Conil.pdf


ANNALS OF GEOPHYSICS, VOL. 46, N. 1, February 2003

57

Influence of the North Atlantic
on simulated atmospheric variability

Sébastien Conil and Zhao X. Li
Laboratoire de Météorologie Dynamique, CNRS, Université Pierre et Marie Curie, Paris, France

Abstract
An atmospheric general circulation model is used to investigate the influence of the North Atlantic Ocean on
atmospheric variability. The study covers the period from 1950 to 1994. The observed sea surface temperature
and sea ice extension are used to force the atmospheric model. Several configurations of the oceanic boundary
conditions were made to isolate the role of the North Atlantic and to study its non-linear interaction with forcings
from other oceanic basins. The multi-realization character of the experiments distinguishes between the internal
random part and the external forced part of the total variability. The potential predictability can thus be evaluated.
The response of the atmosphere is also studied with a modal approach in terms of hemispheric teleconnection
patterns. The North Atlantic Ocean has a direct influence on both the Northern Hemisphere annular mode and the
Pacific-North-America pattern, leading to a weak predictability. However the direct response is largely modulated
by forcings from other oceanic basins. The non-linearity of the system compensates the predictable component of
the annular mode induced by the North Atlantic forcing. Furthermore it reduces the forced component of the
Pacific-North-America pattern, increasing its chaoticity.

1.  Introduction

Atmospheric circulation of the Northern
Hemisphere exhibits variability in a wide range
of timescales, from days to decades (see Feld-
stein, 2000). This variability is dominated by a
small number of large-scale coherent tele-
connection patterns (Wallace and Gutzler, 1981),
such as the PNA (Pacific-North-America pattern)
or the NAO (North Atlantic Oscillation). They
have major climatic impacts and are involved in

many climate phenomena. Understanding the
mechanisms controlling the teleconnection
patterns will contribute to make reliable climate
predictions at different time scales.

Predictability of the climate at seasonal to
decadal timescales arises from two distinct
sources as described by Lorenz (1975). The first
source is the initial states (initial-value problem)
and the second one is the boundary conditions
(potential predictability). They are called the first
and second kinds of predictability respectively
(Collins and Allen, 2002). When an atmospheric
general circulation model is used to investigate
the second kind of predictability, the boundary
conditions are the SST and sea-ice variation. A
number of past studies looking for the role of
the ocean in building atmospheric variability and
its associated predictability utilize forced AGCM,
as in Harzallah and Sadourny (1995) and Zwiers
et al. (2000). They note a robust high predic-
tability in the low latitudes whereas the extra-
tropical regions show weak (and inconsistent)
response.

Mailing address: Dr. Sébastien Conil, Laboratoire de
Météorologie Dynamique, CNRS, Université Pierre et Marie
Curie, casier 99, 4 place Jussieu,75252 Paris Cedex 05,
France; e-mail: conil@lmd.jussieu.fr

Key  words  atmospheric general circulation model −
internal/external variability − climate predictability −
teleconnections



58

Sébastien Conil and Zhao X. Li

Tropical oceanic forcing has been used with
success, in the TOGA (Tropical Ocean-Global
Atmosphere) context, to understand ENSO-
related (El Niño Southern Oscillation) tele-
connections and to forecast associated climate
fluctuations (Trenberth et al., 1998). The role of
the mid-latitude ocean is however much more
controversial (see Kushnir et al., 2002). In
particular, the role of the North Atlantic for low-
frequency climate variability is very uncertain.
Results reported in the literature are often
incoherent. Rodwell et al. (1999) reported a high
hindcast skill of the NAO, originated from the
North Atlantic decadal- scale variation by using
an atmospheric general circulation model forced
by the observed SST for the second half of the
20th century. Similar experiments were also
repeated by other groups, Latif et al. (2000), for
example, pointed out that a considerable part of
this hindcast skill came from the Equatorial Pacific
through global teleconnection mechanisms. The
ENSO influence on the North Atlantic and Europe
atmospheric variability was also depicted in
Fraedrich (1994) or Venzke et al. (1999).

Lack of a suitable theoretical framework is
the main obstacle to understand the role of the
mid-latitude ocean in forcing climate variability.
In fact, mid-latitude atmospheric circulation is
characterized by a strong transient circulation
with large-scale wave-like structures. Response
of such a regime of atmospheric circulation to
the boundary conditions is much more complex.
Strong scale-interactions also increase the dif-
ficulties in understanding the role of the mid-
latitude ocean. For the synoptic time scales, mid-
latitude ocean has mainly a passive role in
integrating the atmospheric variation, such as
surface temperature or wind stress. The ocean-
to-atmosphere signal at low-frequency scale is
often masked by the high-frequency atmosphere-
to-ocean patterns (Frankignoul, 1985).

In this work we address the problem of
the influence of the oceanic boundary condi-
tions on atmospheric variability in the Northern
Hemisphere. This work is a natural extension of
Li (1999) with emphasis on the role of the North
Atlantic Ocean. We will study the atmospheric
response to the oceanic boundary conditions, by
separating internal from external variability. Our
aim is also to identify the teleconnection structures

that are sensitive to the oceanic forcing. We will
particularly focus on the influence of the North
Atlantic and its possible interaction with forcing
from other oceanic basins.

Three configurations corresponding to dif-
ferent oceanic boundary conditions are used.
The first experiment uses the global observed oce-
anic surface conditions. To emphasize the North
Atlantic role, we perform two other experiments,
one forced by observed varying oceanic con-
ditions only in the North Atlantic and clima-
tological conditions elsewhere, the other
with climatological oceanic conditions in the
North Atlantic and observed varying forcing
elsewhere. Such a strategy allows us to assess
the influence of the North Atlantic Ocean in two
complementary ways. In fact the North Atlantic
ocean can have a direct impact on the atmos-
pheric variability, but its influence can be non
linear and the direct impact can be modulated by
other oceanic forcing. This non-linearity can also
act on the internal variability.

The structure of the paper is as follows.
Model, experimental design and statistical
methods are briefly described in Section 2.
Results on the simulated variability, its internal
and external decompositions, and the potential
predictability are presented in Section 3. In
Section 4 we focus on the spatial modes of
variability and their predictability. Discussion
and conclusion are given in Section 5.

2. Model, experiments and analysis method

2.1.  Model description

The model used in this study is LMDZ ver-
sion 3.3, a state-of-the-art climate model de-
rived from the standard version, as described in
Sadourny and Laval (1984). The model is
formulated through finite-difference on the
Arakawa-C grid. Its horizontal resolution is 4°
in latitude and 5° in longitude, with regularly
distributed grid points. The model uses vertical
hybrid coordinates with 19 levels, unevenly
spaced to allow a better resolution in the boun-
dary layer. The advection scheme is designed
to conserve potential enstrophy for divergent
barotropic flow (Sadourny, 1975). Lateral diffu-



59

Influence of the North Atlantic on simulated atmospheric variability

sion is calculated through an iterated Laplacian
operator. Six minutes are the time step used to
resolve the dynamics, but the physical para-
meterizations are evaluated only every 30 min.
Convection is parameterized with a simple mass-
flux scheme developed by Tiedtke (1989). The
cloud parameterization, presented in Le Treut and
Li (1991), uses a cloud water budget and a
statistical description of the subgrid water
distribution. The radiation package is the same
as that used in the model of ECMWF. The short-
wave radiation code is an updated version of the
Fouquart and Bonnel (1980) scheme. Long-wave
radiation scheme was designed by Morcrette
(1991). The planetary boundary layer scheme is
based on a second order closure model. The
surface model is a bucket model for which we
consider a homogeneous layer of 150 mm.
Calculation of the surface temperature is in-
corporated in the boundary layer and based on
the surface energy balance equation. For the
surface moisture, a holding capacity is fixed at
150 mm of water, and all the water above this
value is lost as runoff. A complete description of
the model is available at «http://www.lmd.
jussieu.fr/~lmdz/doc.html». The same version of
the GCM was also used in the coupled ocean -
atmosphere study presented in Li and Conil (2003).

2.2. Realization of experiments

Our main objective is to study the influence
of the North Atlantic oceanic conditions on
atmospheric variability and predictability. The
separation of external and internal components of
the total variability and the evaluation of the
potential predictability require an ensemble
approach. The ensemble size is critical because
the signal-to-noise ratio is weak as shown by Li
(1999) and Mehta et al. (2000). We adopt thus the
ensemble approach for all the three experiments.

An ensemble of 17 simulations was first run
with global SST and sea-ice distributions as
boundary conditions, covering the period 1950-
1994. The initial condition differed slightly from
one simulation to another. The time-varying SST
and sea-ice distributions were obtained from the
GISST data set (Rayner et al., 1996), monthly-
mean GISST data being interpolated into daily

values through a simple spline interpolation
scheme. This experiment will be referred to as
GLOBAL. In order to isolate the role of the North
Atlantic oceanic boundary conditions two
additional experiments (referred to as NOATL
and ATL, hereafter) were also performed.
NOATL consists of 9 integrations with the same
SST and sea-ice information for the global ocean,
except for the North Atlantic (north of 14°N)
where seasonal climatological conditions were
prescribed. ATL is a complementary experiment
containing also 9 integrations with observed
varying SST and sea ice for the North Atlantic
Ocean (north of 14°N) but prescribed clima-
tological conditions elsewhere. An additional
150-year integration (referred to as CLIM) was
performed with climatological SST and sea ice
during the whole integration.

2.3.  Analysis method

In order to identify the relative influence
of the boundary conditions and the internal
dynamics in the atmospheric variability, we
employed the ANOVA (ANalysis Of VAriance)
technique to analyze our ensemble simulations.
This approach has been widely used in the past
and is described in detail in Harzallah and
Sadourny (1995), Rowell (1998) or Von Storch
and Zwiers (1999).

If x
i
 (t, s) represents a variable (e.g. winter

seasonal-mean geopotential height at 500 hPa) at
time t (length T = 44 winters) and spatial position s
(Northern Hemisphere), for the simulation i (total
number I = 17 or 9), it can be split into two parts

        x
i
 (t, s) = E(t, s) + R

i
 (t, s)              (2.1)

where E represents the variations induced by
varying boundary conditions and R

i
 the in-

ternally-generated variations (the random part).
To be able to make this partition, two conditions
are necessary (Scheffe, 1959). The first is that E
and R follow independent Gaussian distributions,
and the second is that E and R are independent.
These two conditions are generally verified for
variables such as geopotential height or tem-
perature at 500 hPa, since their persistence time
scales are much shorter than the year.



60

Sébastien Conil and Zhao X. Li

Two averages can be defined

(2.2)

which is the ensemble mean and

(2.3)

which is the general mean or climatological
mean.

The ensemble mean is a natural estimator of
the boundary-conditions induced variations E,
whereas x

i
 – xEM is an estimator of the internal

variations R
i
. The dispersion among the ensemble

members gives an unbiased estimate of the
internal variability

(2.4)

The variance σ 2
EM

of the ensemble mean is given
by

(2.5)

Following Scheffe (1959), the oceanic-forced
variability σSST can be deduced from the variance
of the ensemble mean after removing the bias
due the internal variability

           (2.6)

An unbiased estimate of the total variance σ 2TOT
is the sum of the internal and external contribu-
tions

(2.7)

In the following, we use the term internal and ex-
ternal variability in reference to σ

INT
  and σ

SST
 . The

proportion of the total variance due to the boundary
forcing measures the potential predictability

(2.8)

The statistical significance is conducted through
a test as in Rowell (1998). The null hypothesis
σSST

2     = 0 or ρ = 0 is rejected at β significance
level when

(2.9)

where F
T–1; T (I–1); β is the F statistic at β  significance

level with degrees of freedom T – 1 and T (I – 1).

3.  Analysis of variance and potential
     predictability

In the following sections we apply the above-
described ANOVA technique to the three
ensemble experiments, GLOBAL, NOATL
and ATL. We focus on the Northern Hemi-
sphere winter, December-January-February,
when the variability is stronger, the telecon-
nections more robust and the potential pre-
dictability higher. As mentioned before, the role
of the North Atlantic is our particular interest and
it can be assessed through combination of the
three different experiments. Two different ways
are possible. But they are not equivalent since
the non-linearity of the model is activated
differently. The first combination uses ATL and
CLIM. The difference between these two ex-
periments gives a direct evaluation of the im-
pact exerted by the North Atlantic. The second
combination uses GLOBAL and NOATL. It
gives us not only the direct influence of the North
Atlantic, but also the non-linear response through
interaction with other oceanic basins.

µ s
T

x t s
T I

x t si
i

I

t

T

t

T

( ) = ( ) = ( )
===
∑∑∑

1 1 1

111

EM , ,

σ
INT

σ INT EM
2 2

11

1
1

s
T I

x t s x t si
i

I

t

T

( ) =
−( )

( ) − ( )( )
==
∑∑ , , .

σ µ
EM EM
2

2

1

1
1

s
T I

x t s s
t

T

( ) =
−( )

( ) − ( )( )
=
∑ , .

σ σ σ
SST EM INT
2 2 21= −

I
.

σ σ σ σ σ
TOT SST INT EM INT
2 2 2 2 21= + = +

−I
I

.

ρ

β

>
+

− −( ) −

1

1
1 1 1

I

F
T T I; ;

ρ
σ
σ

σ σ

σ σ
σ
σ

= =
−

+
− =

+

−

SST

TOT

EM INT

EM INT

EM

INT

2

2

2 2

2 2

2

2

1

1
1

1

1

I
I

I

I

I( )

.

x t s
I

x t si
i

I

EM , ,( ) = ( )
=
∑1

1



61

Influence of the North Atlantic on simulated atmospheric variability

3.1. Total variance

The total variability (interannual standard
deviation) of the geopotential height at 500 hPa
simulated in GLOBAL, NOATL and ATL (fig. 1)
can be compared with the estimation from the
NCEP reanalysis (fig. 5b). While the simulated
variability is overestimated in the high latitudes,
it is, however, too weak at low latitudes. A local
maximum over Greenland is present in the model
as in the observations. But this maximum is too
geographically confined for all three expe-
riments, compared to the observed strong one.
Furthermore, in the three experiments, a strong
maximum is located just in the west of England
over the North Atlantic. Two other local maxima
in the north of the Siberian plain and in the north
of Japan are well represented in the model. The
center over the North Pacific, well identified in
the observation, is also present in GLOBAL and
NOATL, but not in ATL.

3.2. Internal variance

At first glance, the spatial structure, even the
magnitude, of the internal variability (fig. 2)
is very close in the three experiments. The
resemblance to the CLIM is also evident (see fig.
5a). It is mainly zonally distributed, increasing
from low to high latitudes. The maxima located
over the North Atlantic, Greenland and Siberia
are still present, but not the center over the North
Pacific. The fact that different estimations of the
internal variance give similar results indicates
that the internal variance is a robust variable,
almost intrinsic to the model’s fundamental
behaviour. However careful examination still
reveals subtle differences among the expe-
riments, which is the manifestation of the non-
linearity and the interaction between the model’s
forced behaviour and its random variation. In

Fig. 1. Total variability (expressed as interannual
standard deviation, in meters) for winter (December-
January-February) 500-hPa geopotential height in
respectively GLOBAL, NOATL and ATL experiments.



62

Sébastien Conil and Zhao X. Li

Fig.  2.  Same as in fig. 1, but for the internal varia-
bility.

Fig.  3.  Same as in fig. 1, but for the external forced
variability.



63

Influence of the North Atlantic on simulated atmospheric variability

fact, oceanic conditions are able to modulate the
mean atmospheric circulation and also its
transient properties.

3.3. Forced variance

The forced variability is displayed in fig. 3
for the three experiments. The forced variance
deduced from ATL is a direct estimation of the
impact exerted by the North Atlantic. It is in
general very weak. But we can still observe high-
value centers over the Arctic and North Pacific.
These remote influences are probably due to the
hemispheric teleconnection mechanism. The
local influence over the North Atlantic is however
small.

The structure of the forced variance has a
good resemblance between GLOBAL and
NOATL. Their difference gives another eva-
luation for the role played by the North Atlantic.
Visual inspection shows that the forced variance
decreases, from NOATL to GLOBAL, over the
North Pacific and North America, but increases
in the Atlantic sector. This is probably due to the
interaction between the North Atlantic variability
and that of other oceanic basins. The final forced
variance can thus be increased or decreased for
different geographical locations. A more precise
interpretation of this modulation is presented
later.

3.4.  Potential predictability

The potential predictability (fig. 4) induced
by the North Atlantic Ocean alone is very weak
(< 10%). It is not significant in large parts of the
Northern Hemisphere, except in a marginal
region over the Eastern Pacific where the total
variability is very weak and over the Arctic.

For the experiments GLOBAL and NOATL,
the potential predictability (fig. 4) is also weak,

Fig.  4.  Potential predictability (% of total variance)
for winter (DJF) 500-hPa geopotential height in
GLOBAL, NOATL  and ATL. Shaded regions indicate
non-significant zone according to an F test (see text).



64

Sébastien Conil and Zhao X. Li

Table  II.  Same as in table I, but for the region NAE
(North-Atlantic-Europe) (80°W/20°E and 30/90°N).

with values of 10% over Europe and 50% over
the North Pacific, North America and the Gulf
of Mexico. This seems coherent with results
reported in Kumar and Hoerling (1998) and
Cassou and Terray (2001).

The general feature for the potential pre-
dictability is its almost zonal distribution with,
however, larger values over ocean than over land.
In addition, at low latitudes the atmospheric
internal variability is weaker and the potential
predictability is higher.

We already know that the North Atlantic
forcing can modify both internal and external
variances through complex nonlinear interaction
with other oceanic basins. Modifications in the
internal and external variances lead finally to
changes in the potential predictability. Over
the North Pacific and North America, compari-
son between NOATL and GLOBAL reveals a
weakening of the forced variability and an
increase in the internal variability at the same
time. The potential predictability over this region
is thus largely reduced by incorporation of the
North Atlantic. The inverse situation is found in
the sector of the North Atlantic, i.e., the potential
predictability is improved by the incorporation

b

Fig.  5a,b.  Interannual variability (in meters) for winter (DJF) 500-hPa geopotential height in the CLIM experiment
(a) and in the NCEP reanalysis data set (b).

Table  I.  Regional-averaged values of the total,
internal and forced variability for the three experiments
ATL, NOATL and GLOBAL. The average is over the
PNA (Pacific-North-America) region (145°E/80°W
and 30/80°N). Last raw gives the values of potential pre-
dictability. The 99% (or 95%) significance level is
reached when potential predictability is 6.4% (or 4.3%)
for ATL and NOATL, and 6.2% (or 4.2%) for
GLOBAL

       Experiment ATL NOATL GLOBAL

Total variability (m) 55.7 59.9 63

Internal variability (m) 54.8 50.3 55.4

External variability (m) 9.7 32.6 30.1

Pot. predictability (%) 2.4 29.4 22.7

       Experiment ATL NOATL GLOBAL

Total variability (m) 52.2 56.3 57.5

Internal variability (m) 50.6 51.9 52.5

External variability (m) 13 21.9 23.3

Pot. predictability (%) 6.6 15.2 16.3

a



65

Influence of the North Atlantic on simulated atmospheric variability

of the North Atlantic oceanic information since
the internal variability is reduced and the external
one enhanced.

To summarize and quantify our results, we
performed a regional average for these two par-
ticular regions. Tables I and II give respectively
the total, internal and external variances, and the
potential predictability for the PNA and NAE
(North-Atlantic-Europe) regions. The three
experiments ATL, NOATL and GLOBAL are
all included. There is a slight general increase
in the total variance from ATL to NOATL,
then to GLOBAL. However, their decomposition
into internal and external variances and their
respective evolution make the final potential
predictability very different. In the remote PNA
region, the direct impact of the North Atlantic
is weaker than over North Atlantic/Europe.
However the non-linear estimation suggests that
this direct influence is largely modified by its
combination with other ocean forcings. Indeed,
over the PNA region the potential predictability
is substantially reduced by the presence of the
North Atlantic forcing due to decreased external
response and increased chaotic variability. In the
NAE region the modulation of the potential
predictability is weak. The external signal is
stronger with the North Atlantic forcing but the
internal variability is also increased.

4.  Modal analysis

From the results presented above, we can
notice some regional coherence in the vicinity
of the well-known centers of action in the
atmosphere. It is thus possible that the atmos-
pheric response to the oceanic boundary forc-
ing is modal and can be studied through the
modification of its basic regimes and global
teleconnection structures. We will then pursue
our investigation, no longer in the physical
domain, but rather in the «spectral» domain. The
ANOVA technique will be used to analyze the
time coefficients of the dominant modes.

A natural decomposition of the atmospheric
variability is to use the Empirical Orthogonal
Function (EOF). The calculation is done in the
same manner as in Barnston and Livezey (1987)
through a rotated EOF analysis for the Northern

Hemisphere 500-hPa geopotential height. We
first perform the analysis for each of the three
experiments in a separate way. The obtained
principal modes of variability are very close
among the experiments and comparable to those
deduced from observed data, but their relative
importance in explaining the total variance is
different. In order to have a common comparison
base, we performed the EOF analysis for the
super-ensemble containing all members of the
three experiments, one after another. The NCEP
reanalysis data were also added to this super-
ensemble as an additional member. The super-
ensemble thus contained 36 (= 17 + 9 + 9 +1)
members. In this way, we obtained common
coherent spatial patterns X k(s) (where k indicates
the EOF rank), but different time series, α k

i
(t),

associated with each member i of the super-
ensemble. We studed only the first K = 6 EOFs
which represent near 70% of the total variance
of the super-ensemble. The physical field x

i
(t, s)

for each member i (including the NCEP rea-
nalysis data) was thus decomposed into two parts

(4.1)

Our objective was not to extract the most skillful
or most reproducible modes, as can be done with
SVD (Singular-Value Decomposition) analysis
applied simultaneously to the simulation and
observation, but rather to show the influence of
oceanic conditions on the natural atmospheric
dominant modes. The combined EOF technique
extracts thus the common dominant spatial
patterns X k of the super-ensemble. The time series
α

i

k(t) indicates the temporal of the corresponding
spatial structure X k(s) for each simulation i
(including the NCEP reanalysis data set). The
projection (noted as Y

i

k) of a particular member
x

i
(t, s) on its own time series α

i

k(t)  illustrates the
manifestation of the common spatial structure
X k(s) on this particular member

.           (4.2)

Figure 6a-f shows the common EOF X k, while
fig. 7a-f presents the particular projection map
Y k for the NCEP reanalysis data set. We also

x t s t s
i i

k

k

K

, .( ) = ( ) ( )
=

∑α X k
1

Y
i
k

i
k

i
t

T

s
T

t x t s( ) = ( ) ( )
=
∑1

1

α ,



66

Sébastien Conil and Zhao X. Li

Fig.  6a-f.  Common spatial structures obtained through the super-ensemble rotated EOF analysis for DJF-mean
500-hPa geopotential height in the Northern Hemisphere. The explained variance is respectively 16.2% (a); 13.4%
(b); 12.3% (c); 10.7% (d); 9.5% (e), and 7.5% (f ). Total variance is 302 m2s–2. Units are in meters.

a b

c d

e f



67

Influence of the North Atlantic on simulated atmospheric variability

Fig.  7a-f.  Projection of the common EOF structures (shown in fig. 6a-f ) onto the NCEP reanalysis data set. Units
are in meters.

a b

c d

e f



68

Sébastien Conil and Zhao X. Li

performed EOF analysis separately for each
member of the super-ensemble. The obtained
spatial structures (not shown) are very similar to
each other and close to the common structures
in fig. 6a-f.

Figure 6a-f shows slight geographical displa-
cements or distortion of the simulated structures
compared to the observed ones (fig. 7a-f). Such
discrepancies can be related to the systematic error
of the background climatological flow (Kushnir
et al., 2002). They are mainly due to the intrinsic
atmospheric processes but they also mark re-
sponses to oceanic forcing (see Peng and Robin-
son, 2001). Except for some systematic errors,
the model is, in general, able to simulate correctly
the main observed global teleconnection structures
(with spatial shifts, in many cases).

The dominant mode (accounting for 16.2%
of the total variance) is the annular mode with a
strong zonally symmetric pattern, looking like
the AO pattern (Thompson and Wallace, 1998).
The second mode (accounting for 13.4% of the
total variance) has a strong center in the North
Atlantic, near the European coast. This center is
surrounded by a circle with opposite-sign values.
A minor center with the same sign as in the North
Atlantic can be observed in the North Pacific.
This pattern (see fig. 7a-f) is similar to the ob-
served East Atlantic pattern defined by Barnston
and Livezey (1987). The third mode (12.2%)
resembles to the well-known PNA pattern. The
fourth mode (10.7%) has a strong wave-train
pattern linking the North Pacific and North
Atlantic through a cross-pole path. It corresponds
to the observed West Pacific pattern. The fifth
mode (9.5%) has a weak relation with the
observed pattern. It is mainly present in the
NOATL experiment and has a large regional

difference in GLOBAL (no Pacific center) and
is absent from ATL. The last mode that we
considered accounts for 7.5% of the total
variance. It is close to the observed NAO pattern
(Hurrel and Van Loon, 1997).

After this super-ensemble EOF analysis, we
then applied the ANOVA technique to the reduced
data sets, i.e., the time coefficients         for the
first six dominant modes. Results are given in
tables III, IV and V for the three experiments
respectively. For the experiment ATL, potential
predictability was weak for all the modes, since
the oceanic forcing itself was very weak. How-
ever the first and third modes (annular mode and
PNA pattern) reached almost 9%. For both the
experiments NOATL and GLOBAL, the third
mode has the largest potential predictability.
However, the first mode (AO) and the sixth mode
(NAO) have the smallest potential predictability.

The influence exerted by the North Atlantic
Ocean can be assessed through the comparison
between NOATL and GLOBAL. Further com-
parison with ATL can reveal the non-linear
interaction with other oceanic basins. Let us take
the first mode (AO), the experiment ATL shows
that the incorporation of the North Atlantic
oceanic variability leads to a potential predicta-
bility of 8.2%. For the NOATL and GLOBAL
experiments, the potential predictability is almost

Table  III.  Results from ANOVA technique (internal
variance, external variance and potential predictability)
for different dominant atmospheric modes and for the
experiment ATL. The 99% significance level is reached
when potential predictability is 6.34%.

       Mode number 1 2 3 4 5 6

Internal variability (m) 110 98 65 92 76 77

External variability (m) 33 10 21 0 15 11

Pot. predictability (%) 8.2 1 9.6 0 4 1.8

Table  IV.  Same as in table III, but for the experiment
NOATL. The 99% significance level is reached when
potential predictability is 6.34%.

       Mode number 1 2 3 4 5 6

Internal variability (m) 111 100 63 81 83 78

External variability (m) 54 56 104 57 56 28

Pot. predictability (%) 19.4 24.1 73.4 33.6 31  11.5

Table  V.  Same as in table III, but for the experiment
GLOBAL. The 99% significance level is reached when
potential predictability is 6.16%.

      Mode number 1 2 3 4 5 6

Internal variability (m) 113 99 66 86 79 78

External variability (m) 56 61 94 59 59 31

Pot. predictability (%) 19.6 27.7 66.7 32.0 36.0 13.8

α
i
k t( )



69

Influence of the North Atlantic on simulated atmospheric variability

identical, showing no contribution of the North
Atlantic oceanic variability. The non-linear
effects through the interaction with other oceanic
basins totally cancel the direct effect. This
destruction effect is even stronger for the third
mode (PNA) since we observe a significant
decrease for the potential predictability from
NOATL to GLOBAL. The inverse situation
occured for modes 5 and 6 with an increase in
the potential predictability from NOATL to
GLOBAL, showing a positive contribution of the
North Atlantic Ocean.

5.   Summary and conclusions

By using an atmospheric general circulation
model, we studied the atmospheric response to
varying oceanic boundary conditions. The
simulations cover the period from 1950 to 1994.
Three ensemble simulations were performed with
different configurations of the oceanic forcing
to isolate the North Atlantic Ocean’s role. We
used a standard ANOVA technique to separate
internal and external variability from total
variability. The first ensemble GLOBAL was
forced by the global observed oceanic surface
conditions (SST and sea ice). The second
ensemble NOATL was forced by the observed
varying boundary conditions for the global ocean
except for the North Atlantic where climatolog-
ical conditions were used. The third experiment
ATL is a complementary one with observed
varying boundary conditions for the North Atlantic
and climatological ones elsewhere.

Climate response to the North Atlantic
forcing was first assessed through the ATL
experiment. The direct forcing of the North
Atlantic Ocean is weak. It mainly leads to a
reduction of the internal variability and thus an
increase in the potential predictability over the
North Atlantic. The dominant annular mode is
significantly affected by the North Atlantic
forcing and is the major cause of this modi-
fication. The North Atlantic oceanic forcing
creates a weak external signal in the North Pacific
region but the internal variability also increases.
The external variability is associated with the
PNA pattern while the internal variability seems
to be associated with the West Pacific pattern.

The role of the North Atlantic in conjunction
with other basins is also assessed through the
differences between the GLOBAL and NOATL
experiments. The potential predictability over the
North Atlantic sector is slightly enhanced. It is
caused by the Eastern Atlantic pattern and the
mode 5 but not by the AO pattern. Over the North
Pacific and North America sector, internal
variability is largely increased when the North
Atlantic Ocean forcing is added. Moreover the
external signal is significantly reduced and this
leads to a decrease of the potential predictability.
The reduced potential predictability is explained
essentially by the modification of the PNA and
WP modes. The variability created by the North
Atlantic Ocean can be transmitted to the North
Pacific region. Furthermore, it interacts with the
Tropical Pacific forcing, leading to an increase
in the random variability.

Our results suggest that the North Atlantic
Ocean can influence the atmosphere in two
different ways. It can drive an external signal
which is potentially predictable but only weakly.
It can also modify the internal variability. When
those two modifications act together (reducing
chaotic and increasing forced signal) the resulted
potential predictability can become significant.
But the influence of the North Atlantic is not
linear. It interacts with forcings from other
oceanic basins. This interaction can lead to a large
modulation of the direct signal. In particular, over
the North Pacific sector, the interaction of the
direct North Atlantic signal with other oceanic
responses (mostly from Equatorial Pacific) is
destructive for the potential predictability, since
it increases the chaotic fluctuations while it
reduces the predictable forced response. So the
inclusion of the North Atlantic forcing in con-
junction with the Tropical Pacific reduces the
potential predictability in the North Pacific. The
potential predictability in the North Atlantic -
Europe region is, however, slightly increased.

Acknowledgements

Computer resources were allocated by the
IDRIS, the CNRS’ computer center. This work
is supported by the European Commission
through the SINTEX project.



70

Sébastien Conil and Zhao X. Li

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