GHG Protocol · ESRS E1 · Agriculture

Scope 3 Emissions Estimator
for Agriculture

Estimate Scope 3 emissions for agricultural entities. Purchased fertilisers and animal feed (Category 1), upstream and downstream transport, and the processing of sold agricultural products carry the heaviest Scope 3 weight in this sector.

GHG PROTOCOL · LIVEv2026.04ESRS E1 · IFRS S2

Scope 3 emissions, documented.
Not just estimated.

Session
0x461C
Sector
All
Categories
0 / 15
scope3.conf
categories.csv
README.md
01// engagement— GHG Protocol Ch. 3
02entity_name=
03reporting_period=
04currency=
05sector=
08// scope_3_categories— GHG Protocol Table 5.1
09selected=none
★ = typically material for All sectors (median). Missed: cat. 1, 2, 4, 6, 7.
27// materiality_and_exclusions— GHG Ch.6 · ESRS 1.133
Relevance tests performed for each Scope 3 category (GHG Ch.6):
28
29
30
31
32
33
35exclusion.rationale=
Materiality + exclusions (GHG Ch.6 + ESRS 1.133)
38// data_quality_and_sources— GHG Ch.7 · data hierarchy
Data-quality hierarchy applied:
39
40
41
42
43
44
45data_sources.narrative=
Data quality + sources (GHG Ch.7)
48// intensity_metrics— GHG Ch.9 · ESRS E1-5
49revenue_millions_eur=MEUR
50num_employees=FTE
51prior_year_scope3=tCO2e
52scope1_total=tCO2e
53scope2_total=tCO2e
Intensity metrics (GHG Ch.9 / ESRS E1-5)
56// sector_benchmark— CDP 2023 median · tCO2e/M€
Enter revenue (above) to compare against the All sectors (median) sector median (120 tCO2e/M€).
Sector benchmark · CDP 2023 median
60// sensitivity— ±25% total emissions
Enter activity data to see sensitivity analysis.
Sensitivity · ±25% scenarios
65// risk_warnings— ISSA 5000 / ISAE 3410 · rule engine
Enter activity data to run risk analysis.
Risk warnings · rule engine (ISSA 5000)
70// disclosure_and_conclusion— IFRS S2.29 · ESRS E1-6
Tick disclosure items addressed in FS / sustainability report:
71IFRS S2.29(a)(iii) · ESRS E1-6
72ESRS E1-6(58)
73IFRS S2.29(a)(iv) · ESRS E1-6(62)
74ESRS E1-6(63)
75GHG Protocol Ch.6 · ESRS E1-6(57)
76ESRS E1.45
77ESRS E1-6(54)
78ESRS 1.89
79ESRS E1-4
80ESRS E1-1
81ESRS 1.81
82ESRS 1.133
84prepared_by=
85reviewed_by=
99conclusion.narrative=
Disclosure + conclusion · IFRS S2.29 + ESRS E1-6
awaiting input·0 categories · 2 fieldsEUR·ESRS E1 · IFRS S2
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Scope 3 emissions estimation for Agriculture

Agriculture presents a Scope 3 profile shaped by biological processes and land-use dynamics that do not fit neatly into the GHG Protocol's category structure. For arable farming operations, Category 1 (purchased goods and services) is dominated by synthetic fertilisers. The production of ammonium nitrate fertiliser generates approximately 6.7 kg CO2e per kg of nitrogen content through the Haber-Bosch process, making fertiliser procurement one of the most carbon-intensive purchased inputs in any sector. For livestock operations, purchased animal feed (also Category 1) carries embodied emissions from feed crop cultivation, including land-use change emissions where soy or palm-derived feed ingredients are sourced from recently deforested land. The EU Deforestation Regulation (EUDR), which applies from December 2025, adds a traceability requirement that intersects directly with Scope 3 data collection for feed supply chains.

The technical challenge for agriculture is the interaction between Scope 1 biogenic emissions and Scope 3 upstream emissions. A dairy farm's Scope 1 includes enteric methane from cattle and nitrous oxide from manure management and soil application. Its Scope 3 Category 1 includes the embodied carbon in purchased feed, fertiliser, veterinary products, and fuel. Category 3 (fuel and energy related activities) covers upstream emissions from diesel and electricity used in farm operations. Category 4 (upstream transport) captures the delivery of inputs to the farm gate. Category 9 (downstream transport) and Category 10 (processing of sold products) cover the journey from farm gate to processor (abattoir, dairy, grain mill). For vertically integrated agribusinesses that own processing facilities, some of these downstream emissions shift to Scope 1 and Scope 2. Category 11 (use of sold products) is unusual for agriculture: for food products, use-phase emissions are typically the energy used by consumers to cook or refrigerate the product. For biofuel crops, Category 11 captures the combustion emissions when the biofuel is burned by the end user.

Assurance findings in agricultural Scope 3 reporting cluster around fertiliser and feed calculations. Entities that report fertiliser spend without converting to physical quantities (tonnes of nitrogen, phosphorus, potassium) cannot apply the correct emission factors, because a tonne of urea has a different emission factor per kg N than a tonne of ammonium nitrate. Feed-related emissions require knowing the feed composition (percentage soy, maize, wheat, by-products) and the origin of each ingredient, which many farms do not track at this level of detail. Land-use change emissions associated with imported soy are particularly contentious: the emission factor for Brazilian soy from recently converted cerrado land is approximately 8 kg CO2e per kg, compared to approximately 0.4 kg CO2e per kg for European-grown soy with no land-use change. Using a generic "soy" emission factor without specifying origin introduces material error.

For agricultural entities using this estimator, start with your input purchase records. Convert fertiliser purchases from spend to physical quantities (kg of N, P, K applied) and apply production emission factors from sources such as Fertilizers Europe's carbon footprint data or DEFRA. For animal feed, obtain the feed formulation from your feed supplier (or formulate it yourself if you mix on-farm) and apply emission factors per ingredient, using the GFLI (Global Feed LCA Institute) database for feed ingredient lifecycle data. For downstream emissions, estimate distances from farm to first point of sale or processing and apply DEFRA or GLEC transport emission factors by mode. For Category 10 (processing), use published energy intensity data for the relevant processing type (dairy processing at approximately 0.3 to 0.5 kWh per litre of milk processed, grain milling at approximately 50 to 80 kWh per tonne).

Frequently asked questions: Agriculture

How should a livestock farmer estimate Scope 3 emissions from purchased feed?
Obtain the feed formulation showing the percentage composition by ingredient (soy meal, maize, wheat, barley, by-products, minerals). Apply lifecycle emission factors per ingredient from the GFLI database or DEFRA. Pay particular attention to soy-based ingredients: specify the country of origin and whether the soy is certified deforestation-free, as land-use change emissions can increase the soy emission factor by a factor of 20. Multiply the emission factor per kg of each ingredient by the annual quantity consumed, then sum across all ingredients.
Are land-use change emissions included in Scope 3?
Under the GHG Protocol, land-use change emissions associated with purchased agricultural commodities (soy, palm oil, beef, timber) are included in Category 1 when the commodity was produced on land that was recently converted from forest or other natural ecosystem. The GHG Protocol's Land Sector and Removals Guidance (published 2022) provides methodology for accounting for these emissions. However, attribution of land-use change to specific commodity purchases is technically difficult and data-intensive. Use certified supply chain data (RTRS for soy, RSPO for palm) where available, or apply statistical land-use change emission factors by commodity and country of origin.
What emission factors should be used for synthetic fertiliser production?
Fertilizers Europe publishes product-specific carbon footprints for European-manufactured fertilisers. For ammonium nitrate, the production emission factor is approximately 6.7 kg CO2e per kg N. For urea, the production emission factor is approximately 3.5 kg CO2e per kg N, but urea releases an additional 0.73 kg CO2 per kg product when applied to soil through hydrolysis (this is a Scope 1 emission for the farmer). DEFRA publishes UK-specific fertiliser emission factors. For imported fertilisers, the emission factor depends on the manufacturing country's energy mix, particularly for ammonia production.
How does the EU Deforestation Regulation interact with Scope 3 reporting?
The EUDR requires operators placing soy, palm oil, beef, cocoa, coffee, rubber, and wood products on the EU market to demonstrate that those products are deforestation-free and legally produced, with geolocation data for the production plot. The traceability data collected for EUDR compliance (country of origin, geolocation, production date) directly supports more accurate Scope 3 Category 1 emission calculations. Entities that can demonstrate deforestation-free sourcing apply lower emission factors than those using generic country-average factors that include a land-use change component.

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