPCC Guidelines (Volume 3. Reference Manual, pp. 4.2, 4.87), CO2 emissions from agricultural soils are to be included under Land-use change and forestry (LUCF). At the same time, the Summary Report 7A (Volume 1. Reporting Instructions, Tables.27) allows for reporting CO2 emissions or removals from agricultural soils either in the Agriculture sector, under 4.D Agricultural soils or in the Land-use change and forestry sector under 5.D Emissions and removals from soil. Parties may choose either way to report emissions or removals from this source in the common reporting format, but the way they have chosen to report should be clearly indicated, by providing a brief explanation in the documentation box to Table 4.D of the agriculture sector. Double-counting of these emissions or removals should be avoided. Parties should include these emissions or removals consistently in Table8(a) (Recalculation - Recalculated data) and Table10 (Emission trends). (4) Do not provide an estimate of both CO2 emissions and CO2 removals. "Net" emissions (emissions - removals) of CO2 should be estimated and a single number placed in either the CO2 emissions or CO2 removals column, as appropriate. Note that for the purposes of reporting, the signs for removals are always (-) and for emissions (+). (5) Countries are asked to report emissions from international aviation and marine bunkers and multilateral operations, as well as CO2 emissions from biomass, under Memo Items. These emissions should not be included in the national total emissions from the energy sector. Amounts of biomass used as fuel are included in the national energy consumption but the corresponding CO2 emissions are not included in the national total as it is assumed that the biomass is produced in a sustainable manner. If the biomass is harvested at an unsustainable rate, net CO2 emissions are accounted for as a loss of biomass stocks in the land-use change and forestry sector.


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SUMMARY 2 SUMMARY REPORT FOR CO2 EQUIVALENT EMISSIONS Country (Sheet 1 of 1) Year

Submission GREENHOUSE GAS SOURCE AND CO2

(1) CH4 N2O HFCs (2) PFCs (2) SF6 (2) Total

SINK CATEGORIES CO2 equivalent (Gg ) Total (Net Emissions) (1) 1. Energy

A. Fuel Combustion (Sectoral Approach) 1. Energy Industries 2. Manufacturing Industries and Construction 3. Transport 4. Other Sectors 5. Other

B. Fugitive Emissions from Fuels 1. Solid Fuels 2. Oil and Natural Gas

2. Industrial Processes A. Mineral Products B. Chemical Industry C. Metal Production D. Other Production E. Production of Halocarbons and SF6 F. Consumption of Halocarbons and SF6 (2) G. Other

3. Solvent and Other Product Use 4. Agriculture

A. Enteric Fermentation B. Manure Management C. Rice Cultivation D. Agricultural Soils(3) E. Prescribed Burning of Savannas F. Field Burning of Agricultural Residues G. Other

5. Land-Use Change and Forestry(1) 6. Waste

A. Solid Waste Disposal on Land B. Waste-water Handling C. Waste Incineration D. Other

7. Other (as specified in Summary 1.A) Memo Items: (4) International Bunkers Aviation Marine Multilateral Operations CO2 Emissions from Biomass (1) For CO2 emissions from Land-Use Change and Forestry the net emissions are to be reported. Note that for the purposes of reporting, the signs for removals are always (-) and for emissions (+). (2) Actual emissions should be included in the national totals. If no actual emissions were reported, potential emissions should be included. (3) See footnote 4 to table Summary 1.A. (4) See footnote 8 to table Summary 1.A.

GREENHOUSE GAS SOURCE AND SINK CATEGORIES CO2 CO2 Net CO2 CH4 N2O Total emissions removals emissions /

removals emissions

Land-Use Change and Forestry CO2 equivalent (Gg ) A. Changes in Forest and Other Woody Biomass Stocks

B. Forest and Grassland Conversion C. Abandonment of Managed Lands D. CO2 Emissions and Removals from Soil E. Other

Total CO2 Equivalent Emissions from Land-Use Change and Forestry

Total CO2 Equivalent Emissions without Land-Use Change and Forestry (a)

Total CO2 Equivalent Emissions with Land-Use Change and Forestry (a)

(a) The information in these rows is requested to facilitate comparison of data, because Parties differ in the way they report emissions and removals from Land-Use Change and Forestry. Note that these totals will differ from the totals reported in Table 10, sheet 5 if Parties report non-CO2 emissions from LUCF.


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SUMMARY 3 SUMMARY REPORT FOR METHODS AND EMISSION FACTORS USED Country (Sheet 1 of 2) Year

Submission

GREENHOUSE GAS SOURCE AND SINK CO2 CH4 N2O HFCs PFCs SF6

CATEGORIES Method applied

Emission factor

Method applied

Emission factor

Method applied

Emission factor

Method applied

Emission factor

Method applied

Emission factor

Method applied

Emission factor

1. Energy A. Fuel Combustion



3. Transport

4. Other Sectors

5. Other

B. Fugitive Emissions from Fuels

1. Solid Fuels

2. Oil and Natural Gas

2. Industrial Processes

A. Mineral Products

B. Chemical Industry

C. Metal Production

D. Other Production

E. Production of Halocarbons and SF6

F. Consumption of Halocarbons and SF6

G. Other

Use the following notation keys to specify the method applied: D (IPCC default), T1a, T1b, T1c (IPCC Tier 1a, Tier 1b and Tier 1c,

respectively),

RA (Reference Approach), T2 (IPCC Tier 2), T1 (IPCC Tier 1), T3 (IPCC Tier 3),

CR (CORINAIR), CS (Country Specific). OTH (Other)

If using more than one method within one source category, list all the relevant methods. Explanations regarding country-specific methods, other methods or any modifications to the default IPCC methods, as well as information regarding the use of different methods per source category where more than one method is indicated, should be provided in the documentation box. Also use the documentation box to explain the use of notation OTH.

Use the following notation keys to specify the emission factor used:

D (IPCC default), CS (Country Specific), CR (CORINAIR), PS (Plant Specific).

OTH (Other)

Where a mix of emission factors has been used, list all the methods in the relevant cells and give further explanations in the documentation box. Also use the documentation box to explain the use of notation OTH.


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SUMMARY 3 SUMMARY REPORT FOR METHODS AND EMISSION FACTORS USED Country

(Sheet 2 of 2) Year

Submission GREENHOUSE GAS SOURCE AND SINK CO2 CH4 N2O HFCs PFCs SF6

CATEGORIES Method applied

Emission factor

Method applied

Emission factor

Method applied

Emission factor

Method applied

Emission factor

Method applied

Emission factor

Method applied

Emission factor


A. Enteric Fermentation B. Manure Management C. Rice Cultivation D. Agricultural Soils E. Prescribed Burning of Savannas F. Field Burning of Agricultural Residues G. Other

5. Land-Use Change and Forestry A. Changes in Forest and Other Woody Biomass Stocks B. Forest and Grassland Conversion C. Abandonment of Managed Lands D. CO2 Emissions and Removals from Soil E. Other

6. Waste A. Solid Waste Disposal on Land B. Waste-water Handling C. Waste Incineration D. Other

7. Other (as specified in Summary 1.A)

Use the following notation keys to specify the method applied: D (IPCC default), T1a, T1b, T1c (IPCC Tier 1a, Tier 1b and Tier 1c,

respectively), CR (CORINAIR),

RA (Reference Approach), T2 (IPCC Tier 2), CS (Country Specific). T1 (IPCC Tier 1), T3 (IPCC Tier 3), OTH (Other)

If using more than one method within one source category, list all the relevant methods. Explanations regarding country-specific methods, other methods or any modifications to the default IPCC methods, as well as information regarding the use of different methods per source category where more than one method is indicated, should be provided in the documentation box. Also use the documentation box to explain the use of notation OTH.

Use the following notation keys to specify the emission factor used:

D (IPCC default), CS (Country Specific), CR (CORINAIR), PS (Plant Specific).

OTH (Other) Where a mix of emission factors has been used, list all the methods in the relevant cells and give further explanations in the documentation box. Also use the documentation box to explain the use of notation OTH.

Documentation box:

• Parties should provide the full information on methodological issues, such as methods and emission factors used, in the relevant sections of Chapters 3 to 9 (see section 2.2 of each of Chapters 3 - 9) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and further details are needed to understand the content of this table. • Where a mix of methods/emission factors has been used within one source category, use this documentation box to specify those methods/emission factors for the various sub-sources where they have been applied. • Where the notation OTH (Other) has been entered in this table, use this documentation box to specify those other methods/emission factors.


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TABLE 7 SUMMARY OVERVIEW FOR KEY SOURCES Country

(Sheet 1 of 1) Year

Submission

KEY SOURCES GAS CRITERIA USED FOR KEY SOURCE IDENTIFICATION COMMENTS

L T Q

Specify key sources according to the national level of disaggregation used:

For example: 4.B Manure management CH4 X

Note: L = Level assessment; T = Trend assessment; Q = Qualitative assessment.

For estimating key sources Parties may chose the disaggregation level presented as an example in Table 7.1 of the IPCC good practice guidance (page 7.6), the level used in Summary 1A of the CRF or any other

disaggregation level that the Party used to determine its key sources.

Documentation box: Parties should provide the full information on methodologies used for identifying key sources and the quantitative results from the level and trend assessments (according to tables 7.A1 – 7.A3 of the IPCC good practice guidance) in Annex 1 to the NIR.


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TABLE 8(a) RECALCULATION - RECALCULATED DATA Country

(Sheet 1 of 2) Recalculated year: Year

Submission

CO2 CH4 N2O


Previous

submission

Latest

submission Difference Difference(1 ) Impact of

recalculation on total

emissions (2)(3)

Previous

submission Latest



emissions (2)(3)

Previous

submission Latest



emissions (2)(3)

CO2 equivalent (Gg) (%) (%) CO2 equivalent (Gg) (%) (%) CO2 equivalent (Gg) (%) (%)

Total National Emissions and Removals

1. Energy

1.A. Fuel Combustion Activities

1.A.1 Energy Industries

1.A.2 Manufacturing Industries and Construction

1.A.3 Transport

1.A.4 Other Sectors

1.A.5 Other

1.B. Fugitive Emissions from Fuels

1.B.1. Solid fuel

1.B.2. Oil and Natural Gas

2. Industrial Processes

2.A. Mineral Products

2.B. Chemical Industry

2.C. Metal Production

2.D. Other Production

2.G. Other

3. Solvent and Other Product Use

4. Agriculture

4.A. Enteric Fermentation

4.B. Manure Management

4.C. Rice Cultivation

4.D. Agricultural Soils (4)

4.E. Prescribed Burning of Savannas

4.F. Field Burning of Agricultural Residues

4.G. Other

5. Land-Use Change and Forestry (net) (5)

5.A. Changes in Forest and Other Woody Biomass Stocks

5.B. Forest and Grassland Conversion

5.C. Abandonment of Managed Lands

5.D. CO2 Emissions and Removals from Soil

5.E. Other



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TABLE 8(a) RECALCULATION - RECALCULATED DATA Country

(Sheet 2 of 2) Recalculated year: Year

Submission

CO2 CH4 N2O

GREENHOUSE GAS SOURCE AND SINK CATEGORIES Previous

submission Latest

submission Difference Difference(1 )

Impact of recalculatio

n on total emissions (2)

Previous submission

Latest submission Difference Difference(1 )



Previous submission




CO2 equivalent (Gg) (%) (%) CO2 equivalent (Gg) (%) (%) CO2 equivalent (Gg) (%) (%) 6. Waste 6.A. Solid Waste Disposal on Land 6.B. Waste-water Handling 6.C. Waste Incineration 6.D. Other 7. Other (as specified in Summary 1.A) Memo Items: International Bunkers Multilateral Operations CO2 Emissions from Biomass

HFCs PFCs SF6

GREENHOUSE GAS SOURCE AND SINK CATEGORIES Previous

submission Latest

submission Difference Difference(1 )



Previous submission




Previous submission




CO2 equivalent (Gg) (%) (%) CO2 equivalent (Gg) (%) (%) CO2 equivalent (Gg) (%) (%) Total Actual Emissions 2.C.3. Aluminium Production 2.E. Production of Halocarbons and SF6 2.F. Consumption of Halocarbons and SF6 2.G. Other Potential Emissions from Consumption of HFCs/PFCs and SF6 Previous submission Latest submission Difference Difference(

1)

CO2 equivalent (Gg) (%) Total CO2 Equivalent Emissions with Land-Use Change and Forestry (6) Total CO2 Equivalent Emissions without Land-Use Change and Forestry (6)

(1) Estimate the percentage change due to recalculation with respect to the previous submission (Percentage change = 100 x [(LS-PS)/PS], where LS = Latest submission and PS = Previous submission. All cases of recalculation of the estimate of the source/sink category should be addressed and explained in Table 8(b). (2) Total emissions refer to total aggregate GHG emissions expressed in terms of CO2 equivalent, excluding GHGs from the LUCF sector. The impact of the recalculation on the total emissions is calculated as follows: impact of recalculation (%) = 100 x [(source (LS) - source (PS))/total emissions (LS)], where LS = Latest submission, PS = Previous submission. (3) The relative impact of recalculations of the LUCF sector is not considered in this table, until the IPCC completes its work on good practices for this sector and methods for estimating key sources from this sector are available. (4) According to the IPCC Guidelines (Volume 3. Reference Manual, pp. 4.2, 4.87), CO2 emissions from agricultural soils are to be included under Land-use change and forestry (LUCF). At the same time, the Summary Report 7A (Volume 1. Reporting Instructions, Tables.27) allows for reporting CO2 emissions or removals from agricultural soils either in the Agriculture sector, under 4.D Agricultural soils or in the Land-use change and forestry sector under 5.D Emissions and removals from soil. Parties may choose either way to report emissions or removals from this source in the common reporting format, but the way they have chosen to report should be clearly indicated, by providing a brief explanation in the documentation boxes to Table 4D of the agriculture sector. Double-counting of these emissions or removals should be avoided. Parties should include these emissions or removals consistently in Table8(a) (Recalculation - Recalculated data) and Table10 (Emission trends). (5) Net CO2 emissions/removals to be reported. (6) The information in these rows is requested to facilitate comparison of data, because Parties differ in the way they report emissions and removals from Land-Use Change and Forestry.

Documentation box:

Parties should provide detailed information on recalculations in Chapter 10: Recalculations and improvements, and in the relevant sections of Chapters 3 to 9 (see section 2.5 of each of Chapters 3 - 9) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and further details are needed to understand the content of this table.


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TABLE 8(b) RECALCULATION - EXPLANATORY INFORMATION Country

(Sheet 1 of 1) Year

Submission

RECALCULATION DUE TO Specify the sector and source/sink category(1) where changes in estimates have occurred:

GHG CHANGES IN:

Addition/removal/ reallocation Other changes in data (e.g. statistical or editorial changes,

correction of errors) Methods (2) Emission factors (2) Activity data (2) of source/sink categories

(1) Enter the identification code of the source/sink category (e.g. 1.B.1) in the first column and the name of the category (e.g. Fugitive Emissions from Solid Fuels) in the second column of the table. Note that the source categories entered in this table should match those used in Table 8(a). (2) Explain changes in methods, emission factors and activity data that have resulted in recalculation of the estimate of the source/sink as indicated in Table 8(a). Include changes in the assumptions and coefficients in the "Methods" column.

Documentation box:

Parties should provide the full information on recalculations in Chapter 10: Recalculations and improvements, and in the relevant sections of Chapters 3 to 9 (see section 2.5 of each of chapters 3 - 9) of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and further details are needed to understand the content of this table. References should particularly point to the sections of the NIR in which justifications of the changes as to improvements in the accuracy, completeness and consistency of the inventory are reported.


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TABLE 9(a) COMPLETENESS - INFORMATION ON NOTATION KEYS Country

(Sheet 1 of 1) Year

Submission

Sources and sinks not estimated (NE)(1) GHG Sector(2) Source/sink category (2) Explanation

CO2 CH4 N2O HFCs PFCs SF6

Sources and sinks reported elsewhere (IE)(3) GHG Source/sink category Allocation as per IPCC Guidelines Allocation used by the Party Explanation

CO2 CH4 N2O HFCs PFCs SF6

(1) Clearly indicate sources and sinks which are considered in the IPCC Guidelines but are not considered in the submitted inventory. Explain the reason for excluding these sources and sinks, in order to avoid arbitrary interpretations. An entry should be made for each source/sink category for which the notation key NE (not estimated) is entered in the sectoral tables. (2) Indicate omitted source/sink following the IPCC source/sink category structure (e.g. sector: Waste, source category: Waste-water Handling). (3) Clearly indicate sources and sinks in the submitted inventory that are allocated to a sector other than that indicated by the IPCC Guidelines. Show the sector indicated in the IPCC Guidelines and the sector to which the source or sink is allocated in the submitted inventory. Explain the reason for reporting these sources and sinks in a different sector. An entry should be made for each source/sink for which the notation key IE (included elsewhere) is used in the sectoral tables.


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TABLE 9(b) COMPLETENESS - INFORMATION ON ADDITIONAL GREENHOUSE GASES Country

(Sheet 1 of 1) Year

Submission

Additional GHG emissions reported(1) GHG Source category Emissions

(Gg) Estimated GWP value (100-year

horizon)

Emissions CO2 equivalent (Gg)

Reference to the source of GWP value

Explanation

(1) Parties are encouraged to provide information on emissions of greenhouse gases whose GWP values have not yet been agreed upon by the COP. Include such gases in this table if they are considered in the submitted inventory. Provide additional information on the estimation methods used. Documentation box: Parties should provide detailed information regarding completeness of the inventory in the NIR (Chapter 1.8: General assessment of the completeness, and Annex 5). Use this documentation box to provide references to relevant sections of the NIR if any additional information and further details are needed to understand the content of this table.


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TABLE 10 EMISSIONS TRENDS (CO2) Country

(Sheet 1 of 5) Year

Submission


Base year(1) 1990 1991 1992 1993 1994 1995 1996 1997 1998 1999 2000 2001 2002

Change from 1990(1) to

latest reported year

(Gg) (%)

1. Energy A. Fuel Combustion (Sectoral Approach)

1. Energy Industries 2. Manufacturing Industries and Construction 3. Transport 4. Other Sectors 5. Other


2. Industrial Processes A. Mineral Products B. Chemical Industry C. Metal Production D. Other Production E. Production of Halocarbons and SF6 F. Consumption of Halocarbons and SF6 G. Other


A. Enteric Fermentation B. Manure Management C. Rice Cultivation D. Agricultural Soils (2) E. Prescribed Burning of Savannas F. Field Burning of Agricultural Residues G. Other

5. Land-Use Change and Forestry (3) A. Changes in Forest and Other Woody Biomass Stocks B. Forest and Grassland Conversion C. Abandonment of Managed Lands D. CO2 Emissions and Removals from Soil E. Other


7. Other (as specified in Summary 1.A) Total CO2 emissions including net CO2 from LUCF (4 ) Total CO2 emissions excluding net CO2 from LUCF (4 )

Memo Items: International Bunkers

Aviation Marine




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TABLE 10 EMISSIONS TRENDS (CH4)

(Sheet 2 of 5)

Country

Year

Submission

Base year(1) 1990 1991 1992 1993 1994 1995 1996 1997 1998 1999 2000 2001 2002




(Gg) (%)

Total CH4 emissions 1. Energy

A. Fuel Combustion (Sectoral Approach) 1. Energy Industries 2. Manufacturing Industries and Construction

3. Transport 4. Other Sectors 5. Other


2. Industrial Processes A. Mineral Products B. Chemical Industry C. Metal Production D. Other Production E. Production of Halocarbons and SF6 F. Consumption of Halocarbons and SF6

G. Other 3. Solvent and Other Product Use 4. Agriculture


5. Land-Use Change and Forestry A. Changes in Forest and Other Woody Biomass Stocks

B. Forest and Grassland Conversion C. Abandonment of Managed Lands D. CO2 Emissions and Removals from Soil E. Other


7. Other (as specified in Summary 1.A) Memo Items: International Bunkers

Aviation Marine




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TABLE 10 EMISSIONS TRENDS (N2O) Country

(Sheet 3 of 5) Year

Submission

GREENHOUSE GAS SOURCE AND SINK CATEGORIES Base year(1) 1990 1991 1992 1993 1994 1995 1996 1997 1998 1999 2000 2001 2002

Change from 1990(1) to latest reported year

(Gg) (%)

Total N2O emissions 1. Energy

A. Fuel Combustion (Sectoral Approach) 1. Energy Industries 2. Manufacturing Industries and Construction

3. Transport 4. Other Sectors 5. Other


2. Industrial Processes A. Mineral Products B. Chemical Industry C. Metal Production D. Other Production E. Production of Halocarbons and SF6 F. Consumption of Halocarbons and SF6 G. Other



5. Land-Use Change and Forestry A. Changes in Forest and Other Woody Biomass Stocks

B. Forest and Grassland Conversion C. Abandonment of Managed Lands D. CO2 Emissions and Removals from Soil

E. Other 6. Waste

A. Solid Waste Disposal on Land B. Waste-water Handling C. Waste Incineration D. Other

7. Other (as specified in Summary 1.A) Memo Items: International Bunkers

Aviation Marine




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TABLE 10 EMISSION TRENDS ( HFCs, PFCs and SF6) Country

(Sheet 4 of 5) Year

Submission

Base year(1)

1990 1991 1992 1993 1994 1995 1996 1997 1998 1999 2000 2001 2002

Change from

1990(1) to latest

reported year

Chemical GWP GREENHOUSE GAS SOURCE AND SINK

CATEGORIES

(Gg)

Emissions of HFCs(5)

(Gg CO2 equivalent)

HFCs

HFC-23 HFC-23 11700

HFC-32 HFC-32 650

HFC-41 HFC-41 150

HFC-43-10mee HFC-43-10mee 1300

HFC-125 HFC-125 2800

HFC-134 HFC-134 1000

HFC-134a HFC-134a 1300

HFC-152a HFC-152a 140

HFC-143 HFC-143 300

HFC-143a HFC-143a 3800

HFC-227ea HFC-227ea 2900

HFC-236fa HFC-236fa 6300

HFC-245ca HFC-245ca 560

Unspecified mix of listed

HFCs (6) - (Gg CO2 equivalent)

PFCs

CF4 6500

Emissions of PFCs(5) - (Gg CO2 equivalent)

C2F6 9200

CF4 C 3F8 7000

C2F6 C4F10 7000

C 3F8 c-C4F8 8700

C4F10 C5F12 7500

c-C4F8 C6F14 7400

C5F12 SF6 23900

C6F14

Unspecified mix of listed PFCs (6) - (Gg CO2 equivalent)

Emissions of SF6(5) -

(Gg CO2 equivalent)

SF6



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TABLE 10 EMISSION TRENDS (SUMMARY) Country

(Sheet 5 of 5) Year

Submission

Base year(1) 1990 1991 1992 1993 1994 1995 1996 1997 1998 1999 2000 2001 2002



GREENHOUSE GAS EMISSIONS

CO2 equivalent (Gg) (%) CO2 emissions including net CO2 from LUCF(4) CO2 emissions excluding net CO2 from LUCF (4) CH4 N2O HFCs PFCs SF6 Total (including net CO2 from LUCF)(4) Total (excluding net CO2 from LUCF)(4), (7)


Base year(1) 1990 1991 1992 1993 1994 1995 1996 1997 1998 1999 2000 2001 2002



CO2 equivalent (Gg) (%) 1. Energy 2. Industrial Processes 3. Solvent and Other Product Use 4. Agriculture 5. Land-Use Change and Forestry (8) 6. Waste 7. Other Total (including LUCF) (8)

(1) The column "Base year" should be filled in only by those Parties with economies in transition that use a base year different from 1990 in accordance with the relevant decisions of the COP. For these Parties, this different base year is used to calculate the percentage change in the final column of this table. (2) According to the IPCC Guidelines (Volume 3. Reference Manual, pp. 4.2, 4.87), CO2 emissions from agricultural soils are to be included under Land-use change and forestry (LUCF). At the same time, the Summary Report 7A (Volume 1. Reporting Instructions, Tables.27) allows for reporting CO2 emissions or removals from agricultural soils either in the Agriculture sector, under 4.D Agricultural soils or in the Land-use change and forestry sector under 5.D Emissions and removals from soil. Parties may choose either way to report emissions or removals from this source in the common reporting format, but the way they have chosen to report should be clearly indicated, by providing a brief explanation in the documentation box to Table 4.D of the agriculture sector. Double-counting of these emissions or removals should be avoided. Parties should include these emissions or removals consistently in Table8(a) (Recalculation - Recalculated data) and Table10 (Emission trends). (3) Fill in net emissions as reported in table Summary 1.A. Please note that for the purposes of reporting, the signs for removals are always (-) and for emissions (+). (4) The information in these rows is requested to facilitate comparison of data, because Parties differ in the way they report CO2 emissions and removals from land-use change and forestry. (5) Enter actual emissions estimates. If only potential emissions estimates are available, these should be reported in this table and an indication for this be provided in the documentation box. Note that only in these rows the emissions are expressed as CO2 equivalent emissions. (6) In accordance with the UNFCCC reporting guidelines, HFC and PFC emissions should be reported for each relevant chemical. However, if it is not possible to report values for each chemical (i.e. mixtures, confidential data, lack of disaggregation), this row could be used for reporting aggregate figures for HFCs and PFCs, respectively. Note that the unit used for this row is Gg of CO2 equivalent and that appropriate notation keys should be entered in the cells for the individual chemicals. (7) These totals will differ from the totals reported in table Summary 2 if Parties report non-CO2 emissions from LUCF. (8) Includes net CO2, CH4 and N2O from LUCF. Documentation box: • Parties should provide detailed explanations on emissions trends in Chapter 2: Trends in greenhouse gas emissions and, as appropriate, in the corresponding Chapters 3 - 9 of the NIR. Use this documentation box to provide references to relevant sections of the NIR if any additional information and further details are needed to understand the content of this table. • Use the documentation box to provide explanations if potential emissions are reported.


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