Flying has become more energy efficient than driving


Flying has become less energy intensive than driving, at least in the United States, according to the surprising findings of an analysis of energy consumption by the University of Michigan's Transportation Research Institute.

Transporting one person a distance of one mile by aircraft consumed on average the energy equivalent to 2,465 British thermal units (BTUs), compared with 4,211 BTUs for moving one person one mile by car, in 2012.

If fuel use is adjusted to account for commercial freight and mail carried on passenger aircraft, flying consumed just 2,033 BTUs per person mile, according to researcher Michael Sivak.

One BTU is formally defined as the amount of energy needed to raise the temperature of one pound of water by one degree Fahrenheit. Informally, it is roughly the energy released by burning a kitchen match.

A gallon of gasoline contains roughly 124,000 BTUs, a gallon of jet fuel about 135,000 BTUs and diesel almost 139,000 BTUs.

Sivak's research shows driving consumed 71 percent more energy per person-mile than flying in 2012, or more than double if flying data are corrected for cargo ("Energy intensities of flying and driving" April 2015).

Aviation still has a reputation for being a particularly energy-intensive mode of transportation for moving people but Sivak's findings suggest that reputation may no longer be deserved.

At the start of the 1970s, aircraft were particularly inefficient and consumed twice as much fuel per person-mile than passenger cars.

Since then, however, the amount of energy consumed per passenger-mile by aircraft has fallen by almost 80% while the efficiency of driving has improved by less than 17%.

The crossover point, when aircraft became less energy-intensive than cars, occurred around the turn of the millennium.

The switchover in energy intensity is the result of several trends which have tended to make flying more efficient but have had a much more ambiguous effect on driving.

New aircraft are much more fuel efficient than the ones they replaced. Airlines have learned to operate them using less fuel by cutting the amount of unnecessary weight carried on board. And seat occupancy is much higher than it was in previous decades.

In contrast, cars have become heavier and more powerful and they are much more likely to be occupied by just the driver rather than passengers. Carpooling on the way to work, for example, has become much less common than it was in the 1970s and 1980s.

There are several important qualifications to this analysis. The data is based on the United States, famous for its larger and more powerful passenger vehicles. Cars in the European Union and Japan, where vehicles tend to be smaller and lighter, consume far less energy per passenger mile.

Sivak's research is an important reminder about the effect that choices about energy efficiency, vehicle size and engine power have on fuel consumption.

The analysis is also sensitive to trip length. The average length of a driving trip is just 9 miles while an average flight is 914 miles -- 100 times longer.

Short car journeys tend to be much more energy-intensive than longer ones because they are more likely to occur on urban roads (with lots of starts and stops) and have a single occupant.

Longer car journeys ones on the freeways and interstate network are more fuel efficient and more likely to involve multiple occupants, which cuts energy consumption per person-mile dramatically.

But aircraft are also more fuel efficient over longer journeys than shorter ones because so much fuel is consumed during the takeoff phase. By some estimates, takeoff can account for as much as a quarter of the fuel consumed on a short flight.

Sivak's analysis reveals some important truths about energy consumption and transportation. First, energy consumption is directly related to the demand for mobility, a point which is often underplayed in discussions about energy and climate change.

Aviation tends to account for a very high share of per capita fuel consumption and per capita greenhouse emissions not because aircraft are inefficient but because of the long distances involved in air travel compared with other modes of transport such as cars.

Rising fuel consumption and greenhouse emissions stem from an increase in demand for very long distance travel - especially intercontinental flights and among middle and lower income groups -- which are a central part of a modern, interconnected world.

Second, modes of transport are not inherently efficient or inefficient. Better design can result in substantial efficiency improvements. The way in which modes of transport are operated is at least as important as their physical construction. And regulations and fuel prices have an important role to play driving energy efficiency.

At a global level, demand for mobility is set to increase significantly in the decades ahead. As a higher share of the world's population moves out of extreme poverty into middle income status, they too will want to travel long distances for work, leisure and to visit friends and family, and to consume products made far away, which implies an enormous increase in transport demand.

One option is to restrain the demand for mobility through regulations and actions designed to make transport much more expensive (such as increasing the cost of fuel through taxes or emissions charges).

Another is to shift people and products from transport modes with high energy intensity (such as aircraft) to ones which consume less fuel per passenger-mile (such as rail), though Sivak's analysis raises questions about some of the assumptions commonly made about the energy intensity of different modes of transport.

The third option, and in many ways the most promising, is to improve fuel efficiency within existing modes of transport. Sivak shows this course holds enormous promise through improvements in design and choices about how transport modes are operated.

Airlines have become more fuel efficient, in part, because they have cut excess weight and raised seat occupancy to record levels. Cars on the other hand, at least in the United States, have become heavier and drive around with most of the seats empty.

Improvements in transport design and operation offer the best hope of meeting the world's growing demand for mobility while curbing greenhouse emissions.

Efficiency improvements are, in turn, linked to the price of fuel and government regulations. The three approaches to curbing emissions (fuel pricing, mode shifting and enhanced efficiency) are complements rather than substitutes.

Nonetheless, the biggest reductions in greenhouse emissions are likely to come from using existing transport systems more efficiently, rather than trying to force people to stay at home by making travel dramatically more expensive.

© (c) Copyright Thomson Reuters 2015.

©2023 GPlusMedia Inc.

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What really happened was that smaller single-aisle jets--which were flying the 1960's and 1970's with thirsty low-bypass ratio turbofans (or in some cases turbojets!), were all replaced starting in the early 1980's first by the Boeing 737-300/400/500 models powered by the far more fuel-efficient CFM56 turbofan, then from the late 1980's on with the Airbus A320 Family of single-aisle airliners arrived, also with fuel-efficient high-bypass ratio turbofans.

Today, thanks to even better engines, the fuel efficiency of jet airliners is just amazing. The upcoming Airbus A320neo Family of airliners powered by the Pratt & Whitney PW1100G engine promises really impressive fuel burn efficiency, to say the least.

4 ( +4 / -0 )

This analysis, while interesting, misses one important point. It doesn't take into account how necessary each journey is. It is no good doing a simple per mile comparison, while ignoring the fact that most airline journeys are for leisure purposes and so are arguably not needed.

2 ( +3 / -1 )

I bet that travelling in giant airships will be the way of the future. It will be 100x more energy efficient and comfortable. The only downside is the substantially longer time it will take, but with advances in technology I think people will simply be able to work as they travel over the course of a week to London or New York.

1 ( +1 / -0 )

Except for the time spent running the TSA obstacle source.

1 ( +1 / -0 )

My bicycle is way more efficient than both of those!

1 ( +1 / -0 )

Interesting speculation and it is only speculation. There is No science here, just very good statistical math.

there would need to be a real experiment to find out.

1 ( +1 / -0 )

A door to door analysis would have to include driving to and from the airport. Also, almost all flights in the U.S. include a hub transfer, so hundreds of unnecessary miles are travelled by air.

The FAAs "NextGen" upgrade to the airspace will eliminate the need for hubs - allowing all flights to be direct rather than having to follow point-to-point routes. Under the new system, flights will be controlled by satellite rather than ground stations and pilots will have more information in the cockpit about who's flying nearby.

Doors to door, driving is the most efficient and quickest, at least for distances under 1000 miles.


A car traveling 70 mph will take just under 14 1/2 hours to go 1000 miles. This is assuming the car immediately starts driving at 70 mph, maintains 70 mph for the entire trip right up until the destination is reached, and never stops for potty breaks or fuel (for the car OR the passengers). Coincidentally, 14 1/2 hours is how long my flight from ATL to NRT took (gate to gate) - a distance of 6,850 miles.

The plane was averaging 472 mph - taxiing, takeoff, and landings included, and so could complete a 1,000 mile journey in about 2 hours and 6 minutes. Are you REALLY going to claim that the driving to and from the airport is going to take longer than 12 hours and 24 minutes?

0 ( +0 / -0 )

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