The air is starting to feel crisp, the leaves are changing, and the aroma of pumpkin spice lattes are filling your favorite coffee shops. This can only mean one thing – it’s time for my annual post on NOAA’s expectations for the upcoming winter! And once again, one of the key players is found in the tropical Pacific. In contrast with the last two years, when we were looking at potential La Niña development, this year we’re waiting to see if El Niño will arrive in time to impact winter. Without further ado, let’s take a look at NOAA’s 2018-19 Winter Temperature and Precipitation Outlook and see how ENSO has affected this forecast.
As usual: Outlooks are probabilistic, so no guarantees
Wait, just one more thing before jumping to the outlooks. I again remind readers (if this seems repetitive, well, it is) that these forecasts are provided in terms of probabilities (% chance) for below, near, or above average outcomes with the maps showing only the most likely outcome (1). Because the probabilities on these and all CPC outlook maps are less than 100%, there is no guarantee you will see temperature or precipitation departures from normal that match the color on the map. As we’ve explained in earlier blog posts, even when one outcome is more likely than another, there is still always a chance that a less favored outcome will occur. And in fact, for the forecasts to be reliable (a critical part of a probabilistic forecast), less likely outcomes MUST happen from time to time.
Outlook for 2018/19 winter
Finally, the outlooks! Both the temperature and precipitation outlooks depend to a certain extent on typical El Niño impacts, but forecasters think a weak El Niño event is most likely. This means that despite the potential for El Niño, confidence in this outlook is less than we had than during recent strong events like in the winter of 2015/16 (more on confidence below).
This lower confidence is reflected in fairly modest probabilities for the temperature outlook, with the largest probabilities only between 50-60% for above normal temperatures in Hawaii, Alaska, and parts of the Pacific Northwest and northern Rockies. The other shaded regions on the map indicate probabilities between 33-50%, meaning that the forecast only tilts modestly towards above normal temperatures. And while no areas of the country are favored to have below normal temperatures, it certainly wouldn’t be surprising for some areas to experience below normal temperatures this winter. This would be most likely in the white areas labeled EC (more on that later).
Similarly, the precipitation outlook is also much less confident (lower probabilities) than the forecast for the last El Niño winter. The pattern does resemble the typical precipitation pattern seen in an average El Niño, with above-average precipitation favored over much of the southern tier and southern Alaska, and with below-average precipitation most likely in the northern Rockies, around the Great Lakes and in Hawaii. However, the probabilities are much lower than typical for an El Niño winter, reflecting greater uncertainty over what may happen. A 50% chance is exceeded only in northern Florida and southern Georgia, and in Hawaii.
Both maps include blank regions where neither above-, nor near-, nor below-normal is favored. These areas (shown in white and labeled EC for “equal chances”), have the same chance for above-, near-, or below-normal (33.33%). This doesn’t mean that near-average temperature or precipitation is expected this winter in those regions, but rather that there’s no tilt in the odds toward any outcome. And as mentioned earlier, the blank region in the temperature map has the greatest chance of being colder than average this winter.
El Niño: Where’s the confidence?
In two of my earliest posts for the ENSO Blog, I wrote about the relationship between El Niño and winter precipitation and temperature, presenting figures showing precipitation and temperature differences from average for the 20 prior El Niño episodes from 1950-2013. Here those figures are updated below to include events through the 2015/16 El Niño. An important theme emerges from these two figures: in terms of U.S. impacts, no two El Niño episodes are the same, and winter precipitation and temperature become less consistent as the strength of El Niño decreases.
This is especially true for precipitation, with the tendency for wetter seasons often dominating the southern part of the nation during the stronger episodes (maps towards the top of the figure), but drier winters occurring more frequently for the weaker episodes (bottom 12 maps). Thus, the precipitation outlook will be less confident during the weaker episodes.
Temperature patterns over the U.S. (below) are not as well defined, with the El Niño winter-to-winter variability fairly large among the stronger events, although the 3 strongest events (1982-83, 1997-98, and 2015-16) were generally well above average coast to coast. However, some of the other stronger events (1972-73, 1965-66) were much colder, indicating that agreement even among the stronger episodes is lower. An average (not shown) of the 12 weakest events reveals some agreement favoring above average temperatures in the western and central states, but a more muddled picture in the East, where weak El Niño winter temperatures have varied widely from below-normal to above-normal. This East-West split may not be robust due to the small sample size, but it may also indicate that weak El Niño winters feature a typical temperature pattern that is somewhat distinct from the canonical pattern of a warmer-than-normal North and a normal or colder-than-normal South.
This lack of consistency reflects that a weaker El Niño does not exert a strong push (or forcing) on the U.S. If we have a stronger El Niño, the big push from the vigorous tropical heating sets off a cascade of global impacts, including changes in the strength and position of the jet stream that affects U.S. weather, which tends to dominate over other factors that could impact the outlook. Because of an expected smaller push from El Niño, however, other climate patterns are more likely to play a larger role in shaping the upcoming winter. These patterns, like the Arctic Oscillation and the Madden-Julian Oscillation, can have a profound impact on the character of the winter, but are quite challenging to predict months in advance.
The NOAA Climate Prediction Center (CPC) issues seasonal temperature and precipitation forecasts to help communities prepare for what’s likely to come in the next few months. Empowering people with actionable forecasts and winter weather tips is key to NOAA’s effort to build a Weather-Ready Nation.
Lead Editor: Nat Johnson, NOAA GFDL