Weather NJ 2015-2016 Winter Primer

Jonathan Carr
By Jonathan Carr November 18, 2015 20:02

Weather NJ 2015-2016 Winter Primer

This is not a crystal ball reading for total expected snowfalls and temperatures this winter. This is not an approximation of how much snow the left vs. right side of your deck will receive on any particular day. This is an analysis of where we are today and what to look for in order to anticipate a winter event in the mid-to-long range forecasting period this winter. That’t why I am calling it a primer and not an outlook. Hopefully at the least this primer is informative and educational for you. While I admire the boldness and braveness of professional outlets who issue seasonal outlooks, I lack the experience and education to do such. More about me. My comfort zone for specific daily weather is the short (1-3 days) to mid-range (4-6 days) period. I only venture out to the long-range period (7-9 days) when large-scale synoptic events are modeled on consensual guidance and the current pattern supports it. At that level and beyond, I monitor teleconnections that affect our region and slightly up/downstream. With that said, let’s dive in.

Jet Stream – A jet stream is an area of concentrated winds in the upper-stmosphere (most are located ~250mb or 34,000 feet give or take). These winds form channels that wrap around the planet. There are several jet streams in each hemisphere but we’re mostly influenced by the polar jet to our north and sub-tropical jet to our south. Above the polar jet is very cold air. Below the sub-tropical jet is very warm and moist air. In between is mild air. The jet streams are constantly shifting along their x and y axis, visually seen as wobbles. When the wobbles bunch up together, they create very active weather conditions (meridional flow pattern). When the wobbles flatten, they create less active weather conditions (zonal flow pattern). Because the winds wrap around the planet, consider their length almost finite. Therefore, if numerous wobbles bunch up on one side of the planet into a meridional flow pattern, the jet stream will straighten into a zonal flow pattern elsewhere around the planet. So for us to get major winter storms, we want to see a bunch of wobbles over the E. Pacific and continental US in a specific configuration. In general, when the jet stream moves across the surface of the planet, it creates active weather conditions. The more wobbles, the more this happens.

Cyclone vs. Anticyclone – In the northern hemisphere, low pressure organizes into counter-clockwise cyclones. When you suck through a straw, your drink lifts upwards because of the low pressure generated in your mouth. The atmosphere works the same way. Low pressure creates lifting (convergence at the lower levels and divergence at the upper levels) which creates precipitation. The counter-clockwise flow around the center of the low governs wind direction at the surface and air mass temperature movement. Lows can be upper-level (often at the heart of a trough) or surface level (the kind that like to form along jet streams). Whether the system be a hurricane, mid-latitude cyclone, extratropical cyclone or part of the polar vortex, they are all cyclones with the lowest pressure found at their center. Extratropical cyclones are fascinating as they can often intensify into very large areas of energy on the planet. Sandy transitioned from a tropical to extratropical cyclone just before landfall. As Dr. Ryan Maue of WeatherBell Analytics states:

Rapidly intensifying maritime extratropical cyclones are characterized by Sanders and Gyakum (1980) as “meteorological bombs” if their central pressure dropped by a geostrophically adjusted 1 millibar per hour for a period of 24 hours. A warm-core seclusion is the mature stage of an intense marine extratropical cyclone typified by explosive deepening, strong surface winds, and thermally indirect inner-core mature structure as conceptualized within the Shapiro-Keyser and Norwegian cyclone lifecycle models. 

You will hear me say a low is “bombing out” if it meets such criteria. A warm core seclusion is possible in any of Earth’s oceans.

High pressure, on the other hand, likes to organize into clockwise anti-cyclones. This is the direct opposite mechanism as a cyclone. You would blow bubbles through your straw into your drink from the high pressure you create in your mouth. Anticyclones feature sinking air (convergence at the upper levels and divergence at the lower levels) which generally create fair weather conditions. The clockwise flow around the center of the high also governs wind direction at the surface and air mass temperature movement.

You’ll hear me refer to the intensity of low and high pressure systems in millibars. Sea level pressure under neutral pressure conditions is about 1014mb. 1028mb is a weak high. 1050mb+ is a strong high. 1000mb is a weak low. 980mb or less is a strong low. Major NJ storm systems of the past, just for reference, have intensified below 980mb. Sandy was 946mb during landfall. The March 1993 snow storm was in the 960-970mb range. The lower the pressure in mb, the greater the winds around it and greater the storm system.

Ridge vs. Trough – A ridge is a large area of high pressure, usually with an anticyclone in its heart that likes to create an upside-down U-shaped wobble in the jet stream. Underneath this U generally tends to be warmer/drier weather conditions. In the summer, this is when we get a 80-85 degree day with clear blue skies. In the winter, this is when we bottom out with below-zero to single-digit temperatures and the clearest stargazing conditions possible. A trough is a large area of low pressure usually with a cyclone in its heart that likes to create a U-shaped wobble in the jet stream. Underneath this U generally tends to be cloudy conditions with precipitation and/or colder weather conditions in general. In the winter, this is our best chance for winter storms, especially on the bottom-eastern side of the trough where surface low pressure likes to intensify.

Troughs generally rotate from west to east just like the jet stream flow. Therefore, we experience various conditions at the front, middle and back of them. For example, the front of a ridge could bring colder northerly flow. While in the ridge, conditions are fairly calm. The back of the ridge is typically warmer from southerly flow and often precedes a frontal passage along the front of a trough. While in the trough, conditions are unsettled. The back of the trough returns the flow back to northerly as another ridge approaches. It doesn’t adhere to that exact level of regularity but you get the idea. Such northerly and southerly flow are determined by the cyclonic or anti-cyclonic circulation around a low or high.

So what are teleconnections? – The Earth’s surface is 71% water. Water and land heat and cool at different rates as Earth rotisseries it’s surface around the sun’s radiation via revolution within planetary orbit. These different rates of heating and cooling are always trying to equalize through thermodynamics. While this creates a perfect atmosphere of chaos, some hydrospheric patterns can be clearly observed as oscillating anomalies over time. Some can oscillate within their respective polar ranges over weeks and months while others can take years or even decades. Regardless, these oscillations can both visually define and predict jet stream behavior which steers synoptic mid-latitude cyclones and ultimately defines our mesoscale surface weather conditions. So from west to east, let’s talk about the teleconnections that I monitor for our larger region, the mid-Atlantic and NE US.

ENSO (El Niño Southern Oscillation) –  ENSO is one of the most important climate phenomena on Earth due to its ability to change the global atmospheric circulation, which in turn, influences temperature and precipitation across the globe (NOAA Climate.gov). There are 2 states of the ENSO however the anomaly can be measured in the gray area (often it can remain neutral or in-transition for extended periods of time). Typically the time scale of El Nino-La Nina is 3-7 years (Australian Government Bureau of Meteorology).

The first state is El Nino. This occurs when SST (sea surface temperatures) are warmer than average in the central-eastern Pacific Ocean along the equator. El Nino is west-based if the warmest SST anomalies are closer to the central Pacific and east-based if the warmest SST anomalies are closer to W. South America. El Nino typically results in warmer winter temperatures because the polar and subtropical jet stream are separated until east of us in the Atlantic Ocean. This allows the mild air between the streams to dominate the pattern with less polar influence.

The second state is La Nina. This occurs when SST are colder than average in the central-eastern Pacific Ocean along the equator. Warmer SST are found closer to Indonesia and Australia. La Nina can also be west or east-based. La Nina typically results in greater fluctuations of winter temperatures and a more active storm pattern because the jet streams have the potential to phase either over us or to the west of us coming off the Pacific Ocean.

The current state of ENSO is a peaking El Nino that is beginning to shift its warmest SST anomalies westward towards the central Pacific. To quote Meteorologist Bobby Martrich, Mike Defino and the rest of the Eastern PA Weather Authority team:

Currently we favor the best warming based on the trends in trade winds and the Peruvian current to be farther to the west, generally west of 120°W for the upcoming Winter. This will make for a centralized El Niño, focused on the western half of the Niño 3.4 region. Many have speculated that since we have a strong El Niño this year that it unanimously leads to a warm Winter… incorrect. Again, it is all about the placement of the greatest warming of El Niño in the equatorial Pacific.

What this does is focuses jet-stream shaping tropical energy (tropical forcing) further west—energy that typically supports a warm ridge over North America. When the warmest SST are further east, they feed a ridge closer to our region. But because they are now moving further west, the ridge development should shift accordingly─favoring a ridge over W. US. When applying downstream physics, this creates a trough over the E. US which traditionally results in colder winter weather patterns (remember!…opposite of a ridge). El Nino should continue to shift its warmest SST anomalies to the west however it should stick around well into our winter season. The concept, scientifically in theory, is that the first half of winter would be warmer followed by a back-loaded colder and snowier winter. That’s the message that EPAWA is trying to get across.

PDO (Pacific Decadal Oscillation) - According to the State Climate Office of South Carolina:

The Pacific Decadal Oscillation (PDO) is a pattern of Pacific climate variability similar to ENSO in character, but which varies over a much longer time scale. The PDO can remain in the same phase for 20 to 30 years, while ENSO cycles typically only last 6 to 18 months. The PDO, like ENSO, consists of a warm and cool phase which alters upper level atmospheric winds. Shifts in the PDO phase can have significant implications for global climate, affecting Pacific and Atlantic hurricane activity, droughts and flooding around the Pacific basin, the productivity of marine ecosystems, and global land temperature patterns. Experts also believe the PDO can intensify or diminish the impacts of ENSO according to its phase. If both ENSO and the PDO are in the same phase, it is believed that El Niño/La Nina impacts may be magnified. Conversely, if ENSO and the PDO are out of phase, it has been proposed that they may offset one another, preventing “true” ENSO impacts from occurring.

The PDO oscillates between its warm (positive) and cold (negative) phases. Right now the state of PDO is warm (positive). To quote Meteorologist Steve DiMartino of NY NJ PA Weather:

The thermal gradient along and east of the date line to the north of 30N supports the development of a trough to the south of the Aleutian islands and a ridge to develop along the West coast and over western North America.  This is a text book signature of a positive PDO.

The PDO has, no doubt, played a role in impacting El Nino’s affect on the E. US and will continue to do so. The upcoming volatile temperature pattern through Thanksgiving is partially a result along with other current pattern observations. You might have heard the term “the blob” in the Pacific Ocean representing a body of warmer temperatures south of Alaska and west of the NW US. According to Meteorologist David Tolleris of WxRisk:

The “BLOB” is not NEW. It is NOT unique. It is not shocking. It has been around hundreds of years. It’s called the PDO. 

EPO (Eastern Pacific Oscillation) – The EPO is a much shorter-term oscillation. It can flip between its positive and negative phase in a matter of weeks to months. Basically, the positive phase represents a ridge in the NE Pacific (near the Bering Sea/Alaska). This ridge then results in a trough downstream over the W. US and a ridge over E. US, making for warmer temperatures in our region.  The negative phase of the EPO represents a trough for the Bering Sea/Alaska area and ridge for the W. US, often assisting the positive phase of the PNA (we’ll talk about that next) in creating warmer temperatures for the W. US. This then creates a trough for the central/E. US which again, means colder temperatures and more active winter weather conditions for our region. 

PNA (Pacific North American Oscillation) – The PNA is closely linked to the EPO in the sense of being its opposite. While not always the case, since its the next-east oscillation of the EPO downstream, it likes to mirror the jet stream behavior in reciprocal fashion. For example, when the EPO is negative, the PNA likes to go positive and vice-versa. Simple physics…think of waggling a rope on the ground and the waves you create from doing such. These are similar principals in wave behavior. The negative phase of the PNA means a trough over the W. US and likely then a ridge in the E. US. The positive phase of the PNA means a ridge over the W. US and a trough over the E. US. 

AO (Arctic Oscillation) – Moving eastward we arrive at the AO. According to Meteorologist Jeff Masters of Weather Underground:

The Arctic Oscillation (AO) is a pattern of varying pressure and winds over the Northern Hemisphere that can strongly influence mid-latitude weather patterns. When the AO is in its positive phase, jet stream winds are strong and the jet stream tends to blow mostly west to east, with low-amplitude waves (troughs and ridges.) Since the jet stream marks the boundary between cold Arctic air to the north and warm subtropical air to the south, cold air stays bottled up in the Arctic. When the AO is in its negative phase, the winds of the jet stream slow down, allowing the jet to take on more wavy pattern with high-amplitude troughs and ridges. High amplitude troughs typically set up over the Eastern U.S. and Western Europe during negative AO episodes, allowing cold air to spill southwards in those regions and create unusually cold weather.

So what snow lovers want to see is a negative AO. This means the jet stream has relaxed enough to let cold Arctic air spill southward over the E. US. We saw this big time in the second half of winter 2013-2014. We also saw it last winter a few times. This produces the true cold air needed to fuel large snow storms for our region.

NAO (North American Oscillation) – The last oscillation I will talk about is the NAO. For our terms and purposes this winter, a negative NAO means cold active weather vs. a positive NAO meaning warm and inactive weather. During the negative phase, high pressure blocking forms over the Greenland/N. Atlantic area. This forces the jet stream to bubble and dip over the E. US in the form of a trough. When coupled with a -AO, the result is a favorable pattern for a east coast winter storm. High latitude blocking during a -NAO will also slow a storm system down, allowing for increased total precipitation and time to intensify.  The positive phase means less of a meridional jet stream pattern over eastern North America which doesn’t push down a trough. Instead it keeps the east coast slightly warmer while allowing any storm systems crossing the US to race out to sea unobstructed. Smaller snow events are still possible with a positive NAO but major snow accumulations are less likely.

Thanks to Weather NJ follower Hank Siarczynski for pointing out that:

-NAO, a lot depends on its location. If it forms East of Greenland, the cold temps and storm track generally gets locked into the Midwest, Plains and Ohio Valley. West of Greenland, the East Coast gets the winter wonderland effect.

Sometimes when a low positions itself over the geographic coordinates of 50N/-50W, it can form a block and slow storm systems down.

Teleconnection Summary – All of the above oscillations work together as the jet stream does its thing. The ideal pattern to look for, for a major east coast snow storm, is a -EPO/+PNA/-AO/-NAO. Obviously decent snow storms can still happen under less ideal setups but it puts people like me on the edge of our seat when they all show together. You’ll hear me refer to these teleconnections throughout the winter when analyzing whether or not model guidance supports the current pattern. With a -EPO/neutral PNA/+AO/+NAO, the pattern is unfavorable for sustained cold beyond Thanksgiving Weekend which suggests transient cold shots between longer periods of mild weather.

Siberian Snow Cover – Another potential indicator of our winter is the analysis of Siberian snow cover. There is actually an index for it. Meteorologist Joe Cioffi states:

This indicator is strongly positive of another cold snowy winter. The index that measures this, after a slow start, accelerated in mid month and it has finished. The index finishes among the top 3 which puts it in line with the last 2 winters. The index has worked well if you use it as a straight correlation. In other words fast growth rates mean cold and snowy winters in the east. Where the index failed last year was that the coldest areas were confined to the northeast and not the entire east coast and midwest. The high index reading last year led some long range forecasters to conclude that a pattern of “blocking” would develop. Blocking in the atmosphere at northern latitudes displaces cold air southward. However this did not occur! The atmosphere found a different way to deliver cold air to the east.  We rate this indicator as a POSITIVE for a cold and snowy winter.

In addition to Siberian snow cover, extreme North American snow cover is modeled to increase as well with several northern Pacific storm systems moving into W. Canada. The key principal here is that “snow breeds snow” When wind flow passes over snow cover to our north and west, the air is cooled more which could make the surface difference between 31 degrees or less (snow) vs. 33 degrees or more (rain) downwind. If you’re a snow lover in the mid-Atlantic, you want to see a healthy SE Canadian/Great Lakes area snowpack form once the Siberian and N. Canadian snow packs establish, which they are doing. The SE Canadian snowpack might be a little late to the party however.

Influence of Typhoons – Every long-range forecaster’s nightmare! When typhoons in the W. Pacific fail to make landfall on E. Asia and instead curve northward towards the Bering Sea, it has a tremendous impact downstream for the continental US. The cyclonic nature of a typhoon curving northward creates a ridge in the E. Pacific/W. US which translates to a cold trough in the E. US. We saw this several times over the past winters, including last November. The downstream impacts tend to occur a few weeks or so after the curve. This is another thing I’ll be watching for and it could happen pretty soon in the W. Pacific. As long as the NW Pacific stays warm, such an occurrence is possible.

Types of East Coast Winter Storms and Snowfall – Here on the east coast, we typically see snowfall from a few different scenarios:

Miller-A – Miller-A systems generally originate near or in the Gulf of Mexico. The low tracks across the SE US and ejects into the Atlantic Ocean somewhere between say Georgia and Virginia. It then tracks near what we call the benchmark (the BM) which is a geographic location of 40N -70W (just south of E. Long Island). This is an ideal track for a New Jersey snow storm. If the low tracks inside of the BM (NE of it), New Jersey sees more rain than snow. In that case, let it wash over you. If the low tracks outside of the BM (SE of it) then it can result in a miss out to sea. The March 1993 snow storm was a classic Miller-A.

Miller-B – Miller-B systems often come onshore off the Pacific Ocean and/or generally approach from our west. They transfer energy to another low that can take a BM-like track. During the transfer, enormous dry slots can occur that can majorly bust forecasts. Once the transfer is complete, if the low hangs around long enough, it can result in a major snow storm. The President’s Day Weekend snow storm of 2003 was a classic Miller-B.

Clipper – Clipper are systems that originate in Canada (often called Alberta Clippers). They dip southward enough to get caught in the jet stream and get shot eastward along the US/Canadian border and over the Great Lakes. These systems are often cold systems and are known for very light/powdery snow. Clippers are generally moisture-starved but the colder environment allows for higher snow ratios (inches of snow to inches of rain). They are notorious for putting down a quick coating to a few inches of snow that instantly sticks. This can often result in a nice rush hour surprise. Most clippers usually move through the area pretty quickly however sometimes they can transfer (in a Miller-B fashion) to a coastal low for a larger snowfall total.

Lake Effect Snow – Whenever a strong W/NW, NW or N/NW flow occurs over the Great Lakes, snow showers can form to the E/SE, SE or S/SE of them. These snow showers can hold together all the way to the Atlantic Ocean (over New Jersey). Sometimes you will hear them referred to as a flizzard when they hit. They can lead to very brief white-out conditions in New Jersey with little to no accumulation but can stack up to feet of snow in places like Buffalo/Syracuse, NY.

Ice Storm – Sometimes winter storms start out as snow but warmer air invades the mid-levels. This can happen when a low tracks too far west but imposes upon an existing colder air mass in place. Precipitation starts out as rain at the strongest levels of warm air advection then changes to sleet before hitting the ground or hits the ground and freezes as freezing rain. Sometimes you will hear a term called cold air damming. For example, the appalacian mountains can lock the colder air mass in place at the surface and allow the warmer air to pass overhead—at a high enough elevation to result in all snow at the surface. I’ll point this out if/when it happens this winter.

Wind Direction – As a low passes by, it’s important to note the change in wind direction. If a low is to our south, it’s counter-clockwise flow will produce easterly winds off the above-freezing Atlantic Ocean. This will prevent snow from occurring most of the time. It won’t be until the low is SE or E of us to change the wind direction to N/NE, allowing colder air to change rain over to snow. We deal with this a lot on the coast and it’s often frustrating for the snow lover. This is not an issue for clippers and lake effect snow because in those cases, the wind flow is generally out of the NW—tapping colder, Canadian, polar or Arctic air. This is an issue for Miller-A and Miller-B events that take a ~BM track.

Model Guidance – The models are not preaching gospel. They are producing guidance. Their output are the result of super-computer calculations based on current atmospheric measurements at runtime. It is best to use their overall consensus and look at the current overall pattern. Does the pattern support it or not? If no then we’ll likely watch it disappear of guidance. If yes then we’ll pursue accordingly. I like to monitor the European (ECMWF), American (GFS), Canadian (GGEM) and UKMET in the mid-to-long range. In the short range, I like to monitor the 12km NAM and Canadian (RGEM). In the ultra short-range, I like to use the HRRR. I’m sure I left a few out and there is new model technology coming out all the time.

Timing is where it can get confusing. Models are based on zulu time. The 00Z run is midnight, 06Z is 6AM, 12Z is noon and 18Z is 6pm in Greenwich Mean Time (at 0 degrees of longitude). To convert to our time you subtract 4 or 5 hours depending on which side of daylight saving we are. We just moved into EST so it’s minus 5 until March. That means that 00Z is actually 7PM on the east coast. What you need to know is that the 00Z runs populate during overnight hours while 12Z runs populate during daytime hours. 06Z and 18Z runs happen in between but feature less data input than the 00Z and 12Z runs.

How I will track winter storms – By now it should be clear that social meteorology is not about “who posted first about the storm system.” Big storm systems show up on long-range model guidance all the time only to disappear in the mid-range. Even though I obsessively monitor model guidance out to two weeks, I likely will only start discussing possibilities if A) They are showing on multiple models in the long range and B) The current pattern supports such an event happening. And just because I discuss the possibility does not mean I am forecasting it to happen. I will discuss the system so long as it stays on consensual guidance into the mid-range. Once mid-range guidance transitions into short-range guidance, with the system still showing, I will begin making snowfall accumulation maps. You will likely see an initial thoughts map 3 days before the storm’s impact, several updated thoughts maps 2-1 days out, and a final map the day of the approaching storm system. This is the strategy that I’ve found to be most effective over the years of delivering forecasts to the public. It allows me to narrow possibilities over time but gives you an idea of what to expect (best vs. worst case scenario). Again, it’s not about being first, it’s about being accurate while narrowing the realm of total possibilities over time.

What does it all mean? – Because we are in a somewhat bizarre pattern, it will be difficult for anyone to nail down the long range pattern this year. Eastern PA Weather Authority is using the winters of 1957-1958 and 2002-2003 as their top two favorite analogs and they mostly nailed the last two winters. Right now with the state of most short-term teleconnections (not ENSO nor PDO), anything is on the table. The temperature fluctuations that we’re about to see next week and then into December should be mostly driven by the combination of a positive warm PDO and west-based weakening El Nino. Once we’re into January, should the El Nino continue to shift west then the PDO should in theory regain more control of the pattern. This would create the ridge in the W. US/trough in the E. US setup for the back half of winter, allowing for colder temperatures and active winter storm tracks. With that said, and again in theory, the first half of this winter looks warmer overall but with transient cold shots while the back half of this winter looks colder overall but with transient warm shots. Regardless of temperature, I think we are looking at an active subtropical jet stream which should bring plenty of precipitation to our area, rain or snow.

In English –  Many local long-range forecasters are calling for a warmer and less snowy first half of winter followed by a colder and snowier second half of winter. I personally have to admire the scientific skill-set of these long range forecasters. They are truly delivering the most scientific-based explanations possible so you have to give it up to them for that. However, we have to keep in mind that the atmosphere has a mind of its own, especially over long periods of time and chaos. For this reason, I will concentrate on large-scale storm system possibilities when they first show up in the 7-10 day period on model guidance. I will then walk them into the mid-range via discussion/model analysis and ultimately the short-range. I will pay attention to teleconnections to see if they support the model guidance. Basically, each 7-9 day period at a time.  If you have any questions, please post them in the comments and I’ll be glad to answer. Thanks for your time and patience and I hope you’ve enjoyed this winter primer article. As always, please be safe! JC

 References

Australian Government Bureau of Meteorology

Cioffi, Joe (Meteorologist). Meteorologist Joe Cioffi Weather Updates

DeFino, Mike (Meteorologist). Eastern PA Weather Authority

DiMartino, Steve (Meteorologist). NY NJ PA Weather

Martrich, Bobby (Meteorologist). Eastern PA Weather Authority

Masters, Jeff. PhD (Meteorologist). Weather Underground

Maue, Ryan. PhD (Meteorologist). Warm Seclusion Extratropical Cyclones. Florida State University

NOAA Climate.gov

State Climate Office of North Carolina

Tolleris, David (Meteorologist). WxRisk

 Image Credit

“Suddenly you Find Yourself” by Greg Molyneux Photography

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Jonathan Carr
By Jonathan Carr November 18, 2015 20:02

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