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🇹🇭 Thailand's Sources of N₂O Emissions

Thailand's Sources of N2O Emissions

Key Insights

Agricultural Emissions Dominate

Thailand's N₂O emissions have been predominantly driven by agriculture, particularly since the adoption of Green Revolution technologies in the 1960s. The increased use of nitrogen-based fertilizers significantly boosted emissions, with agriculture consistently contributing the largest share of N₂O emissions. Despite fluctuations, the sector's emissions have shown a general upward trend, peaking in the 2010s before a slight decline in the 2020s.

Energy Sector's Rising Influence

The energy sector has seen a notable rise in N₂O emissions, especially from the late 20th century onwards. This increase aligns with Thailand's industrialization and energy consumption growth, particularly after the discovery of natural gas in 1978. The sector's contribution to total N₂O emissions has grown, reflecting the country's expanding energy needs and industrial activities.

Impact of Policy and Economic Events

Economic and policy events have also influenced Thailand's emissions trajectory. The Asian Financial Crisis in 1997 temporarily reduced industrial output and energy consumption, leading to a dip in emissions. Conversely, the introduction of biofuels in 2003 and the commitment to the Paris Agreement in 2015 have contributed to efforts in reducing emissions, although the impact on N₂O specifically is less pronounced compared to CO₂.

Background

The chart shows a national breakdown by source of the yearly nitrous oxide (N2O) emissions from human activities and processes, expressed as weight in megatonnes (Mt). Human-induced emissions are the main driver of the increasing atmospheric nitrous oxide that is warming our planet. The sources of human nitrous oxide emissions are

  • Agriculture
  • Energy
  • Industry
  • Waste
  • Other

Agriculture

Emissions related to agriculture are mainly from the use of synthetic fertilizers and manure management.


Synthetic fertilizer, used for agricultural processes, contains a lot of nitrogen. That nitrogen in the soil reacts and causes considerable N2O emissions. The use of excess fertilizer, meaning more fertilizer than the plants can use to grow, causes even higher relative emissions. Applying the right amount of fertilizer at the right time can reduce N2O emissions. There are many technical solutions to reduce emissions while keeping, or even increasing, agricultural yields.


When manure is left on the field or otherwise managed in dry processes, it emits considerable amounts of nitrous oxide. Manure can be managed by wet processes, which reduces nitrous oxide emissions but increases methane emissions. Some technical solutions focus on modifying the animal feed to reduce the nitrogen in the manure, thereby reducing nitrous oxide emissions.

Energy, Industry, Waste, and Other

All non-agricultural categories together have much lower emissions than agricultural emissions alone.


N2O emissions related to energy are almost all from the combustion of fossil fuels. For example, the combustion of fossil fuels in power plants, cars, and airplanes not only causes CO2 emissions but also emits nitrous oxide (N2O). Any advances to reducing fossil fuel dependency will thus also reduce nitrous oxide emissions.


Most industry-related emissions are from the chemical industry for producing fertilizer, nylon, and similar products. Technologies are available to reduce emissions in these processes.

Nitrous oxide emissions from waste come from, for example, wastewater treatment and landfills.

Wikipedia: Nitrous oxide
 IPCC: AR6, 5.16 Anthropogenic nitrous oxide (N2O) emissions

Units and Measures

N2O emissions are expressed in the total weight in megatonnes per year. 1 Megatonne is equal to 1 million tonnes.

Wikipedia: Megatonne
 Wikipedia: Global warming potential

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About the Data

The last available year in all the emission datasets is 2023. N2O emissions come from the PRIMAP-Hist dataset. It is a rich dataset that combines several published sources to create a historical emissions time series for various greenhouse gases.

The Key Insights paragraph was generated using a large language model (LLM) using a structured approach to improve the accuracy. This included separating the context generation from the interpretation and narrative.

Data Sources

PRIMAP-hist The PRIMAP-hist national historical emissions time series (1750-2023)
Update cycle: Every few monthsDelay: Less than 1 yearCredits: Gütschow, Johannes; Busch, Daniel; Pflüger, Mika (2024): The PRIMAP-hist national historical emissions time series (1750-2023) v2.6. Zenodo.