Winter 2022-23 Outlook

Local Winter Outlook:

Winter 2022-23 Temperature Outlook:

Locally, the odds have been tilted slightly toward colder-than-normal (not just a tenth of a degree colder than normal, but among the coldest third of the winters from 1991-2020) in northeast Iowa, southeast Minnesota, and western Wisconsin. 

Why colder-than-normal?

• Favorable things for a colder-than-normal winter.
  1. Weak La Niñas (41% chance for this winter) tend to favor colder- and near-normal winters. Just 2 have been among the warmest third.
  2. Moderate La Niñas (27% chance for this winter) tend to be in the coldest third of winters. Out of the 6 moderate La Niñas, 4 have been among the coldest third, and 2 were near-normal.  The one negative with this is that the past 2 winters were moderate La Niñas and they were both near-normal. One thing to note is that this is a small sample size.
  3. The CFS version 2 climate model is favoring colder-than-normal temperatures for this winter.
  4. Above-normal sea surface temperatures in the northern Pacific also favor colder-than-normal temperatures in the north-central US and Great Lakes. However, these sea surface temperature anomalies can change quickly, so not always good for seasonal forecasts.
• Unfavorable things for a colder-than-normal winter. 
  1. Very few winters have been in the coldest third over the past decade (optimal climate normal). La Crosse has only had 1 winter in the coldest third and Rochester has only had 2 winters (2013-14 & 2018-19) in the coldest third.
  2. Since the late-1980s, La Niña winters have been highly variable at La Crosse.  There were 4 warmer-than-normal, 4 near-normal, and 5 colder (5) than normal. Meanwhile, there have been more near-normal winters (6) than either colder (3) or warmer (4) than normal at Rochester.

Winter 2022-23 Precipitation Outlook:

Locally, wetter-than-normal (not just a hundredth of an inch wetter than normal, but among the wettest third of the winters from 1991-2020) is slightly favored across the Upper Mississippi River Valley. This was based on recent trends over the past decade. Meanwhile, in northeast Iowa and southeast Minnesota, there are equal chances for drier-, near-, and wetter-than-normal.

Why wetter-than-normal?

• Favorable things for a wetter-than-normal winter.
  1. Dynamical climate models are suggesting wetter-than-normal across much of Wisconsin. 
  2. During the past 15 years (optimal climate normal), La Crosse, WI has had 8 winters that were wetter-than-normal winters, 4 winters with near-normal precipitation, and 3 winters that were drier than normal.  Rochester, MN has had 9 winters that were wetter-than-normal winters, 5 winters with near-normal precipitation, and only 1 winter that was drier than normal (2019-20).

• Unfavorable things for a wetter-than-normal winter​
  1. La Niñas can be highly variable with precipitation. La Crosse has seen 8 in the wettest third, 8 near normal, and 8 in the driest third. Meanwhile, Rochester has had 10 near-normal, 7 among the wettest third, and 7 among the driest third.

Wetter-than-normal does not necessarily mean that it will be snowier than normal. The seasonal snow has been highly variable during the 24 La Niñas since 1949-50.

• In La Crosse WI, 8 were in the snowiest third, 7 were near-normal, and 9 were in the lowest third for snow. These winters averaged 44.3" of snow which was 2" less than the 1991-2020 normal of 46.3". The snow total ranged from 19.4" (1975-76) to 73.2" (1974-75) - a very large range. 
• In Rochester MN, 13 were in the snowiest third, 9 were near-normal, and 2 were in the lowest third for snow.  These winters averaged 48.9" of snow which was 4.2" less than the 1991-2020 normal of 53.1". The snow total ranged from 28.4" (1975-76) to 70.5" (2011-12) - again, a large range. 

Snowstorms will occur at times this winter. However, the frequency, number, and intensity of these events cannot be predicted on a seasonal timescale.

What is La Niña?:

What is La Niña?

Author: Mike Halpert
October 23, 2017

La Niña literally means "the little girl." in Spanish.  La Niña is also sometimes called El Viejo (Old Man), anti-El Niño, or simply "a cold event" or "a cold episode".  La Niña refers to abnormally cold water temperatures across the central and eastern equatorial waters (5°N-5°S, 120°-170°W)] of the Pacific Ocean.  La Niñas typically occur every 3 to 7 years.

How do La Niña's Develop?
 

During La Niña, the surface winds across the entire tropical Pacific are stronger than usual, and most of the tropical Pacific Ocean is cooler than average. This results in more upwelling of cold water off the Peruvian coast which results in even colder waters in the central and eastern equatorial waters.  Rainfall increases over Indonesia (where waters remain warm) and decreases over the central tropical Pacific (which is cool). Over Indonesia, there is more rising air motion and lower surface pressure. There is more sinking air motion over the cooler waters of the central and eastern Pacific.

Generalized Walker Circulation (December-February) anomaly during La Niña events, overlaid on a map of average sea surface temperature anomalies. Anomalous ocean cooling (blue-green) in the central and eastern Pacific Ocean and warming over the western Pacific Ocean enhance the rising branch of the Walker circulation over the Maritime Continent and the sinking branch over the eastern Pacific Ocean. Enhanced rising motion is also observed over northern South America, while anomalous sinking motion is found over eastern Africa. NOAA Climate.gov drawing by Fiona Martin. 

How long does La Niña typically last?
 

La Niña episodes typically last 9-12 months. They both tend to develop during the spring (March-June), reach peak intensity during the late autumn or winter (November-February), and then weaken during the spring or early summer (March-June).  it is common for La Niña to last for two years or more.  The longest La Niña lasted 33 months.

Global La Niña Impacts:

During  La Niña winters, cooler-than-normal temperatures are typically found across western and central Canada, Japan, eastern China, southern Brazil, parts of western and southern Africa, and Madagascar.  Wetter-than-normal conditions are found in Indonesia, western and central Canada, and southeast Africa.  Meanwhile, drier-than-normal conditions are seen across central South America.

U.S. La Niña Impacts:

There has been a fair amount of variability in the winter temperature and precipitation patterns during La Niña, but also that there are some clear tendencies for above or below normal temperature or precipitation in some regions. 

La Niña Composites:

Another way to examine the common features of La Niña winters is to create a composite map (an average of all of these individual maps). This will highlight those regions that often have temperature or precipitation anomalies of the same sign. For temperature, there’s a strong tendency for temperatures to be below average across some of the West and North, particularly in the Northern Plains, with a weaker signal for above-average temperatures in the Southeast, as shown in the image below. 

Winter temperature differences from average (degrees F) during La Niña winters dating back to 1950. Temperatures tend to be colder than average across the northern Plains and warmer than average across the southern tier of the United States. NOAA Climate.gov image using data from ESRL and NCEI.

Winter precipitation differences from average (inches) during La Niña winters dating back to 1950. Precipitation tends to be below-average across the southern tier of the United States and wetter than average across the Pacific Northwest and Ohio Valley. NOAA Climate.gov image using data from ESRL and NCEI.

The precipitation pattern, presented above, shows negative anomalies (indicating below-normal rainfall) across the entire southern part of the country with a weaker signal of above-average precipitation in the Ohio Valley and in the Pacific Northwest and the northern Rockies. 

However, these figures are based on about 20 different La Niña episodes, many of them from the 1950s, 1960s, and 1970s, and we have not removed the longer-term trends from the temperature and precipitation data used here. The trend is an important component of seasonal temperature forecasts. It’s fairly trivial to break the sample size in half and compare the temperature patterns for the older half to the more recent half. That provides a significantly different picture, with the average of the latest events much warmer than the earlier ones.  We can see this by comparing the right image below (more recent events) with the one to the left of it (older events). 

Comparison of winter temperature differences from average (degrees F) between the earliest and most recent ten La Niña winters dating back to 1950. Temperatures tend to be warmer across much of the country during the most recent ten La Niña events as compared to the earliest ten La Niña events. NOAA Climate.gov image using data from ESRL and NCEI.

This picture is consistent with long-term warming trends in the United States.  These historical relationships along with guidance provided by a suite of computer models play a strong role in the final outlooks. Differences between the two periods for the precipitation composites are much smaller and therefore are not shown here. 
 

Footnotes

(1) The terciles, technically, are the 33.33 and 66.67 percentile positions in the distribution. In other words, they are the boundaries between the lower and middle thirds of the distribution, and between the middle and upper thirds. These two boundaries define three categories: below-normal, near-normal, and above-normal. In the maps, the CPC forecasts show the probability of the favored category only when there is a favored category; otherwise, they show EC (“equal chances”). Often, the near-normal category remains at 33.33%, and the category opposite the favored one is below 33.33% by the same amount that the favored category is above 33.33%. When the probability of the favored category becomes very large, such as 70% (which is very rare), the above rule for assigning the probabilities for the two non-favored categories becomes different. 

La Niña Winter Temperatures

Author: Tom Di Liberto (October 6, 2017)

Midwest La Niña Winter (DJF) Average Temperature Departures (24 Winters since 1949-50)

1949-1950	1954-1955	1955-1956	1964-1965

1970-1971	1971-1972	1973-1974	1974-1975

1975-1976	1983-1984	1984-1985	1988-1989

1995-1996	1998-1999	1999-2000	2000-2001

2005-2006	2007-2008	2008-2009	2010-2011

2011-2012	2017-2018	2020-2021	2021-2022
2022-2023

La Niña Winter Precipitation

Author: Tom Di Liberto (October 12, 2017)

Midwest La Niña Winter Winter (DJF) Precipitation Departures (24 Winters since 1949-50)

1949-1950	1954-1955	1955-1956	1964-1965

1970-1971	1971-1972	1973-1974	1974-1975

1975-1976	1983-1984	1984-1985	1988-1989

1995-1996	1998-1999	1999-2000	2000-2001

2005-2006	2007-2008	2008-2009	2010-2011

2011-2012	2017-2018	2020-2021	2021-2022
2023-2023

La Niña Seasonal Snow

Author: Stephen Baxter (November 21, 2017)

La Niña is associated with a retracted jet stream over the North Pacific Ocean. The retreat of the jet stream results in more blocking high pressure systems that allow colder air to spill into western and central Canada and parts of the northern contiguous U.S. At the same time, storm track activity across the southern tier of the U.S. is diminished under upper-level high pressure, which also favors milder-than-normal temperatures. The storm track is, in turn, shifted northward across parts of the Ohio Valley and Great Lakes (2).

Based on climate analysis (3) from this new snow dataset, we see that La Niña favors increased snowfall over the Northwest and the northern Rockies, as well as in the upper Midwest Great Lakes region. Reduced snowfall is observed over parts of the central-southern Plains, Southwest, and mid-Atlantic.

Snowfall departure from average for all La Niña winters (1950-2009). Blue shading shows where snowfall is greater than average and brown shows where snowfall is less than average. Climate.gov figure based on analysis at CPC using Rutgers gridded snow data.

This La Niña footprint is pretty intuitive. Given the northward shift of the storm track, relatively cold and wet conditions are favored over the northern Rockies and northern Plains, resulting in the enhancement of snowfall. Warmer and drier winters are more likely during La Niña over more southern states, and this is exactly where seasonal snowfall tends to be reduced (4). The more vigorous storm track and slight tilt toward colder temperatures over the northern tier of the U.S. during La Niña modestly increase the chance of a relatively snowy winter.

Snow and Strength

We can break up the snow pattern further and look at the weakest and strongest La Niña events. Splitting La Niña events into strength reveals some interesting differences worth investigating further. In this preliminary analysis below, there is a suggestion that weaker events are snowier over the Northeast and northern and central Plains on average. 

On the other hand, stronger La Niña events (see below) are snowier across the Northwest, the northern Rockies, western Canada, and the Alaska panhandle. Also, there is a tendency toward below-average snowfall over the mid-Atlantic, New England, and northern and central Plains, which is not seen during weak La Niña.

Snowfall departure from average for stronger La Niña winters (1950-2009). Blue shading shows where snowfall is greater than average and brown shows where snowfall is less than average. Climate.gov figure based on analysis at CPC using Rutgers gridded snow data.

Overall, stronger La Niña events exert more influence on the winter climate pattern over western North America. Weaker events appear to be associated with more widespread above-average snow over the northern United States. Because a weak La Niña means that the forcing from the Pacific is weaker than normal, it may imply other mechanisms (e.g. Arctic Oscillation) may be at play and is worth further investigation.

The predictability of seasonal snowfall may be somewhat similar to precipitation in that one or two big events can dramatically affect the seasonal average. Thus, in general, the expected prediction skill is likely to be lower than for temperature. However, because temperature also plays an important role in snowfall, some predictability is likely nonetheless. And like for seasonal temperature and precipitation, knowing the state of ENSO is a pretty reasonable place to start.

Midwest La Niña Seasonal Snow Departures (24 Winters since 1949-50)

1949-1950	1954-1955	1955-1956	1964-1965

1970-1971	1971-1972	1973-1974	1974-1975

1975-1976	1983-1984	1984-1985	1988-1989

1995-1996	1998-1999	1999-2000	2000-2001

2005-2006	2007-2008	2008-2009	2010-2011

2011-2012	2017-2018	2020-2021	2021-2022
2022-2023

Footnotes

1. This new dataset is documented in Kluver et al. (2016) “Creation and Validation of a Comprehensive 1° by 1° Daily Gridded North American Dataset for 1900-2009: Snowfall” in the Journal of Atmospheric and Oceanic Technology. The dataset for this analysis goes up to 2009, so we are going to look at winters from 1950-51 to 2008-09. Total cold season snowfall accumulation from October through April is used here.
    
2. This is consistent with the temperature pattern: the storm track is enhanced where the temperature gradient is stronger than normal.
    
3. Here we are using composite analysis to show snowfall. In this case, we take just the La Niña years between 1950-51 and 2008-09 and compute the mean. For the strength composites, we divide the 18 La Niña winters between 1951-2009 into weak or strong cases. The median ONI value used to split them is -0.95°C during December-February (DJF) average. We need to be cautious in drawing too many conclusions based on the large reduction in our sample size. Composites also emphasize variance: regions with more year-to-year variability will have higher amplitude composite signals.
    
4. The areas in the South that favor below-average snowfall during La Niña are most evident where the snowfall climatology is reasonably high. That is where the signal is most likely to come through the noise

La Niña AWSSI

Author: Midwestern Regional Climate Center

CONUS AWSSI during La Niña (23 Winters since 1954-55)

1954-1955	1955-1956	1964-1965	1970-1971

1971-1972	1973-1974	1974-1975	1975-1976

1983-1984	1984-1985	1988-1989	1995-1996

1998-1999	1999-2000	2000-2001	2005-2006

2007-2008	2008-2009	2010-2011	2011-2012

2017-2018	2020-2021	2021-2022	2022-2023

La Crosse, WI AWSSI during La Niña (23 Winters since 1954-55)
 

1954-1955	1955-1956	1964-1965	1970-1971

1971-1972	1973-1974	1974-1975	1975-1976

1983-1984	1984-1985	1988-1989	1995-1996

1998-1999	1999-2000	2000-2001	2005-2006

2007-2008	2008-2009	2010-2011	2011-2012

2017-2018	2020-2021	2021-2022	2022-2023

Rochester, MN AWSSI during La Niña (23 Winters since 1954-55)
 

1954-1955	1955-1956	1964-1965	1970-1971

1971-1972	1973-1974	1974-1975	1975-1976

1983-1984	1984-1985	1988-1989	1995-1996

1998-1999	1999-2000	2000-2001	2005-2006

2007-2008	2008-2009	2010-2011	2011-2012

2017-2018	2020-2021	2021-2022	2022-2023

Additional Information

Information Sheet (2-page) - pdf

The Accumulated Winter Season Severity Index (AWSSI)
Barbara E. Mayes Boustead, Steven D. Hilberg, Martha D. Shulski, and Kenneth G. Hubbard. Journal of Applied Meteorology and Climatology, Vol. 54, No. 8, August 2015: 1693-1712. 
Abstract | Full Text | PDF (2545 KB)

An Accumulated Winter Season Severity Index. Barbara Mayes Boustead, NOAA/NWS, Valley, NE; and S. Hilberg, M. D. Shulski, and K. G. Hubbard. Presented at 93rd Annual Meeting of the American Meteorological Society, January 2013. 

An Accumulated Winter Season Severity Index (AWSSI). Webinar for the NWS Central Region, February 2017. 

For more information, please contact Barb Mayes Boustead (barbara.mayes@noaa.gov) at the National Weather Service or Steve Hilberg (hberg@illinois.edu).

La Niña Severe Weather:

La Niña Severe Weather:

Author: Michael K. Tippett and Chiara Lepore
April 27, 2017

ENSO shifts the atmospheric circulation (notably, the jet stream) in ways that affect winter temperature and precipitation over the U.S. The changes in spring (March-May) are similar to those during winter, but somewhat weaker.

These shifts would also be expected to impact thunderstorm activity: El Niño tends to shift the jet stream farther south over the U.S., which blocks moisture from the Gulf of Mexico, reducing the fuel for thunderstorms. On the other hand, La Niña is associated with a more wavy and northward shifted jet stream, which might be expected to enhance severe weather activity in the south and southeast. Indeed, historic tornado outbreaks in 1974, 2008, and 2011 started during La Niña conditions.

However, tornado and severe weather activity is more variable (“noisier” and harder to predict) than ordinary weather (think temperature and precipitation), and any ENSO signal is harder to see. Until recently, the only solid evidence showing that more tornadoes occur during La Niña conditions was for winter (January-March), when the ENSO signal is strongest, but average tornado activity is relatively low (Cook & Schaefer, 2008).

A recipe for tornadoes

A clearer picture of the impact of ENSO emerges when we look at the ingredients that are conducive to tornado and thunderstorm occurrence (Allen et al., 2015a).  Instead of only looking at individual weather events, it’s important to consider the environmental cues for the outbreak of severe weather.   

Two important ingredients for tornadoes are atmospheric instability (e.g., warm, moist air near the surface and cool dry air aloft) and vertical wind shear (winds at different altitudes blowing in different directions or speeds). Measures of these tornado-friendly ingredients can be combined into indexes that are less noisy than actual tornado reports and let us see how the phases of ENSO make the environment more or less favorable for severe weather (footnote 1).

In much of the U.S., La Niña conditions are associated with increases in these environmental factors and in tornado and hail reports. The largest signal is present in the south and southeast (including parts of Texas, Oklahoma, Kansas, Louisiana, Arkansas, and Missouri), except in Florida where the opposite relation is observed. Positive values indicate increased activity, and negative values indicate decreased activity compared to the long-term average (1979-2015).

Figure 1. Sea surface temperature pattern showing the warm phase of the Pacific Decadal Oscillation (top). The status of the PDO between 1950 and this year, shown at bottom, indicates a predominantly positive phase from about 1978 to 1998 and a negative phase since 1999.   Image Credit: Climate Impacts Group, University of Washington.

In the South and Southeast, where the signal is strongest, we see a clear shift in activity with the ENSO phase, but with a tremendous range of variability, meaning some El Niño years still have high severe weather activity, and some La Niña years are relatively inactive. While increased tornado activity is generally associated with La Nina conditions, blaming this year’s high activity on the weak La Nina conditions would be exaggerating the strength of the historical relationship (footnote 2).

Regional (100-90W, 31-36N) totals of March-May tornado reports, hail events, a tornado environment index (TEI), and a hail environment index (HEI) expressed as a percentage of their 1979-2015 average and conditioned on the ONI. Box edges mark the 25^th and 75^th percentiles, and whiskers extend 1 and a half times the interquartile range. Figure by climate.gov; data from the authors.

Footnotes
 

1: The tornado environment index (TEI) and hail environment index (HEI) are functions of monthly averages of convective precipitation, convective available potential energy, and storm-relative helicity. TEI and HEI are calibrated to match the recent climatology of tornado numbers and hail events. See Tippett et al. (2012) and Allen et al. (2015b) for more details.

2: Inside baseball: Further details of the ENSO relation

Overall, La Nina conditions are associated with enhanced U.S. tornado activity, but more detailed aspects of ENSO may also be relevant (Lee et al., 2012). Gulf of Mexico sea surface temperature is close to the part of the U.S. most strongly impacted by severe weather: warm Gulf of Mexico surface water in spring enhances low-level moisture transport and southerly flow and is associated with enhanced US tornado and hail activity (Molina et al., 2016). The Gulf of Mexico sea surface temperature is negatively correlated with the tropical Pacific sea surface temperature, meaning when the tropical Pacific is cooler than average (La Niña), the Gulf of Mexico is usually warmer than average.

Seasonal (May-July) averages of Gulf of Mexico SST can be predicted with some skill (Jung and Kirtman, 2016). Atmospheric angular momentum is related to ENSO and also shows the impact of tropical forcing on tornado activity (Gensini and Marinaro, 2016).

Local La Niña Statistics:

Past La Niña Winters Statistics for the Local Area:

In the tables below, red represents a value in the upper third of winters, blue represents a value in the lower third of winters, and black represents a near-normal.  For La Crosse, the temperature and precipitation data extend back to the 1872-73 winter and snowfall back to 1895-96. For Rochester, the temperature and precipitation data extend back to the 1886-87 winter and snowfall back to 1908-09.

La Crosse, WI:
 

Rochester, MN

Arctic Oscillation:

Climate Variability: Arctic Oscillation (AO)

Author: LuAnn Dahlman
August 30, 2009

The Arctic Oscillation (AO) refers to an atmospheric circulation pattern over the mid-to-high latitudes of the Northern Hemisphere. The most obvious reflection of the phase of this oscillation is the north-to-south location of the storm-steering, mid-latitude jet stream. Thus, the AO can have a strong influence on weather and climate in major population centers in North America, Europe, and Asia, especially during winter.

The AO's positive phase is characterized by lower-than-average air pressure over the Arctic paired with higher-than-average pressure over the northern Pacific and Atlantic Oceans. The jet stream is farther north than average under these conditions, and storms can be shifted northward of their usual paths. Thus, the mid-latitudes of North America, Europe, Siberia, and East Asia generally see fewer cold air outbreaks than usual during the positive phase of the AO.

Conversely, AO's negative phase has higher-than-average air pressure over the Arctic region and lower-than-average pressure over the northern Pacific and Atlantic Oceans. The jet stream shifts toward the equator under these conditions, so the globe-encircling river of air is south of its average position. Consequently, locations in the mid-latitudes are more likely to experience outbreaks of frigid, polar air during winters when the AO is negative. In New England, for example, higher frequencies of coastal storms known as "Nor'easters" are linked to AO's negative phase.

This graph shows monthly values for the Arctic Oscillation index.

AO phases are analogous to the Southern Hemisphere's Antarctic Oscillation (AAO), a similar pattern of air pressure and jet stream anomalies in the Southern Hemisphere. Viewed from above either pole, these patterns show a characteristic ring-shape or "annular" pattern; thus, AO and AAO are also referred to as the Northern Annular Mode (NAM) and Southern Annular Mode (SAM), respectively.

Monthly and Daily values for the Arctic Oscillation Index are available from NOAA's Climate Prediction Center.

References
Thompson, D.W.J., S. Lee, and M.P. Baldwin, 2002: Atmospheric Processes Governing the Northern Hemisphere Annular Mode/North Atlantic Oscillation. From the AGU monograph on the North Atlantic Oscillation, 293, 85-89.

Thompson, D.W.J., and J.M. Wallace, 2001: Regional Climate Impacts of the Northern Hemisphere Annular Mode. Science, 293, 85-89.

Thompson, D.W.J., and J.M. Wallace, 2000: Annular modes in the extratropical circulation. Part I: Month-to-month variability. J. Climate, 13, 1000-1016.

Thompson, D.W.J., and J.M. Wallace 1998: The Arctic Oscillation signature in wintertime geopotential height and temperature fields. Geophys. Res. Lett. 25, 1297-1300.