Airlines could cut emissions sharply by flying more efficiently

Summary:

Global aviation emissions could be reduced dramatically by making better use of efficiency measures that already exist, according to a new international analysis of commercial air travel. The study, published in Communications Earth & Environment, examined 27.5 million flights operated in 2023 across more than 26,000 city pairs, covering nearly 3.5 billion passengers worldwide.

The researchers found striking differences in carbon dioxide efficiency between routes, aircraft models, and regions. Emissions ranged from around 30 grams of CO₂ per kilometre per paying passenger on the most efficient routes to nearly 900 grams on the least efficient. On average, aviation emitted 84.4 grams of CO₂ per kilometre per passenger in 2023, but this figure varied widely depending on aircraft choice, seating configuration, and passenger occupancy.

According to the analysis, airlines could cut emissions by about 11% immediately by deploying their most efficient aircraft on routes they already serve. Larger reductions would be possible by combining three measures: prioritising fuel-efficient aircraft, shifting toward all-economy seating layouts, and increasing average passenger loads to 95%. If applied globally, these changes could reduce aviation emissions by between 50% and 75% without reducing flight numbers or relying on future fuels.

As co-author Dr Milan Klöwer of the University of Oxford said: “Our results clearly show that efficiency-focused policy could swiftly reduce aviation emissions by more than half, without reducing flight numbers or waiting for future fuels. These are tools that we can use right now.”

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— Press Release —

Global aviation emissions could be halved through maximising efficiency gains, new study shows

A new study co-led by the University of Oxford has found that global aviation emissions could be reduced by 50-75% through combining three strategies to boost efficiency: flying only the most fuel-efficient aircraft, switching to all-economy layouts, and increasing passenger loads. Crucially, the study shows that around a 11% reduction in global aviation emissions is achievable immediately, by using the most efficient aircraft that airlines already have more strategically on routes they already fly.

The study, published in Nature Communications Earth & Environment, analysed more than 27 million commercial flights in 2023, covering 26,000 city pairs and nearly 3.5 billion passengers. This revealed enormous variability in emissions efficiency, with some routes producing nearly 900 grams of CO₂ per kilometre for each paying passenger – almost 30 times higher than the most efficient, at around 30 grams of CO₂ per kilometre.

Co-author Dr Milan Klöwer (Department of Physics, University of Oxford) said: “Our results clearly show that efficiency-focused policy could swiftly reduce aviation emissions by more than half, without reducing flight numbers or waiting for future fuels. These are tools that we can use right now.”

Globally, average aviation emissions were 84.4 grams of CO₂ per kilometre for each paying passenger in 2023. But the study identifies three practical levers to reduce this figure: operating only the most fuel-efficient aircraft, removing premium-class seating to carry more passengers, and raising passenger loads to 95%.

Aircraft model alone was found to make a significant difference, with emissions ranging from 60–360 gram CO₂ per kilometre for each passenger. According to the analysis, replacing all aircraft with the most efficient models – the Boeing 787-9 (long-haul) and the Airbus A321neo (short and medium-haul) – would result in fuel savings of 25% to 28%.

Dr Klöwer added: “While economically and practically unfeasible to replace all older aircraft short term, this analysis shows the potential more efficient aircraft have in comparison to other efficiency gains. Realistically, this would be a long-term transition – one that could be promoted by policies that reward efficiency, so that the most efficient aircraft are favoured whenever replacement decisions are made.”

Seating configurations also matter, since business and first-class seats are up to 5 times more CO₂-intense than economy class seats. The researchers found that increasing passenger numbers to the maximum seating configuration for the most efficient aircraft would further reduce emissions by 22% to 57%.

In 2023, aircraft passenger occupancy ranged from 20% to 100%, with an average of 79%. According to the analysis, increasing average occupancy to 95% would further reduce emissions by 16%.

If these three measures were applied globally, the study estimates that emissions could be reduced by between 50% and 75% -though this full reduction would require systemic changes. Nevertheless, the analysis found that airlines could reduce emissions by around 11% right now by flying their most efficient aircraft on routes where they already operate.

Lead author Professor Stefan Gössling (Linnaeus University) said: “Efficiency-based policies have a great potential to curb aviation emissions, and can be in airlines’ own economic interest. But the reality is that many airlines continue to fly with old aircraft, low passenger occupancies, and growing proportions of premium-class seating.”

The researchers suggest that efficiency improvements could be promoted using policy tools and market-based measures, such as emissions ratings for airlines, adjusted landing fees based on aircraft performance, and carbon intensity caps – drawing parallels to standards used in sectors like household appliances and vehicles.

The study was based on data from Airline Data, the International Civil Aviation Organization, and the International Air Transport Association. This showed that the regions with the most inefficient flights were Africa, Oceania, the Middle East, Central Asia, and North America. The regions with the most efficient flights were Brazil, India, and Southeast Asia.

The study also involved researchers from atmosfair providing data and the Munich University of Applied Sciences.

Journal Reference:
Gössling, S., Klöwer, M., Leitão, J.C. et al., ‘Large carbon dioxide emissions avoidance potential in improved commercial air transport efficiency’, Communications Earth & Environment 7, 13 (2026). DOI: 10.1038/s43247-025-03069-4

Article Source:
Press Release/Material by University of Oxford
Featured image credit: Spencer Imbrock | Unsplash