Planes, Shipping Lanes, and Automobiles: Surprising Ways Climate Change Can Affect Transportation

By Alan Buis,
NASA’s Jet Propulsion Laboratory

The effects of global climate change are broad and impact everyone, as well as Earth’s natural systems.

Much has been written about the major impacts of climate change. Effects such as rising global surface temperatures, higher sea levels, longer and more intense heat waves, melting glaciers and ice sheets, polar sea ice loss, extreme weather and climate events, and impacts on animal habitats are well-documented and in the news regularly.

In this new NASA Climate feature series, we’re examining some of the lesser-known, and often surprising, ways Earth’s changing climate is affecting our world.

Before the Industrial Revolution, human travels had little impact on Earth’s climate. That changed once we began burning fossil fuels to power trains, boats, cars, trucks, and planes. Today, transportation generates about a fourth of global carbon dioxide emissions, second only to the electric power sector.

Climate change is affecting transportation in major ways, such as the ongoing shift to zero-emissions automobiles. But some of the impacts of climate on transportation are less obvious. Here are a few.

Bumpier Skies

Our changing atmosphere may make future airline flights bumpier by strengthening vertical wind shear in jet streams. Jet streams are fast-moving belts of wind that travel around the planet in wavy, meandering paths in the upper parts of the atmosphere. Aviators often use or avoid them to increase the efficiency of their flights.

Aircraft turbulence intensities range from light to extreme. Credit: National Oceanic and Atmospheric Administration/National Weather Service

Vertical wind shear creates irregular air motions called turbulence, which is a significant and costly issue for airlines, resulting in injuries, damaged aircraft, delayed flights, and inspections and investigations.

Sometimes bumpy flights happen without significant cloudiness or thunderstorms. This phenomenon is known as “clear-air turbulence.” British atmospheric scientist Paul Williams of the University of Reading studies clear-air turbulence. Among his findings:

  • By 2050, the frequency of reported clear-air turbulence is expected to double, and the average strength of turbulence is expected to increase by 10 to 40 percent.
  • Severe turbulence at typical airplane cruising altitudes could become two to three times more common. This will impact airspace over large regions of the Northern Hemisphere.


Researchers at NASA’s Langley Research Center designed a special infrasound microphone that could pick up the ultralow frequencies generated by turbulence in the skies. This technology is being tested on the Stratodynamics HiDRON glider for both turbulence detection and aeronautical research. Credit: NASA

NASA develops technologies to improve aviation efficiency and maintain safety. Researchers at NASA’s Langley Research Center recently designed a special infrasound microphone that can “hear” ultralow frequencies generated by turbulence. This technology was tested on an uncrewed stratospheric glider called HiDRON.

Climate change can also make it harder for aircraft to take off. As temperatures rise, air becomes less dense, so planes have a harder time generating the lift they need to become airborne. Because of this, some aircraft runways may not be long enough for certain planes to take off. It also might force aircraft operators to reduce the takeoff weight of planes and helicopters.


Map showing the extent of Arctic sea ice on March 6, 2023, the day of its annual maximum. This year’s end-of-winter extent was the fifth lowest in the satellite record maintained by the National Snow and Ice Data Center. Arctic sea ice extent peaked at 14.62 million square kilometers (5.64 million square miles), a total area that is roughly 1.03 million square kilometers (398,000 square miles) below the 1981–2010 average maximum.

Compared to the average maximum, the Arctic Ocean in winter 2023 was missing an area of ice equivalent to the states of Texas and Arizona combined. The yellow outline shows the median sea ice extent for February from 1981–2010. A median is the middle value; that is, half of the extents were larger than the yellow line and half were smaller. Credit: NASA Earth Observatory, using data from the National Snow and Ice Data Center

Arctic Travel Gets Both Safer and More Dangerous


This map shows unique ship visits to Arctic waters between September 1, 2009, and December 31, 2016. Dots and lines represent the locations of ships as transmitted by shipboard beacons to satellite receivers. The denser and brighter the coloring of the dots, the greater the number of distinct ship transits reported in that region, with bright yellow and green representing areas with the highest traffic. Over the seven-year span, the mean center of shipping activity moved 300 kilometers north and east—closer to the North Pole. Credit: Greg Fiske, Woods Hole Research Center

One of its most significant changes to the planet is the continuing decline of Arctic sea ice. Over the past 40 years, the amount of ice cover at both the annual maximum and minimum has shrunk, and the percentage of thick ice that survives from year to year has also dropped. As reported in 2018, this has opened the Arctic to new commerce opportunities, but also to serious environmental concerns. At the center of both lies the shipping industry.


Inuit and other indigenous peoples of the Arctic travel the sea ice by snow machine and by dog team. Credit: Shari Fox, National Snow and Ice Data Center

On the positive side, reduced sea ice cover is increasingly allowing ships to sail across the Arctic Ocean without support from icebreaker ships. This can significantly shorten travel times between Asia, Europe, and North America. As a result, many nations are preparing for more Arctic shipping.

There are also negatives. Scientists and environmentalists worry more shipping activity will increase pollution and oil spills and disturb marine life. And ships are still encountering plenty of ice as they sail closer to the North Pole and in waters that are not well charted. Increased exploration and tourism also mean search-and-rescue operations become more challenging for the U.S. and Canadian coast guards. Finally, some traditional travel routes over the sea ice (used by snowmobiles, trucks, and other vehicles) could become unsafe as the ice thins.

(Not) Rollin’ on the River


Landsat 7 captured this image of the Mississippi River just south of Memphis, Tennessee, on August 8, 2012. In August 2012, water was several feet below the historic normal stage for Memphis, and many sandbars were newly exposed or greatly expanded. As of August 17, 2012, river gauges in the Memphis region recorded levels at -2.4 to -8.3 feet (below historic normal stage). Credit: NASA Earth Observatory, using Landsat data provided by the United States Geological Survey.

Climate change is expected to increase the frequency and/or intensity of droughts and floods, so the impacts on water levels in rivers and reservoirs may become more severe and erratic.

The impacts on shipping cargo by boat could be significant. Water levels can drop such that rivers can become too shallow to navigate, and some ships may have to carry less cargo to safely navigate a river. In the United States, cargo transport along the Mississippi River has been impacted in recent years. For example, low water in 2012 closed an 11-mile stretch of the Mississippi River near Memphis. Such closures have a big economic impact along the river.