So why did more snow accumulate and glaciers advance during the cold of the Lttle Ice Age??
Trenberth’s 1999
paper framing the effects of global warming on extreme precipitation
declared, “With higher average temperatures in winter expected, more
precipitation is likely to fall in the form of rain rather than snow, which
will increase both soil moisture and run off, as noted by the IPCC (1996) and
found in many models.” The 2001
IPCC 3rd Assessment repeated those expectations stating,
“Northern Hemisphere snow cover, permafrost, and sea-ice extent are projected
to decrease further.” Soon climate scientists like Dr. Viner proffered alarming
scenarios that ‘children would no longer know what snow was’. Similarly in 2008
politicians like RFK Jr. warned DC children would be deprived of the fun of
sledding due to global warming. But our climate naturally oscillates and by
early February of 2010 Snowmageddon
was blanketing the USA’s eastern seaboard with record snows, making global
warming predictions the butt of many jokes. The heavy snows didn’t disprove CO2
had caused any warming, but it definitely highlighted failed predictions.
In 2011 Chris
Mooney writing for the DeSmog blog noted heavy snowfall had become a
“communications nightmare” for global warming theory and urged, “We need to
move the public to a place where drawing a warming-snowstorm
connection isn’t so challenging”. Kevin Trenberth was already on point. Just
two weeks after the 2010 Snowmageddon, Trenberth appeared in a NPR interview
flip-flopping to a new climate change framework in which a “Warming Planet Can
Mean More Snow”. Now he argued, "The fact that the oceans are warmer now
than they were, say, 30 years ago means there's about on average 4 percent more
water vapor lurking around over the oceans than there was, say, in the 1970s”.
Thus “you can get dumped on with more snow partly as a consequence of global
warming," A year later the Union of Concerned Scientists held a press
conference asserting global warming was no longer causing less snow, but
causing heavier snow. And now, every year as heavy snowstorms approach,
Trenberth and his well-groomed media outlets bombard the public, urging them
not to be misled by their senses, but trust that cold and snowy days have
worsened due to global warming.
Trenberth
bases his warmer-earth-more-cold-and-snow alchemy on the Clausius–Clapeyron
relation stating, “the water holding capacity of the atmosphere goes up
exponentially at a rate of 7% per degree Celsius.” Indeed the Clausius–Clapeyron
relation is undeniable physics. The problem is Trenberth misapplies it. First as
seen in the graph below from the peer-reviewed paper Weather
And Climate Analyses Using Improved Global Water Vapor Observations,
there is little evidence of a steady increase in total precipitable water vapor
(TPW) ever paralleling rising CO2. The important question Trenberth never asked
was, “if TPW has declined since 1998, has there been no warming since 1998?”
Indeed in accord with less water vapor, several top climate scientists have
reported a global warming hiatus over the same period and the Climate Reference
Network reports no warming trend over the USA for the past decade. Furthermore,
ocean temperatures were in agreement. Based on Argo data a consensus
of scientists reported heat content in the upper 300 meters of the ocean
had “increased from 1984 to 1992 followed by a short cooling episode in
1992/93, and then increased from 1994 to 2003/2004, followed by flattening or a
decrease.” Note the decline in water vapor from 1992 to 1994 and the decline
since 1998 coincides with those ocean temperatures. All things considered, the
uptick in heavier snow since 2009 cannot be explained by Trenberth’s new normal
“warmer and wetter” assumption.
“Old school” scientists seek to understand causes of extreme
events by examining changes in atmospheric circulation and other contributing
weather dynamics. In contrast Trenberth does not want scientists to use the
standard null hypothesis to test if CO2 warming was a contributing factor. He
simply assumes CO2 must be and accuses
other researchers of erroneously accepting the standard null hypothesis
indicating no effect from rising CO2 (type 2 errors). Based on pure
assumptions, he wants to allot some portion of every extreme event to rising CO2,
even when an no anthropogenic signal emerges from standard scientific analyses
and modeling experiments, as discussed in part
1. According
to Trenberth, due to the dominating effects of natural variability,
CO2-driven climate models do a very poor job of simulating large changes in
atmospheric circulation. While one model run will force large changes, the next
model run will not. To side step that problem, instead of asking if there have
been trends in atmospheric and oceanic circulation changes that produced
snowfall extremes, Trenberth wants researchers to simply ask, “Was it [snowfall] related to higher than
normal SSTs off the coast or farther afield” and then assume those higher
temperatures were partly due to rising CO2. But that’s bad science. Higher than
normal sea surface temperatures often have no connection to any theoretical CO2
heating. Warmer sea surface temperatures associated with a storm can be solely
caused by a redistribution of warm water during an El Nino event. A shift in
the North Atlantic Oscillation, or a shift in the jet stream
can reduce wind fields and warm sea surfaces because weaker winds ventilate
less heat and reduce evaporative cooling. Elsewhere shifts in atmospheric
circulation can reduce cloudiness and increase solar heating.
Global Water Vapor trend from Vonder Haar 2012 |
Trenberth has reported that 70% of the moisture involved
in a storm is typically in place at the beginning of the storm, suggesting
global warming has increased the available moisture. But again observations do
not support Trenberth’s simplistic “warmer and wetter” attributions. For
example in the 2011
Groundhog Day Blizzard the amount of available water vapor was far below
normal as seen in the diagram posted by meteorologist Joseph
D’Aleo at WUWT. So another question Trenberth’s attribution studies must
ask, “where does the moisture come from for an extreme snow event when a region
is not “warmer and wetter?”
Still there are many useful questions that can be asked to
determine if the affects of climate change have exceeded the boundaries of
natural variability. For example, do
similar extreme snowfalls happen independently of sea surface temperatures that
are warmer or cooler than normal? That question is easily answered from a
historical perspective that encompasses just 100 to 150 years. Historical extremes like the Great Blizzard of
1888 dropped very similar amounts of snow on America’s northeast, despite a
very different climate background with colder ocean temperatures from the
Little Ice Age and extensive Arctic sea ice. Comparing the Great Blizzard of
1888 with Snowmaggedon, higher than normal SST temperatures do not appear to be
a critical factor.
To separate natural weather dynamics from climate change
scientists must also establish why snowfall varies greatly over small
timeframes; timeframes that are too short for CO2 to hypothetically alter ocean
temperatures. As anyone having lived in New England knows, during any given
winter the depth of snowfall is totally dependent on 2 crucial factors: 1) how
fast the storm moves along the coast and 2) how far from the coast the storm
travels. Unquestionably slow moving storms cause the most extreme precipitation
events, rain or snow. For the American east coast, colder than normal
temperatures south of Greenland encourage more frequent blocking ridges of high
pressure, and those blocks cause storms to slow down and even stall. These
“Greenland blocks” were also responsible for Superstorm Sandy’s sudden shift
back towards the coast.
Greenland blocks are more common during negative phases of
the North Atlantic Oscillation (NAO), a phase that has coincided with the
recent rise in heavy snowstorms. So we must also ask if global warming has
affected a shift to the negative phase of the North Atlantic Oscillation (NAO)?
But previous research had suggested increased CO2 promoted a more positive NAO
during the latter decades of the 20th century. Within a framework of
a single year or a few decades, shifts in the NAO are often associated changes
in snowfall. But if we ask if climate change altered trends in a given NAO
phase, researchers report in the paper Need for
Caution in Interpreting Extreme Weather Statistics, “no significant changes
either in the mean or in the entire PDFs [Probability Density Functions]” of the
NAO index over the last 140 years.
As
illustrated in the diagram below, the positions of cold air masses on land and
warm air masses over the ocean determine where precipitation falls as snow or
rain. For example during the Blizzard of 2013, despite being surrounded by warm
ocean waters Nantucket
Island received the least amount of snowfall (6.3 inches) while further
west Providence Rhode Island (18 inches) and Hartford, Connecticut (22.8
inches) surrounded by a colder air mass received record snow. For snow to form,
moist warm air must be raised to an altitude where temperatures are below
freezing, with an optimal snow forming temperature hovering around -12 degrees
C (10F). Typically a cold air mass
(or mountains) forces the rise in altitude. According to the Clausius-Clapeyron
relation, air at 31 degree F can only hold a given amount of moisture, no
matter how greatly the global average temperature varies. The critical factor
that determines how much snow will accumulate is the temperature of the air
nearer the ground. If lower air layers are warmer than 0°C (32F), the snow will
melt as it falls forming rain, freezing rain or sleet. Only where the entire
air column is below freezing do we get snow. If the storm track moves too far
out to sea, or if the cold air mass is to far inland, the warm air mass gets
less lift, and much less snow forms. Thus to attribute the cause of extreme
snowfall a scientist must also ask, “what was the position of the storm track?”
And how much cold air was in place?
Trenberth
cavalierly suggests that it’s always cold enough to snow in winter, but that
that is misleading. For blizzards to occur sufficient cold air must already be
in place and that is not a given. Dips in the jet stream and storm tracks
across North America pull cold Arctic air southward along the storms trailing
edge. To produce Snowmageddon blizzards along the east coast, enough cold air
had to reach the southeast and overflow the Appalachian barrier where it is
dammed up along the coast (Rauber
2005). The snows that reached Jacksonville Florida in 2015 were the result
of a stronger than normal flow of cold air over the Appalachians. Similar to
“lake effect snow”, after flowing over the ocean, the cold dry air picked up
enough moisture to dust Jacksonville with light snows.
Accordingly the National Snow
and Ice Data Center experts tell us, “While it can be too warm to snow, it cannot be too cold to snow. Snow can
occur even at incredibly low temperatures as long as there is some source of
moisture and some way to lift or cool the air”. In contrast, Mooney
relays Trenberth’s message contradicting those experts stating, “Heavy
snows mean the temperature is just below freezing, any cooler and the amount would be a lot less.”… “Warmer waters off
the coast help elevate winter temperatures and contribute to the greater snow
amounts. This is how global warming plays a role.” Why would Trenberth make that up?
Dips
in the jet stream and stronger storms capable of pulling an abundance of cold
Arctic air equatorward are often associated with the negative phase of the
North Atlantic/Arctic Oscillation (AO). Although December 2015 had been mild,
when weather forecasters recognized a shift to the AO’s negative phase in early
January 2016, they
correctly predicted conditions would be just right for the Blizzard
of 2016 that buried the mid-Atlantic States in 2 feet of snow 2 weeks
later. So to explain contributions of extreme snowfall, scientists must ask how
do natural cycles of the North Atlantic/Arctic Oscillation contribute to
extremes.
As would be predicted by a shift to more frequent negative
phases of the NAO/AO, the USA was experiencing greater incursions of cold
Arctic air that promoted both more record low temperatures and greater
snowfall, as was the case in the 1960s and 70s. Despite projections
by CO2 driven models that the ratio of record high temperatures would
exceed record low temperatures by 20 to 1 in 2050, in 2013
and 2014
record low temperatures exceeded record highs. However to counter such
contradictory observations, Trenberth pushes another unscientific and
non-falsifiable explanation. Suggesting risingCO2 was preventing extreme cold
that he claims reduce snowfall, Trenberth submitted,
“below normal
temperatures can be fully consistent with climate change but are likely warmer
than they otherwise would have been.”
Winter storms are low-pressure systems, or cyclones, that
spin in a counter-clockwise direction as they travel across North America. Most
winter cyclones in North America are initiated by the curvature of the jet
stream as it passes around the Rocky Mountains, or curve northward along the
eastern seaboard. The North American topography favors two major storm centers
in western North America. One lies just east of the Canadian Rockies where
“Alberta Clippers” form. Clippers are fasting moving storms. Typically they
will not produce record heavy snowfall because the moisture supply flowing into
northern North America is relatively low and the Clippers’ swift passage does
not allow for sustained snow accumulation. However Clippers can evolve into
major storms over the Great Lakes or eastern seaboard where moisture is
available or when they align with storms initiated by the subtropical jet
stream. The other storm center lies just east of Colorado. These storms often
gather more moisture from the Gulf of Mexico and are slower moving. Typically
these storms deliver heavier snowfall.
Of importance to east coast snowfall, either storm type will pull cold
Arctic air southward and eastward toward the coast, setting the stage for
greater snowfall totals from the next storm. In fact it was an Alberta Clipper
that set the stage for the east coast Blizzard
of 2015.
When storms track along the east coast, they intensify due to the sharp contrast between warm Atlantic temperatures and cold land temperatures. The sharp contrast favors “explosive cyclogenesis”, a phenomenon that is most common along the Gulf Stream and along the Kuroshio Current and promotes extreme snowfalls in New England and Japan respectively. In addition to the land-sea contrast, there is also a steep temperature gradient over the Atlantic due to the warm Gulf Stream. Along the coast of North Carolina in February, coastal waters are typically 10 degrees C (50 F), while just 130 kilometers to the east, Gulf Stream waters register 22 degrees C (72 F) Reddy 1994. In addition to the heat and moisture evaporating from warm Gulf Stream waters, winter storms travelling up the coast will pull warm moist tropical air northward in what is called the “warm conveyor” as illustrated below in the Washington Post illustration of the 2015 blizzard. Notice the head of the storm’s “comma” shape is an area of extreme snowfall, where the storm had pulled warm and moist air northward and westward which then rose over the colder air already in place from previous storms.
Nevertheless ignoring all the potent weather dynamics that
naturally drive anomalously warmer sea surface temperatures ahead of a storm,
Trenberth emailed his favorite media outlets Joe
Romm, Chris
Mooney and others to assert, “At present sea surface temperatures are more
the 2 degrees F above normal over huge expanses (1000 miles) off the east coast
and water vapor in the atmosphere is about 10% higher as a result. About half of this can be attributed to climate
change.”
Was this 50% contribution ever scientifically tested and
peer reviewed? Did Trenberth determine “how much warmth was transported
northward on the warm conveyor side of the storm?” Did Trenberth ask how much
warmth was picked up from the Gulf Stream and carried westward to cooler
coastal waters? Did the storm temporarily reverse the latitudinal temperature
gradient? Trenberth’s untested opinion of a 50% contribution attributed to
rising CO2 was simply an opinion. It was an opinion pushed to satisfy the “need
to move the public to a place where drawing a warming-snowstorm connection isn’t so challenging” and thus protect
the global warming theory.
More yellow journalism followed a few weeks later in
Mooney’s “What
the massive snowfall in Boston tells us about global warming”. Keeping the
focus on global warming Mooney reported, “sea surface temperatures off the
coast of New England are flashing red”.
Michael Mann added to the global warming meme reporting, “Sea surface temperatures
off the coast of New England right now are at record levels, 11.5C (21F) warmer
than normal in some locations.” But Mooney, Mann and Trenberth were not
interested in discussing the details of those fleeting warm anomalies. They
never considered the warm conveyor delivered above normal warmth northwards and
then dragged that warmth and Gulf Stream warmth westward. They never tell us
how fleeting those warm anomalies were. Yet for the month of February 2015
temperatures on land and sea were all several degrees colder than normal as
seen in the illustration by CBSBoston’s
chief meteorologist. It was extreme cold that intensified the storm. And
despite below normal sea surface temperatures and thus below normal water
vapor, the storm gathered enough moisture and Boston experienced
record-breaking snows.
Trenberth has now revised his 1999 framework. Despite the
record cold that reduces water vapor, he still argues global warming causes
more snow in winter. He maintains warming will still cause more rain and
reduced snow in the fall and spring. But again the evidence contradicts his
claims. Although Trenberth focuses public attention on a decreasing trend in
spring snow extent, like the winter, there has also been an increasing trend in
autumn snow extent as seen in the graph below from Rutgers
Global Snow Lab.
So why does Trenberth persist in claiming extreme snowfalls
are due to a warmer and wetter world. Trenberth betrays his intentions when he
writes, “The main way climate
change is perceived is through changes in extremes because those are outside
the bounds of previous weather. Climate change from human influences is
difficult to perceive and detect because natural weather-related variability is
large. Even with a significant climate change, most of the time, the weather is
within previous bounds.” So Trenberth has organized a media campaign to not
only overturn the null hypothesis, but to reverse our understanding of the
difference between climate and weather. He wants you believe every extreme
weather event is worsened by CO2, whether or not there is any evidence.