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iForest - Biogeosciences and Forestry

iForest - Biogeosciences and Forestry
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Distribution of the major forest tree species in Turkey within spatially interpolated plant heat and hardiness zone maps

iForest - Biogeosciences and Forestry, Volume 5, Issue 2, Pages 83-92 (2012)
doi: https://doi.org/10.3832/ifor0611-005
Published: Apr 30, 2012 - Copyright © 2012 SISEF

Research Articles

In disciplines such as agriculture, forestry and horticulture, it is customary to make use of various hardiness zone maps intended for the selection of the plant species to be cultivated within specific regions. The most widely used of these maps is the USDA Plant Hardiness Zone (PHZ) map. Recently, the American Horticultural Society also created the Plant Heat Zone (AHZ) Map. PHZ and AHZ maps have not yet been produced for Turkey. To overcome deficiencies of these maps and compare the distribution of major forest tree species over these zones, data from 260 meteorological stations recorded during the period from 1975-2008 and 458 144 forest stand-type polygon centroid data were used. PHZ and AHZ maps were created through the interpolation of meteorological data using the regularized spline with tension (RST) method. According to the interpolation results, there are 7 PHZs (4-10) and 8 AHZs (2-9) in Turkey. Finally, the distribution of 15 major forest tree species over these zones was investigated. The most commonly detected species were distributed among PHZs 5 and 10 coincided with Juniperus spp., Quercus spp. and Abies spp., and the species found between PHZs 5 and 10 were those exhibiting the most extensive distributions. Pinus brutia and Quercus spp. were found to be the most widely distributed species among the AHZs.

Forest trees, Plant hardiness zones, Plant heat zones, Regularized spline with tension method, Turkey

  Introduction  

Planting and growing an exotic species outside of its natural habitat presents a dilemma because it is unknown whether such a species will survive. Experts in fields addressing this issue (forest and agricultural engineers, horticulturists and landscape architects) have built up considerable knowledge about the species in their regions as a result of long-term observations. However, it is very difficult to predict whether a species that will be grown in a region for the first time will prosper or perish. Various restrictive factors, such as drought, insect and fungus damages, extreme heat and cold, soil wetness, day length, nutrient deficiencies, salinity and air pollution affect plant growth. Plants are very well adapted to the extreme conditions existing within their natural range of occurrence; however, they are likely to suffer when they are grown outside these regions.

Various approaches may be adopted in order to decide whether to use plants outside of their natural habitat. For example, in European forestry, the adaptation possibilities of species to newly planted areas are investigated by performing long-term provenance trials. Species-specific breeding or seed zones can also be utilized for this purpose. In addition, seed or plant materials can be transferred with minimum risk within a breeding zone ([23]). Progeny tests, garden experiments and provenance trials are also used to produce breeding zone maps ([22]). Seed breeding zones are created by considering characteristics such as climate, vegetation, and elevation ([22]).

Climate is one of the most important factors affecting plant distribution. Seed or seedling transfer can be performed when the climatic characteristics of the growing region of a plant species are known. Climate classifications have been obtained using various climatic factors affecting plant growth. Bioclimatic classifications or indexes are used in studies on the distribution of plants, animals and ecosystems ([10]). The most commonly used bioclimatic indices, mainly based on temperature and precipitation parameters, were developed by De Martonne ([16]), Köppen ([24]), Thornthwaite ([45]), Bagnouls & Gaussen ([11]), and Rivas-Martinez ([42]), as described by Attorre et al. ([10]).

Hardiness zones have been used for many years to select species for use in plantations of exotic or ornamental species in North America. Additionally, it has been stated that cold hardiness zones could be used in performing seed transfer of economically important pine species in North America ([43]). Plant Hardiness Zones (PHZs) help determine under which environmental conditions plants can survive or be grown ([31]). For this reason, numerous systems have been generated to map the PHZs in North America. The most widely used of these is the USDA PHZ Map, which was generated based on mean extreme annual minimum temperatures ([12]). Although this system is referred to as a PHZ map, it is limited to cold resistance. The foundation of this system goes back to the map produced by Rehder ([41]) using observations performed in the Arnold Arboretum ([53]). The mean monthly extreme minimum temperatures, measured from various meteorological stations located in the US and Canada, were classified by Rehder using 5 °F (2.6-2.7 °C) intervals, and 7 PHZs were delineated. In the following years, another classification method, referred to as the Arnold Arboretum hardiness zones classification, was developed by Wyman ([52]) and Wyman & Flint ([53]). Mean extreme annual minimum temperatures were used in this classification. Hardiness zones were designed using 5, 10 and 15 °F intervals, obtaining 10 distinct hardiness zones, and a PHZ map was constructed for the US. This map was revised in 1967 and 1971 ([53]). The PHZs developed by the USDA are currently used for plant selection. In this classification system, 10 PHZs (1-10) were created with 10 °F intervals. Zones 2 through 10 were separated into sub-zones a and b, with 5 °F intervals. The USDA PHZ map was created for the US in 1960 using this classification. In 1990, this map was revised, and an 11th zone was added. This map was subsequently revised again, and the 12th and the 13th zones were added in 2012 ([49]). PHZs for Canada and Mexico can also be found in the 1990 USDA map ([15]). These zones and the temperatures pertaining to them are reported in Tab. 1. Another similar map was created specifically for Canada in 1967 ([38], [39], [40]). The difference between this map and the USDA map is that 7 totally different climate variables (mean minimum temperature of the coldest month, frost-free period in days, rainfall from June through November, mean maximum temperature of the warmest month, rainfall in January, mean maximum snow depth, and maximum wind gust over 30 years) were used. In the Canadian map, the southern part of the country was separated into 11 different PHZs. This map was updated using thin-plate smoothing spline interpolation techniques ([30]). However, this classification system is limited to relatively local use. In contrast, the USDA classification system for plant cold hardiness is currently widely used throughout the world. The reason this system is so extensively accepted worldwide is that the values of the extreme minimum temperatures under which plants can survive and grow have been observed and recorded for many years, and it is easy to obtain information concerning the cold hardiness zones of many plants from numerous books and records. Similarly, PHZ maps in which the mean extreme annual minimum temperatures are taken into account have been created for the entire world ([29]), for Europe ([21], [44]), for Australia ([14]) and for China ([51]).

Tab. 1 - Criteria used to classify USDA PHZ and AHS AHZ maps. (1): USDA ([49]); (2): AHS ([1]).

USDA plant hardiness zone Definition of USDA PHZ Definition of AHS AHZ
Mean extreme annual
minimum temperatures (1)
AHS plant heat zone Average number of days
per year above 30 °C (2)
Fahrenheit (°F) Celsius (°C)
PHZ 1 > -50 > -45.6 AHZ 1 < 1
PHZ 2 -50 -40 -40.0 - -45.5 AHZ 2 1 - 7
PHZ 3 -40 - -30 -34.5 - -39.9 AHZ 3 > 7 - 14
PHZ 4 -30 - -20 -28.9 - -34.4 AHZ 4 > 14 - 30
PHZ 5 -20 - -10 -23.4 - -28.8 AHZ 5 > 30 - 45
PHZ 6 -10 - 0 -17.8 - -23.3 AHZ 6 > 45 - 60
PHZ 7 0 - 10 -12.3 - -17.7 AHZ 7 > 60 - 90
PHZ 8 10 - 20 -6.7 - -12.2 AHZ 8 > 90 - 120
PHZ 9 20 - 30 -1.2 - -6.6 AHZ 9 > 120 - 150
PHZ 10 30 - 40 4.4 - -1.1 AHZ 10 > 150 - 180
PHZ 11 40 - 50 10.0 - 4.5 AHZ 11 > 180 - 210
PHZ 12 50 - 60 15.6 - 10.1 AHZ 12 > 210
PHZ 13 60 - 70 21.1 - 15.7 - -

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Although hardiness zones are generally useful for the selection of species to be used in long-term afforestation activities in a particular area/region, they are also commonly used for phytosanitary risk analysis ([29]). Additionally, PHZ maps have been used for the interpretation of climate change. For example, after the USDA PHZ map developed for the US in 1990 was revised by the National Arbor Day Foundation ([37]), it was observed that cold hardiness zones had shifted to some extent towards northern latitudes. Similarly, due to changing climatic conditions, changes in the PHZs of the revised Canadian map have particularly been observed in western Canada ([30]). Furthermore, for plant material to be used effectively, plant adaptation regions have been delimited by combining ecoregion and hardiness zone classifications ([50]).

In addition to plant cold hardiness zones, a plant heat hardiness zone classification system for the US was also created. In this system, the annual mean number of days with a maximum temperature ≥ 30 °C was used because above this threshold value plant proteins begin to degrade ([18]). The classification scheme for the cold and heat hardiness zones can be seen in Tab. 1. This hardiness classification system was developed by the American Horticultural Society (AHS), and it is known as the AHS Plant Heat Zones (AHZ) system. The AHS plant heat hardiness classification system is relatively new and has been commonly used following the publication the US AHZ map in 1997 ([1]). A similar Mexican AHZ map was developed in 2005 ([18]). Plant cold hardiness zones indicate the most extreme winter conditions, whereas plant heat hardiness zones indicate the most extreme summer conditions ([18]). Although records concerning plant cold hardiness zones have long been maintained, records concerning plant heat hardiness zones are rare.

Turkey’s climate is generally characterized as belonging to the Mediterranean macro-climate zone and varies considerably due to geomorphology (e.g., mountains extending parallel to the shore, high mountainous areas). As an example, Turkey’s Aegean and Mediterranean coasts exhibit a temperate climate with a highly seasonal precipitation regime, while the Black Sea coast presents a uniformly rainy and humid temperate climate. A continental semi-arid climate type is dominant in Central and Eastern Anatolia and Central Thrace away from sea effects ([17], [48]). The mean temperature is 12.81 °C, according to long-term observations. Temperatures have continuously increased over the last 15 years, and the average temperature was 15.20 °C in 2010. In addition, the mean total precipitation is approximately 640 mm annually ([47]).

The forested area of Turkey covers approximately 21.2 million ha. However, almost half of this forest area shows canopy cover values of less than 10%, and these areas are considered to be unproductive. A nationwide afforestation initiative was undertaken over approximately 2 million ha until 2006 to properly forest these unproductive forests, open areas and areas that had been burned down ([32]). An afforestation and erosion control action plan was developed for the period 2008-2012 to forest the unproductive forest areas and to rehabilitate them ([32]). This initiative is aimed at carrying out the afforestation of over 252 000 ha in a 5-year period. Additionally, afforestation and rehabilitation of unproductive forest areas are presented as important strategies for combating climate change according to the Turkish National Climate Change Strategy Document ([33]).

Breeding zone maps in Turkey are available for Pinus brutia, P. nigra, and P. sylvestris ([6]), Picea orientalis ([7]), Cedrus libani ([8]), and Fagus orientalis ([9]). However, these maps have been only used for seed transfer within the natural range of these species. Provenance trials and progeny tests have been performed with some fast growing natural and exotic forest tree species. However, these efforts have remained nearly local. No accuracy tests have been carried out for most species-specific seed transfer zones prepared using geographic and climatic parameters in Turkey. In this context, Isik et al. ([22]) emphasized that the provenance experiments they conducted for P. brutia did not support the reported seed transfer zones of this species. Many factors affect the growth of forest tree species in Turkey, and the most limiting is summer drought. Extremely low temperatures, soil properties and air humidity are also limiting factors ([22]). Growth-limiting factors can be diverse locally due to the great climate variability of Turkey. This problem can be solved by carrying out seed and seedling transfer via breeding zones in the natural distribution areas of forest trees. However, growing forest tree species outside of their natural distribution areas has been a perpetual problem in Turkey.

In particular, conifer species such as Pinus brutia, P. nigra, P. sylvestris, P. pinea and Cedrus libani, are extensively used in afforestation programs. These species are often planted outside the conditions of their natural range, resulting in their suffering from summer drought, extreme cold or insect damage in some cases. For example, in Calabrian pine plantations implemented in northern and central Thrace, considerable tree losses were reported during the 1985-1986 winter frosts ([46]). No AHZ map currently exists for Turkey, whereas PHZs are noted superficially in the map by Heinze & Schreiber ([21]) for the European continent.

In this study, we aimed first to generate plant cold and heat hardiness zone maps for Turkey through interpolation of meteorological data and then to determine the cold and heat hardiness zone distribution statistics of the major forest tree species of Turkey. The developed hardiness maps and the information obtained from these statistics should be helpful in the selection of tree species to be used in plantations.

  Materials and methods 

Meteorological data

In this study, measurements of minimum monthly temperature values and the annual number of days with a maximum temperature ≥ 30 °C recorded from 280 meteorological stations during the period from 1975-2008 were used. The locations of the stations are displayed in Fig. 1. The lowest minimum monthly temperatures used in determining the PHZs were generally found to occur in the winter months of December, January, and February. If the records for these particular months were missing, the associated year was excluded from the calculation of the mean extreme annual minimum temperatures for the 34-year study period. Stations with less than 20 years of data were also omitted from the analysis, and thus, the interpolation results were obtained using the data from 260 stations.

Fig. 1 - Locations of the meteorological stations in Turkey used in the study.

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A similar approach was applied for constructing the AHZs. First, raw monthly data pertaining to the number of days with a maximum temperature ≥ 30 °C were examined. It was observed that the days with a maximum temperature ≥ 30 °C were mainly clustered between the months of March and November. However, the monthly distribution of the days with a maximum temperature ≥ 30 °C was observed to vary greatly depending upon the meteorological station from which the data were acquired. It was found that in the June to August period in particular, temperature values reached well over 30 °C. Years in which no records had been collected for the June to August period were excluded from the calculation of the annual mean number of days with a maximum temperature ≥ 30 °C. Again, stations with less than 20 years of records within the whole 34-year period were excluded from the analysis. Thus, data from a total of 250 stations were included in the interpolation. For each station, after the mean annual extreme minimum temperatures and annual mean number of days with a maximum temperature ≥ 30 °C were calculated, we proceeded to constructing and mapping the plant cold and heat hardiness zones for each station. The values used in the classification of the plant cold and heat hardiness zones are shown in Tab. 1. There are 13 zones in the USDA PHZ map, subdivided into a and b sub-zones ([49]). However, no such detailed classification can be found in other maps used in different parts of the world ([21], [14], [51]), as no in-depth research has been carried out on hardiness zones outside US. Therefore, the sub-zones described above were not used in this study.

Forest tree data

After of the PHZ and AHZ maps were created, the zones where major tree species can be found in Turkish forests were determined. In this stage, 458 144 stand-type polygon centroid data acquired from the General Directorate of Forestry (GDF) were employed (Fig. 2).

Fig. 2 - Forest map of Turkey and the locations of the forest tree data used in the study (red points).

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Generation of plant hardiness zone maps

To produce the PHZ and AHZ maps, meteorological point-based data were converted to continuous surface data using the regularized spline with tension (RST) method ([35], [34]). To determine appropriate prediction parameters (tension, the number of points in the segment - segmax, the number of points used for interpolation within the segment and its neighborhood - npmin, smoothing) for the RST method ([36]), different tension and smoothing parameters were tested by cross-validation. Initially, the default values of the method (npmin = 300 and segmax = 40) were used. The number of points in a segment is controlled by segmax, and the number of points used for interpolation (within the segment and its neighborhood) is controlled by npmin ([36]). According to the cross-validation results, if the predictions were carried out with a tension of 20 and 0.2 smoothing for the mean extreme annual minimum temperatures and with a tension of 100 and 0.8 smoothing for the annual mean number of days with a maximum temperature ≥ 30 °C, the minimum RMSE (Root Mean Square Error) could be acquired, and the predictions could further decrease the error rate (Fig. 3).

Fig. 3 - RMSE of cross-validation with different tension and smoothing values a) for mean extreme annual minimum temperatures and b) for the annual mean number of days with a maximum temperature ≥ 30 °C.

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According to the results of the cross-validation method, it was found that the maps for the mean extreme annual minimum temperatures and mean annual number of days with a maximum temperature ≥ 30 °C were excessively generalized, and some local details were not shown when using parameters likely to give the least error. This may be likely due to the limited number of pinpoint values (meteorological stations) on the map and/or their large intervening distance (average 70 km). To reduce the effect of distant stations and to produce a much more detailed map, numerous interpolation maps with various tension, smoothing, npmin and segmax parameters were produced (Tab. 2). Maps showing the lowest RMSE values were visually checked depending on station average values. Plant cold and heat hardiness zone maps were then produced using the USDA PHZ and AHS AHZ classifications. Finally, the raster cell values from the obtained PHZ and AHZ maps were loaded into the polygon centroids of a forest stand type attribute table ([19]). The zones showing the distribution of 15 tree species were determined through queries performed on the vector data.

Tab. 2 - Interpolation parameters used in the PHZ and AHZ maps produced in this study.

segmax/npmin Tension/
smoothing
15/30 20-40-60-80-100/
0.2-0.4-0.6-0.8
30/60 20-40-60-80-100/
0.2-0.4-0.6-0.8
60/120 20-40-60-80-100/
0.2-0.4-0.6-0.8
120/240 20-40-60-80-100/
0.2-0.4-0.6-0.8

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  Results 

Validation test of maps

Goodness-of-fit of the maps obtained was tested by comparing the predicted and observed values for mean extreme annual minimum temperatures in each meteo station. Although maps obtained using the parameters 30 npmin 15 segmax and 60 npmin 30 segmax showed rather low RMSEs (less than 0.5 °C), they were not used because these maps exhibited strip-like patterns. The next best-fitting map (RMSE < 1 °C), obtained using the parameters 80 tension, 0.2 smoothing, 120 npmin and 60 segmax, was chosen for the construction of the plant cold hardiness zone map (Tab. 3).

Tab. 3 - RMSE values of the PHZ maps produced with different parameters.

Tension_smoothing segmax_npmin
15_30 30_60 60_120 120_240
20_0.2 0.77 1.13 1.77 2.22
40_0.2 0.37 0.52 1.07 1.36
60_0.2 0.28 0.35 0.89 1.04
80_0.2 0.23 0.28 0.83 0.91
100_0.2 0.20 0.79 0.85 0.85
20_0.4 1.26 1.58 1.99 2.40
40_0.4 0.93 1.06 1.27 1.58
60_0.4 0.86 0.92 1.03 1.22
80_0.4 0.83 0.87 0.93 1.06
100_0.4 0.81 0.84 0.97 0.97
20_0.6 1.41 1.75 2.13 2.52
40_0.6 1.03 1.19 1.42 1.75
60_0.6 0.93 1.02 1.15 1.37
80_0.6 0.89 0.95 1.04 1.19
100_0.6 0.87 0.91 1.08 1.08
20_0.8 1.54 1.87 2.24 2.62
40_0.8 1.13 1.30 1.55 1.87
60_0.8 1.01 1.12 1.27 1.50
80_0.8 0.96 1.03 1.14 1.30
100_0.8 0.93 0.98 1.19 1.19

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Analogously, predicted annual mean number of days with a maximum temperature ≥ 30 °C were compared to the observed (station) values for each produced map. The results obtained using the parameters 80 or 100 tension, 0.2 smoothing, 15 segmax, and 30 npmin and 100 tension, 0.2 smoothing, 30 segmax, and 60 npmin showed the lowest RMSEs, but the corresponding maps exhibited strip-like patterns. For this reason, the map produced using the parameters 80 tension, 0.2 smoothing, 60 segmax and 120 npmin (RMSE = 1.65 °C) was chosen for the construction of the plant heat hardiness zone map (Tab. 4).

Tab. 4 - RMSE values of the AHZ maps produced, using different parameters.

Tension_smoothing segmax_npmin
15_30 30_60 60_120 120_240
20_0.2 3.97 6.36 9.32 12.44
40_0.2 1.64 2.50 4.01 6.36
60_0.2 1.11 1.55 2.32 3.70
80_0.2 0.90 1.18 1.65 2.50
100_0.2 0.79 0.99 1.90 1.90
20_0.4 5.53 7.95 10.70 13.41
40_0.4 2.75 3.85 5.56 7.93
60_0.4 2.01 2.64 3.62 5.22
80_0.4 1.67 2.11 2.77 3.85
100_0.4 1.48 1.81 3.09 3.09
20_0.6 6.62 8.97 11.53 13.97
40_0.6 3.65 4.87 6.64 8.95
60_0.6 2.77 3.52 4.62 6.30
80_0.6 2.36 2.89 3.67 4.87
100_0.6 2.11 2.53 4.04 4.04
20_0.8 7.45 9.72 12.12 14.37
40_0.8 4.42 5.70 7.47 9.70
60_0.8 3.45 4.28 5.44 7.14
80_0.8 2.97 3.59 4.44 5.69
100_0.8 2.69 3.18 4.83 4.83

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Plant cold and heat hardiness zones in Turkey

The meteorological stations showing the lowest mean extreme annual minimum temperatures and the highest mean extreme annual minimum temperatures in Turkey were those of Agri and Kas (-32.89 °C and 2.80 °C, respectively - Tab. 5). According to the generated PHZ maps (Fig. 4), it can clearly be concluded that not all of the USDA PHZs are present in Turkey. A total of 7 PHZs, with mean extreme annual minimum temperatures ranging between -34.4 °C and 4.4 °C, can be observed. These 7 zones are located between PHZs 4 and 10. In the central and eastern Anatolian region, where the continental climate is dominant, 4 to 7 PHZs are present (Fig. 4). The 10th PHZ, in which the mean extreme annual minimum temperatures are higher, is located on the Mediterranean coastline. Other coastline regions are situated in the 9th PHZ. A considerable portion (32.99%) of the country is found in PHZ 7. In contrast, PHZ 4 covers the smallest area (0.38% - Tab. 6).

Tab. 5 - Summary statistics for the observed and interpolated mean extreme annual minimum temperatures and annual mean number of days with a maximum temperature ≥ 30 °C during the period from 1975-2008 in Turkey (interpolated values in parenthesis).

Parameters Mean Minimum Maximum Standard
deviation
Mean extreme annual minimum temperatures -11.10
(-11.22)
-32.89 (Agri)
(-32.48)
2.80 (Kas)
(2.45)
7.80
(7.60)
Annual mean number of days with a maximum temperature ≥ 30 °C 52.54
(52.88)
4.56 (Zonguldak)
(5.74)
144.24 (Cizre)
(141.35)
30.70
(30.12)

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Fig. 4 - USDA Plant Hardiness Zone (PHZ) map of Turkey.

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Tab. 6 - The distribution of land in Turkey according to the PHZ and AHZ.

USDA Plant Hardiness Zones AHS Plant Heat Zones
Zones Area
(1000 ha)
% Zones Area
(1000 ha)
%
1 - - 1 - -
2 - - 2 137.11 0.18
3 - - 3 1205.27 1.55
4 298.8 0.38 4 17141.64 22.02
5 4793.63 6.16 5 25864.88 33.22
6 8362.92 10.74 6 13636.91 17.51
7 25685.62 32.99 7 11501.15 14.77
8 17954.34 23.06 8 6674.85 8.57
9 18272.86 23.47 9 1697.83 2.18
10 2491.45 3.2 10 - -
11 - - 11 - -
12 - - 12 - -
13 - - - - -
Total 77859.62 100 - 77859.62 100

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The Zonguldak stations had the fewest (4.56) annual mean number of days with a maximum temperature ≥ 30 °C. The maximum value for this parameter (144.24 days year-1) was registered at the Cizre station (Tab. 5). Based on measurements obtained from the meteorological stations, only AHZ categories 2-9 out of the 12 previously reported are present in Turkey (Fig. 5). AHZ 5 covers the largest area (33.22 %), with an annual mean number of days with a maximum temperature ≥ 30 °C ranging from 30 to 45. AHZ 2, in which the days with temperatures ≥ 30 °C ranges from 1 to 7, corresponds to 0.18% of the land area (Tab. 6). In contrast, AHZ 9, which was associated with an annual mean of more than 120 days with a maximum temperature ≥ 30 °C, corresponds to 2.18 % of the land area.

Fig. 5 - AHS Plant Heat Zone (AHZ) map of Turkey.

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Distribution of forest trees in plant cold hardiness zones

None of the centroids of the polygons for the 458 144 investigated stand types was located in PHZ 4. Juniperus spp., Quercus spp. and Abies spp. were found to be the most widely distributed species across PHZs. These particular species were found between PHZ 5 and 10. The narrowest distribution was showed by Liquidambar orientalis, which was found only in PHZ 9. Exotic Eucalyptus species were planted in PHZs 7 to 10. Other species, such as P. orientalis and P. sylvestris, existed in PHZs 5 to 9; P. brutia, C. libani, P. pinea, were found in PHZs 7 to 10; and P. nigra and F. orientalis were observed in PHZs 6 to 10. It was found that Castanea sativa, Alnus spp. and Carpinus spp. were located in PHZs 7, 8 and 9, in which the mean extreme annual minimum temperatures were less than -6.6 °C. Additionally, differences were found among the PHZs where the investigated tree species were most densely distributed. P. sylvestris was predominantly found in PHZ 7. In contrast, P. nigra, P. orientalis, Abies spp., Juniperus spp., F. orientalis and Quercus spp. inhabited PHZ 8 extensively. All of the remaining investigated species were mainly linked to PHZ 9 (Tab. 7).

Tab. 7 - USDA PHZs in which the main forest tree species are distributed in Turkey.

Species USDA Plant Hardiness Zones Total
5 6 7 8 9 10
Pinus brutia - - 2395 28381 107132 18165 156073
Pinus nigra - 76 15353 75223 36115 340 127107
Pinus sylvestris 3082 4732 16970 14596 753 - 40133
Abies spp. 84 502 3713 6356 2542 33 13230
Picea orientalis 9 756 3493 8238 749 - 13245
Juniperus spp. 53 106 1357 5652 4942 284 12394
Cedrus libani - - 4 1891 4005 1636 7536
Pinus pinea - - 4 120 2926 245 3295
Quercus spp. 19 372 7801 24099 1369 616 52276
Fagus orientalis - 8 3638 14442 7402 187 25677
Carpinus spp. - - 141 441 461 - 1043
Alnus spp. - - 4 1304 1804 - 3112
Castanea sativa - - 48 942 1376 - 2366
Eucalyptus spp. - - 19 207 350 27 603
Liquidambar orientalis - - - - 54 - 54
Total 3247 6552 5494 181892 189980 21533 458144

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Distribution of forest trees in plant heat hardiness zones

As for heat hardiness zones associated with the forest trees in Turkey, none of the 458 144 centroids obtained was located in AHZ 1. Among the investigated forest species, the annual mean number of days with a maximum temperature ≥ 30 °C ranged from 2 to 150 in the distribution area of P. brutia and Quercus spp., and these species were present in every AHZ zone from 2 to 9. After P. brutia and Quercus spp., the most widely abundant species were P. nigra, Abies spp. Fagus orientalis and C. sativa, which were observed in AHZs 2 to 8. The narrowest distribution was that of Liquidambar orientalis, which was only found in AHZs 7 and 8, where the average number of days with a temperature ≥ 30 °C was more than 60. The plant heat hardiness zones in which the investigated species were predominantly found varied considerably. Abies spp., P. orientalis, F. orientalis, C. sativa, Alnus spp. and Carpinus spp. were extensively encountered in AHZ 4, while P. nigra, P. sylvestris, Quercus spp. and Eucalyptus spp. were mainly located in AHZ 5, Juniperus spp. in AHZ 6, P. brutia and C. libani in AHZ 7, and P. pinea and L. orientalis in AHZ 8 (Tab. 8).

Tab. 8 - AHZs in which the main forest tree species are distributed in Turkey.

Species AHS Plant Heat Zones Total
2 3 4 5 6 7 8 9
Pinus brutia 2 21 3508 1984 31967 54033 45753 1805 156073
Pinus nigra 4 1053 24861 5048 26679 13481 10549 - 127107
Pinus sylvestris 19 454 18421 20667 572 - - - 40133
Abies spp. 19 1022 6835 2635 1133 1111 475 - 1323
Picea orientalis - - 13238 7 - - - - 13245
Juniperus spp. - 13 741 2023 4796 3006 1761 - 12394
Cedrus libani - - 3 43 2485 4469 536 - 7536
Pinus pinea - -- 111 288 411 965 1520 - 3295
Quercus spp. 43 1794 12661 18525 10246 4635 4289 83 52276
Fagus orientalis 91 3181 14896 6036 902 447 124 - 25677
Carpinus spp. - 155 576 258 17 31 6 - 1043
Alnus spp. - - 3107 5 - - - - 3112
Castanea sativa 12 295 1906 56 14 10 73 - 2366
Eucalyptus spp. - - 51 185 176 143 48 - 603
Liquidambar orientalis - - - - - 6 48 - 54
Total 190 7988 100915 120192 79398 82391 65182 1888 458144

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  Discussion 

Validation test of the maps

Climatic factors are among the most important factors affecting plant growth. Therefore, climatic characteristics associated with the species being addressed are essential. In agricultural, forestry or horticultural studies, continuous surface climatic data are employed more effectively compared to pinpoint data. In recent years, developments in computer technologies have created new opportunities for researchers to conduct more detailed studies ([20]). The thin plate spline interpolation method, a form of the regularized spline with tension method (RST) adopted in this study, was used by McKenney et al. ([30]) to revise the Canadian PHZ map. The RMSE value of the of annual extreme minimum temperatures map was less than 1 °C, while the RMSE value for the average number of days with a temperature ≥ 30 °C was less than 2 days.

Based on the above evidence, in this study we decided to apply the RST method for pinpoint data interpolation and map production. However, the limited number and the geographic distribution of the meteorological data used in this study is a matter deserving to come under scrutiny. Most of the weather stations in Turkey are located next to urban areas, and only few are inside forested areas. For this reason, the distance between the stations considered in this study is approximately 70 km. This uneven and sparse distribution may locally increase the error rates of the interpolated surface. As the effects of climatic changes are currently being felt with increasing strength, reliable climatic data are needed more than ever before. The majority of the developed world has already set up extensive meteorological networks, while the developing world is lagging behind due to budget cuts and different priorities ([20]). Thus, the number of meteorological stations in the countryside in Turkey needs to be increased.

Plant cold and heat hardiness zones in Turkey

In the PHZ map produced for Europe by Heinze and Schreiber in 1984, PHZs 4 to 10 are generally encountered in central to southern Europe, while PHZ 3 is encountered in northern European countries, including Norway, Sweden and Finland. PHZs 1 and 2 are found beyond a latitude of 60° in northern Russia. PHZs 4 to 10 can also be found in Turkey on the European PHZ map ([21]). Overall, 7 of 13 PHZs can be found in Turkey. However, the European PHZ map is rather small in scale and depends upon old meteorological data. It has been reported that some shifts have occurred in PHZs due to changing climatic conditions ([30]). In this study, at the same time a larger-scale map was produced, and a more detailed and up-to-date Turkish PHZ map was created using data from meteorological records from 1975 to 2008.

The results of this study showed there were 7 PHZs in Turkey, whereas the majority of other European countries exhibited only 3 or 4, which is believed to be the result of Turkey’s geographic location and landforms. Turkey has the form of a peninsula, in which the terrestrial climate dominates the central part of the country, while steep mountainous terrain is located in its eastern region. These conditions cause numerous climatic types to take place over the countryside. For this reason, 8 of the 12 AHZs can be found in Turkey. AHZ map, which represent a relatively new form of hardiness classification, have not been completed for Turkey and for the rest of Europe.

Distribution of forest trees in plant cold hardiness zones

Cold and heat hardiness zone maps are not useful in cases where the plants of interest can survive in zones which are not known; therefore, it is necessary to determine where plants survive through long-term observations.

Observations concerning cold hardiness have been recorded for many years. Many botanical books report plant characteristics in association with the USDA PHZs in which they survive. When a PHZ is specified, both the lower and upper zone boundaries are given in some cases, while in others only the lower boundaries are reported (Tab. 9). Additionally, there might be differences concerning the zone boundaries for particular species, which are thought to arise from observations performed outside their natural distribution area; however, such observations should be made within the species’ natural range. Moreover, irrigation and fertilization treatments can bolster plant hardiness.

Tab. 9 - Comparison of the PHZ and AHZ values determined for some of the forest tree species in Turkey with those from other sources: (a) Cheers ([13]); (b) Krüssmann ([25], [26], [27], [28]); (c) AHS ([2], [3], [4], [5]).

Species USDA Plant Hardiness Zone (PHZ) AHS Plant Heat Zone (AHZ)
Cheers(a) Krüssmann(b) This study American
Gardener(c)
This study
Abies nordmanniana 4-9 5 5-10 - 8-2
Abies cilicica - 6 - - -
Abies equitrojani - 6 - - -
Abies nordmanniana subsp. bornmulleriana - 6 - - -
Cedrus libani 6-9 7 7-10 - 8-4
Juniperus communis 2-9 - 5-10 6-1 8-3
Juniperus excelsa - 7 - - -
Juniperus foetidissima - 9 - - -
Juniperus oxycedrus - 9 - - -
Juniperus phoenicea - 8-9 - - -
Juniperus sabina 3-9 3-7 - 7-1 -
Picea orientalis 3-9 5 5-9 8-1 5-4
Pinus brutia - 8 7-10 - 9-2
Pinus nigra 4-9 4 6-10 - 8-2
Pinus pinea 8-10 - 7-10 - 8-4
Pinus sylvestris 4-9 5 5-9 7-1 6-2
Alnus glutinosa 4-9 6 7-9 - 5-4
Alnus orientalis 7-10 6 - - -
Carpinus betulus 6-9 5 7-9 8-1 8-3
Carpinus orientalis 6-9 6 - - -
Castanea sativa 5-9 6 7-9 - 8-2
Eucalyptus camaldulensis 9-12 - 7-10 - 8-4
Eucalyptus grandis 10-11 - - - -
Fagus orientalis 5-10 6 6-10 - 8-2
Liqiudambar orientalis 8-11 - 9 - 8-7
Quercus cerris 7-10 7 5-10 - 9-2
Quercus coccifera - 9 - - -
Quercus frainetto - 6 - - -
Quercus ilex 7-10 8 - - -
Quercus infectoria - 9 - - -
Quercus libani - 7 - - -
Quercus macranthera - 6 - - -
Quercus petraea 5-9 5 - - -
Quercus pontica - 6 - - -
Quercus pubescens - 7 - - -
Quercus robur 3-10 5 - - -
Quercus trojana - 8 - - -

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In this study, the PHZs in which several forest tree species occur in Turkey were identified and compared to the PHZs given in the literature. Concerning this analysis, the PHZs identified here for Quercus spp. were fairly similar to those reported in the literature. Species such as Abies spp., P. orientalis, P. nigra, P. sylvestris, C. libani, Juniperus spp., Alnus spp., C. sativa, F. orientalis, Carpinus spp. and L. orientalis were found in higher PHZs compared with previous studies (Tab. 9). As mentioned above, this might be due to the fact that the observations concerning these species were made outside of their natural distribution areas. In contrast, P. brutia, P. pinea and Eucalyptus spp. were found in lower PHZs as compared with evidence reported in the literature. This might be due to the extensive use of both species in plantations over the country. Moreover, since its complex geomorphology, there are numerous valleys and gorges showing specific microclimates in Turkey, and this affects climatic conditions over relatively short distances. However, depicting local conditions using the sparse weather station network currently in place is rather difficult.

Distribution of forest trees in plant heat zones

AHZ classification represents a relatively new methodology; for this reason, no AHZ has been determined for the majority of plants. Only 5 out of all of the investigated tree species are assigned to a specific AHZ in the literature. Of these species, Carpinus spp. was assigned to a similar AHZs in both this and previous studies. Picea orientalis, previously reported as associated to AHZs 8-1, was found within AHZs 5-4 in this investigation (Tab. 9). Moreover, the AHZs determined for Juniperus spp. were different from zones previously determined for several Juniperus species. This may be due to the fact that data from forest inventories in Turkey are aggregated for several species of the genera Abies, Juniperus, Quercus, Carpinus and Alnus, and no species-level information were collected. Therefore, forest inventory must be conducted at the species level so that a more reliable information on the distribution of forest trees in Turkey could be obtained.

Hardiness zones have gained great importance due to a wide expansion of the horticulture sector in general, introducing new species and increasing the use of native species outside of their natural distribution areas ([31]). The most important advantage of PHZs is that the hardiness zones where most ornamental plants can be found have been determined based on observations performed over about a hundred years. This is the main reason that PHZ and AHZ classifications are preferable to other bioclimatic classifications, such as Köppen and De Martonne. Additionally, most bioclimatic classifications are based on climatic parameters such as temperature, precipitation and evapotranspiration, and represent climate characteristics in the natural distribution areas of plant species. Bioclimatic classifications based on water efficiency (such as the De Mortanne Aridity Index and Thornthwaite Precipitation Effectiveness Index) can be insufficient in the case of plant species growing outside of their natural distribution areas, or in areas where water deficiency is not a main limiting factor for plant growth. Furthermore, extreme temperatures have not been considered as a parameter in many bioclimatic classifications. Long-term observations demonstrated that extreme minimum and maximum temperatures were the most important limiting factor for plant growth in areas to be irrigated and fertilized, such as gardens. Extreme temperatures are used as a parameter in the Continentality and Thermicity Indexes developed by Rivas-Martinez ([42]). Determination of the index values in which all species can be present is essential for common usage of these bioclimatic indices, which are quite new.

  Conclusion 

Plant hardiness zone maps may be disputed because of they are highly general, and the hardiness of a particular species can be dramatically affected by local conditions. Despite these drawbacks, the use of these maps is gradually becoming common. Along with the cold and heat hardiness maps produced in this study, the delineation of the zones in which some forest tree species can survive is becoming more critical in the selection of species to be planted. In addition to their use in forestry, plant hardiness zones are employed in the selection of species in other fields, especially in gardening.

  Acknowledgments 

The authors sincerely appreciate the cooperation provided by both the Turkish State Meteorological Service and the General Directorate of Forestry.

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Authors’ Affiliation

(1)
OY Yilmaz
D Tolunay
Department of Forest Engineering, Faculty of Forestry, Istanbul University, 34473 Bahçeköy, Istanbul (Turkey)

Corresponding author

Citation

Yilmaz OY, Tolunay D (2012). Distribution of the major forest tree species in Turkey within spatially interpolated plant heat and hardiness zone maps. iForest 5: 83-92. - doi: 10.3832/ifor0611-005

Academic Editor

Marco Borghetti

Paper history

Received: Nov 25, 2011
Accepted: Mar 27, 2012

First online: Apr 30, 2012
Publication Date: Apr 30, 2012
Publication Time: 1.13 months

© SISEF - The Italian Society of Silviculture and Forest Ecology 2012

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