24 Variability of the European climate on the basis of differentiation of indicators of continentalism


Chapter 24
Variability of the European Climate
on the Basis of Differentiation of Indicators
of Continentalism
Agnieszka Wypych
24.1 Introduction
The climate in Europe is shaped by geographical location, relief and the parallel
orientation of orographic barriers, as well as the presence of a huge continental
mass in the East and the Atlantic Ocean on the West. The primary factors are the
supply of solar energy and atmospheric circulation, the influence of which varies
seasonally. The presence of permanent and seasonal pressure centers determines
the advection of definite air masses (Martyn 1992). The climatic interactions within
the ocean atmosphere continent system are comprehensively characterized by the
annual air temperature amplitude. Apart from the influence of land size it also
reflects the influence of other elements  hipsometry and relief. The interaction of
these mutual dependences,  climate continentality, has long been a subject
undertaken by many European and Russian scientists. The intensity of climatic
influence of the ocean on the land mass is expressed by several indices of which
serve to describe existing relations in definitive formulas.
Visible global climate change, particularly apparent in the rise of air temperature,
affects temperature amplitude, and therefore the course of climate continentality
indices.
According to Bryson (Kożuchowski and Marciniak 1992), climate conditions of
the borderlands, within zones of both sea and continental air masses, are sensitive
indicators of change. The transitionality of the Polish climate, which manifests itself
in the presence of both oceanic and continental influences, enables the spatial and
temporal analyses of their changeability. In 1947, Romer suggested the oceanisation
of the European climate, citing the rise of average annual climatic values, particularly
the slight decline in summer temperatures (Romer 1947).
The observed tendencies of temperature changes, as well as a decline in the
range of precipitation totals (showing effects of pluvial oceanisation) are confirmed
A. Wypych (*)
Department of Climatology, Institute of Geography and Spatial Management,
Jagiellonian University, Gronostajowa 7, 30-387 Cracow, Poland
e-mail: awypych@geo.uj.edu.pl
R. Przybylak et al. (eds.), The Polish Climate in the European Context: 473
An Historical Overview, DOI 10.1007/978-90-481-3167-9_24,
© Springer Science + Business Media B.V. 2010
474 A. Wypych
in many Polish and foreign climatological research works (e.g. Ewert 1966;
Kożuchowski and Wibig 1988; Kożuchowski and Marciniak 1992, 2002). The authors
confirm a relationship between periods of increased continental and oceanic influence
and the course of circulation indices, however they unanimously emphasize the
lack of visible coexistence of thermal and pluvial continentality (Kożuchowski
and Wibig 1988).
The aim of this research is to define the regularity in the spatial and temporal
diversity of thermal and pluvial continentality indices in Europe. This will define
the characteristics of European climate changeability with respect to the range and
the intensity of oceanic air mass influence. The role of atmospheric circulation will
also be considered as a factor in the shaping of climate conditions.
24.2 Material and Methods
Monthly air temperature and precipitation totals gathered in the project entitled
 European Climate Assessment (Klein Tank et al. 2002) were used in the
research. Ten stations situated in the temperate latitudes between 48° and 53°N
were chosen (Table 24.1, Fig. 24.1). For each year values of the chosen thermal
and pluvial continentality indices were calculated (Table 24.2), along with their
basic measures of dispersion: standard deviation and changeability coefficient.
The analysis was carried out with particular consideration of the long-term
Table 24.1 Source material characteristic
Location Data periods
Station j latitude l longitude h m a.s.l Temperature Precipitation
Paris 48°49 N 02°20 E 75 1901 2000 1886 2000
Frankfurt 50°07 N 08°40 E 103 1870 1944 1870 1944
1946 1983 1946 1983
1986 1999 1983 1990
1993 1999
Munich 48°10 N 11°30 E 515 1879 1944 1879 1944
1948 1998 1948 1988
Berlin 52°27 N 13°18 E 55 1876 2000 1876 2000
Prague 50°05 N 14°25 E 191 1775 2000 1805 2000
Vienna 48°14 N 16°21 E 198 1901 2000 1901 2000
Cracow 50°04 N 19°58 E 220 1792 2000 1901 2000
Kiev 50°24 N 30°32 E 166 1900 1996 1900 1942
1944 1996
Poltava 49°36 N 34°33 E 160 1900 1940 1900 1940
1944 1981 1944 1981
1983 1990 1983 1990
Lugansk 48°34 N 39°15 E 59 1905 1919 1900 1906
1921 1941 1909 1919
1944 1996 1921 1941
1943 1996
475
Fig. 24.1 Location of the selected European stations
Table 24.2 Selected continentality indices
Indice/Author Formula
Thermal Ewert (1996) A - (3.81sin Õ+ 0.1)
K = 100
continentality
38.39 sin Õ+ 7.47
A  annual amplitude of temperature
j  geography latitude
A
Johansson-Ringleb
K = 0.6(1.6 - 14) - D + 36
sin Õ
A  annual amplitude of temperature
j  geography latitude
D  difference of mean autumn and spring
temperature
Pluviothermal RychliÅ„ski A - 12 sin Õ l
K = 4
continentality
sin Õ L
A  annual amplitude of temperature
j  geography latitude
l  annual precipitation total
L  long-term annual mean precipitation total
Pluvial Vemi%0Å„s index of precipitation R
III -IX
K = 100
continentality
R
RIII IX  precipitation totals of selected
months
R  annual precipitation total
R
Quotient of the winter
XII -II
K =
and summer precipitation
R
VI -VIII
totals
R  precipitation totals of selected months
476 A. Wypych
variability of the Ewert index (thermal) and Vemi%0Å„ index (pluvial). A detailed
study of these values enabled identification of climate continentalism and oceanism
periods and phases in Europe.
In most cases, the data gathered between 1901 and 2000 was used. Cracow was
chosen as the base station because it is highly representative of Central Europe (the
Historical Station of the Climatology Department of the Institute of Geography and
Spatial Management of the Jagiellonian University). Long-term courses of the con-
tinentality indices in Cracow were correlated with the monthly index of the NAO
based on the difference of normalized sea level pressures (SLP) between Ponta
Delgada, Azores and Stykkisholmur/Reykjavik, Iceland (Hurrell et al. 2003) and
with regional circulation indices by Niedzwiedz (1993). The indices are as follows:
P  progression index (westerly zonal index), S  meridional circulation index (with
the southern component) and C  cyclonicity index. These simplify characteriza-
tion of the most important features of atmospheric circulation in a given year. The
construction of the regional circulation indices was based on indices worked out by
Murray and Lewis with further modification to the Polish classification of circula-
tion types (Niedzwiedz 1993).
24.3 Thermal Continentality
The influence of air temperature is the simplest index that enables identification of
continental and oceanic interaction on the thermal conditions of Europe. It is
expressed in annual temperature amplitudes. Combined with increased intensity of
continental influences, the annual and daily amplitudes values rise as well. The
characteristic features of continental climates are a warm summer and severe
winter, as well as warmer temperatures in spring than autumn (Martyn 1992).
The long-term mean values of the thermal continentality indices calculated for
the aforementioned stations situated in Europe (Table 24.3) confirm the weakening
of oceanic influences from the West to the East. The air temperature amplitude
value varies from 17.4°C in Paris to 30.5°C in Lugansk.
For the stations situated in Germany the influence of the continent s shape and
the altitude on the course of isoamplitudes is apparent. Northernmost Berlin,
because of its proximity to the coast, distinguishes itself with a lower air tempera-
ture amplitude, about 1.0°C less than in Munich. The increasing climate continen-
tality farther inland is confirmed by calculated values of the thermal continentality
indices. Apart from the amplitude, these values also take into account the geo-
graphical location (latitude) and the difference between autumn and spring tem-
peratures (Johansson-Ringleb index). The indices (Table 24.3) range in value from
about 40% (Ewert index) on the West of the continent (Paris  39.6%) up to 70%
for the stations situated by the Black Sea (corresponding to 48.9% and 66.6% for
the Johansson-Ringleb index). The calculated values suggest a border condition
located between oceanic and continental climate types at 19°E  isoamplitude 23°C
or with a shift (of about 06°l) to the West  isoline 50% (Ewert index).
Table 24.3 Long-term mean and standard deviation values of thermal and pluvial continentality indices
Continentality indices
Thermal Pluviothermal Pluvial
Precipitation Quotient of the winter and
Station Ampl. (°C) Ewert (%) J-R* (%) RychliÅ„ski totals (mm) Vemi%0Å„ (%) summer precipitation totals
Paris Mean 17.4 39.6 48.9 44.1 621.4 58.6 0.99
s 2.3 6.4 3.1 12.2 111.0 12.8 0.46
Frankfurt Mean 20.0 46.1 52.8 55.9 638.5 60.4 0.81
s 2.7 7.5 3.4 16.6 122.6 14.4 0.46
Munich Mean 20.9 50.0 54.4 64.2 930.0 71.8 0.42
s 2.8 8.0 3.5 15.7 123.2 11.2 0.17
Berlin Mean 20.6 46.4 52.3 56.2 589.0 62.9 0.72
s 2.9 7.6 3.4 16.2 92.0 13.6 0.30
Prgue Mean 21.9 51.1 54.7 65.8 476.6 73.8 0.37
s 2.8 7.8 3.4 18.0 88.6 16.4 0.23
Vienna Mean 22.1 53.2 56.0 70.1 653.2 65.3 0.66
s 2.6 7.3 3.2 14.4 108.8 14.6 0.32
Cracow Mean 23.2 54.6 56.3 70.9 678.9 71.8 0.41
s 3.1 8.6 3.9 18.6 111.5 15.6 0.20
Kiev Mean 27.3 65.8 61.8 92.7 525.4 63.9 0.78
s 3.5 9.8 4.4 32.5 153.2 21.9 0.50
Poltava Mean 29.2 71.1 64.2 102.0 309.0 59.7 1.09
s 2.3 10.1 4.7 36.4 111.0 25.8 1.07
Lugansk Mean 30.5 75.5 66.6 115.1 360.8 64.6 0.76
s 3.9 10.9 4.9 42.6 136.9 27.8 0.60
*Johansson-Ringleb index
24
Variability of the European Climate on the Basis of Differentiation of Indicators
477
478 A. Wypych
The stations situated farther inland (e.g. Kiev, Poltawa) distinguish themselves
with larger fluctuations of index values for the given period. The standard deviation
calculated for the Ewert index ranges from 6.4 in Paris up to 10.9 in Lugansk. The
variation of other thermal indices standard deviations is slightly smaller
(Table 24.3).
The long-term indices changeability in all stations shows a statistically insignifi-
cant decline (a = 0.05) (Fig. 24.2). Over the course of many years, the periods found
to be dominated by oceanic and continental influences are very clearly defined;
moreover they exist synchronically for all stations.
The thermal conditions at the end of the nineteenth century show continental
influence as prevailing. In the first two decades of the twentieth century the influ-
ence of the Atlantic Ocean increased, which is also observed in the second half of
the twentieth century. Between 1901 and 2000 the clear predominance of the oce-
anic climate was interrupted by periods with continental thermal conditions. These
short-term episodes took place from the 1930s to 1950s at different times for the
stations considered (Fig. 24.2). The alternate periods of oceanism and thermal con-
tinentality distinguished themselves with varying degrees of interaction. They are
more remarkable in stations of continental climate type. In Lugansk, Poltawa, Kiev
and even in Cracow the deviations from the long-term means amounted to Ä…15
20% (Ä…1,5s). The biggest force was that of continental influences. The last phase
of climate oceanism appeared inside the continent in only about 1970 and lasted up
to the end of the twentieth century (Fig. 24.2).
24.4 Pluvial Continentality
The influence of the ground on precipitation has its effects on the annual totals
as well as variances in precipitation throughout the year. Pluvial oceanism is
characterized by high levels of precipitation appearing relatively evenly throughout
the year, with a slight increase during the autumn winter period. Maximum
precipitation levels typically coincide with an increase in continental influences
(Martyn 1992).
The annual mean precipitation totals for the considered European stations vary
from 930 mm in Munich to 309 mm in Poltava. This spatial diversity is caused by
the distance from the ocean and topographic relief (Fig. 24.1). The low precipita-
tion totals in Prague result from that station s localization in the rain shadow from
the nearby mountain ranges, whereas the high totals in Munich are correlated with
that city s altitude (Table 24.1). The pluvial continentality increase from the West
to the East can be noticed in the trend of annual totals, which is confirmed by the
pluvial indices values (Table 24.3). In Paris the ratio of the winter and summer
precipitation totals equals 0.99. This value indicates equal levels of precipitation
throughout the year. The index reaches lower and lower values in the Eastern parts
of the continent, dropping to 0.41 in Cracow. The values calculated for Munich
(0.42) and Prague (0.36) are exceptions; their geographical locations affect the
24 Variability of the European Climate on the Basis of Differentiation of Indicators 479
Fig. 24.2 Multi-annual courses of Ewert thermal index values (%) in selected European stations
smoothed by 11-year running average (solid line). Straight line  linear trend
480 A. Wypych
annual precipitation distribution (Table 24.3). In the stations situated deep within
the continent such as Kiev, Poltawa and Lugansk, the ratio of winter to summer
totals increases. This can be related to the influence of the Black Sea on the pluvial
conditions. Similar spatial diversity is shown by the Vemi%0Å„ index (Table 24.3).
The stations situated in the eastern Europe distinguish themselves with more
intensive long-term changeability of precipitation totals. The standard deviation
reaches 27.8% in Lugansk (Vemi%0Å„ index), a value twice as high than in the case of
Paris (12.8%; Table 24.3).
The long-term changeability of the pluvial continentality indices is statistically
significant only for the stations exhibiting the continental climate type (Kiev,
Lugansk). During the years considered, Poltawa experienced a large drop in the
Vemi%0Å„ precipitation index (Fig. 24.3), however, this has not been the case over the
long term for other stations. In Kiev and Lugansk, for instance, there was a signifi-
cant increase in the Vemi%0Å„ index (Fig. 24.3). There is also a clear decline in the ratio
of winter to summer precipitation totals that confirms the pluvial continentality of
precipitation in this part of Europe. Due to the lack of support for this observed
tendency, the precipitation data from Poltawa station is considered suspect with
regard to homogeneity and was excluded from further analysis. Cracow and Vienna
aside, the stations situated in Western and Central Europe experienced an increase
in continental influence, however statistically insignificant, in Vemi%0Å„ s annual pre-
cipitation distribution index (Fig. 24.3). The winter to summer precipitation ratio
doesn t consider overall decline, so it should be assumed that increased springtime
precipitation (from March to May) is an important factor.
For the long-term courses of indices, it is difficult to distinguish periods of oce-
anism or continentalism in pluvial conditions. The changeability coefficient reaches
values consistently greater that those of the thermal indices. The stations in Kiev
and Lugansk are exceptions as the tendency of pluvial continentality is statistically
significant. Up to the 1950, oceanic influences determined precipitation conditions.
In the second half of the twentieth century (apart from some individual cases)
Vemi%0Å„ s index values exceeded their long-term mean by about two times the stan-
dard deviation, confirming the precipitation continentality prevalent in that time
period.
24.5 Climate Continentalism in Relation to Atmospheric
Circulation Patterns
Atmospheric circulation is a primary factor influencing climate conditions.
Understanding its variability with time is useful in calculating the changeability
index of certain climate components. The intensity and type of circulation can be
described in a quantitative way by several types of indices. The foundation of devel-
oped circulation indices is the estimation of changes in circulation conditions and
the description of their influence on their behavior of meteorological components
(Ustrnul 2002).
24 Variability of the European Climate on the Basis of Differentiation of Indicators 481
Fig. 24.3 Multi-annual courses of Vemi%0Å„ precipitation index values (%) in selected European
stations smoothed by 11-year running average (solid line). Straight line  linear trend
482 A. Wypych
The varying intensity of oceanic and continental influences on the analyzed area
confirms the importance of atmospheric circulation in the shaping of pluvial and
thermal continentality in Europe. The correlation coefficient values between the
continentality indices and NAO index, as presented in Table 24.4, also outline the
significant influence of local conditions.
The correlation is statistically significant for the pluvial continentality indices
exclusively for the stations situated deep within the continent. The correlation coef-
ficient values range from -0.25 (Kiev) up to -0.336 (Lugansk) for precipitation
totals and -0.225 (Cracow) and -0.291 (Lugansk) for Vemi%0Å„ s index (Table 24.4).
The insignificance of the statistical correlation between the NAO and the ratio of
winter to summer precipitation totals confirms that zonal circulation plays a very
important role especially in the shaping of annual precipitation totals. Their annual
distribution also remains under the influence of meridional circulation. This refers
primarily to the autumn months (October and November) as well as in late spring
and summer (from May to August) when the highest frequency of southern air mass
advection is recorded (Gerstengarbe et al. 1999).
Though slight, statistically significant circulation influence on thermal condi-
tions is confirmed by the air temperature amplitude correlation coefficients calcu-
lated for Frankfurt, Munich and Prague (-0.192, -0.219 and -0.224, respectively)
and for the Ewert index (-0.176, -0.216 and -0.223, respectively).
Specific analysis of the influence of atmospheric circulation on the changeability
of continentality indices in Cracow, conducted thanks to the use of regional circulation
indices constructed for southern Poland (Table 24.5), shows that the parallel air
masses flow influences thermal conditions. The correlation coefficient reaches
statistically significant vales for the Progression index (P), however there is a lack of
significant links between zonal circulation and precipitation totals changeability.
Zonal circulation and annual precipitation distribution also lack any significant
correlation (Table 24.5). The long-term behavior of the annual precipitation totals is
influenced by the Cyclonicity index changeability; an increase of the precipitation
totals often accompanies more frequent occurrences of cyclones.
24.6 Conclusions
The characteristics of the long-term changeability of the thermal and pluvial conti-
nentality in Europe show that the geographical location influences the extent of the
climate oceanisation and its tendency to change. For the stations situated in Central
and Eastern Europe (Cracow, Kiev, Poltawa, Lugansk) the changeability of the
thermal and pluvial conditions shown by the indices described herein is remarkable
(statistically significant for precipitation). In the Western part of the continent the
fluctuation of the indices values are considerably smaller and do not exhibit a
significant directional change.
The observed climatic warming, most clearly demonstrated by the increase of
temperature during the winter months, is not confirmed by the course of the thermal
Table 24.4 Correlation coefficients between selected continentality indices and NAO index (values significant at the level of significance a = 0.05 are bolded)
Continentality indices
Thermal Pluvio-thermal Pluvial
Precipitation Quotient of the winter and
Station Ampl. Ewert J-R* Rychliński totals Vemi%0ń summer precipitation totals
Paris -0.095 -0.095 -0.052 -0.221 -0.107 -0.120 0.113
Frankfurt -0.192 -0.176 -0.118 -0.197 -0.063 -0.058 -0.104
Munich -0.219 -0.216 -0.154 -0.283 -0.144 -0.044 -0.123
Berlin -0.152 -0.131 -0.030 -0.114 0.016
0.014 -0.007
Prague -0.224 -0.223 -0.135 -0.216 -0.093 -0.045 -0.124
Vienna -0.077 -0.079 0.012 -0.129 -0.076 -0.050 -0.066
Cracow -0.169 -0.169 -0.063 -0.297 -0.314 -0.225 -0.093
Kiev -0.027 -0.021 0.102 -0.294 -0.250 -0.159 -0.021
Poltava   
0.031 0.031 0.118 
Lugansk 0.106 0.136 0.183 -0.306 -0.336 -0.291 0.042
*Johansson-Ringleb
Table 24.5 Correlation of coefficients between selected continentality indices and regional circulation patterns by Niedzwiedz (1993) in Cracow (significant
values at the level of significance a = 0.05 are bolded)
Continentality indices
Thermal Pluvio-thermal Pluvial
Precipitation Quotient of the winter and
Index Ampl. Ewert J-R* Rychliński totals Vemi%0ń summer precipitation totals
Progression (P) -0.270 -0.270 -0.207 -0.293 -0.090 -0.103 0.030
Meridional circulation (S) 0.053 0.053 -0.006 0.056
0.035 0.060 -0.013
Cyclonicity (C) -0.112 -0.112 -0.167 0.169
0.395 0.289 -0.009
24
Variability of the European Climate on the Basis of Differentiation of Indicators
483
484 A. Wypych
continentality indices. The trends in recent climatic oceanisation are not statistically
significant, however  as previously mentioned  are more prevalent in the stations
of the continental climate type.
The long-term changeability of the pluvial continental indices is remarkable only
deep within the continent. In Cracow, Kiev and Lugansk an increase in continental
climatic features in the annual precipitation distribution is observed.
Atmospheric circulation and local conditions influence the tendencies of climate
continentality s changeability in Europe. Over long-term courses of the thermal
continentality indices, the oceanisation periods  particularly in the beginning and
in the second half of the twentieth century  occur simultaneously with increases
in influence of zonal circulation. No such link exists in the case of pluvial indices.
The inconsistency between the changeability s direction of pluvial conditions and
climate oceanisation tendency at the end of the last century suggests that apart from
circulation factors, local factors  such as anthropopression  are important in
developing the climate changeability, especially in continental areas.
References
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nentalizmu kuli ziemskiej. Prace i Studia Inst Geogr Uniw Warszawskiego 11:9 17
Gerstengarbe FW, Werner PC, Rüge U (1999) Katalog der Großwetterlagen Europas (1881 1998)
nach P. Hess und H. Brezowsky. Potsdam-Inst., Offenbach. http://www.pikpotsdam.de/uwerner/
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Hurrell JW, Kushnir Y, Visbeck M, Ottersen G (2003) An overview of the North Atlantic oscillation.
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A (eds) Oscylacja Północnego Atlantyku i jej rola w kształtowaniu zmienności warunków
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