How the polar vortex and warm ocean are intensifying a major US winter storm

A severe winter storm is threatening states from Texas to New England with freezing rain, sleet, and snow, causing hazardous travel conditions, dangerous wind chills, and power outages.
The storm’s ferocity may be partly due to a warm ocean, which can contribute to the development of intense storms by increasing evaporation and moisture availability.
A strong Arctic air mass from the north and warmer air from the south created favorable conditions for precipitation, with the jet stream playing a key role in steering the storm system.
The polar vortex, a belt of fast-moving air circulating around the North Pole, can stretch southward over the United States, creating ideal conditions for severe winter weather by reflecting upward waves back down and affecting the jet stream.
Even as Earth warms overall, intense winter storms may become more frequent or severe due to disruptions in the polar vortex and other factors, highlighting the need for continued research and improvement in storm prediction and response capabilities.

Boston and much of the U.S. faced a cold winter blast in January 2026. Craig F. Walker/The Boston Globe via Getty Images

A severe winter storm sweeping across the central and eastern U.S. in late January 2026 is threatening states from Texas to New England with crippling freezing rain, sleet and snow. Several governors issued states of emergency as forecasters warned of hazardous travel conditions, dangerous wind chills and power outages amid bitter cold expected to linger for days.

The sudden blast may come as a shock to many Americans after a mostly mild start to winter, but that warmth may be partly contributing to the ferocity of this storm.

As atmospheric and climate scientists, we conduct research that aims to improve understanding of extreme weather, including what makes it more or less likely to occur and how climate change might or might not play a role.

To understand what Americans are experiencing with this winter blast, we need to look more than 20 miles above the surface of Earth, to the stratospheric polar vortex.

A forecast for Jan. 26, 2026, shows the freezing line in white reaching far into Texas. The light band with arrows indicates the jet stream, and the dark band indicates the stratospheric polar vortex. The jet stream is shown at about 3.5 miles above the surface, a typical height for tracking storm systems. The polar vortex is approximately 20 miles above the surface.
Mathew Barlow, CC BY

What creates a severe winter storm like this?

Multiple weather factors have to come together to produce such a large and severe storm.

Winter storms typically develop where there are sharp temperature contrasts near the surface and a southward dip in the jet stream, the narrow band of fast-moving air that steers weather systems. If there is a substantial source of moisture, the storms can produce heavy rain or snow.

In late January, a strong Arctic air mass from the north was creating the temperature contrast with warmer air from the south. Multiple disturbances within the jet stream were acting together to create favorable conditions for precipitation, and the storm system was able to pull moisture from the very warm Gulf of Mexico.

A map of storm warnings on Jan. 24, 2026. — The National Weather Service issued severe storm warnings (pink) on Jan. 24, 2026, for a large swath of the U.S. that could see sleet and heavy snow over the following days, along with ice storm warnings (dark purple) in several states and extreme cold warnings (dark blue).
National Weather Service

Where does the polar vortex come in?

The fastest winds of the jet stream occur just below the top of the troposphere, which is the lowest level of the atmosphere and ends about seven miles above Earth’s surface. Weather systems are capped at the top of the troposphere, because the atmosphere above it becomes very stable.

The stratosphere is the next layer up, from about seven miles to about 30 miles. While the stratosphere extends high above weather systems, it can still interact with them through atmospheric waves that move up and down in the atmosphere. These waves are similar to the waves in the jet stream that cause it to dip southward, but they move vertically instead of horizontally.

A chart shows how temperatures in the lower layers of the atmosphere change between the troposphere and stratosphere. Miles are on the right, kilometers on the left.
NOAA

You’ve probably heard the term “polar vortex” used when an area of cold Arctic air moves far enough southward to influence the United States. That term describes air circulating around the pole, but it can refer to two different circulations, one in the troposphere and one in the stratosphere.

The Northern Hemisphere stratospheric polar vortex is a belt of fast-moving air circulating around the North Pole. It is like a second jet stream, high above the one you may be familiar with from weather graphics, and usually less wavy and closer to the pole.

Sometimes the stratospheric polar vortex can stretch southward over the United States. When that happens, it creates ideal conditions for the up-and-down movement of waves that connect the stratosphere with severe winter weather at the surface.

A stretched stratospheric polar vortex reflects upward waves back down, left, which affects the jet stream and surface weather, right.
Mathew Barlow and Judah Cohen, CC BY

The forecast for the January storm showed a close overlap between the southward stretch of the stratospheric polar vortex and the jet stream over the U.S., indicating perfect conditions for cold and snow.

The biggest swings in the jet stream are associated with the most energy. Under the right conditions, that energy can bounce off the polar vortex back down into the troposphere, exaggerating the north-south swings of the jet stream across North America and making severe winter weather more likely.

This is what was happening in late January 2026 in the central and eastern U.S.

If the climate is warming, why are we still getting severe winter storms?

Earth is unequivocally warming as human activities release greenhouse gas emissions that trap heat in the atmosphere, and snow amounts are decreasing overall. But that does not mean severe winter weather will never happen again.

Some research suggests that even in a warming environment, cold events, while occurring less frequently, may still remain relatively severe in some locations.

One factor may be increasing disruptions to the stratospheric polar vortex, which appear to be linked to the rapid warming of the Arctic with climate change.

Two globes, one showing a stable polar vortex and the other a disrupted version that brings brutal cold to the South. — The polar vortex is a strong band of winds in the stratosphere, normally ringing the North Pole. When it weakens, it can split. The polar jet stream can mirror this upheaval, becoming weaker or wavy. At the surface, cold air is pushed southward in some locations.
NOAA

Additionally, a warmer ocean leads to more evaporation, and because a warmer atmosphere can hold more moisture, that means more moisture is available for storms. The process of moisture condensing into rain or snow produces energy for storms as well. However, warming can also reduce the strength of storms by reducing temperature contrasts.

The opposing effects make it complicated to assess the potential change to average storm strength. However, intense events do not necessarily change in the same way as average events. On balance, it appears that the most intense winter storms may be becoming more intense.

A warmer environment also increases the likelihood that precipitation that would have fallen as snow in previous winters may now be more likely to fall as sleet and freezing rain.

There are still many questions

Scientists are constantly improving the ability to predict and respond to these severe weather events, but there are many questions still to answer.

Much of the data and research in the field relies on a foundation of work by federal employees, including government labs like the National Center for Atmospheric Research, known as NCAR, which has been targeted by the Trump administration for funding cuts. These scientists help develop the crucial models, measuring instruments and data that scientists and forecasters everywhere depend on.

Mathew Barlow has received federal funding for research on extreme events and also conducts legal consulting related to climate change..

Judah Cohen does not work for, consult, own shares in or receive funding from any company or organization that would benefit from this article, and has disclosed no relevant affiliations beyond their academic appointment.

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Q. What is causing the severe winter storm sweeping across the central and eastern US?

A. The storm is caused by multiple weather factors coming together, including a strong Arctic air mass from the north, warmer air from the south, and favorable conditions for precipitation.

Q. What is the polar vortex, and how does it relate to severe winter storms?

A. The polar vortex is a belt of fast-moving air circulating around the North Pole in the stratosphere. When it stretches southward over the US, it creates ideal conditions for severe winter weather at the surface.

Q. How does climate change affect the polar vortex and severe winter storms?

A. Climate change may be weakening the polar vortex, leading to more frequent and intense cold events. However, the relationship between climate change and severe winter storms is complex, and more research is needed to fully understand its impact.

Q. Why are we still getting severe winter storms even if the climate is warming?

A. While snow amounts are decreasing overall due to climate change, some research suggests that even in a warming environment, cold events may still remain relatively severe in some locations.

Q. What role does the jet stream play in severe winter storms?

A. The jet stream plays a crucial role in steering weather systems and creating favorable conditions for precipitation. When the polar vortex stretches southward over the US, it can interact with the jet stream, leading to more intense winter weather.

Q. How do warmer oceans contribute to severe winter storms?

A. Warmer oceans lead to more evaporation, which means more moisture is available for storms. This can produce energy for storms and increase their intensity.

Q. Can warming reduce the strength of storms by reducing temperature contrasts?

A. Yes, warming can reduce the strength of storms by reducing temperature contrasts. However, this effect may be outweighed by the increased moisture availability from warmer oceans.

Q. Are intense winter storms becoming more intense due to climate change?

A. On balance, it appears that the most intense winter storms may be becoming more intense due to climate change.

Q. What are some of the challenges in predicting and responding to severe weather events?

A. Scientists face several challenges in predicting and responding to severe weather events, including limited funding for research and data collection, as well as the complexity of the relationships between atmospheric waves and extreme weather events.