The subarctic climate (also called subpolar climate, subalpine climate, or boreal climate) is a climate characterised by long, usually very cold winters, and short, cool to mild summers. It is found on large landmasses, away from the moderating effects of an ocean, generally at latitudes from 50° to 70°N poleward of the humid continental climates. These climates represent Köppen climate classification Dfc, Dwc, Dsc, Dfd, Dwd and Dsd. In very small areas at high altitudes around the Mediterranean Basin, Iran, Kyrgyzstan, Tajikistan, Turkey, Alaska and other parts of the northwestern United States (Eastern Washington, Eastern Oregon and Idaho) and Russian South-Eastern regions the climate is classified as Dsc with a dry summer climate, such as in Seneca, Oregon.
Contents
1Description
1.1Precipitation
1.2Vegetation and land use
2Distribution
3Charts of selected sites
4See also
5References
Description
This type of climate offers some of the most extreme seasonal temperature variations found on the planet: in winter, temperatures can drop to −40 °C (−40 °F) and in summer, the temperature may exceed 30 °C (86 °F). However, the summers are short; no more than three months of the year (but at least one month) must have a 24-hour average temperature of at least 10 °C (50 °F) to fall into this category of climate and the coldest month should average below 0 °C (32 °F) (or −3 °C (27 °F)). Record low temperatures can approach −70 °C (−94 °F).[1]
With 5–7 consecutive months where the average temperature is below freezing, all moisture in the soil and subsoil freezes solidly to depths of many feet. Summer warmth is insufficient to thaw more than a few surface feet, so permafrost prevails under most areas not near the southern boundary of this climate zone. Seasonal thaw penetrates from 2 to 14 ft (0.61 to 4.27 m), depending on latitude, aspect, and type of ground.[2] Some northern areas with subarctic climates located near oceans (southern Alaska, the northern fringe of Europe, Sakhalin Oblast and Kamchatka Oblast), have milder winters and no permafrost, and are more suited for farming unless precipitation is excessive. The frost-free season is very short, varying from about 45 to 100 days at most, and a freeze can occur during any month in many areas.
Precipitation
Most subarctic climates have very little precipitation, typically no more than 380 mm (15 in) over an entire year. Away from the coasts, precipitation occurs mostly in the warmer months, while in coastal areas with subarctic climates the heaviest precipitation is usually during the autumn months when the relative warmth of sea vis-à-vis land is greatest. Low precipitation, by the standards of more temperate regions with longer summers and warmer winters, is typically sufficient in view of the very low evapotranspiration to allow a water-logged terrain in many areas of subarctic climate and to permit snow cover during winter.
A notable exception to this pattern is that subarctic climates occurring at high altitudes in otherwise temperate regions have extremely high precipitation due to orographic lift. Mount Washington, with temperatures typical of a subarctic climate, receives an average rain-equivalent of 101.91 inches (2,588.5 mm) of precipitation per year.[3] Coastal areas of Khabarovsk Krai also have much higher precipitation in summer due to orographic influences (up to 175 millimetres (6.9 in) in July in some areas), whilst the mountainous Kamchatka peninsula and Sakhalin island are even wetter since orographic moisture is not confined to the warmer months and creates large glaciers in Kamchatka. Labrador, in eastern Canada, is similarly wet throughout the year due to the semi-permanent Icelandic Low and can receive up to 1,300 millimetres (51 in) of rainfall equivalent per year, creating a snow cover of up to 1.5 metres (59 in) that does not melt until June.
Vegetation and land use
Vegetation in regions with subarctic climates is generally of low diversity, as only hardy species can survive the long winters and make use of the short summers. Trees are mostly limited to conifers, as few broadleaved trees are able to survive the very low temperatures in winter. This type of forest is also known as taiga, a term which is sometimes applied to the climate found therein as well. Even though the diversity may be low, numbers are high, and the taiga (boreal) forest is the largest forest biome on the planet, with most of the forests located in Russia and Canada. The process by which plants become acclimated to cold temperatures is called hardening.
Agricultural potential is generally poor, due to the natural infertility of soils[citation needed][dubious – discuss] and the prevalence of swamps and lakes left by departing ice sheets, and short growing seasons prohibit all but the hardiest of crops. (Despite the short season, the long summer days at such latitudes do permit some agriculture.) In some areas, ice has scoured rock surfaces bare, entirely stripping off the overburden. Elsewhere rock basins have been formed and stream courses dammed, creating countless lakes.[2]
Distribution
The Dfc climate, by far the most common subarctic type, is found in the following areas:[4][5]
Much of Siberia
The Kamchatka Peninsula
Mountain summits in Scotland
The northern and central parts of the Kuril Islands and Sakhalin Island
The Western Alps between 1,600 and 2,100 meters (5,200 and 6,900 ft), and the Eastern Alps between 1,450 and 1,800 meters (4,760 and 5,910 ft) –France, Switzerland, Germany, Italy and Austria.
The center of Romania.
In some parts of Germany.
The Tatra Mountains in Poland, above 800 meters (2,600 ft).
The Eastern Anatolia, between 1,600 and 2,100 meters (5,200 and 6,900 ft) – Turkey.
The Pyrenees, between 1,600 and 2,100 meters (5,200 and 6,900 ft) – Andorra, France and Spain.
The northern inland regions of Fennoscandia (milder winters in coastal areas)
Most of Interior, Western and Southcentral Alaska
The high Rocky Mountains in Colorado, Wyoming, Idaho and Montana and the White Mountains of New Hampshire
Much of Canada from about 53–55°N to the tree line, including:
Southern Labrador
Certain areas within Newfoundland interior and along its northern coast
Quebec: Jamésie, Côte-Nord and far southern Nunavik
Far northern Ontario
The northern Prairie Provinces
The Rocky Mountain Foothills in Alberta and British Columbia.
Most of the Yukon
Most of the Northwest Territories
In parts of East Asia, like China, the Siberian High makes the winters colder than places like Scandinavia or Alaska interior but extremely dry (typically with around 5 millimeters (0.20 in) of rainfall equivalent per month) that snow cover is very limited, creating a Dwc climate in:
Much of northern Mongolia
Russia:
Most of Khabarovsk Krai except the south
Southeastern Sakha Republic
Southern Magadan Oblast
Northern Amur Oblast
Northern Buryatia
Zabaykalsky Krai
Irkutsk Oblast
China:
Tahe County and Mohe County in Heilongjiang
Northern Hulunbuir in Inner Mongolia
Gannan in Gansu (due to extreme altitude)
Huangnan, eastern Hainan and eastern Guoluo in Qinghai (due to extreme altitude)
Most of Garzê and Ngawa Autonomous Prefectures (due to extreme altitude) in Sichuan
Most of Qamdo Prefecture (due to extreme altitude) in the Tibet Autonomous Region
Parts of Ladakh (including Siachen Glacier) and Spiti regions of India.
Parts of Kaema Plateau(including Mount Baekdu, Samjiyon, Musan) in North Korea
Further north in Siberia, continentality increases so much that winters can be exceptionally severe, averaging below −38 °C (−36 °F), even though the hottest month still averages more than 10 °C (50 °F). This creates Dfd, Dwd and Dsd climates.[clarification needed]
The Southern Hemisphere, which has no large landmasses in the upper-middle latitudes that can have both the short but well-defined summers and severe winters that characterize this climate, has very few locations with this climate. One example is parts of the Snowy Mountains in Australia, although they're more alpine than true subarctic.
Should one go poleward or even toward a polar sea, one finds that the warmest month has an average temperature of less than 10 °C (50 °F), and the subarctic climate grades into a tundra climate even less suitable for trees. Equatorward or toward a lower altitude, this climate grades into the humid continental climates with longer summers (and usually less-severe winters); in a few locations close to a temperate sea (as in North Norway and southern Alaska), this climate can grade into a short-summer version of an oceanic climate, the subpolar oceanic climate, as the sea is approached. In China and Mongolia, as one moves southwestwards or towards lower altitudes, temperatures increase but precipitation is so low that the subarctic climate grades into a cold semi-arid climate.
Charts of selected sites
Anchorage, Alaska, United States
Climate chart (explanation)
J
F
M
A
M
J
J
A
S
O
N
D
19
−5
−12
19
−3
−10
15
1
−7
12
7
−2
19
14
4
24
18
9
46
19
11
82
18
10
76
13
5
52
5
−2
30
−2
−9
28
−4
−10
Average max. and min. temperatures in °C
Precipitation totals in mm
Source: NOAA
Imperial conversion
J
F
M
A
M
J
J
A
S
O
N
D
0.7
23
11
0.7
27
14
0.6
35
19
0.5
45
29
0.7
57
39
0.9
64
47
1.8
66
52
3.2
64
50
3
55
42
2
41
29
1.2
28
17
1.1
24
13
Average max. and min. temperatures in °F
Precipitation totals in inches
Yellowknife, Northwest Territories, Canada
Climate chart (explanation)
J
F
M
A
M
J
J
A
S
O
N
D
14
−23
−31
13
−19
−28
13
−11
−23
11
0
−11
19
11
1
27
18
9
35
21
12
41
18
10
33
10
4
35
1
−4
24
−10
−18
16
−20
−28
Average max. and min. temperatures in °C
Precipitation totals in mm
Source: Environment Canada[6]
Imperial conversion
J
F
M
A
M
J
J
A
S
O
N
D
0.6
−9
−24
0.5
−1
−19
0.5
12
−10
0.4
33
12
0.8
51
33
1.1
65
48
1.4
70
54
1.6
65
51
1.3
51
39
1.4
34
24
0.9
14
0
0.6
−3
−18
Average max. and min. temperatures in °F
Precipitation totals in inches
Moosonee, Ontario, Canada
Climate chart (explanation)
J
F
M
A
M
J
J
A
S
O
N
D
34
−15
−27
23
−12
−26
32
−5
−20
39
4
−9
54
12
−1
71
18
5
101
22
8
76
20
8
90
15
4
73
8
−1
54
−1
−9
35
−11
−22
Average max. and min. temperatures in °C
Precipitation totals in mm
Source: Environment Canada[7]
Imperial conversion
J
F
M
A
M
J
J
A
S
O
N
D
1.3
5
−16
0.9
11
−15
1.2
24
−4
1.5
38
16
2.1
53
31
2.8
65
40
4
71
47
3
69
46
3.5
58
39
2.9
46
31
2.1
31
16
1.4
12
−8
Average max. and min. temperatures in °F
Precipitation totals in inches
Samedan, Graubünden, Switzerland
Climate chart (explanation)
J
F
M
A
M
J
J
A
S
O
N
D
30
−2
−18
25
0
−17
31
3
−12
44
6
−6
81
12
−1
87
16
2
89
18
3
99
18
3
72
15
0
59
11
−4
54
4
−11
31
−2
−16
Average max. and min. temperatures in °C
Precipitation totals in mm
Source: MeteoSchweiz[8]
Imperial conversion
J
F
M
A
M
J
J
A
S
O
N
D
1.2
28
0
1
32
1
1.2
37
11
1.7
44
22
3.2
53
30
3.4
60
35
3.5
65
37
3.9
64
37
2.8
59
32
2.3
51
24
2.1
38
13
1.2
29
3
Average max. and min. temperatures in °F
Precipitation totals in inches
Luleå, Sweden
Climate chart (explanation)
J
F
M
A
M
J
J
A
S
O
N
D
32
−7
−13
26
−6
−13
23
−1
−9
18
4
−3
23
11
2
32
17
9
42
20
12
42
18
11
31
12
6
34
6
0
31
−2
−6
27
−6
−11
Average max. and min. temperatures in °C
Precipitation totals in mm
Source: World Weather Information[9]
Imperial conversion
J
F
M
A
M
J
J
A
S
O
N
D
1.3
19
9
1
21
9
0.9
30
16
0.7
39
27
0.9
52
36
1.3
63
48
1.7
68
54
1.7
64
52
1.2
54
43
1.3
43
32
1.2
28
21
1.1
21
12
Average max. and min. temperatures in °F
Precipitation totals in inches
Nerdal/Mo i Rana, Norway
Climate chart (explanation)
J
F
M
A
M
J
J
A
S
O
N
D
146
−3
−8
117
−2
−7
112
2
−4
74
5
−1
64
12
4
70
16
8
97
18
10
110
16
9
155
11
6
186
6
2
136
1
−4
163
−1
−6
Average max. and min. temperatures in °C
Precipitation totals in mm
Source: met.no/klimastatistikk/eklima
Imperial conversion
J
F
M
A
M
J
J
A
S
O
N
D
5.7
27
17
4.6
29
19
4.4
35
24
2.9
42
30
2.5
53
38
2.8
61
46
3.8
64
51
4.3
62
49
6.1
52
42
7.3
43
35
5.4
34
26
6.4
30
20
Average max. and min. temperatures in °F
Precipitation totals in inches
Tromsø, Norway
Climate chart (explanation)
J
F
M
A
M
J
J
A
S
O
N
D
95
−2
−7
87
−2
−7
72
0
−5
64
3
−2
48
8
2
59
13
6
77
15
9
82
14
8
102
9
4
131
5
1
108
1
−3
106
−1
−5
Average max. and min. temperatures in °C
Precipitation totals in mm
Source: World Weather Information Service
Imperial conversion
J
F
M
A
M
J
J
A
S
O
N
D
3.7
28
20
3.4
28
20
2.8
31
23
2.5
37
28
1.9
46
36
2.3
55
43
3
60
48
3.2
57
46
4
49
40
5.2
40
33
4.3
33
27
4.2
30
22
Average max. and min. temperatures in °F
Precipitation totals in inches
Kiruna, Sweden
Climate chart (explanation)
J
F
M
A
M
J
J
A
S
O
N
D
30
−11
−22
25
−9
−20
26
−5
−18
27
−1
−9
34
8
−2
49
15
5
86
18
7
74
15
5
49
10
1
47
−2
−11
42
−7
−13
34
−9
−20
Average max. and min. temperatures in °C
Precipitation totals in mm
Source: SMHI[10]
Imperial conversion
J
F
M
A
M
J
J
A
S
O
N
D
1.2
12
−7
1
16
−4
1
23
−1
1.1
30
15
1.3
47
29
1.9
59
41
3.4
64
45
2.9
59
42
1.9
49
33
1.9
28
13
1.7
20
8
1.3
16
−4
Average max. and min. temperatures in °F
Precipitation totals in inches
Verkhoyansk, Sakha Republic, Russia
Climate chart (explanation)
J
F
M
A
M
J
J
A
S
O
N
D
6
−43
−49
6
−37
−46
5
−20
−39
6
−3
−22
12
10
−3
23
20
6
33
23
9
32
18
4
14
9
−3
13
−9
−19
10
−32
−40
8
−40
−47
Average max. and min. temperatures in °C
Precipitation totals in mm
Source: Pogoda.ru.net
Imperial conversion
J
F
M
A
M
J
J
A
S
O
N
D
0.2
−45
−56
0.2
−34
−51
0.2
−4
−37
0.2
26
−8
0.5
50
27
0.9
68
43
1.3
74
48
1.3
65
40
0.6
47
27
0.5
16
−3
0.4
−26
−40
0.3
−40
−52
Average max. and min. temperatures in °F
Precipitation totals in inches
Mohe, Heilongjiang, China
Climate chart (explanation)
J
F
M
A
M
J
J
A
S
O
N
D
5
−22
−36
4.4
−13
−33
6.9
−3
−24
24
8
−8
33
18
0
68
24
8
99
26
12
107
23
9
50
16
1
16
5
−10
13
−11
−25
7.4
−21
−34
Average max. and min. temperatures in °C
Precipitation totals in mm
Source: Weather China[11]
Imperial conversion
J
F
M
A
M
J
J
A
S
O
N
D
0.2
−7
−33
0.2
9
−28
0.3
26
−12
0.9
46
19
1.3
64
33
2.7
76
46
3.9
78
53
4.2
74
49
2
62
35
0.6
41
14
0.5
13
−14
0.3
−6
−29
Average max. and min. temperatures in °F
Precipitation totals in inches
Lukla, Nepal
Climate chart (explanation)
J
F
M
A
M
J
J
A
S
O
N
D
11
1
−18
18
2
−16
22
5
−12
28
8
−7
34
12
−3
96
15
2
154
14
4
145
13
4
81
13
1
37
9
−7
6.2
6
−13
13
3
−16
Average max. and min. temperatures in °C
Precipitation totals in mm
Source: weatherbase.com[12]
Imperial conversion
J
F
M
A
M
J
J
A
S
O
N
D
0.4
34
−1
0.7
35
3
0.9
40
10
1.1
47
19
1.4
53
26
3.8
58
35
6.1
58
39
5.7
56
38
3.2
55
33
1.5
48
20
0.2
42
10
0.5
38
3
Average max. and min. temperatures in °F
Precipitation totals in inches
Crater Lake, Oregon, United States
Climate chart (explanation)
J
F
M
A
M
J
J
A
S
O
N
D
267
1
−8
205
2
−8
196
3
−7
123
6
−5
84
10
−2
57
15
2
20
21
5
25
21
5
52
17
3
127
11
−1
239
4
−5
290
2
−7
Average max. and min. temperatures in °C
Precipitation totals in mm
Source: SHMI[13]
Imperial conversion
J
F
M
A
M
J
J
A
S
O
N
D
11
34
18
8.1
35
18
7.7
37
19
4.8
43
23
3.3
50
29
2.2
58
35
0.8
69
41
1
69
41
2
63
37
5
52
31
9.4
40
24
11
35
20
Average max. and min. temperatures in °F
Precipitation totals in inches
Norilsk, Krasnoyarsk Krai, Russia
Climate chart (explanation)
J
F
M
A
M
J
J
A
S
O
N
D
22
−25
−34
17
−24
−33
20
−17
−29
21
−9
−21
21
−1
−10
45
9
1
52
17
8
61
14
5
64
6
0
44
−6
−13
35
−18
−26
34
−22
−31
Average max. and min. temperatures in °C
Precipitation totals in mm
Source: SHMI[14]
Imperial conversion
J
F
M
A
M
J
J
A
S
O
N
D
0.9
−13
−29
0.7
−11
−27
0.8
1
−20
0.8
16
−6
0.8
30
14
1.8
48
34
2
63
46
2.4
57
41
2.5
43
32
1.7
21
9
1.4
0
−15
1.3
−8
−24
Average max. and min. temperatures in °F
Precipitation totals in inches
Östersund, Sweden
Climate chart (explanation)
J
F
M
A
M
J
J
A
S
O
N
D
19
−6
−13
16
−4
−12
14
1
−8
20
5
−3
23
13
3
47
18
8
61
19
10
48
17
9
34
12
5
25
6
1
19
0
−5
18
−3
−10
Average max. and min. temperatures in °C
Precipitation totals in mm
Source: yr.no
Imperial conversion
J
F
M
A
M
J
J
A
S
O
N
D
0.7
22
9
0.6
25
11
0.6
33
18
0.8
42
27
0.9
55
37
1.9
64
46
2.4
66
50
1.9
63
48
1.3
53
41
1
44
34
0.7
32
23
0.7
26
15
Average max. and min. temperatures in °F
Precipitation totals in inches
Oulu, Finland
Climate chart (explanation)
J
F
M
A
M
J
J
A
S
O
N
D
33
−6
−14
28
−6
−13
23
−1
−9
34
6
−3
32
13
3
49
18
9
70
21
12
65
18
10
57
13
5
46
6
1
41
0
−6
36
−4
−11
Average max. and min. temperatures in °C
Precipitation totals in mm
Source: Tilastokeskus: Tilastoja Suomen ilmastosta 1981-2010
For other people named Steve Gadd, see Steve Gadd (disambiguation). Steve Gadd Gadd at Bodø Jazz Open, 2014 Background information Birth name Stephen Kendall Gadd Born ( 1945-04-09 ) April 9, 1945 (age 73) Irondequoit, New York, U.S. Genres Jazz post-bop jazz fusion rock blues R&B Occupation(s) Musician, drummer, percussionist and session musician Instruments Drums, percussion Years active 1968–present Website www.drstevegadd.com Stephen Kendall Gadd (born April 9, 1945 [1] ) is an American drummer, percussionist, and session musician. Gadd is one of the most well-known and highly regarded session and studio drummers in the industry, recognized by his induction into the Modern Drummer Hall of Fame in 1984. [2] Gadd's performance on Paul Simon's "50 Ways to Leave Your Lover" and Steely Dan's "Aja" are examples of his style. He has worked with popular musicians from many genres including Simon ...
У этого термина существуют и другие значения, см. Подольск (значения) . Не следует путать с Подольском — городом в Одесской области Украины. Город Подольск Флаг Герб 55°25′47″ с. ш. 37°32′40″ в. д. H G Я O Страна Россия Россия Субъект Федерации Московская область Городской округ Подольск Глава Николай Игоревич Пестов История и география Основан 1627 [2] Первое упоминание 1559 Город с 1781 года Площадь 40,39 км² Высота центра 160 м Тип климата умеренно-континентальный Часовой пояс UTC+3 Население Население ↗ 302 831 [1] человек ( 2018 ) Плотность 7497,67 чел./км² Национальности русские и другие Конфессии Православные христиане Этнохороним подольча́не, подольча́нин, подольча́нка Цифровые идентификаторы Телефонный код +7 4967 Почтовые индексы 142100—142134 Код ОКАТО 46 460 Код ОКТМО 46 760 000 001 Прочее Карта города Карта Н...
У этого термина существуют и другие значения, см. Лира. Лира Аполлон с лирой, ок. 460 до н. э. Археологический музей в Дельфах. Классификация Струнный инструмент, Хордофон Родственные инструменты Арфа Лира на Викискладе Ли́ра (др.-греч. λύρα , лат. lyra ) — старинный струнный щипковый инструмент (хордофон). Содержание 1 Лира в античности 1.1 Общая характеристика 1.2 Этос и функционирование лиры 2 Другие значения термина 3 Рецепция 4 Примечания 5 Литература Лира в античности | Общая характеристика | В Древней Греции и Древнем Риме словом лира в широком смысле обозначался любой инструмент семейства лир — хе́лис (др.-греч. χέλυς , лат. chelys, chelis букв. черепаха), ба́рбит (др.-греч. βάρβιτον, βάρβιτος , лат. barbitos, barbitus ), фо́рминга (др.-греч. φόρμιγξ ), или кифара (др.-греч. κιθάρα , лат. cithara ). В узком смысле лирой назывался хелис — простейшая и самая лёгкая по весу из лир, с корпусом из панци...
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