Real-time Weather-Climate Discussion and Predictive
Insights Edward
Berry, NWS and Klaus Weickmann, ESRL/PSD
Since our last discussion ( Latest
CPC MJO Discussion and tools Part 1.
Weather-Climate Overview Figure 1 (below)
shows a time-longitude section of near equatorial SSTA
for November 2004 to the present. The life cycles of the 2004-05
central
Pacific warm event (denoted by "EN"), the weak
2005-06 La-Nina ("LN") and the recent evolution toward basin wide
El-Nino conditions are seen. See past
weather-climate discussions for details on the earlier warm and cool
events. There has been a biennial component to the recent ENSO
cycle
with warm events during 2002-03, 2004-05 and now 2006-07. Consistent
with this quasi-periodicity, the recent warm event developed quite
rapidly, surprising climate scientists who typically expect a slower
3-4 year ENSO cycle. The persistent warmth in the Indo-Pacific
warm pool in recent years (+1.0-1.5 sigma anomalies), and especially
east of 140E since ~July 2001, has maintained the climate system in a
precursor El Nino state for much of the time. The period since 2001 is
comparable to the January 1990-July 1995 period, which also saw
weak-moderate basin-wide warmings every year or two. The increased
temperature of the
warm pool presumably reflects "global warming" and seems to be having
an
impact on the behavior of ENSO. Finally we note that
the rapid sequence of these subseasonal convective events, with little
suppressed convection in between, can also be viewed as a single, slow
eastward propagating feature, especially if monthly averaging were
performed.
Nevertheless, two distinct oceanic Kelvin waves were excited by the
sequence as shown by the March and May wind events (not shown). Now we review the
last year's variations in the global circulation. Figure 4 shows a
contour plot
of vertical and zonal mean anomalies of relative atmospheric
angular momentum (AAM, top panel) and a time series plot of the
global mean AAM (bottom panel).
Consistent with the ENSO cycle (see bottom panel), AAM is low during
the La Nina of 2005-06 and has been increasing since that time.
However, a substantial portion of the global increase comes from the
stratosphere and is due to westerly phase of the QBO, which peaked in
~July-August 2006 .
The top panel shows a prevalence for easterly (or negative) AAM
anomalies (green/blue colors) in the tropics and subtropics with some
evidence for poleward movement. At the same time, westerly AAM
anomalies (yellow/orange colors) developed abruptly in equatorial
regions in late January 2006 and have dominated the deep tropics,
especially over the northern hemisphere, since late June 2006. Recently
the westerly anomalies moved to the northern subtropics in association
with the September-October MJO. There are many other cases of poleward
movement of anomalies on subseasonal time scales that have been
detailed in previous discussions. Eventually, subtropical
westerlies are expected to intensify and persist when convection
becomes established over the central equatorial Pacific in association
with the current El Nino. Fig. 6 is a
sequence of daily mean 150mb vector wind anomalies during flareup #1
when convection first developed over the Indian Ocean. The
number on each plot depicts the location of the flareup, which began on
the equator
~ 4 September. The divergent outflow from the
convection interacted with a baroclinic wave train moving
through Asia, so by September 10 Rossby wave energy
dispersed eastward through an intense anticyclone northeast of Japan to
a cyclonic anomaly south of Alaska.
By September 14 additional wave energy tracked across Asia to the
now amplifying anticyclone across Alaska. A low over
the Gulf of Alaska four days earlier was forced inland into the USA
Pacific Northwest. At the same time, twin anticyclones and
easterly flow on the equator developed over the Indian Ocean with
downstream twin cyclones across the west Pacific as the circulation
responded to the persistent convection. By the 15th the trough over the
Pacific northwest was digging southward along the USA west coast.
During this period there were also weaker flare-ups occurring
across the warm date line SSTs. The divergent outflows from the
central Pacific forced a
subtropical jet that interacted with the western USA trough. This
combination contributed to an outbreak of severe
local storms across the central part of the
country. Finally, as the MJO moved east-northeast, wave trains
combined
across the central Pacific and led to an extreme weather event
involving baroclinic cyclogenesis across western Kansas on September
21 (not shown). Fig. 7 is a
sequence of maps depicting the total
surface wind during October 1-5, approximately the time of flareup #2.
MJO convection had now shifted eastward to the west Pacific and twin
surface cyclones developed there on 1 October. These low level twin
cyclones were the first sign of the westerly wind burst shown on Fig. 5
that subsequently initiated the oceanic Kelvin wave still moving along
the east Pacific thermocline at the time of this writing. By 5 October,
the northern low had moved poleward toward Japan and interacted with
wave energy dispersing
from eastern Asia. Figure 7 (Total surface vector wind for the dates
shown.)
Figure 9 (Daily mean 250 mb vector wind anomalies
for the dates shown.)
Part 2.
Predictive Insights
In these discussions a Global
Synoptic-Dynamic Model of subseasonal atmospheric variability (GSDM) is
utilized as a framework for real-time monitoring, and to help evaluate
model predictions and assist
with the preparation of week 1-3 forecasts. The
GSDM organizes the interactions of four subseasonal time scales into a
sequence of repeatable events. The MJO provides the primary
oscillatory component while teleconnection patterns, monthly
oscillations and synoptic scale wave energy dispersion contribute
additional time scales. The global and zonal earth-atmosphere angular
momentum budget
(AAM) is used as a dynamical framework for the GSDM. The GSDM
consists of four stages with Stage 1 having low AAM, Stage 2 having a
positive AAM tendency, Stage 3 have high AAM and Stage 4 have a
negative AAM tendency. GSDM Stages 1 and 3 tend to be more persistent
while Stages 2 and 4 are generally transitional. Focusing on North America during
Northern winter, the synoptics of GSDM Stage 1 include split
mid-latitude flows
across the North Pacific and Atlantic Oceans and combined flows over
Asia
and North America, as is also typically observed during La-Nina events.
This situation favors a negative phase of the PNA with western
USA troughs and an active southwest flow storm track including possible
high impact weather events across the
Plains during winter and spring.
During GSDM Stage 2, a west Pacific wave train linked to a large
amplitude ridge just
off the North American west coast into Alaska is probable. High
impact weather includes outbreaks of bitterly cold
Arctic airmasses targeting the central USA. GSDM Stage 3 is
characterized by an anomalously extended and southward displaced
jet from East Asia to the west coast of North America, with split flows
over the continents. As during El Nino, a positive phase of the
PNA and/or negative
TNH is favored. Often
the USA west coast and Deep South can be the target of extreme
precipitation (including severe thunderstorms) and high wind events.
During GSDM Stage 4 zonal mean westerly flow
collapses throughout the subtropics, leaving individual subtropical
jets, including one which impacts the USA Desert Southwest.
Locations such as Arizona into Colorado may receive excessive
precipitation during Stage 4.
See this link
for our accepted MWR paper that discusses the GSDM (in
press) Daily wind animations show that a
recent Rossby wave energy dispersion linked to the MJO arcing into the
Southern Hemisphere extratropics contributed to the flare-up of the
South Pacific tropical convection roughly a week ago. This region of
forcing has been expanding back to the west-northwest toward the
Philippines during the last few days. Moreover, convectively
coupled Kelvin waves emanating from the MJO along with the expanding
date line/South Pacific convection have allowed some filling in to
occur between the 2 regions (working against suppression). Twin
upper tropospheric anticyclones supporting cross equatorial flow from
the Southern Hemisphere are also present around the date line, allowing
the linkage of a subtropical jet with the trough currently moving
into the western USA. GSDM Stage 4 best describes the
weather-climate situation for roughly the past couple of weeks.
However, a transition to GSDM Stage 1 may be in
progress. For instance, animations show the recent Kamchatka block
has become "dislodged" tied to Rossby wave energy
dispersion from the IO convection. As shown by most models (but with
large differences in the details) the trough which has been present
across the Gulf of Alaska is about to deepen into the western USA
leading to a greater projection onto the negative phase of the PNA.
Arctic air has been building up across Alaska and northwest Canada for
the last several weeks, and this trough will have that airmass as a
cold air source. This possibility has been discussed in a Blog (link) maintained by
Ed Berry starting November 4th.
Please see the CPC
Drought Monitor for areas of dryness and the latest official
outlooks and statements from Storm
Prediction Center not only for severe storms, but also fire weather
concerns. Finally, the CPC CPC
USA Hazards Assessment for offers additional insights not only for
possible week 1 high impact weather, but week 2 as well. Week 2 (3-9 December 2006): Same
as week 1, but with the usual synoptic variations in amplitude. Perhaps
another episode of baroclinic development across the Rockies and Plains
may occur toward the end of this period. The week 1
storm system will not be the "last western/central USA" trough in this
series. In fact,
the stronger and slower moving troughs may not occur until the last
half
of December, particularly if a transition from GSDM Stage 1-2 occurs. Week 3 (10-16 December 2006): We may have a
period during weeks 4-6 of extremely cold air covering particularly the
central USA should a mature GSDM Stage 2 evolve. That may allow a snow
pack to build across locations such as the Upper Mississippi Valley and
Great Lakes. Given the magnitude of our warm ENSO (and other factors) I
would be surprised not to see an anomalously strong combined jet
~30-35N extend from East Asia into the western USA (with split flow
across North America) by ~ the middle of January 2007, which would be
GSDM Stage 3. This would significantly increase the probability of high
impact weather (heavy precipitation, high winds, etc.) for the USA west
coast perhaps affecting California the most (other regions for hazards
and weather understood). Additional
NCEP Ensemble Output
Part I begins with an overview of the SSTs, tropical convective
forcing and large scale circulation anomalies. We briefly review key
aspects of the development of the current warm ENSO.
We then turn to case studies of the
complex interactions between the global circulation and
tropical flare-ups including those with the MJO. These
interactions led to
several high impact weather/extreme events. A
synopsis of the current weather-climate situation with predictive
insights follows in Part 2. For information on the status of El
Nino and the MJO (including a week 1-2 global hazards outlook) please
see the following links.
Figure 1 (Hovmoller plots of SSTs and SSTAs;
latest images of various TAO/TRITON SST monitoring tools are here )
Figure 2 (below) is a
Hovmoller plot of near equatorial (7.5N-S) OLR anomalies since December
2004. Their large scale,
slow evolution is consistent with the warm-cool-warm
SST anomalies seen in Fig. 1. During warm conditions, convection is
enhanced near the dateline and the western Indian Ocean but suppressed
over Indonesia while during cool conditions it is enhanced and
concentrated over Indonesia. Subseasonal convective activity is
superimposed on the ENSO cycle. The MJO contribution to the activity
was relatively weak with only three moderate to strong events (~April
2005, January 2006 and September 2006) during this period. The
remainder of the
variability has eastward propagating characteristics but its recurrence
time is faster, typically around 25-30 days. In fact, since the 2001-02
cool season MJO activity
has been somewhat unusual with fewer multiple MJOs and more summer
activity. The warmth and expansion of the
Indo-Pacific warm pool may not only be affecting ENSO but
also the MJO.
Of particular note in Fig. 2 is the close sequence of
three subseasonal events during March-early May 2006 and an event
during June 2006. These were closely linked with important changes in
the pattern of Pacific Ocean SST anomalies, as detailed below.
Figure 2 (Hovmoller plot of near equatorial
OLRA for roughly the last 2 years; latest image here;
additional plots here )
Figure 3. (Zonal wind (left) and SST (right)
anomalies along the equator during 2006.)
Figure 4. (Zonal and vertical mean AAM (top) and global
AAM (bottom) anomalies during last year. Contours on top are total
field while colors are anomalies.)
Figure 5 (Outgoing
longwave radiation anomalies in two tropical bands. Shading shows 3-day
running means while contours are a time-space filtered version of the
color shaded field.)
Figure 6
(Daily-average 150 mb vector wind anomalies for the dates shown.)
Figure 8 (Daily 150 mb
vector wind anomalies for the dates shown.)
Finally, Fig. 9 is a
sequence of 250mb daily mean vector wind anomalies for October 23-25.
By this time the MJO dynamical signal was very
weak, and the dominate tropical forcing was from the central Pacific
(purple oval). As flare-up #3 occurred, twin anticyclones
responded around 160E (not shown). A baroclinic wave packet from
Asia
interacted with them, and resulted in an anticyclonic wave break west
of Hawaii by 23 October (shown by dark arrow and
purple colored low). As the "purple
low" shifted west another flare-up
occurred by the 24th leading to cross
equatorial flow and an intense
subtropical jet into the Desert Southwest by 25 October.
Meanwhile, wave energy dispersing from the central Pacific
contributed to a "digging" cyclonic circulation anomaly along the USA
west coast
(the orange low). As the "orange low" moved along the
subtropical jet into the central Plains, an early season blizzard
occurred across Colorado while roughly 2 dozen tornadoes were reported
over southwest Kansas. Given the rapid evolution of these events,
most prediction models did not capture this high impact weather event
until about
2 days before it occurred.
Full disk
satellite imagery show two prominent areas of tropical
convective forcing at the present time. One is located over the warm
SSTs
around the equatorial date line (including weak tropical cyclone
activity) with the other larger region centered over the IO at ~5S/60E
but extending from southern Africa into northwestern Indonesia. The
latest 3-day averaged OLRA are ~minus 70-90 W/m**2 for both
areas. Based on animations
of 150mb and 250mb daily mean vector wind anomalies (ERSL/PSD),
the IO forcing appears to be organizing into an MJO. The IO convection
is flanked by quadrapole anomalies of upstream twin subtropical
anticyclones (and low level
westerlies) and downstream subtropical cyclones, and these features are
interacting with the extratropics through wave energy dispersion
processes. In fact, the latest Wheeler diagram shows an MJO projection
well above 1 sigma and there is also a projection onto the
coherent OLR modes. A phase speed
computation has a movement of roughly 5m/s or about 20 deg of longitude
during the 5-day period from November 15-20.
Where we go from here remains tremendously uncertain. There are going
to be impacts from tropical
convective flare-ups and these are mostly unpredictable by current
models. The positive AAM tendency we are now seeing is partly
attributable to the current MJO. MJO forcing is expected to consolidate
into a large region of intense tropical
rainfall extending from near the Philippines to the South Pacific
centered ~150E by around week 3. This region may then stall before
shifting east-southeast toward the central Pacific/SPCZ by early
January 2007. Thus GSDM Stage 1 (with subtropical jets) may be
the preferred weather-climate situation through week 2, followed by
GSDM Stage 2 for much of mid-late December. Afterwards, GSDM
Stage 3 may appear, which is "typical" during the warm phase of ENSO.
In the USA outlooks that follow, confidence is below average for week
1 and then as low as it gets for weeks 2-3.
There is still an on-going tropical
cyclone risk across the central Pacific and possibly other regions (see the Tropical Prediction
Center for links). Satellite
pictures show evidence of development trying to occur west-northwest of
the equatorial date line. Locations such as the Philippines may be
impacted later this period. Tropical cyclone Yani is weakening in the
area of the South Pacific islands; however, more development may
follow. Finally, locations across the Indian Ocean may become at risk
for tropical cyclone development as the MJO slowly moves
east.
