Real-time Weather-Climate Discussion and
Predictive Insights
Edward Berry, NWS and Klaus Weickmann,
ESRL/PSD
Since our last discussion (
The signal from the Madden-Julian Oscillation
(MJO) has
remained very weak, as indicated by monitoring tools such as the
Wheeler plot
(shown here)
and the coherent modes Hovmollers (here). Instead,
convection has been mostly persistent across the western Pacific Ocean
(~150-160E) although a 50-60 day "oscillation" was prominent from late
April to late June 2006. Another recurrent mode of
tropical forcing with a ~30 day time scale has been present,
especially over the equatorial Indian Ocean. The seasonal
Part I presents an overview of the SST,
tropical
convective and circulation evolutions since April 2006. One focus
will be
on the diagnosis/attribution of an excessive rainfall event along the
USA East
Coast during
the period of
Latest
CPC MJO Discussion and tools
Part 1.
Weather-Climate
Overview (updated September 9, 2006)
Figure 1 (below)
shows two
time-longitude sections of near equatorial five-day averaged SST (left)
and
SSTA (right) in deg. C. The life cycle of a recent central Pacific warm
event
(denoted by EN) is seen from boreal summer
2004 extending into spring 2005.
During this time, SSTs of
29C and greater, a threshold for supporting persistent tropical
convection,
extended east of the date line (vertical dash line). The
evolution toward
La Nina (LN) is seen from fall 2005 up through February 2006, with 29C
and
warmer SSTs well to the west of the date line. During March,
surface
westerly wind anomalies appeared across the equatorial central and east
Pacific
linked to an eastward shift of the tropical convective forcing to the
west Pacific (discussed
below). These westerly wind anomalies initiated a weak oceanic
Kelvin
wave-like response, contributing to a warming of the basin.
Similar
events occurred during May 2006 and just recently during July
2006. The first two of these events are
indicated
by dashed orange lines on Fig. 1. For the first time in 7
months, the 29C isotherm crossed the date line around May 1.
Figure 2 (below) is a time-longitude plot of the near
equatorial (7.5 N-S) anomalous outgoing longwave
radiation (OLRA) field since late summer 2004. Recall we
use OLRA as a proxy for deep tropical convection. The
purpose here
is to contrast the seasonal evolution of the tropical
convective forcing during 2005 with that in 2006.
In 2005, the stationary response to El-Nino peaked
in Feb 2005 and broke
down by
early March so that by May 2005, the most intense tropical
convection had shifted west toward
Figure 3 is a time-longitude
plot of
near equatorial OLRA focusing on roughly the last 6 months. Continuing
with the numbering sequence from the discussion posted May 17th,
multiple
evolutionary behaviors
are evident. For example, a strong
convectively coupled Kelvin wave
developed
from the enhanced forcing across the TNA (tropical North Atlantic)
during early May (dashed line
segment
A), and led to event #6 and arguably #7. These included a seasonal
northward propagation of OLRA toward India as seen in a time-latitude
diagram in Fig.
4.
The
green rectangles along ~90E highlight the ~30-day
recurring equatorial IO convective flare-ups, while the orange
rectangle
denotes
an event that contributed to forcing the extreme precipitation episode
over the
eastern USA (discussed below).
The other feature of note is the ~50-60 day interval between strong
convective forcing over the west Pacific (~1 May and then again ~ 1
July) and the
suppressed conditions in between (10 May-10 June). Partially coinciding with the
suppressed conditions
over the west Pacific Ocean, Event #4 appeared to
initiate a period of enhanced tropical
convection across the warm
SSTs of
the TNA during mid April which remained persistent in
this
area
until
roughly mid-June (see
dashed purple oval and line
centered ~40W). Such a
cycle of
persistent forcing "oscillating" between 80-180E and 80W-0W is expected
to impact the
large scale circulation, in particular the strength of the tropical to
mid-latitude westerly flow.
Figure 3. (Same as Fig. 2 except for the last 6 months)
Figure 4. (Time-latitude section of the total OLR field for 60-90E).
The slowly evolving 50-60 day tropical
convective forcing was associated with variations in the strength of
the
global
westerly flow. Fig. 5 shows the global integral of
relative atmospheric angular momentum, its global tendency, and the
frictional and mountain torque, which force the total AAM. The times
when tropical convection was
active-suppressed-active over the western Pacific are shown as
orange-green-orange shading in the first panel. The second panel shows
that these instances correspond roughly with a
positive-negative-positive relative AAM tendency. A similar
relationship occurs during an MJO when convection oscillates over the
west
Pacific Ocean. Moreover, the global torques, which are seen in the
next two panels, have the friction torque
leading the mountain torque, just as with an MJO. This relation is
highlighted with downward pointing
arrows that connect torque anomalies of the same sign. While this phase
relation is as expected, the magnitude of the torques tend to be more
comparable during an MJO. Here the mountain torque curve
clearly includes shorter time scales as well as larger excursions
compared to the frictional torque. These are generally induced by
mobile mid-latitude wavetrains, which can be influenced by tropical
convection but have faster inherent time scales. (Such interactions are
generally averaged out when compositing over many MJOs.)
Nevertheless, the atmosphere seeks to maintain an AAM balance in the
face of a large mountain torque and this
is the essence of what we call "the mountain-frictional torque
index cycle". The same wavetrains that induce the mountain torque
transport momentum meridionally into adjacent latitude bands where it
reaches
the surface and is removed from the atmosphere by the frictional
torque. This process is represented by the upward
pointing arrows that connect the mountain torque to an opposite sign of
the frictional torque. (During northern winter, the surface wind
field associated with the PNA teleconnection pattern plays a prominent
role in this removal or rebalancing process.) In summary, these curves
represent a mixture of mid-latitude and tropical forcing processes that
can become coupled via tropical-extratropical interactions. For
example, a transient interaction between
the convection and mid-latitude wavetrains can produce a mountain
torque while a mountain
torque induced fluctuation in the tradewinds can feed back on tropical
convection.
The two phenomena or processes (i.e., mountain and tropical convective
forcing) are
inexorably intertwined and difficult to disentangle in individual
events without careful monitoring. Nevertheless, the curve in panel 1
shows a fairly simple variation in global AAM.
Figure 5. (The global integral of relative atmospheric angular
momentum
(AAM), the relative AAM tendency, the frictional torque and the
mountain torque. The
latter also shows contributions from various mountain ranges.)
A much more complicated picture emerges if one wants to regionalize
these
global anomalies. As a start, Fig. 6 shows the zonal and vertical mean
relative AAM
anomalies, and the global anomaly curve repeated underneath. Comparing
the panels
shows the
primary contribution to the global signal comes from the tropics and
subtropics with easterly anomalies present there during low global AAM
and westerly flow anomalies during high global AAM. The top panel
also includes a well-defined
poleward propagating signal, especially in
easterly wind anomalies during late May through June 2006. As the
easterly anomalies move poleward they are replaced by westerly
anomalies in the northern subtropics. Fig. 6 also has vertical lines
that mark a period
16-30 June that brackets the USA east coast precipitation event, which
occurred shortly after
easterly flow anomalies shifted poleward to ~35N.
Before examining the daily maps from this
period, the zonal and vertically integrated AAM budget
will be discussed. Readers uninterested in these more technical
insights can skip to Fig. 8.
Figure 6 (Plots of, top panel: vertically
and zonally averaged tropospheric
AAM
anomalies; bottom: globally averaged AAM anomaly. Latest reanalysis plots here
and here;
additional plots here.
See text for details.)
To help focus the discussion of the budget we will consider only the
time period
during June 2006 when the convection goes from being inactive to
being active over the western Pacific Ocean (see the shaded rectangles
in panel 4) and bands of
negative
and positive tendency "jump-step" poleward into the northern hemisphere
(panel 1). Visually the flux convergence of AAM transport makes the
largest contribution to the tendency term in
Fig. 7, and
even more so since the color contour interval in panel 2 is twice that
of the other panels. Much of the poleward propagation is due to
systematic momentum transports with the transporting phenomena ranging
from
divergent circulations to Rossby wave dispersions to baroclinic wave
processes. The large momentum sink centered ~30N early in the
period (along first dotted line) is followed by a strong surge in the
tradewinds over the
western hemisphere implying a large positive frictional torque (panel
3, orange shading). As the trades weaken, the
mountain torque
starts increasing as convection becomes established over the
west-central Pacific. Northerly meridional flows off of Asia support
high pressure and a positive mountain torque from Asia, while easterly
low level inflow into the west Pacific convection projects
on an
atmospheric Kelvin wave whose sea level pressure signal propagates
rapidly east and gives a
positive mountain torque from the Andes.
Thus the torques help "flesh out" the poleward propagation but it is
mostly a dynamical feature related to the momentum transports. We
should note that the Coriolis and gravity wave drag torques are part of
the vertically integrated AAM budget but are not shown. The former can
be
large and partially
compensate the mountain torque. It is related to changes in the global
mass distribution that accompany the mountain torque. Also, the zonal
budget
is not balanced
using the NCEP/NCAR Reanalysis data, i.e., the sum of panels 2-4 plus
the Coriolis and gravity wave drag torque
is not equal to panel 1. On the other hand, the global budget (Fig. 5)
is a better balanced field suggesting problems in the meridional
structure of the torque and/or AAM flux divergence fields.
The specific feature of interest for the east coast precipitation event
is the strong trade flow and positive frictional torque that develops
around 10-25 June in
association with the poleward movement of negative AAM tendencies and a
following band of positive tendencies. As
already noted, this is associated with a 50-60 day oscillation in
west Pacific tropical convection combined with a mountain-friction
torque index cycle.
However, there are other time scales involved in the event including:
2) ~30-day tropical convective
variability, and 3) fast baroclinic wave /Rossby wave energy dispersions.
The 30-day flareup over the Indian Ocean (see orange box on Fig. 3) essentially indicated that convection had returned to the equatorial eastern hemisphere and started the process of changing the downstream atmospheric circulation anomalies. However, the connection between the tropical convection and the circulation changes over North America is fraught with "starts", "pauses" and local energy sources along the way. The wave energy disperses, gets trapped locally, disperses again and then gets involved in a major baroclinic development around 160W over the Pacific Ocean. This all occurs during 16-30 June and provides the large scale dynamical forcing for the rain event.
Figure 7 (The zonal and vertical integral of the physical processes making up the atmospheric angular momentum budget. A 5-day running mean has been applied to the data. The annotations emphasize episodes of poleward propagation of zonal AAM anomalies. See text.)
Figure 8 is a sequence of daily mean maps of 250mb vector wind anomalies designed to illustrate the synoptic details leading to the excessive rainfall event along the USA East Coast. Nevertheless, The sequence begins with June 16th, about the time of the central IO convective flare-up and when AAM tendency was maximized on the equator (Fig.7). In general, the dashed orange ovals denote the IO flare-up while the larger purple oval depicts the western Pacific tropical convective forcing. The red H's and L's indicate anticyclonic and cyclonic circulation anomalies, respectively. The orange lines for both June 17 and 24 indicate the approximate locations of a trough axis and the dashed purple arrows emphasize key wind field structures.
On June 16 and 17, a baroclinic wave packet moving rapidly east-southeast through southern Asia interacted with the divergent outflow from the IO tropical convective flare-up. The extensive meridional flow on 16 June from 10N to 80N is the first indication of a strong tropical-extratropical interaction. By June 18 the outflow from the now intense IO convection helps produce a jet streak west of Japan (curved purple arrow). At the same time easterly flow anomalies are being established around 35N and westerly anomalies are appearing in the northern tropics of the eastern hemisphere. During June 19-21 energy propagates downstream over the North Pacific leading to L-H couplet along 145W-135W. This represents an effective retrogression of the H that was over the southwest USA 17-18 June. At the same time a large anticyclone just west of the dateline becomes intense and circular with nearly 40 m/s wind anomalies. By June 21, the subtropical westerlies have expanded considerably from the Indian Ocean to the east Pacific where they feed into the 145W trough over the Gulf of Alaska. By 23 June, the dateline anticyclone begins to disperse energy eastward leading to amplification of the ridge around 120W. The westerly flow in the subtropics continues to feed into the L-H couplet over the east Pacific-western North American region. This pattern amplifies further on 25 June and also deepens the downstream trough over the central USA. By 28 June the subtropical westerlies have expanded across the western hemisphere and now appear to feed into the intense trough over eastern Canada and the anticyclone just to the east of New England (southerly wind anomalies in excess of 40m/s in between these systems). This sequence from 23-28 June contributes the immediate dynamical forcing for the east coast precipitation event. Of course the weak flow aloft near 35N (e.g., June 26) is a reminder of the strong trades at the surface that were instrumental in transporting moisture toward the USA east coast. These moisture laden winds from the deep Tropical North Atlantic were transported northward and dynamically lifted across the USA East Coast for about 6 days, allowing for tremendous and destructive rainfall. At upper levels, there was also tropospheric moisture transport from the Pacific Ocean in association with the enhanced westerly flow. As the tropical convective forcing propagated into the central Pacific, the global circulation began a transition to GSDM Stage 3 (see this link for our accepted MWR paper that discusses the GSDM), allowing this East Coast excessive rain synoptic pattern to break down by the end of June.
Figure 8.
(Sequence of daily mean 250mb vector wind anomalies for the period from
June 16-30, 2006. See text for details, and this
link for a useful RWD diagnostic from the Tokyo Climate Center
. Please see this link
for animations of various fields including the operational 150mb and
250mb daily mean vector wind anomalies)
2.
Predictive Insights Since the time period of the sequence shown in
Fig. 8, at
least 2 other well defined RWDs have
occurred. One was from about July 16-21
and the other
from July 24-31. The former led to
retrogression of the ridge position back toward the western The MJO remains very weak, and there
is some evidence of weak
air-sea coupling between the tropical convection and warm SSTs west of
the date
line. An eastward propagating dynamical
signal has moved into the Western Hemisphere, moving along the East
Pacific
ITCZ (phase speed ~8-10m/s). Finally,
consolidation of tropical forcing is taking place centered
~10-15N/110E that involves the Asian monsoon systems and an
intense flare-up just north of the
equator centered ~60E (see link to
coherent modes Hovmollers). Consistent with previous events
during the last several months, we expect Indian
Ocean flare-up to propagate northeast and also merge with the on-going
convective
activity from While
tropical convection should persist west of the date line (SST boundary
forcing), general suppression may occur around Zonal
mean westerly wind anomalies should continue to increase from 15S-25N,
with
magnitudes
at 200mb ~5m/s at 15N. Animations of
150mb and 250mb daily mean vector wind anomalies (animations here;
the reader can naviagate to the reanalysis data animations) shows the
appearance of twin
upper tropospheric anticyclones around the date line within the
tropics, with
distorted twin subtropical anticyclones ~120E.
These anticyclones (with lower tropospheric cyclones) are the
result of the divergent outflows from the tropical
forcing
discussed above. The pair at the date
line is a response to the SST boundary forcing (and perhaps an ENSO
signal
due to
an evolving possible warm event; a slower process than subseasonal),
and are
contributing to the recent increase of zonal mean anomalous westerly
flow
throughout the tropical and subtropical atmospheres. Some of
the anomalous westerly flow is already impacting not only the Tropical
North
Atlantic, but also enhancing moisture transport into the Desert
Southwest of
the . GSDM
Stage 1-2 best describes the global circulation now (see links to AAM
plots
here). A transition to GSDM Stage 2 would be most
probable by week 2, possibly persisting into week 3 although uncertainty remains extremely high.
This
would suggest
retrogression of a ridge back into the Great Basin and perhaps into 
Figure 9. (Same as Fig. 8
except for the dates shown. Please see this link here
for operational plots of various fields)
Tropical
Ocean SSTs remain above average across most of the Western Hemisphere
and the
Indian Ocean, with cooler than normal values centered on
Figure 10.
(Week 2 calibtrated tercile probabilities
for temperature from the CDC ensemble; forecast )
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 (26 August -1 September 2006): GSDM
Stage 2 is
probable. Please see Figs. 11-12. A modification would be to
suggest a shift toward below normal temperatures from perhaps
the
Upper Mississippi Valley/Great Lakes possibly into the
Northeast with a stronger tilt toward the
above normal tercile from the Great Basin to the Pacific
Northwest. Near normal may be most probable elsewhere. Much
of the country is likely to remain dryer than normal, especially from
the High Plains into most of the Rockies and western states. An
area of near to
above normal rainfall may be probable for the Desert Southwest and the
Mid
Atlantic-New England. Tropical cyclone
activity may remain suppressed across the North Atlantic. Week 3 (2-8 September 2006): Per
above, unclear. Additional
NCEP
Ensemble Output 
Figure 11. (Same as
10 but for
precipitation; forecast)
