Space Weather

Wednesday, December 15, 2021

Global Warming my thoughts behind it.

I was asked to make a blog post on warming global temperatures, and why it might be happening. I’m a meteorologist not a climatologist, but to most people I’m the only scientist they know, so I get asked about the climate change debate a lot.  Climate Science is a little out of my wheelhouse. But I have a decent understanding of it, so I feel comfortable with the subject. I don’t often post about global warming. But when asked about the subject; I will discuss the issue and what I believe to be true. Weather and climate are two different subjects, but they are related. Climate is the result of short-term weather events average over a very long time.  There are two sides in the climate change debate, those who believe humans are the primary cause, and those to think the primary cause is cyclical patterns and variations. Which side is right is still in debate? IMO, there is no proven science as of yet, only theories. I think we’re still 8-15 years away from having enough facts to determine who is right. That would be right around 2030.

There are those who say global warming is a lie. But that isn’t true. There is plenty of evidence and data that shows this to be true. There is enough data to support the idea that greenhouse gas emissions into the atmosphere is the chief reason. The question comes down to which greenhouse gas emissions are primarily the reason. Many on the human caused change side, say carbon dioxide (CO²) is the main player. Whereas I and others who think as I do, believe the culprit is water vapor. Many of us have our reasons for supporting one side or the other. We all look at things in a different way. So, what you might see or believe is different from what I see and believe. But to get to the bottom of the global warming debate we have to look at the whole picture and look at everything we can find.  Junk science is on both sides of the climate chasm. So, we have to step carefully if we don’t’ what to plummet to the bottom. In order to do that we have to look at the available evidence and data with an open mind.   This post will try to do that. I will show the reasons for what I believe to be the case.

Before we look at now, I want to look to the past.

A look at the last ice age:

There have been at least five documented major ice ages during the 4.6 billion years since the Earth was formed, four that occurred during the Pleistocene Epoch and most likely many more before humans came on the scene about 2.3 million years ago.  The last ice age lasted for 75,000 to 100,000 years. The Earth has been warming since the last ice age, which officially ended 8,000-12,000 years ago. During the last ice age, a large part of the northern hemisphere was covered with glaciers, the southern hemisphere wasn’t impacted as bad but still there is evidence that shows southern South America and southern Africa we’re dealing with glaciation as well.  But the glaciers did not just sit there. There was a lot of movement over time, and there were about 20 cycles when the glaciers would advance and retreat as they thawed and refroze.

As the name implies the overall climate was much colder and drier than it is today.  During peak periods with most of the water frozen, global average temperatures were 5 to 10 degrees C (9 to 18 degrees F) below today’s temperature averages.  How did the last ice age end? We do know there was a change in the relative strength of the sun roughly 20,000 years ago due to orbital changes in Earth’s orbit.  Examined sediment cores around the globe as well as ancient air trapped in Antarctic ice, have found that CO² led to global warming. It is likely that the waters of the Southern Ocean may have begun to release carbon dioxide, enough to raise concentrations in the atmosphere by more than 100 parts per million over millennia—roughly equivalent to the rise in the last 200 years. This is what likely allowed the ice sheets to retreat. Leading to the relatively balmy, stable interglacial climate sometimes called the "long summer" that we now enjoy.  

So clearly CO² can lead to a warming atmosphere. But before y’all say aha. We will have to look closer.

I’ve seen where global warming groups talk a lot about the rapid change in temperature anomalies. They believe humans are the primary reason for the global warming over the last 100 to 200 years.   They cite how global temperatures over the last 100 years have risen between 0.50- and 0.75-degrees C. The global warming folks say the reason is for the exponential higher temperature change, is due to human activities human-generated greenhouse gases, including CO², which they believe is the primary greenhouse gas responsible for what is going on. That is well and fine. But when questioned about irregularities in the data. climate scientists seem to want to say the questioner is asinine and a denier of science. But the truth is there is uncertainty in both the data about past climate and the current climate models used to project future climate.    CO² isn’t the only greenhouse gas involved in all of this. We can’t just make calculations about doubling the amount of CO² in the atmosphere without taking amplifying or mitigating effects of all these other factors into the equation.    

This is where I come in:

The historic record in ice cores taken from Greenland and Antarctica shows that Earth’s climate has changed abruptly in the past and that means it could change rapidly in the future.  We can see clear indications of long-term changes discussed above, with CO² and proxy temperature changes associated with the last ice age and its transition into our present interglacial period of warmth. But we can also see there is a chaotic variation in the pattern. These temperature variations are very irregular. The unpredictability shows they are not part of the regular oscillations in the pattern. Rather, they look like rapid, decade-long transitions between cold and warm climates followed by long interludes in one of the two states. The best-known example of these events is the Younger Dryas cooling of about 12,000 years ago, named for arctic wildflower remains identified in northern European sediments. This event began and ended within a decade and for its 1000-year duration the North Atlantic region was about 5°C colder. This tells me, there are processes involved that don’t include just CO².  Most of us would surely agree, that what happened in the past can occur again. If that is indeed true, then we would have to agree that changes that happened in the past can occur again, with or without mankind in the equation.  IMO, yes humans are having an impact on a warming earth. But are we the main or sole reason? IMO No!

Water Vapor vs Carbon Dioxide:

As I said above, I don't believe the Earth warming all because of CO². There are just too many checks in the climate with destructive interference potential to allow CO² to have that much complete sway over the entire system.

Many who don’t buy into the greenhouse warming climate debate, believe the teleconnections are the reason for the warming. But teleconnections aren’t the root cause of the warming of the climate. The teleconnections are still there and work the same way, but we have to adjust and figure in the warming oceans, to reliably use them.  The oceans have warmed since the last PDO, this is especially true in the arctic. But that has is due to water vapor not CO².

We can clearly see when comparing summer and winter temperature anomalies. Because of the temperature to water vapor mixing ratio relationship, a rise in winter temperature is linked to the increase in water vapor, due to being a product of cyclically warm oceans. When we look at the summer temp anomaly, we don’t see the big spike since it would take a lot more water vapor to bring about warmer temperature anomalies during the summer. Without the summer spike in temperature, there is a limit on how much ice can melt overall.  If we can see a few winters in a row that have ice buildup due to a lack of summer melting, we would end up with a dramatic increase in ice thickness.

Why? Increased WV raises the base temperature of the planet overall in a distorted manner  

There is no CO² mixing ratio for the atmosphere. If you can’t construct a mixing ratio chart, there is no true way to see the exact CO² link. The link between water vapor and temperature is proven and verifiable, as is the fact that weather naturally directly responds to it.

There is no doubt that the Sun is the long-term climate driver, on the scale of centuries and millennia, on the Earth. But most of the heat comes from the oceans through the release of water vapor. The oceans contain 99.9% of the energy involved in the ocean/atmospheric system.  The oceans do release a lot of stored CO²; but they also release the lion’s share of the atmospheric water vapor.  Water vapor is by far the most abundant and important greenhouse gas in the atmosphere, not CO².  The oceans are in the driver seat, water vapor is directly linked to the natural cyclical processes produced by the warm oceans.

CO² is only a little more than 2 PPM higher than last year at this time, much of that coming from the world’s oceans. Dec. 6, 2021 atmospheric Co2 was at 415.41 ppm, last year on Dec. 7th it was 413.26 ppm. That is a 1 Year Change of 2.15 ppm (0.52%).  The more CO² the greater the likelihood for a greener Earth, to help take more of it out of the air.

The current debate:

 

Most of the time when talking about global warming, air temperature is used as the main metric. But in truth temperature isn’t the greatest metric when it comes measuring climate. But as I showed above, the saturation mixing ration is much better because it is much more precise. But that be as it may, the human caused global warming crowd uses air temperature so for the sake of this post so will I.

 

Here is a look at the temperature trends over the last several decades. These do in fact show the Northern Hemisphere is indeed warming.





While I’m not old enough to have lived through the 1950’s through the 1970’s, many of those who follow me on social media or on this blog are. Those of y’all who are old enough to remember, tell me how winter temperatures have changed, they tell me that back in the day, winter was generally colder, with cold lasting through the heart of winter, winters were much snowier as well. Those who preach at the church of global warming, gloss over a lot of that. Many in the GW crowd, imply that temperatures have been noticeably warming much farther back than the 1980’s. The question is how true is that in reality? We have to remember that there are many degrees (pun intended) when it comes to truth.   







   

Over the last 10 years, every major weather event is labeled as having global warming as the cause. If it’s too cold it’s global warming, if it’s too hot it’s global warming, strong hurricanes making landfall are due to global warming, not enough snow and ice, it’s global warming, too much snow and ice it’s global warming. It’s easy to win and prove your point when you control both sides of the field.  A warming planet, does have an impact on weather, take the December 10th -11th tornado outbreak. While climate warming didn’t cause the outbreak, it helped enhance the setup for the potential for stronger tornadoes.  This time of year, we’re transitioning to the wintertime pattern, which sees colder air in the mid and upper levels. At the same time, we can have warming in the lower levels, this is especially true for those closer to the Gulf of Mexico. In the case of this outbreak, we had that warm low level flow along with a more vigorous low level jet. All of this was ahead of the strong trough dropping out of the west.  This trough tapped into the dry air over the Southwest and Mexico. So as the low cut up toward the north and east, it dragged the strong cold front into the warm moist inflow off the Gulf of Mexico. So, while December outbreaks aren’t unheard of, they are rare. As a result of the dynamics I’ve mentioned, we had the prolific tornado outbreak.  With the SST in the Gulf of Mexico, above average, it helped enhance the parameters, leading to the what we saw happen. But before you say…So warming is behind all the severe weather across the planet… there are many instances where we see the warming temperatures have the exact opposite effect; this is very apparent when comparing the last few Atlantic hurricane seasons to the same seasons in the western Pacific. Tropical activity in the western Pacific  has been well below average and the storm track as been changed a bit more east . This is a result of the general placement of the cold pool and high pressure to the north.

 

When we look at the temperature anomalies in the lower atmosphere over the last several decades, we can see some interesting things.



We can almost divide that chart between pre-Super El Nino 1997-1998 and post-Super El Nino 1997-1998.  Before that El Nino, we went from a mostly cold with some warmth pattern, to on the whole a warm pattern with cold sprinkled in occasionally.  The oceans hold an enormous amount of energy. The majority of the Earth’s water vapor and for that matter CO² come out of the Oceans. Until just recently we had 200 years of high solar activity. Before that we had 200 years of general low solar activity. The oceans work on a time scale of decades and centuries. The atmosphere/ocean system takes time to build up to a change. We had strong/super El Nino’s in 1972-1973, 1982 1983, 1997-1998, 2015-2016.



Looking we can see how after the 1997-1998 El Nino, temperatures spiked, the following La Nina cooled things off a lot, but not enough. To me it looks like the water vapor release from the event led to a higher plateau when it came to world temperatures. We also see the super El Nino of 2015-2016 has resulted in a similar plateau spike. This all shows that it took a long time for all that water vapor to be distributed with the atmosphere adapting to the new changes. The warmer the temperatures get the less temperature increase we see, there is only so much gas in the tank.  So, the warmer the temperatures get the more energy it takes to keep it there. This is part of the natural balance the global system is always trying to achieve. So, when looking at the global temperature anomalies, we see the biggest changes in the colder and drier parts of the planet. We can see this when looking at the arctic.   During the arctic cooling season, we see the most warming, whereas, during the arctic warming season we only see slight variations in temperature rise. This distortion is part of the global system and how it reacts and adapts to water vapor.



 This also shows that up till 20-30 years ago, winters we’re generally colder. This supports the observations raised by people back in the 50-70’s that said winters then were quite cold.  

So yes, temperatures are increasing over time, and warming is causing weather to react. But it is all disproportional, as water vapor distribution is distorted. The system has a much easier time adapting to warming, than it does to cooling, due to the natural interference the system has built into it.  In spite of what global warming fanatics will tell you, we haven’t seen a lot of evidence that we have been quickly warming for the last 125 years. But over the last few decades as water vaper increased as evidenced by the plateaus shown in the global temperature charts it has. The system has numerous checks and balances built into it.  These are designed to keep things in overall check. There are limits to how warm it can get. The warmer the temperatures get the harder it is for the temperatures to become even warmer. If I’m right about water vapor being the primary greenhouse gas responsible for the warming, there is a limit to how much people kind can change things all that much. But that doesn’t mean we shouldn’t try to limit our contributions to a changing climate.    

 

 


Monday, November 15, 2021

How the 2021 hurricane season, matched up to my outlook.

 

The winter upper-level weather pattern is becoming well established. So, it’s time to put the summer and fall behind us.

Even through the official 2021 Atlantic Hurricane Season doesn’t end until November 30th, the tropics are quiet and another named storm is looking unlikely. So, I wanted to go over how the season basically went and how it compared to the hurricane outlook I released back in May.

The 2020 hurricane season:



First let’s look back that the statistics for 2020. Last year, saw the most active Atlantic hurricane season in recorded history, with a total of 31 tropical cyclones, 30 named storms, 13 hurricanes, and 6 major hurricanes. There were 11 storms that made landfall in the United States. The majority of those made landfall in the Gulf of Mexico with three of them passing through Arkansas. 2020 had the 2nd highest seasonal ACE in Recorded history, 2nd only to 1933. The season broke numerus records.

My call for 2021:

Named Storms 18-26, Hurricanes 6-13, Major hurricanes 3-6, U.S. landfalling tropical cyclones of 6-10. I called for an Accumulated Cyclone Energy (ACE) value of 140-190. In the Outlook I also said the Northeast was at a heightened risk for tropical cyclone impacts.



As of right now, the 2021 Atlantic hurricane season has seen 21 named storms, seven of which were hurricanes (Elsa, Grace, Henri, Ida, Larry, Nicolas and Sam).  The season had Four major hurricanes (Grace, Ida, Larry and Sam). Eight landfalling U.S. named storms. Ace is standing at 145.1, as of 18:00 UTC November 7.

The northeast had direct impacts from 4 named storms: Elsa, Fred, Henri, Ida. Henri made landfall on August 22, near Westerly, Rhode Island.

So, the season did fall within all the parameters I set back in the spring.

 A quick look at the 2021 season:

The beginning of the season started busy. While not as early as last year’s first storm, Arthur, Ana marked another early start to the Atlantic hurricane season, forming northeast of Bermuda on May 22. There were four named storms that formed in the month of June. The Atlantic Basin then shutdown for July, when no new storms formed. August saw the tropical Atlantic wake back up leading to five named storms forming. August included Major Hurricane Ida; she became a Category 4 borderline 5 and made landfall in the Louisiana.  Ida caused 115 deaths and more then $65 billion in damage. September is historically the busiest month of the hurricane season; that was surely the case this year. Nine named storms formed. Six of the nine storms only reached tropical storm strength. Stronger storms included Nicholas, Larry, and Sam. Sam was the most powerful hurricane of the season, reaching category four status with winds sustained at 155+ mph; I think Sam made it to Category 5, but that isn’t official. Luckily Sam made no landfall and eventually dissipated over the north Atlantic. November has had only one named storm so far. Tropical storm Wanda formed over the north Atlantic and dissipated a few days later.

Overall, the 2021 hurricane season was over active. But the intensity of the storms ended up being closer to average.  This year saw the entire official name list used. Making 2021 only the third time on record, behind the 30 named storms of 2020 and 2005’s 28 named storms that this has occurred. While we had 21 named storms, The ACE was only 145.1. ACE is the only true measure of a season’s activity. Most of the storms that formed this season were weak extremely short-lived storms.  Of the 21 storms, Larry and Sam made up the bulk of this season’s total ACE.   

I’ve seen the main stream media going on and on about how active this season was, I’ve seen some reports that said this is the 3rd most active Atlantic Hurricane Season on record.



But is that really true?

The most active Atlantic Hurricane Seasons based on named storms.

Rank   Year    Number of Storms

1.        2020 … 30

2.        2005 … 28

3.        2021 … 21

4.        1933 … 20

5.        2012 … 19

6.        2011 … 19

7.        2010 … 19

8.        1995 … 19

9.        1887 … 19

10.      1969 … 18

11.      2008 … 16

12.      2003 … 16

13.      1936 … 16

14.      2007 … 15

15.      2004 … 15

16.      2001 … 15

17.      2000 … 15

 

The active Atlantic Hurricane Seasons based on ACE.

1933 … 258.57

2005 … 250.1275

1893 … 231.1475

1926 … 229.5575

1995 … 227.1025

2004 … 226.88

2017 … 224.8775

1950 … 211.2825

1961 … 205.395

1998 … 181.7675

1887 … 181.26

1878… 180.85

2020 … 180.3725

2003 … 176.84

1999 … 176.5275

1964 … 169.7675

1932 … 169.6625

1996 … 166.1825

1886… 166.165

1969 … 165.7375

2010 … 165.4825

1906… 162.88

1955 … 158.17

1899 … 151.025

1980 … 148.9375

2008 … 145.7175

1966 … 145.2175

2021 … 145.1

 

Most people think of a hurricane season's activity based on the number of named storms. While that is a good metric to use, a season's true activity is measured by ACE.

ACE is a measurement of a hurricane season based on each storm's intensity and how long it lasts. Its calculation is a little cumbersome but it gives the best indicator of activity. is generally used to measure the combined duration and strength of tropical cyclones. It is also a good metric for scientists to compare storms against each other and across different seasons.

 ACE is calculated by squaring the storms wind speed in knots at six-hour intervals (advisory issue times), then divided by 10,000. For example, a 35-knot (40 mph) tropical storm for one advisory would have an ACE of 0.1225.

 So, while this hurricane season’s 21 named storms, places it 3rd on the list of named storms. It is only listed at 28 based on ACE. So, in spite of what several media outlets are pushing; it wasn’t really super active.

 




 

Sunday, November 14, 2021

Northeast 2021-2022 Winter Outlook Part Three

 


Here is the links for part one and part two.

 

Part two

  

The Days have been getting shorter and the temperatures have been getting colder. This time of year, many of y’all, want me to look into my crystal-ball, and try to give you a leg up on what might happen this winter. 

Please keep in mind, longer-range seasonal predictions often involve the broader picture of what’s to come. Outlooks like this cover the overall region. And don’t go into local detail, for individual in your back yard snowfall amounts. As we see every winter snowfall extent and amounts can vary greatly, over relatively short distances.

This outlook will be more in plain speak. Details on what teleconnections are and what they mean, can be found in part two.

The signals I use to try and figure out how things will be this winter are very mixed. So that is telling me this winter is going to see a lot of variability.    

If you don’t want to read through the entire outlook, you can skip to the bottom to the conclusion. But you will miss the reasons I decided on the end result.

 

 The analog seasons:

Over the course of this three-part outlook, I’ve been talking about analogs. Here is the list of analog seasons that I’ve settled on. 

1950 -1952, 1954-1955, 1989-1990, 1995-1996, 2007-2008, 2008-2009, 2010-2011, 2011-2012, 2017-2018, 2020-2021.

2010-2011 is triple weighted, and 2017-2018 is double weighted.

 








Teleconnections:


 Image from Tropical Tidbits.

La Nina…

During La Nina, we typically see the jet stream come out of Western Canada, dip across the Upper Midwest that then move somewhere over the Ohio Valley and then into the Northeast.  On average temperatures are warmer near the jet stream and south of it.  The Northeast pattern tends to be active.

This is a double dip La Nina, meaning this is the 2nd year in a row for La Nina.  2nd year La Ninas tend to be weaker than 1st year ones.

Some weather outlets are calling for an east based La Nina this winter, others are calling for a general Pacific Basin wide La Nina. The type of La Nina is important, as these variations can make for much different winter outcomes. Everything I’ve been looking at, has me thinking this is going to end up being a La Nina Modoki (hybrid La Nina) When we look at the subsurface temperature anomalies, subsurface temperatures are very cool, and look to be more west based. La Nina Modoki events are very rare, even rarer than El Nino Modoki. We had a La Nina Modoki in 1989. The winter of 2010-2011 was another La Nina Modoki.

If this does become a La Nina Modoki, it would tend to have the storm track a little farther north than when we see an east based La Nina.  This would setup the Northern Mid Atlantic region as the battle zone. This would mean the Northern Mid Atlantic and those close to it, would see a roller coaster of temperatures fluctuations that could vary from week to week. This could have large implications was to precipitation types during the winter.

We also see a lot of variability when it comes to La Nina, especially 2nd year La Ninas.  2011-2012 was a second year La Nina, that winter was dismal with warm temperatures and well below average snowfall.  But 2000-2001 was a second year La Nina that was the opposite.   So, while La Nina can be a big driver, we have to look beyond the ENSO.

 

Southern Oscillation Index…

I’ve been talking about the pattern change for quite some time. One of the teleconnections I watch, is the Southern Oscillation Index (SOI). When we see big changes in the SOI it can affect the North American pattern two to three weeks down the road. Looking at the chart we can see the SOI take a nose dive a little before Halloween. This is strongly connected to the very cold pattern setting up for this weekend into the rest of November.

 

Strong La Nina have SOI  30-day values up around the upper 20’s into the 30’s. The last moderate La Nina had the mid-teens to mid-20’s. So far this La Nina is barely making it into the 11’s. So right now, this is quite weak.  There isn’t really any drive here that is trying to push the SOI into a strong positive state.




So I’m thinking this La Nina is going to be weak, instead of moderate or strong.

 

Eastern Pacific Oscillation and Western Pacific Oscillation…

Right now, the EPO is positive and the WPO is negative. The ensembles are in disagreement as to where the EPO is heading, But I think the EURO has the better handle on things. The reason for backing the EURO has the do with the WPO. The WPO is strongly negative. The ensembles are in rough agreement that the WPO will stay primarily negative as we move into the first half of Winter.   The WPO typically rules the roost with it comes to EPO. A negative WPO tends to force the EPO back to negative during those times the EPO becomes positive.

 





 Images from WeatherBell.


The North Pacific Oscillation…

The PDO is important because La Nina is located in the Pacific and will be a driving force.  This PDO is Negative and on average that tends to drive colder air to the Eastern US.

 

Quasi-Biennial Oscillation…

Right now, the QBO is negative. Typically, when the QBO as negative in November, along with winters that experienced a weak La Nina. The QBO stayed negative for December into March.  When this is Negative during a Moderate La Nina, we tend to get more snow.

 

The Pacific North American Pattern…  

The PNA is currently slightly negative, if we want abundant cold air this isn’t a good thing.




When the PNA is negative we tend to see a zonal (west to east) flow over the northern CONUS. The positive phase leads to a meridional (north to south) flow.

The Positive Phase brings warmer/drier weather to the West and colder/wetter weather to the East.

The PNA also reflects the strength of the Aleutian Low.

 


 

Cold Pool in the Gulf of Alaska:

Typically, during a La Nina, we tend to see an area of 500mb low pressure stubbornly stay over the Gulf of Alaska.  This kind of setup makes it hard to get much in the way of cold infiltrating into the eastern half of the CONUS, as we end up with a negative PNA. We will have to watch to see if it can be replaced with ridging during the winter or at least shift enough Southwest of the Aleutian Islands to allow more of a positive PNA. The placement of the cold Pool is indicating that we might see the low pressure break down or move more to the southwest. This would lead to a better chance for cold air into the East do to a positive PNA.  

For true cold air in the wintertime into the central and eastern CONUS; we need a snowpack over a large part of Canada. This would help break down the Low in the Gulf of Alaska.  Otherwise, it is very hard to have polar and arctic airmasses drop into the CONUS.  This goes back to the zonal flow I was talking about earlier, where you get milder Maritime Pacific and Continental airmasses.

The cold pool reaches the Aleutians and south of there. This means we should see a western ridge develop, as the western trough moves west. This would increase the odds of a trough developing into the Midwest and Northeast, leading to cold air trying to overwhelm the pattern for December into the early part of January.  

 

 

Eurasian Snow Cover / Arctic Sea Ice Extent:

Two other teleconnections that I use are Eurasian snow cover, and arctic sea Ice extent during the month of October. The use of these two has fallen out of favor in most outlooks. But I still use them as there is a weak correlation between them and overall winter weather here in the Northeast.

Eurasian Snow Cover…






From the graph of the Eurasian snow cover trends leading into the Northern Hemisphere winter from 1967 to 2021. This chart is showing the snowfall extent during the entire month of October 2021. From the graph above, you see, overall, we’re running on the lower side of average. The winter of 2017-2018 had slightly less snow extent. Generally, the lower the Eurasian October snow extent, the milder the East Coast winter.

On average the more area snowfall coverage in Siberia in October, leads to better chances for colder winters on the East Coast.

 

Sea Ice is another thing I look at in October

Sea Ice Cover…

 






Average monthly air temperatures were well below freezing across much of the Arctic Ocean in October. As a result, the sea ice extent has been quickly growing, and by the end of October, ice covered most of the Arctic Ocean. Overall, the ice extent remained below average for this time of year in the Barents and Kara Seas, as well as within northern Baffin Bay and the East Greenland Sea.

In October, the sea ice extent ended up higher than any year since 2015, as well as higher than observed in 2007, 2011, and 2012.

As has been the case for many recent years, sea ice has been running below normal, in many cases due to long-term warming global temperatures. Although still under a degree of research, there is a correlation that shows generally the less sea ice present in the area of the Barents-Kara Sea, east of Greenland, moving into the winter season, the greater the likelihood of cold snaps over North America as the polar vortex swoops in every now and again.

Stratospheric Warming:

 I’ve been talking about the Sudden Stratospheric Warming (SSW), that just occurred and the one that looks to take place sometime in December. If we indeed see a December SSW it would correlate with the cold December idea I’ve been floating around for the last few months.

Climatology:

The Hurricane Season…

There is some correlation between Hurricane activity in the Atlantic Basin and the following winter.

looks like 2011 was the best analog. Especially with how the season shut down.

2004 and 2007 are also both good examples of seasons that significantly slowed down after September. In 2004 the early season was quiet, but the months of August and September combined produced 12 Named Storms, 9 Hurricanes, 6 Major Hurricanes. After that there were only 3 marginal, short-lived storms.

2007 was similar to 2021 in that there were lots of weaker tropical storms. September had 8, but almost the whole month of October elapsed before Hurricane Noel developed at the end of the month.

This year we had Hurricane Sam, which racked up a lot of ACE points, we also had Tropical Storms Victor and Wanda, these helped to redistribute heat from the tropics into the North Atlantic.  I feel this will help make it more likely for a negative NAO, leading to a better chance for North Atlantic Blocking to support cold air for at least the first part of winter.

 

The Warm Fall…

 

October has been very warm overall.  The last couple of days have been cool. But the month as a whole, is one of the warmest Octobers in the Northeast over the historic record.



When we look at past years that had similar patterns to this one, we come up with a front-loaded winter, like I’ve been talking about over the last few months. 

Winters after a wet October tend to see above average snowfall across New York State and New England.  Throw in the Warm Summers and we even greater chances for average to above average snow.

This has been a wet fall, on average very wet Octobers tend to be during La Nina’s. This coronation is likely because the pattern is telling us we’re going to see a lot of activity.

On average Warm Summers and Falls when added to La Nina. 

Some of these occurred in:

1955-1956

2005-2006

2016-2017

 

Cold Mays…

There is a moderate relationship between cold Mays and years that had an active hurricane season, lead to an early start to winter in the Northeast and Middle Atlantic.

Years that had cold Mays, Warm Octobers, and Octobers that had an SSW event.   1950,1954, 1955, 1960, 1979, 1989,1995. Those winters had cold Novembers and Decembers.

 


Lake Effect…

Every year the lake belts deal with lake effect.

We’ve been very warm overall, so Erie and Ontario are very warm.  Right now, the Lower Lakes are about 4-5 degrees warmer than what is considered average for November.  Right now, Lake Erie has water temperatures of almost 59 degrees, the warmest on record, more than 4 degrees above average. Lake Ontario water temperature is at almost 57 degrees, the warmest on record, more than 5 degrees above average.

Does that mean, everyone near Lakes Ontario and Erie will see huge snowfall events? In answer, that depends.

Which leading us to The Big Question: Will these warm water temperatures play a role in increasing lake effect snow in early winter?

First, the actual water temperature isn't the prime factor when it comes to lake effect snow.  It’s the difference between the lake water temperature and the air temperature of the colder air moving over the lake surface.

Typically, as we approach winter, the water temperature begins to drop at roughly the same rate in September and October regardless of the highest water temperature reached during the summer. This year the fall was very warm, so the lakes stayed a little warmer later into the year.  But by the time we get into December, the water temperatures will likely cool off back to around average.

So, while the lake is primed, lake snow is all about potential.   Things have to line up. We need the timing of the cold air incursions and the storm tracks to a line; Also, the Wind direction has to be right, so areas that depend on lake snow can see large variability within the typical snowbelt areas.

The pattern does support several shots of cold air over the next few weeks. So, those downwind of Lake Erie and Lake Ontario are at risk for heavier lake effect snow events during the early season.

 

Solar:

When dealing with the long term, the sun is the main driver of weather and climate on the planet.  We’re just coming out of a solar minimum. During the winter, solar activity should stay at relatively low levels.  Low solar seems to favor a persistence for more in the way of high latitude blocking. With higher-than-average geopotential heights around Greenland and Iceland.  The Great Lakes and East Coast tend to see more in the way of cold air intrusions during low solar winters, which increased the odds of seeing more snow.

 

Storm Tracks:

The storm track pattern for this winter…

Typically, during La Nina winters we see many storms cut to our west and move over the Great Lakes. Most of us know a storm cutting to our west places the Northeast and Mid-Atlantic in the warm sector.

The developing pattern supports the idea for at least a few Miller-B events. A Miller-B means a storm that approaches the Northeast, and then transfers its energy to the coast.  These types of storms tend to impact eastern New York State and New England more than they do the Middle Atlantic and the rest of the region.

In October we had to early season nor’easters. Giving the setup that looks to set up would tend to favor a more easterly track for coastal storms. But if we can get blocking which lines up with a coastal storm track. If this happens the Mid Atlantic into southern New England could end up with at least one big snow event. If my idea of a La Nina Modoki setting up, would make the chance for a few coastal storms having at least some impacts. 

Behind these storms we typically see cold air outbreaks, where Clippers can provide light to moderate snow events.

 

Conclusion:

December…

The reasons I’ve shown above, support the idea of an early start to winter, that I’ve been pushing for a while now.  We’re into Mid November and the pattern has already flipped to one that is overall cold for this time of year. December looks to be very cold overall. December looks to be very snowy as well. 

 

January…

The CPC is expecting the La Nina to peak mid-winter. But there are signs that the La Nina may peak before then.  So, I believe January will end up overall mild. The pattern will still be very active, with most of the storms cutting up through the Great Lakes. There could be a few Miller-B storms that end up forming, but these would likely miss the Mid Atlantic, but could favor New England with a snowstorm or two.

 

February into March…

February is the month; I’m having the biggest trouble with.  I believe it will start out with above average temperatures. But as we get past mid-February, we could see some colder air try to move into the Northeast and Middle Atlantic. But overall February will be a warm month.  On average the month of February, has the region seeing their best opportunity for storminess.  But with the southeast ridge pushing north, it would come down to timing of events as to which kind of P-type we end up with.   March will likely see a continuation of the general February pattern. As the La Nina should be starting to fade, we would be relining on other teleconnections to play a role, but the area will likely see March with overall slightly below average, which would be similar to the last several winters. So we could see some storminess that leads to increased snow chances for the end of February into March.  

 

So, this winter is going to be somewhat similar to last winter, but with a bit more bite to it when and where it does get cold and snowy, it also looks erratic with changeable jet stream patterns over the December through March period, more so than last winter.

 

My overall idea for snow amount and temperature across the region…

For the Northern Mid-Atlantic region, the pattern supports the idea of an overall above average winter when it comes to temperature. This winter will see a very active pattern. As I said earlier this area will be where the battle ground sets up between the colder air to the north and the warmer air to the south. While the general storm track won’t be favorable for a giant snowstorm, it does feature a good chance for small to medium storms. So, while I think the overall precipitation amount will be above average; the warmer overall temperatures will increase the odds for more rain and ice events as opposed to snow events, so overall seasonal snowfall will likely end up 75%-90% of average.

 For Pennsylvania into western New York State and the Southern Tier along with Southern New England… This part of the region will likely see overall temperatures slightly above average. But with overall temperatures closer to average, this area will likely see conditions similar to last winter. With an active storm track, snowfall will likely end up slightly below average to slightly above average. so overall seasonal snowfall will likely end up 90%-110% of average.

For the rest of New York State and New England. This part of the Northeast will likely end up with overall temperatures slightly below the 30-year average. With the pattern that looks to setup I’m thinking overall snowfall will end up being 100% to 130% of the average.

As far as lake effect, the traditional snowbelts should end up with an average to above average year. Inside the lake snowbelts, snowfall can very greatly over very small distances.




  

Some outlets change these seasonal forecasts has conditions change during the season. But I don’t like to do that. I release an outlook, and I live with it. I don’t know how it will work out until the end of the season.

Well, that’s it, I put a lot of thought in this and tried to find a balance between the conflicting signals. Remember this is showing the overall snow and temperature for the entire winter. There can also be variability inside the general three areas found on my maps.