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Picea glauca

January 01, 1970

Picea glauca, the white spruce,[3] is a species of spruce native to the northern temperate and boreal forests in North America. Picea glauca is native from central Alaska all through the east, across western and southern/central Canada to the Avalon Peninsula in Newfoundland, and south to Montana, North Dakota, Minnesota, Wisconsin, Michigan, Upstate New York and Vermont, along with the mountainous and immediate coastal portions of New Hampshire and Maine, where temperatures are just barely cool and moist enough to support it. There is also an isolated population in the Black Hills of South Dakota and Wyoming.[4][5][1][6] It is also known as Canadian spruce, skunk spruce, cat spruce, Black Hills spruce, western white spruce, Alberta white spruce, and Porsild spruce.[7]

White spruce
Mature white spruce in Fairbanks, Alaska
Scientific classification
Kingdom: Plantae
Clade: Tracheophytes
Clade: Gymnospermae
Division: Pinophyta
Class: Pinopsida
Order: Pinales
Family: Pinaceae
Genus: Picea
Species:
P. glauca
Binomial name
Picea glauca
(Moench) Voss
Natural range
Synonyms[2]
List
  • Abies alba (Aiton) Michx. nom. illeg.
  • Abies arctica A.Murray bis
  • Abies canadensis Mill.
  • Abies coerulea Lodd. ex J.Forbes
  • Abies laxa (Münchh.) K.Koch
  • Abies rubra var. violacea Loudon
  • Abies virescens R.Hinterh. & J.Hinterh.
  • Picea acutissima Beissn.
  • Picea alba (Aiton) Link
  • Picea canadensis (Mill.) Britton, Sterns & Poggenb. nom. illeg.
  • Picea coerulea (Lodd. ex J.Forbes) Link
  • Picea laxa Sarg.
  • Picea tschugatskoyae Carrière nom. inval.
  • Pinus abies var. laxa Münchh.
  • Pinus alba Aiton
  • Pinus canadensis Du Roi nom. illeg.
  • Pinus coerulea Lodd. ex Loudon nom. inval.
  • Pinus glauca Moench
  • Pinus laxa (Münchh.) Ehrh.
  • Pinus tetragona Moench
  • Pinus virescens Neilr. nom. inval.
Genomic information
NCBI genome ID3330
Ploidy2
Genome size20 Gbp
Number of chromosomes12
Year of completion2015
Sequenced organelleplastid and mitochondrion
Organelle size123 kbp and 5.93 Mbp
Year of completion2015

Description edit

The white spruce is a large evergreen conifer which normally grows to 15 to 30 metres (50 to 100 ft) tall, but can grow up to 40 m (130 ft) tall with a trunk diameter of up to 1 m (3 ft 3 in). The bark is thin and scaly, flaking off in small circular plates 5 to 10 centimetres (2 to 4 in) across. The crown is narrow – conical in young trees, becoming cylindrical in older trees. The shoots are pale buff-brown, glabrous in the east of the range, but often pubescent in the west, and with prominent pulvini. The leaves are needle-like, 12 to 20 millimetres long, rhombic in cross-section, glaucous blue-green above (hence glauca) with several thin lines of stomata, and blue-white below with two broad bands of stomata.[4]

The cones are pendulous, slender, cylindrical, 3 to 7 cm long and 1.5 cm wide when closed, opening to 2.5 cm broad. They have thin, flexible scales 15  mm long with a smoothly rounded margin. They are green or reddish, maturing to pale brown 4 to 8 months after pollination. The seeds are black, 2 to 3 mm long, with a slender, 5 to 8 mm long pale brown wing.[4]

  •  
    Young tree
  •  
    Mature tree
  •  
    Mature tree that has lost its lower branches
  •  
    The bark is thin and scaly, flaking off in small circular plates
  •  
    Twig with striped, blue-green, four-sided needles
  •  
    Mature female cone
  •  
    Female cone
  •  
    Young female cone
  •  
    Male cone and pollen

Seeds edit

 
Seeds

Seeds are small, 2.5 to 5 mm long, oblong, and acute at the base. Determinations of the average number of sound seeds per white spruce cone have ranged from 32 to 130.[8][9]

Common causes of empty seed are lack of pollination, abortion of the ovule, and insect damage.

The average weight per individual seed varies from 1.1 mg to 3.2 mg.[10]

Each seed is clasped by a thin wing 2 to 4 times as long as the seed. Seed and wing are appressed to the cone scale. Embryo and megagametophyte are soft and translucent at first; later the endosperm becomes firm and milky white, while the embryo becomes cream-coloured or light yellow. At maturity, the testa darkens rapidly from light brown to dark brown or black.[11] Mature seeds "snaps in two" when cut by a sharp knife on a firm surface.[11]

White spruce cones reach their maximum size after 800 GDD. Cone moisture content decreases gradually after about 1000 GDD.[12]

Cone colour also can be used to help determine the degree of maturation, but cones may be red, pink or green.[13] Collection and storage dates and conditions influence germination requirements and early seedling growth.[14][15][16]

A bushel (35 L) of cones, which may contain 6500 to 8000 cones, yields 6 to 20 ounces (170 to 570 g) of clean seed.[17]

Seed dispersal begins after cone scales reflex with cone maturation in the late summer or early fall of the year of formation. Cones open at moisture contents of 45% to 70% and specific gravities of 0.6 to 0.8.[12][14][16] Weather affects both the initiation and pattern of seed dispersal, but cone opening and the pattern of seed dispersal can vary among trees in the same stand.[7] Even after dispersal has begun, cold, damp weather will cause cone scales to close; they will reopen during dry weather. Most seed falls early rather than late, but dispersal may continue through fall and winter and even into the next growing season.[18][19] Seed dispersal occurs mainly in late summer or early fall.[8]

White spruce seed is initially dispersed through the air by wind. Both the initiation and pattern of seed dispersal depend on the weather,[7] but these can vary among trees in the same stand.[18] Small amounts of white spruce seed are normally dispersed beyond 100 m from the seed source, but exceptionally seeds have been found more than 300–400 m from the nearest seed source.[18]

Root system edit

 
Nursery seedlings showing roots

The root system of white spruce is highly variable and adaptable, responding to a variety of edaphic factors, especially soil moisture, soil fertility, and mechanical impedance.[20][21] On soils that limit rooting depth, the root system is plate-like, but it is a common misconception to assume that white spruce is genetically constrained to develop plate-like root systems irrespective of soil conditions.[22] In the nursery, or naturally in the forest, white spruce usually develops several long 'running' roots just below the ground surface.[23]

The structure of the tracheids in the long lateral roots of white spruce varies with soil nitrogen availability.[24]

Stem edit

 
Trunk; bark is scaly or flaky and grey-brown.

White spruce can live for several hundred years, with an estimated average lifespan of 250 to 300 years.[25]

Slow-growing trees in rigorous climates are also capable of great longevity. White spruce 6 to 10 m (20 to 33 ft) high on the shore of Urquhart Lake, Northwest Territories, were found to be more than 300 years old.[26]

Bark edit

The bark of mature white spruce is scaly or flaky, grey-brown or ash-brown, but silvery when freshly exposed.[27][28] Resin blisters are normally lacking, but the Porsild spruce Picea glauca var. porsildii Raup has been credited with having smooth resin-blistered bark.[29]

White spruce bark is mostly less than 8 mm and not more than 9.5 mm thick.[30][31]

Chemistry edit

Isorhapontin can be found in spruce species such as the white spruce.[32]

P. glauca has three different genomes; a nuclear genome,[33] a mitochondrial genome,[34] and a plastid (i.e. chloroplast) genome.[35] The large (20 Gbp) nuclear genome of P. glauca (genotype WS77111) was published in 2015,[36] and the organellar (plastid and mitochondrial) genomes (genotype PG29) were published in SD Jackman et al. 2015.[37] The plastid genome of P. glauca (genotype WS77111) has also been published.[38]

Varieties edit

 
Dwarf Alberta white spruce in Los Angeles County Arboretum and Botanic Garden

Several geographical varieties have been described, but are not accepted as distinct by all authors. These comprise, from east to west:[4]

  • Picea glauca var. glauca (typical or eastern white spruce): from Newfoundland west to eastern Alberta, on lowland plains.
  • Picea glauca var. densata (Black Hills white spruce): The Black Hills in South Dakota.
  • Picea glauca var. albertiana (Alberta white spruce): The Rocky Mountains in Alberta, British Columbia and northwest Montana.
  • Picea glauca var. porsildii (Alaska white spruce): Alaska and Yukon.

The two western varieties are distinguished by pubescent shoots, and may be related to extensive hybridisation and intergradation with the closely related Engelmann spruce found further south in the Rocky Mountains. White spruce also hybridises readily with the closely related Sitka spruce where they meet in southern Alaska and northwestern British Columbia; this hybrid is known as Picea × lutzii.[4]

Distribution and habitat edit

 
White spruce taiga along the Denali Highway in the Alaska Range; white spruce in Alaska grows even more northerly than this, partly due to the oceanic Alaska Current

White spruce has a transcontinental range in North America. In Canada, its contiguous distribution encompasses virtually the whole of the Boreal, Subalpine, Montane, Columbia, Great Lakes–St. Lawrence, and Acadian Forest Regions, extending into every province and territory.[39][40] On the west coast of Hudson Bay, it extends to Seal River, about 59°N, "from which the northward limit runs apparently almost directly north-west to near the mouth of the Mackenzie River, or about latitude 68°".[41] Collins and Sumner[42] reported finding white spruce within 13 km of the Arctic coast in the Firth Valley, Yukon, at about 69°30′ N, 139°30′ W. It reaches within 100 km of the Pacific Ocean in the Skeena Valley, overlapping with the range of Sitka spruce (Picea sitchensis), and almost reaching the Arctic Ocean at latitude 69° N in the District of Mackenzie, with white spruce up to 15 m high occurring on some of the islands in the Delta near Inuvik.[43] The wide variety of ecological conditions in which 4 Quebec conifers, including white spruce, are able to establish themselves, was noted by Lafond,[44] but white spruce was more exacting than black spruce. In the United States, the range of white spruce extends into Maine, Vermont, New Hampshire, New York, Michigan, Wisconsin, Minnesota, and Alaska,[28][45] where it reaches the Bering Strait in 66°44′ N" at Norton Bay and the Gulf of Alaska at Cook Inlet.[7]

Southern outliers have been reported in southern Saskatchewan and the Cypress Hills of southwestern Saskatchewan[7][46] and southeastern Alberta,[47] northwestern Montana,[28] south-central Montana, in the Black Hills on the Wyoming–South Dakota boundary, on the Manitoba–North Dakota boundary, and at Shushan, New York.[48][49][50]

White spruce is the northernmost tree species in North America, reaching just north of 69°N latitude in the Mackenzie River delta.[51] It grows between sea level and an elevation of 1,520 m (4,990 ft). Its northern distribution roughly correlates to the location of the tree line, which includes an isothermic value of 10 °C (50 °F) for mean temperature in July, as well as the position of the Arctic front; cumulative summer degree days, mean net radiation, and the amount of light intensities also figure. White spruce is generally found in regions where the growing season exceeds 60 days annually.[7]

 
Mixed forest with balsam fir (Abies balsamea) at the southern edge of the white spruce range in Maine on the West Peak of Mount Bigelow

The southern edge of the zone in which white spruce forms 60% or more of the total stand corresponds more or less to the July isotherm of 18 °C (64 °F) around the Great Lakes; in the Prairie Provinces its limit is north of this isotherm. During the summer solstice, day length values range from 17 hours at its southern limits to 24 hours above the Arctic Circle.[7]

One of the hardiest conifers, white spruce in parts of its range withstands mean daily January temperature of −6.7 °C (19.9 °F) and extreme minimum temperatures as low as −56.5 °C (−69.7 °F); minimum temperatures of −50 °C (−58 °F) are general throughout much of the range except the southernmost and southeasternmost parts.[52] By itself, or with black spruce and tamarack (Larix laricina), white spruce forms the northern boundary of tree-form growth.[53] White spruce up to 15 m in height occur at 69°N on islands in the Mackenzie Delta near Inuvik in the Northwest Territories. Hustich (1966)[54] depicted Picea spp. as forming the northernmost limit of tree growth in North America.

The arctic or northern timberline in North America forms a broad transition zone from Labrador to northern Alaska. In Labrador, white spruce is not abundant and constitutes less than 5% of the forest, with a range that coincides very closely with that of black spruce but extending slightly further north.[55]

The range of white spruce extends westwards from Newfoundland and Labrador, and along the northern limit of trees to Hudson Bay, Northwest Territories, Yukon, and into northwestern Alaska.[52] Across western Canada and Alaska, white spruce occurs further north than black spruce, and, while poplar (Populus), willow, and birch may occur along streams well into the tundra beyond the limits of spruce, the hardwoods are usually no more than scrub.[56] Spruce characteristically occurs in fingers of tree-form forest, extending far down the northern rivers and as scattered clumps of dwarfed "bush" spruce on intervening lands.[48][57] In Manitoba, Scoggan[46] noted that the northernmost collection of white spruce was at latitude 59°48’N, but Bryson et al.[58] found white spruce in the northern edge of continuous forest in central Canada at Ennadai Lake, about 60°45′ N, 101°’W, just north of the northwest corner of Manitoba. Bryson et al.[58] noted that the forest retained "the same general characteristics as when it was first described [by Tyrrell[59]] in 1896". Collins and Sumner[42] reported finding white spruce within 13 km of the Arctic coast in the Firth valley, Yukon, at about 69°30′ N, 139°30′ W, and Sargent[45] noted that white spruce in Alaska "reached Behring Strait in 66°44′ N".

 
White spruce in the former District of Ungava, dwarfed (note seated human in white for scale, center)

Climate, especially temperature, is obviously a factor in determining distributions of northern flora. Halliday and Brown[57] suggested that white spruce's northern limit corresponds "very closely" with the July mean monthly isotherm of 10 °C in Ungava, but that the northern limit west of Hudson Bay was south of that isotherm. Other climatic factors that have been suggested as affecting the northern limit of white spruce include: cumulative summer degree days, position of the Arctic front in July, mean net radiation especially during the growing season, and low light intensities.[7] Topography, soil conditions, and glaciation may also be important in controlling northern limits of spruce.[60]

The southern limit of distribution of white spruce is more complex. From east of the main range of coastal mountains in British Columbia, the southern continuous limit of white spruce is the forest/prairie interface through Alberta, Saskatchewan, Manitoba, the northern parts of Minnesota and Wisconsin, central Michigan, northeastern New York, and Maine.[52] Sargent[45] and Harlow and Harrar[28] also included Vermont and New Hampshire; and, while Dame and Brooks[61] excluded New York and states further west, they included Massachusetts as far south as Amherst and Northampton, "probably the southern limit of the species" in that area. Nisbet[62] gave the range of white spruce as extending to "Carolina", but he did not recognize red spruce as a species and presumably included it with white spruce.

Towards the southern parts of its range, white spruce encounters increasingly effective ecological competition from hardwoods, some of which may reinforce their growth-rate or sprouting competitiveness with allelopathic depredation of coniferous regeneration.[63] Further southward extension of the distribution is inhibited by white spruce's cold requirement.

As an exotic species edit

As an exotic, white spruce is widespread but uncommon. It was introduced into England[64] and parts of continental Europe[62][65] in or soon after the year 1700, into Denmark about 1790,[66] and into Tasmania and Ceylon shortly before 1932.[67]

Nisbet[62] noted that firmly-rooted white spruce served very well to stabilize windswept edges of woods in Germany. In a narrow belt of mixed Norway and white spruces over an extremely exposed hilltop crest at high elevation in northern England, the Norway spruce were "completely dwarfed" whereas the white spruce had reached heights of between 3 and 4.3 m.[68] The age of the belt was not recorded, but adjoining 66-year-old stands may have been of the same vintage.

White spruce has also been used as a minor plantation species in England and Scotland.[69][70][71] In Scotland, at Corrour, Inverness-shire, Sir John Stirling Maxwell in 1907 began using white spruce in his pioneering plantations at high elevations on deep peat. However, plantations in Britain have generally been unsatisfactory,[72] mainly because of damage by spring frosts after mild weather had induced flushing earlier in the season. However, the species is held in high regard in the Belgian peat region, where it grows better than do the other spruces.[73]

Ecology edit

 
Growing in the riparian zone amid treeless bogs

White spruce is a climax canopy tree in the boreal forests of Canada and Alaska. It generally occurs on well-drained soils in alluvial and riparian zones, although it also occurs in soils of glacial and lacustrine origin.[7] The understory is dominated by feather mosses (Hylocomium splendens, Pleurozium schreberi, Ptilium crista-castrensis) and fork mosses, and occasionally peat moss.[74] In the far north, the total depth of the moss and underlying humus is normally between 25 and 46 cm (10 and 18 in), although it tends to be shallower when hardwoods are present in the stand.[7]

White spruce grows in soils with pH values of 4.7–7.0, although they have been found in soils as acidic as 4.0 in subalpine fir forests in the Northwest Territories. A presence of calcium in the soil is common to white spruce found in northern New York. White spruce most commonly grows in the soil orders of Alfisols and Inceptisols. Soil properties such as fertility, temperature, and structural stability are partial determinants of the ability of white spruce to grow in the extreme northern latitudes.[7] In the northern limits of its range, white spruce is the climax species along with black spruce; birch and aspen are the early succession species.[74] Wildfires typically occur every 60 to 200 years, although they have been known to occur as infrequently as every 300 years.[74]

White spruce will grow in USDA Growing Zones 3–7, but is not adapted to heat and humidity and will perform poorly in a hot climate.[citation needed] The tree attains its greatest longevity and growth potential in Zones 3–4.

Wildlife such as deer, rabbits, and grouse browse the foliage during the winter.[75]

Soils edit

 
White spruce growing in the riparian zone of the Sautauriski River, Québec

White spruce occurs on a wide variety of soils, including soils of glacial, lacustrine, marine, and alluvial origins; overlying basic dolomites, limestones and acidic Precambrian and Devonian granites and gneisses; and Silurian sedimentary schists, shales, slates, and conglomerates.[76] The wide range of textures accommodated includes clays, even those that are massive when wet and columnar when dry, sand flats, and coarse soils.[39][77][78][79][80] Its occurrence on some organic soils is not characteristic, except perhaps on shallow mesic organic soils in Saskatchewan and in association with black spruce on organic soils in central Yukon.[7]

Podzolized, brunisolic, luvisolic, gleysolic, and regosolic (immature) soils are typical of those supporting white spruce throughout the range of the species.[79] Soils supporting white spruce are most commonly Alfisols or Inceptisols.[7] In the podzol region of Wisconsin, white spruce occurs on loam podzols, podzolized gley loams, strongly podzolized clays, gley-podzol clays, stream-bottom soils, and wood peat.[77] Moist sandy loams also support good growth.[28] On sandy podzols,[77] it is usually a minor species.[7] Good development occurs on moist alluvium on the banks of streams and borders of swamps.[79][81][82][83][84][39][85][86] White spruce makes good growth on well-drained lacustrine soils in Alberta Mixedwoods,[87] on moderately-well-drained clay loams in Saskatchewan,,[88] and on melanized loams and clays (with sparse litter and a dark-coloured organically-enriched mineral horizon) in the Algoma district of Ontario.[78]

White spruce becomes less accommodating of soil with increasing severity of climate. The distribution of white spruce in Labrador seems to depend almost entirely on the character of the soil,[85] and between the southwestern shores of Hudson Bay and the northeastern regions of Saskatchewan, white spruce is confined to very local physiographic features, characterized by well-drained or fertile soils.[89]

On dry, deep, outwash deposits in northern Ontario, both white spruce and aspen grow slowly.[90] But, broadly, white spruce is able to tolerate considerable droughtiness of sites that are fertile, and no fertile site is too moist unless soil moisture is stagnant.[91] Soil fertility holds the key not just to white spruce growth but to the distribution of the species. At least moderate fertility is needed for good growth, but white spruce occurs on many sites where nutrient deficiencies depress its growth more than that of black spruce, red spruce, Norway spruce, and the pines generally.[92] Minimum soil-fertility standards recommended for white spruce sufficient to produce 126 to 157 m3/ha of wood at 40 years are much higher than for pine species commonly planted in the Lake States (Wilde 1966):[93] 3.5% organic matter, 12.0 meq/100 g exchange capacity, 0.12% total N, 44.8 kg/ha available P, 145.7 kg/ha available K, 3.00 meq/100 g exchangeable Ca, and 0.70 meq/100 g exchangeable Mg.

 
Mossy forest floor under white spruce

Forest floors under stands dominated by white spruce respond in ways that vary with site conditions, including the disturbance history of the site.[7] Composition, biomass, and mineral soil physical and chemical properties are affected. In Alaska, the accumulation of organic layers (to greater thicknesses in mature stands of spruce than those in hardwood stands on similar sites) leads to decreased soil temperatures, in some cases leading to the development of permafrost.[94][95][96] Acidity of the mineral soil sampled at an average depth of 17 cm in 13 white spruce stands on abandoned farmland in Ontario increased by 1.2 pH units over a period of 46 years.[97]

A considerable range of soil pH is tolerated by white spruce.[79] Thrifty stands of white spruce in Manitoba have developed on soils of pH 7.6 at only 10 cm below the surface, and pH 8.4 at 43 cm below the surface;[98][99] rooting depth in those soils was at least 81 cm. An abundant calcium supply is common to most white spruce locations in New York state.[7] Chlorosis was observed in young white spruce in heavily limed nursery soils at about pH 8.3.[79] Wilde[93] gave 4.7 to 6.5 as the approximate optimum range of pH for white spruce in Wisconsin, but optimum growth seems possible at pH levels up to 7.0 and perhaps higher.[91] Alluvium on the floodplains of northern rivers shows pH levels from 5.0 to 8.2.[100] High-lime ecotypes may exist,[101] and in Canada Forest Section B8 the presence of balsam poplar and white spruce on some of the moulded moraines and clays seems to be correlated with the considerable lime content of these materials,[39][102] while calcareous soils are favourable sites for northern outliers of white spruce.[56]

Mature stands of white spruce in boreal regions often have well-developed moss layers dominated by feather mosses, e.g., Hylocomium splendens, Pleurozium schreberi, Ptlium crista-castrensis, and Dicranum, rather than Sphagnum.[103][104] The thickness of the moss–organic layer commonly exceeds 25 cm in the far north and may approach twice that figure. The mosses compete for nutrients and have a major influence on soil temperatures in the rooting zone. Permafrost development in parts of Alaska, Yukon, and the Northwest Territories is facilitated by the insulative organic layer (Viereck 1970a, b, Gill 1975, Van Cleve and Yarie 1986).[94][95][105][106]

Cold hardiness edit

 
Young tree with light snowcover

White spruce is extremely hardy to low temperatures, provided the plant is in a state of winter dormancy. Throughout the greater part of its range, white spruce routinely survives and is undamaged by winter temperatures of −50 °C (−58 °F), and even lower temperatures occur in parts of the range.[7][52] Boreal Picea are among the few extremely hardy conifers in which the bud primordia are able to survive temperatures down to −70 °C, −94 °F.[107]

Especially important in determining the response of white spruce to low temperatures is the physiological state of the various tissues, notably the degree of "hardening" or dormancy. A natural progression of hardening and dehardening occurs in concert with the seasons.[108] While different tissues vary in ability to tolerate exposure to stressful temperatures, white spruce, as with woody plants in general, has necessarily developed sufficient winter hardiness in its various tissues to enable them to survive the minimum temperatures experienced in the distribution range.

White spruce is subject to severe damage from spring frosts. Newly flushed shoots of white spruce are very sensitive to spring frost.[109][110][111] This sensitivity is a major constraint affecting young trees planted without overstorey nurses in boreal climates.[112]

Forest succession edit

 
Disturbed roadside blooms with early succession fireweed; behind, late-succession Alaskan white spruce forest, Yukon

Forest succession in its traditional sense implies two important features that resist direct examination.[113] First, classical definitions generally connote directional changes in species composition and community structure through time, yet the time frame needed for documentation of change far exceeds an average human lifespan.[113] The second feature that defies quantitative description is the end point or climax.

Floodplain deposits in the Northwest Territory, Canada, are important in relation to the development of productive forest types with a component of white spruce.[82] The most recently exposed surfaces are occupied by sandbar vegetation or riparian shrub willows and Alnus incana. With increasing elevation, the shrubs give way successively to balsam poplar and white spruce forest. In contrast, older floodplains, with predominantly brown wooded soils, typically carry white spruce–trembling aspen mixedwood forest.

Interrelationships among nutrient cycling, regeneration, and subsequent forest development on floodplains in interior Alaska were addressed by Van Cleve et al.,[114] who pointed out that the various stages in primary succession reflect physical, chemical, and biological controls of ecosystem structure and function. Thus, each successional stage has a species combination in harmony with site quality. Short-circuiting succession by planting a late successional species such as white spruce on an early successional surface may result in markedly reduced growth rates because of nitrogen insufficiency. Without application of substantial amounts of fertilizer, use would have to be made of early successional alder and its site-ameliorating additions of nitrogen.

 
Old-growth Alaskan white spruce, Yukon

Neiland and Viereck noted that “the slow establishment and growth of spruce under birch stands [in Alaska] may be partially due to effects of shading and general competition for water and nutrients, but may also be more directly related to the birch itself. Heikinheimo[115][116] found that birch ash inhibited white spruce seedlings, and Gregory[117] found that birch litter has a smothering effect on spruce seedlings.".[118]

On dry upland sites, especially south-facing slopes, the mature vegetation is white spruce, white birch, trembling aspen, or a combination of these species. Succession follows in one of two general patterns. In most cases, aspen and birch develop as a successional stage after fire before reaching the spruce stage. But, occasionally, with optimal site conditions and a source of seed, white spruce will invade with the hardwoods or within a few years thereafter, thereby producing even-aged white spruce stands without an intervening hardwood stage.

Associated forest cover edit

 
Taiga in the Gaspésie, Québec, including other species

The White Spruce Cover Type may include other species in small numbers. In Alaska, associates include paper birch, trembling aspen, balsam poplar, and black spruce; in western Canada, additional associates are subalpine fir, balsam fir, Douglas-fir, jack pine, and lodgepole pine.[119] Seral species giving way to white spruce include paper birch, aspen, balsam poplar, jack pine, and lodgepole pine. On certain river bottom sites, however, black spruce may replace white spruce.[119] Earlier successional stages leading to the white spruce climax are the white spruce–paper birch, white spruce–aspen, balsam poplar, jack pine, and lodgepole pine types. The type shows little variation. The forest is generally closed and the trees well formed, other than those close to the timberline. Lesser vegetation in mature stands is dominated by mosses. Vascular plants are typically few, but shrubs and herbs that occur “with a degree of regularity” include: alder, willows, mountain cranberry, red-fruit bearberry, black crowberry, prickly rose, currant, buffaloberry, blueberry species, bunchberry, twinflower, tall lungwort, northern comandra, horsetail, bluejoint grass, sedge species, as well as ground-dwelling mosses and lichens. Several white spruce communities have been identified in interior Alaska: white spruce/feathermoss; white spruce/dwarf birch/feathermoss; white spruce/dwarf birch/sphagnum; white spruce/avens/moss; and white spruce/alder/bluejoint.[120][119]

Of the Eastern Forest Cover Types recognized by the Society of American Foresters,[121] only one, White Spruce, names that species in its title. The eastern White Spruce Cover Type, as defined, encompasses white spruce both in pure stands, and in mixed stands "in which white spruce is the major [undefined] component."[122]

In most of its range, white spruce occurs more typically in association with trees of other species than in pure stands.

White spruce is an associated species in the following Eastern Forest cover types, by the Society of American Foresters; in the Boreal Forest Region: (1) jack pine, (5) balsam fir, (12) black spruce, (16) aspen, (18) paper birch, and (38) tamarack; in the Northern Forest Region: (15) red pine, (21) eastern white pine, (24) hemlock-yellow birch, (25) sugar maple-beech-yellow birch, (27) sugar maple, (30) red spruce-yellow birch, (32) red spruce, (33) red spruce-balsam fir, (37) northern white-cedar, and (39) black ash-American elm-red maple.[7][121]

Predators edit

 
Choristoneura fumiferana, the eastern spruce budworm. Adult (silvery) and pupa (dark brown) on a white spruce.

Outbreaks of spruce beetles have destroyed over 2,300,000 acres (9,300 km2) of forests in Alaska.[123]

Although sometimes described, e.g., by Switzer (1960),[124] as relatively resistant to attack by insects and disease, white spruce is far from immune to depredation. Important insect pests of white spruce include the spruce budworm (Choristoneura fumiferana), the yellow-headed spruce sawfly (Pikonema alaskensis), the European spruce sawfly (Gilpinia hercyniae), the spruce bud moth (Zeiraphera canadensis),[125] and spruce beetle (Dendroctonus rufipennis).[126][125][127] As well, other budworms, sawflies, and bark beetles, gall formers, bud midges, leaf miners, aphids, leaf eaters, leaf rollers, loopers, mites, scales, weevils, borers, pitch moths, and spittlebugs cause varying degrees of damage to white spruce.[127]

A number of sawflies feed on spruce trees. Among them European spruce sawfly, yellow-headed spruce sawfly, green-headed spruce sawfly and the spruce webspinning sawfly.[125]

More than a dozen kinds of looper feed on the spruces, fir, and hemlock in eastern Canada. The full-grown larvae of the larvae vary in length from 15 mm to 35 mm. Some feed briefly in the fall and complete their feeding in the spring; others feed mainly in the summer; still others feed mainly in the late summer and fall.

The fall and spring feeding group includes the dash-lined looper (Protoboarmia porcelaria indicataria), the diamond-backed looper (Hypagyrtis piniata), the fringed looper (Campaea perlata), and the false loopers (Syngrapha species). The summer feeding group includes the false hemlock looper (Nepytia canosaria Walker), occasionally occurring in large numbers and usually in conjunction with the hemlock looper (Lambdina fiscellaria), the Eupithecia species, the yellowlined conifer looper (Cladara limitaria), and the saddleback looper (Ectropis crepuscularia).

The late summer and fall group includes the common spruce-fir looper (Semiothisa signaria dispuncta) and the similar hemlock angle (moth) Macaria fissinotata on hemlock, the small spruce loopers Eupithecia species, the gray spruce looper Caripeta divisata, occasionally abundant, the black-dashed hydriomena moth (Hydriomena divisaria), and the whitelined looper (Eufidonia notataria).

Cultivars edit

 
A dwarf Alberta white spruce, with reversion in one branch

Numerous cultivars of various sizes, colours and shapes have been selected for use in parks and gardens. The following have gained the Royal Horticultural Society's Award of Garden Merit.[128]

  • Picea glauca ‘Echiniformis’[129]
  • Picea glauca var. albertiana ‘Alberta Globe’[130]
  • Picea glauca var. albertiana ‘Conica’[131]

'Conica' is a dwarf conifer with very slender leaves, like those normally found only on one-year-old seedlings, and very slow growth, typically only 2–10 cm (34–4 in) per year. Older specimens commonly 'revert', developing normal adult foliage and starting to grow much faster; this 'reverted' growth must be pruned if the plant is to be kept dwarf.

Uses edit

 
Black Hills spruce grown as bonsai

The wood of white spruce is of a lower quality than that of Engelmann spruce, but is stronger. It was used to make shelters and as firewood by Native Americans and European settlers in Alaska, where lodgepole pine does not grow.[132] The wood is of major economic importance in Canada, being harvested for paper and construction. It is also used as a Christmas tree.

The wood is also exported to Japan where, known as "shin-kaya", it is used to make go boards as a substitute for the rare kaya wood.

Black Hills spruce (Picea glauca var. densata) is used for bonsai.

White spruce is the provincial tree of Manitoba[133] and the state tree of South Dakota.

The new growth or tips of white spruce is used in beer making,[134] gin production,[135] flavouring pop,[136] candy making or in pickles and preserves. [137]

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External links edit

  •   Media related to Picea glauca at Wikimedia Commons

January 01, 1970
picea, glauca, white, spruce, species, spruce, native, northern, temperate, boreal, forests, north, america, native, from, central, alaska, through, east, across, western, southern, central, canada, avalon, peninsula, newfoundland, south, montana, north, dakot. Picea glauca the white spruce 3 is a species of spruce native to the northern temperate and boreal forests in North America Picea glauca is native from central Alaska all through the east across western and southern central Canada to the Avalon Peninsula in Newfoundland and south to Montana North Dakota Minnesota Wisconsin Michigan Upstate New York and Vermont along with the mountainous and immediate coastal portions of New Hampshire and Maine where temperatures are just barely cool and moist enough to support it There is also an isolated population in the Black Hills of South Dakota and Wyoming 4 5 1 6 It is also known as Canadian spruce skunk spruce cat spruce Black Hills spruce western white spruce Alberta white spruce and Porsild spruce 7 White spruce Mature white spruce in Fairbanks Alaska Conservation status Least Concern IUCN 3 1 1 Scientific classification Kingdom Plantae Clade Tracheophytes Clade Gymnospermae Division Pinophyta Class Pinopsida Order Pinales Family Pinaceae Genus Picea Species P glauca Binomial name Picea glauca Moench Voss Natural range Synonyms 2 ListAbies alba Aiton Michx nom illeg Abies arctica A Murray bis Abies canadensis Mill Abies coeruleaLodd ex J Forbes Abies laxa Munchh K Koch Abies rubra var violacea Loudon Abies virescens R Hinterh amp J Hinterh Picea acutissima Beissn Picea alba Aiton Link Picea canadensis Mill Britton Sterns amp Poggenb nom illeg Picea coerulea Lodd ex J Forbes Link Picea laxa Sarg Picea tschugatskoyae Carriere nom inval Pinus abies var laxa Munchh Pinus alba Aiton Pinus canadensis Du Roi nom illeg Pinus coerulea Lodd ex Loudon nom inval Pinus glauca Moench Pinus laxa Munchh Ehrh Pinus tetragona Moench Pinus virescens Neilr nom inval Genomic informationNCBI genome ID3330Ploidy2Genome size20 GbpNumber of chromosomes12Year of completion2015Sequenced organelleplastid and mitochondrionOrganelle size123 kbp and 5 93 MbpYear of completion2015 Contents 1 Description 1 1 Seeds 1 2 Root system 1 3 Stem 1 4 Bark 1 5 Chemistry 2 Varieties 3 Distribution and habitat 3 1 As an exotic species 4 Ecology 4 1 Soils 4 2 Cold hardiness 4 3 Forest succession 4 4 Associated forest cover 4 5 Predators 5 Cultivars 6 Uses 7 References 8 External linksDescription editThe white spruce is a large evergreen conifer which normally grows to 15 to 30 metres 50 to 100 ft tall but can grow up to 40 m 130 ft tall with a trunk diameter of up to 1 m 3 ft 3 in The bark is thin and scaly flaking off in small circular plates 5 to 10 centimetres 2 to 4 in across The crown is narrow conical in young trees becoming cylindrical in older trees The shoots are pale buff brown glabrous in the east of the range but often pubescent in the west and with prominent pulvini The leaves are needle like 12 to 20 millimetres long rhombic in cross section glaucous blue green above hence glauca with several thin lines of stomata and blue white below with two broad bands of stomata 4 The cones are pendulous slender cylindrical 3 to 7 cm long and 1 5 cm wide when closed opening to 2 5 cm broad They have thin flexible scales 15 mm long with a smoothly rounded margin They are green or reddish maturing to pale brown 4 to 8 months after pollination The seeds are black 2 to 3 mm long with a slender 5 to 8 mm long pale brown wing 4 nbsp Young tree nbsp Mature tree nbsp Mature tree that has lost its lower branches nbsp The bark is thin and scaly flaking off in small circular plates nbsp Twig with striped blue green four sided needles nbsp Mature female cone nbsp Female cone nbsp Young female cone nbsp Male cone and pollen Seeds edit nbsp Seeds Seeds are small 2 5 to 5 mm long oblong and acute at the base Determinations of the average number of sound seeds per white spruce cone have ranged from 32 to 130 8 9 Common causes of empty seed are lack of pollination abortion of the ovule and insect damage The average weight per individual seed varies from 1 1 mg to 3 2 mg 10 Each seed is clasped by a thin wing 2 to 4 times as long as the seed Seed and wing are appressed to the cone scale Embryo and megagametophyte are soft and translucent at first later the endosperm becomes firm and milky white while the embryo becomes cream coloured or light yellow At maturity the testa darkens rapidly from light brown to dark brown or black 11 Mature seeds snaps in two when cut by a sharp knife on a firm surface 11 White spruce cones reach their maximum size after 800 GDD Cone moisture content decreases gradually after about 1000 GDD 12 Cone colour also can be used to help determine the degree of maturation but cones may be red pink or green 13 Collection and storage dates and conditions influence germination requirements and early seedling growth 14 15 16 A bushel 35 L of cones which may contain 6500 to 8000 cones yields 6 to 20 ounces 170 to 570 g of clean seed 17 Seed dispersal begins after cone scales reflex with cone maturation in the late summer or early fall of the year of formation Cones open at moisture contents of 45 to 70 and specific gravities of 0 6 to 0 8 12 14 16 Weather affects both the initiation and pattern of seed dispersal but cone opening and the pattern of seed dispersal can vary among trees in the same stand 7 Even after dispersal has begun cold damp weather will cause cone scales to close they will reopen during dry weather Most seed falls early rather than late but dispersal may continue through fall and winter and even into the next growing season 18 19 Seed dispersal occurs mainly in late summer or early fall 8 White spruce seed is initially dispersed through the air by wind Both the initiation and pattern of seed dispersal depend on the weather 7 but these can vary among trees in the same stand 18 Small amounts of white spruce seed are normally dispersed beyond 100 m from the seed source but exceptionally seeds have been found more than 300 400 m from the nearest seed source 18 Root system edit nbsp Nursery seedlings showing roots The root system of white spruce is highly variable and adaptable responding to a variety of edaphic factors especially soil moisture soil fertility and mechanical impedance 20 21 On soils that limit rooting depth the root system is plate like but it is a common misconception to assume that white spruce is genetically constrained to develop plate like root systems irrespective of soil conditions 22 In the nursery or naturally in the forest white spruce usually develops several long running roots just below the ground surface 23 The structure of the tracheids in the long lateral roots of white spruce varies with soil nitrogen availability 24 Stem edit nbsp Trunk bark is scaly or flaky and grey brown White spruce can live for several hundred years with an estimated average lifespan of 250 to 300 years 25 Slow growing trees in rigorous climates are also capable of great longevity White spruce 6 to 10 m 20 to 33 ft high on the shore of Urquhart Lake Northwest Territories were found to be more than 300 years old 26 Bark edit The bark of mature white spruce is scaly or flaky grey brown or ash brown but silvery when freshly exposed 27 28 Resin blisters are normally lacking but the Porsild spruce Picea glauca var porsildii Raup has been credited with having smooth resin blistered bark 29 White spruce bark is mostly less than 8 mm and not more than 9 5 mm thick 30 31 Chemistry edit Isorhapontin can be found in spruce species such as the white spruce 32 P glauca has three different genomes a nuclear genome 33 a mitochondrial genome 34 and a plastid i e chloroplast genome 35 The large 20 Gbp nuclear genome of P glauca genotype WS77111 was published in 2015 36 and the organellar plastid and mitochondrial genomes genotype PG29 were published in SD Jackman et al 2015 37 The plastid genome of P glauca genotype WS77111 has also been published 38 Varieties edit nbsp Dwarf Alberta white spruce in Los Angeles County Arboretum and Botanic Garden Several geographical varieties have been described but are not accepted as distinct by all authors These comprise from east to west 4 Picea glauca var glauca typical or eastern white spruce from Newfoundland west to eastern Alberta on lowland plains Picea glauca var densata Black Hills white spruce The Black Hills in South Dakota Picea glauca var albertiana Alberta white spruce The Rocky Mountains in Alberta British Columbia and northwest Montana Picea glauca var porsildii Alaska white spruce Alaska and Yukon The two western varieties are distinguished by pubescent shoots and may be related to extensive hybridisation and intergradation with the closely related Engelmann spruce found further south in the Rocky Mountains White spruce also hybridises readily with the closely related Sitka spruce where they meet in southern Alaska and northwestern British Columbia this hybrid is known as Picea lutzii 4 Distribution and habitat edit nbsp White spruce taiga along the Denali Highway in the Alaska Range white spruce in Alaska grows even more northerly than this partly due to the oceanic Alaska Current White spruce has a transcontinental range in North America In Canada its contiguous distribution encompasses virtually the whole of the Boreal Subalpine Montane Columbia Great Lakes St Lawrence and Acadian Forest Regions extending into every province and territory 39 40 On the west coast of Hudson Bay it extends to Seal River about 59 N from which the northward limit runs apparently almost directly north west to near the mouth of the Mackenzie River or about latitude 68 41 Collins and Sumner 42 reported finding white spruce within 13 km of the Arctic coast in the Firth Valley Yukon at about 69 30 N 139 30 W It reaches within 100 km of the Pacific Ocean in the Skeena Valley overlapping with the range of Sitka spruce Picea sitchensis and almost reaching the Arctic Ocean at latitude 69 N in the District of Mackenzie with white spruce up to 15 m high occurring on some of the islands in the Delta near Inuvik 43 The wide variety of ecological conditions in which 4 Quebec conifers including white spruce are able to establish themselves was noted by Lafond 44 but white spruce was more exacting than black spruce In the United States the range of white spruce extends into Maine Vermont New Hampshire New York Michigan Wisconsin Minnesota and Alaska 28 45 where it reaches the Bering Strait in 66 44 N at Norton Bay and the Gulf of Alaska at Cook Inlet 7 Southern outliers have been reported in southern Saskatchewan and the Cypress Hills of southwestern Saskatchewan 7 46 and southeastern Alberta 47 northwestern Montana 28 south central Montana in the Black Hills on the Wyoming South Dakota boundary on the Manitoba North Dakota boundary and at Shushan New York 48 49 50 White spruce is the northernmost tree species in North America reaching just north of 69 N latitude in the Mackenzie River delta 51 It grows between sea level and an elevation of 1 520 m 4 990 ft Its northern distribution roughly correlates to the location of the tree line which includes an isothermic value of 10 C 50 F for mean temperature in July as well as the position of the Arctic front cumulative summer degree days mean net radiation and the amount of light intensities also figure White spruce is generally found in regions where the growing season exceeds 60 days annually 7 nbsp Mixed forest with balsam fir Abies balsamea at the southern edge of the white spruce range in Maine on the West Peak of Mount Bigelow The southern edge of the zone in which white spruce forms 60 or more of the total stand corresponds more or less to the July isotherm of 18 C 64 F around the Great Lakes in the Prairie Provinces its limit is north of this isotherm During the summer solstice day length values range from 17 hours at its southern limits to 24 hours above the Arctic Circle 7 One of the hardiest conifers white spruce in parts of its range withstands mean daily January temperature of 6 7 C 19 9 F and extreme minimum temperatures as low as 56 5 C 69 7 F minimum temperatures of 50 C 58 F are general throughout much of the range except the southernmost and southeasternmost parts 52 By itself or with black spruce and tamarack Larix laricina white spruce forms the northern boundary of tree form growth 53 White spruce up to 15 m in height occur at 69 N on islands in the Mackenzie Delta near Inuvik in the Northwest Territories Hustich 1966 54 depicted Picea spp as forming the northernmost limit of tree growth in North America The arctic or northern timberline in North America forms a broad transition zone from Labrador to northern Alaska In Labrador white spruce is not abundant and constitutes less than 5 of the forest with a range that coincides very closely with that of black spruce but extending slightly further north 55 The range of white spruce extends westwards from Newfoundland and Labrador and along the northern limit of trees to Hudson Bay Northwest Territories Yukon and into northwestern Alaska 52 Across western Canada and Alaska white spruce occurs further north than black spruce and while poplar Populus willow and birch may occur along streams well into the tundra beyond the limits of spruce the hardwoods are usually no more than scrub 56 Spruce characteristically occurs in fingers of tree form forest extending far down the northern rivers and as scattered clumps of dwarfed bush spruce on intervening lands 48 57 In Manitoba Scoggan 46 noted that the northernmost collection of white spruce was at latitude 59 48 N but Bryson et al 58 found white spruce in the northern edge of continuous forest in central Canada at Ennadai Lake about 60 45 N 101 W just north of the northwest corner of Manitoba Bryson et al 58 noted that the forest retained the same general characteristics as when it was first described by Tyrrell 59 in 1896 Collins and Sumner 42 reported finding white spruce within 13 km of the Arctic coast in the Firth valley Yukon at about 69 30 N 139 30 W and Sargent 45 noted that white spruce in Alaska reached Behring Strait in 66 44 N nbsp White spruce in the former District of Ungava dwarfed note seated human in white for scale center Climate especially temperature is obviously a factor in determining distributions of northern flora Halliday and Brown 57 suggested that white spruce s northern limit corresponds very closely with the July mean monthly isotherm of 10 C in Ungava but that the northern limit west of Hudson Bay was south of that isotherm Other climatic factors that have been suggested as affecting the northern limit of white spruce include cumulative summer degree days position of the Arctic front in July mean net radiation especially during the growing season and low light intensities 7 Topography soil conditions and glaciation may also be important in controlling northern limits of spruce 60 The southern limit of distribution of white spruce is more complex From east of the main range of coastal mountains in British Columbia the southern continuous limit of white spruce is the forest prairie interface through Alberta Saskatchewan Manitoba the northern parts of Minnesota and Wisconsin central Michigan northeastern New York and Maine 52 Sargent 45 and Harlow and Harrar 28 also included Vermont and New Hampshire and while Dame and Brooks 61 excluded New York and states further west they included Massachusetts as far south as Amherst and Northampton probably the southern limit of the species in that area Nisbet 62 gave the range of white spruce as extending to Carolina but he did not recognize red spruce as a species and presumably included it with white spruce Towards the southern parts of its range white spruce encounters increasingly effective ecological competition from hardwoods some of which may reinforce their growth rate or sprouting competitiveness with allelopathic depredation of coniferous regeneration 63 Further southward extension of the distribution is inhibited by white spruce s cold requirement As an exotic species edit As an exotic white spruce is widespread but uncommon It was introduced into England 64 and parts of continental Europe 62 65 in or soon after the year 1700 into Denmark about 1790 66 and into Tasmania and Ceylon shortly before 1932 67 Nisbet 62 noted that firmly rooted white spruce served very well to stabilize windswept edges of woods in Germany In a narrow belt of mixed Norway and white spruces over an extremely exposed hilltop crest at high elevation in northern England the Norway spruce were completely dwarfed whereas the white spruce had reached heights of between 3 and 4 3 m 68 The age of the belt was not recorded but adjoining 66 year old stands may have been of the same vintage White spruce has also been used as a minor plantation species in England and Scotland 69 70 71 In Scotland at Corrour Inverness shire Sir John Stirling Maxwell in 1907 began using white spruce in his pioneering plantations at high elevations on deep peat However plantations in Britain have generally been unsatisfactory 72 mainly because of damage by spring frosts after mild weather had induced flushing earlier in the season However the species is held in high regard in the Belgian peat region where it grows better than do the other spruces 73 Ecology edit nbsp Growing in the riparian zone amid treeless bogs White spruce is a climax canopy tree in the boreal forests of Canada and Alaska It generally occurs on well drained soils in alluvial and riparian zones although it also occurs in soils of glacial and lacustrine origin 7 The understory is dominated by feather mosses Hylocomium splendens Pleurozium schreberi Ptilium crista castrensis and fork mosses and occasionally peat moss 74 In the far north the total depth of the moss and underlying humus is normally between 25 and 46 cm 10 and 18 in although it tends to be shallower when hardwoods are present in the stand 7 White spruce grows in soils with pH values of 4 7 7 0 although they have been found in soils as acidic as 4 0 in subalpine fir forests in the Northwest Territories A presence of calcium in the soil is common to white spruce found in northern New York White spruce most commonly grows in the soil orders of Alfisols and Inceptisols Soil properties such as fertility temperature and structural stability are partial determinants of the ability of white spruce to grow in the extreme northern latitudes 7 In the northern limits of its range white spruce is the climax species along with black spruce birch and aspen are the early succession species 74 Wildfires typically occur every 60 to 200 years although they have been known to occur as infrequently as every 300 years 74 White spruce will grow in USDA Growing Zones 3 7 but is not adapted to heat and humidity and will perform poorly in a hot climate citation needed The tree attains its greatest longevity and growth potential in Zones 3 4 Wildlife such as deer rabbits and grouse browse the foliage during the winter 75 Soils edit nbsp White spruce growing in the riparian zone of the Sautauriski River Quebec White spruce occurs on a wide variety of soils including soils of glacial lacustrine marine and alluvial origins overlying basic dolomites limestones and acidic Precambrian and Devonian granites and gneisses and Silurian sedimentary schists shales slates and conglomerates 76 The wide range of textures accommodated includes clays even those that are massive when wet and columnar when dry sand flats and coarse soils 39 77 78 79 80 Its occurrence on some organic soils is not characteristic except perhaps on shallow mesic organic soils in Saskatchewan and in association with black spruce on organic soils in central Yukon 7 Podzolized brunisolic luvisolic gleysolic and regosolic immature soils are typical of those supporting white spruce throughout the range of the species 79 Soils supporting white spruce are most commonly Alfisols or Inceptisols 7 In the podzol region of Wisconsin white spruce occurs on loam podzols podzolized gley loams strongly podzolized clays gley podzol clays stream bottom soils and wood peat 77 Moist sandy loams also support good growth 28 On sandy podzols 77 it is usually a minor species 7 Good development occurs on moist alluvium on the banks of streams and borders of swamps 79 81 82 83 84 39 85 86 White spruce makes good growth on well drained lacustrine soils in Alberta Mixedwoods 87 on moderately well drained clay loams in Saskatchewan 88 and on melanized loams and clays with sparse litter and a dark coloured organically enriched mineral horizon in the Algoma district of Ontario 78 White spruce becomes less accommodating of soil with increasing severity of climate The distribution of white spruce in Labrador seems to depend almost entirely on the character of the soil 85 and between the southwestern shores of Hudson Bay and the northeastern regions of Saskatchewan white spruce is confined to very local physiographic features characterized by well drained or fertile soils 89 On dry deep outwash deposits in northern Ontario both white spruce and aspen grow slowly 90 But broadly white spruce is able to tolerate considerable droughtiness of sites that are fertile and no fertile site is too moist unless soil moisture is stagnant 91 Soil fertility holds the key not just to white spruce growth but to the distribution of the species At least moderate fertility is needed for good growth but white spruce occurs on many sites where nutrient deficiencies depress its growth more than that of black spruce red spruce Norway spruce and the pines generally 92 Minimum soil fertility standards recommended for white spruce sufficient to produce 126 to 157 m3 ha of wood at 40 years are much higher than for pine species commonly planted in the Lake States Wilde 1966 93 3 5 organic matter 12 0 meq 100 g exchange capacity 0 12 total N 44 8 kg ha available P 145 7 kg ha available K 3 00 meq 100 g exchangeable Ca and 0 70 meq 100 g exchangeable Mg nbsp Mossy forest floor under white spruce Forest floors under stands dominated by white spruce respond in ways that vary with site conditions including the disturbance history of the site 7 Composition biomass and mineral soil physical and chemical properties are affected In Alaska the accumulation of organic layers to greater thicknesses in mature stands of spruce than those in hardwood stands on similar sites leads to decreased soil temperatures in some cases leading to the development of permafrost 94 95 96 Acidity of the mineral soil sampled at an average depth of 17 cm in 13 white spruce stands on abandoned farmland in Ontario increased by 1 2 pH units over a period of 46 years 97 A considerable range of soil pH is tolerated by white spruce 79 Thrifty stands of white spruce in Manitoba have developed on soils of pH 7 6 at only 10 cm below the surface and pH 8 4 at 43 cm below the surface 98 99 rooting depth in those soils was at least 81 cm An abundant calcium supply is common to most white spruce locations in New York state 7 Chlorosis was observed in young white spruce in heavily limed nursery soils at about pH 8 3 79 Wilde 93 gave 4 7 to 6 5 as the approximate optimum range of pH for white spruce in Wisconsin but optimum growth seems possible at pH levels up to 7 0 and perhaps higher 91 Alluvium on the floodplains of northern rivers shows pH levels from 5 0 to 8 2 100 High lime ecotypes may exist 101 and in Canada Forest Section B8 the presence of balsam poplar and white spruce on some of the moulded moraines and clays seems to be correlated with the considerable lime content of these materials 39 102 while calcareous soils are favourable sites for northern outliers of white spruce 56 Mature stands of white spruce in boreal regions often have well developed moss layers dominated by feather mosses e g Hylocomium splendens Pleurozium schreberi Ptlium crista castrensis and Dicranum rather than Sphagnum 103 104 The thickness of the moss organic layer commonly exceeds 25 cm in the far north and may approach twice that figure The mosses compete for nutrients and have a major influence on soil temperatures in the rooting zone Permafrost development in parts of Alaska Yukon and the Northwest Territories is facilitated by the insulative organic layer Viereck 1970a b Gill 1975 Van Cleve and Yarie 1986 94 95 105 106 Cold hardiness edit nbsp Young tree with light snowcover White spruce is extremely hardy to low temperatures provided the plant is in a state of winter dormancy Throughout the greater part of its range white spruce routinely survives and is undamaged by winter temperatures of 50 C 58 F and even lower temperatures occur in parts of the range 7 52 Boreal Picea are among the few extremely hardy conifers in which the bud primordia are able to survive temperatures down to 70 C 94 F 107 Especially important in determining the response of white spruce to low temperatures is the physiological state of the various tissues notably the degree of hardening or dormancy A natural progression of hardening and dehardening occurs in concert with the seasons 108 While different tissues vary in ability to tolerate exposure to stressful temperatures white spruce as with woody plants in general has necessarily developed sufficient winter hardiness in its various tissues to enable them to survive the minimum temperatures experienced in the distribution range White spruce is subject to severe damage from spring frosts Newly flushed shoots of white spruce are very sensitive to spring frost 109 110 111 This sensitivity is a major constraint affecting young trees planted without overstorey nurses in boreal climates 112 Forest succession edit nbsp Disturbed roadside blooms with early succession fireweed behind late succession Alaskan white spruce forest Yukon Forest succession in its traditional sense implies two important features that resist direct examination 113 First classical definitions generally connote directional changes in species composition and community structure through time yet the time frame needed for documentation of change far exceeds an average human lifespan 113 The second feature that defies quantitative description is the end point or climax Floodplain deposits in the Northwest Territory Canada are important in relation to the development of productive forest types with a component of white spruce 82 The most recently exposed surfaces are occupied by sandbar vegetation or riparian shrub willows and Alnus incana With increasing elevation the shrubs give way successively to balsam poplar and white spruce forest In contrast older floodplains with predominantly brown wooded soils typically carry white spruce trembling aspen mixedwood forest Interrelationships among nutrient cycling regeneration and subsequent forest development on floodplains in interior Alaska were addressed by Van Cleve et al 114 who pointed out that the various stages in primary succession reflect physical chemical and biological controls of ecosystem structure and function Thus each successional stage has a species combination in harmony with site quality Short circuiting succession by planting a late successional species such as white spruce on an early successional surface may result in markedly reduced growth rates because of nitrogen insufficiency Without application of substantial amounts of fertilizer use would have to be made of early successional alder and its site ameliorating additions of nitrogen nbsp Old growth Alaskan white spruce Yukon Neiland and Viereck noted that the slow establishment and growth of spruce under birch stands in Alaska may be partially due to effects of shading and general competition for water and nutrients but may also be more directly related to the birch itself Heikinheimo 115 116 found that birch ash inhibited white spruce seedlings and Gregory 117 found that birch litter has a smothering effect on spruce seedlings 118 On dry upland sites especially south facing slopes the mature vegetation is white spruce white birch trembling aspen or a combination of these species Succession follows in one of two general patterns In most cases aspen and birch develop as a successional stage after fire before reaching the spruce stage But occasionally with optimal site conditions and a source of seed white spruce will invade with the hardwoods or within a few years thereafter thereby producing even aged white spruce stands without an intervening hardwood stage Associated forest cover edit nbsp Taiga in the Gaspesie Quebec including other species The White Spruce Cover Type may include other species in small numbers In Alaska associates include paper birch trembling aspen balsam poplar and black spruce in western Canada additional associates are subalpine fir balsam fir Douglas fir jack pine and lodgepole pine 119 Seral species giving way to white spruce include paper birch aspen balsam poplar jack pine and lodgepole pine On certain river bottom sites however black spruce may replace white spruce 119 Earlier successional stages leading to the white spruce climax are the white spruce paper birch white spruce aspen balsam poplar jack pine and lodgepole pine types The type shows little variation The forest is generally closed and the trees well formed other than those close to the timberline Lesser vegetation in mature stands is dominated by mosses Vascular plants are typically few but shrubs and herbs that occur with a degree of regularity include alder willows mountain cranberry red fruit bearberry black crowberry prickly rose currant buffaloberry blueberry species bunchberry twinflower tall lungwort northern comandra horsetail bluejoint grass sedge species as well as ground dwelling mosses and lichens Several white spruce communities have been identified in interior Alaska white spruce feathermoss white spruce dwarf birch feathermoss white spruce dwarf birch sphagnum white spruce avens moss and white spruce alder bluejoint 120 119 Of the Eastern Forest Cover Types recognized by the Society of American Foresters 121 only one White Spruce names that species in its title The eastern White Spruce Cover Type as defined encompasses white spruce both in pure stands and in mixed stands in which white spruce is the major undefined component 122 In most of its range white spruce occurs more typically in association with trees of other species than in pure stands White spruce is an associated species in the following Eastern Forest cover types by the Society of American Foresters in the Boreal Forest Region 1 jack pine 5 balsam fir 12 black spruce 16 aspen 18 paper birch and 38 tamarack in the Northern Forest Region 15 red pine 21 eastern white pine 24 hemlock yellow birch 25 sugar maple beech yellow birch 27 sugar maple 30 red spruce yellow birch 32 red spruce 33 red spruce balsam fir 37 northern white cedar and 39 black ash American elm red maple 7 121 Predators edit nbsp Choristoneura fumiferana the eastern spruce budworm Adult silvery and pupa dark brown on a white spruce Outbreaks of spruce beetles have destroyed over 2 300 000 acres 9 300 km2 of forests in Alaska 123 Although sometimes described e g by Switzer 1960 124 as relatively resistant to attack by insects and disease white spruce is far from immune to depredation Important insect pests of white spruce include the spruce budworm Choristoneura fumiferana the yellow headed spruce sawfly Pikonema alaskensis the European spruce sawfly Gilpinia hercyniae the spruce bud moth Zeiraphera canadensis 125 and spruce beetle Dendroctonus rufipennis 126 125 127 As well other budworms sawflies and bark beetles gall formers bud midges leaf miners aphids leaf eaters leaf rollers loopers mites scales weevils borers pitch moths and spittlebugs cause varying degrees of damage to white spruce 127 A number of sawflies feed on spruce trees Among them European spruce sawfly yellow headed spruce sawfly green headed spruce sawfly and the spruce webspinning sawfly 125 More than a dozen kinds of looper feed on the spruces fir and hemlock in eastern Canada The full grown larvae of the larvae vary in length from 15 mm to 35 mm Some feed briefly in the fall and complete their feeding in the spring others feed mainly in the summer still others feed mainly in the late summer and fall The fall and spring feeding group includes the dash lined looper Protoboarmia porcelaria indicataria the diamond backed looper Hypagyrtis piniata the fringed looper Campaea perlata and the false loopers Syngrapha species The summer feeding group includes the false hemlock looper Nepytia canosaria Walker occasionally occurring in large numbers and usually in conjunction with the hemlock looper Lambdina fiscellaria the Eupithecia species the yellowlined conifer looper Cladara limitaria and the saddleback looper Ectropis crepuscularia The late summer and fall group includes the common spruce fir looper Semiothisa signaria dispuncta and the similar hemlock angle moth Macaria fissinotata on hemlock the small spruce loopers Eupithecia species the gray spruce looper Caripeta divisata occasionally abundant the black dashed hydriomena moth Hydriomena divisaria and the whitelined looper Eufidonia notataria Cultivars edit nbsp A dwarf Alberta white spruce with reversion in one branch Numerous cultivars of various sizes colours and shapes have been selected for use in parks and gardens The following have gained the Royal Horticultural Society s Award of Garden Merit 128 Picea glauca Echiniformis 129 Picea glaucavar albertiana Alberta Globe 130 Picea glaucavar albertiana Conica 131 Conica is a dwarf conifer with very slender leaves like those normally found only on one year old seedlings and very slow growth typically only 2 10 cm 3 4 4 in per year Older specimens commonly revert developing normal adult foliage and starting to grow much faster this reverted growth must be pruned if the plant is to be kept dwarf Uses edit nbsp Black Hills spruce grown as bonsai The wood of white spruce is of a lower quality than that of Engelmann spruce but is stronger It was used to make shelters and as firewood by Native Americans and European settlers in Alaska where lodgepole pine does not grow 132 The wood is of major economic importance in Canada being harvested for paper and construction It is also used as a Christmas tree The wood is also exported to Japan where known as shin kaya it is used to make go boards as a substitute for the rare kaya wood Black Hills spruce Picea glauca var densata is used for bonsai White spruce is the provincial tree of Manitoba 133 and the state tree of South Dakota The new growth or tips of white spruce is used in beer making 134 gin production 135 flavouring pop 136 candy making or in pickles and preserves 137 References edit a b Farjon A 2013 Picea glauca IUCN Red List of Threatened Species 2013 e T42323A2972485 doi 10 2305 IUCN UK 2013 1 RLTS T42323A2972485 en Retrieved 12 November 2021 Picea glauca World Checklist of Selected Plant Families Royal Botanic Gardens Kew via The Plant List Note that this website has been superseded by World Flora Online USDA NRCS n d Picea glauca The PLANTS Database plants usda gov Greensboro North Carolina National Plant Data Team Retrieved 2 October 2015 a b c d e Farjon A 1990 Pinaceae Drawings and Descriptions of the Genera Koeltz Scientific Books ISBN 3 87429 298 3 Rushforth K 1987 Conifers Helm ISBN 0 7470 2801 X Earle Christopher J ed 2018 Picea glauca The Gymnosperm Database a b c d e f g h i j k l m n o p q r Nienstaedt Hans Zasada John C 1990 Picea glauca In Burns Russell M Honkala Barbara H eds Conifers Silvics of North America Vol 1 Washington D C United States Forest Service USFS United States Department of Agriculture USDA Retrieved 14 November 2010 via Southern Research Station a b Waldron R M 1965 Cone production and seedfall in a mature white spruce stand The Forestry Chronicle 41 3 314 329 doi 10 5558 tfc41316 3 Zasada J C Viereck L A 1970 White spruce cone and seed production in interior Alaska 1957 68 USDA For Serv Pacific NW For Range Exp Sta Portland OR Res Note PNW 129 11 p Coates et al 1994 Hellum A K 1976 Grading seed by weight in white spruce USDA For Serv Tree Plant Notes 27 1 16 17 23 24 Cited in Coates et al 1994 Zasada J C Foote M J Deneke F J Parkerson R H 1978 Case history of an excellent white spruce cone and seed crop in interior Alaska cone and seed production germination and seedling survival USDA For Serv Pacific NW For Range Exp Sta Portland OR Gen Tech Rep PNW 65 53 p a b Crossley D I 1953 Seed maturity in white spruce Canada Dep Resour and Devel For Branch For Res Div Ottawa ON Silv Res Note 104 16 p a b Cram W H Worden H A 1957 Maturity of white spruce cones and seed For Sci 3 263 269 Teich A H 1970 Genetic control of female flower colour and random mating in white spruce Can Dep Fish For Can For Serv Ottawa ON Bi mo Res Notes 26 2 a b Zasada J C 1973 Effect of cone storage method and collection date on Alaskan white spruce Picea glauca seed quality p 1 10 paper 19 in Proc Seed Problems IUFRO Symp Seed Processing Bergen Norway Working Party S2 01 Royal Coll For Bergen Norway Vol 1 Coates et al 1994 Edwards I K 1977 Fertility of transplant fields at the Prince Albert Forest Nursery Can Dep Fish Environ Can For Serv Northern For Res Centre Edmonton AB Inf Rep NOR X 189 21 p a b Winston D A Haddon B D 1981 Effects of early cone collection and artificial ripening on white spruce and red pine germination Can J For Res 11 817 826 USDA Forest Service 1948 Woody plant Seed Manual USDA For Serv Washington DC Misc Publ 654 416 p a b c Zasada J 1986 Natural regeneration of trees and tall shrubs on forest sites in interior Alaska p 44 73in Van Cleve K Chapin F S Flanagan P W Viereck L A Dyrness C T Eds Forest Ecosystems in the Alaskan Taiga a Synthesis of Structure and Function Springer Verlag New York NY Rowe J S 1953 Viable seed on white spruce trees in midsummer Can Dep Northern Affairs and National Resources For Branch For Res Div Ottawa ON Silv Leafl 99 2 p Wagg J W G 1964 White spruce regeneration on the Peace and Slave River lowlands Can Dep For For Res Branch Ottawa ON Publ 1069 35 p Wagg J W B 1967 Origin and development of white spruce root forms Can Dep For Rural Devel For Branch Ottawa ON Publ 1192 45 p Sutton R F 1969 Form and development of conifer root systems Commonw For Bureau Oxford U K Tech Communication No 7 131 p Mullin R E 1957 Experiments with root and top pruning of white spruce nursery stock Ont Dep Lands For Res Div Toronto ON Res Rep 36 31 p Krasowski M J Owens J N 1999 Tracheids in white spruce seedling s long lateral roots in response to nitrogen availability Plant and Soil 217 1 2 215 228 Dallimore W Jackson A B 1961 A Handbook of Coniferae including Ginkgoaceae 3rd 1948 ed reprinted with corrections Arnold London U K 686 p Hare F K Ritchie J 1972 The boreal bioclimates Geogr Rev 62 333 365 Brayshaw T C 1960 Key to the native trees of Canada Canada Dep For Bull 125 43 p a b c d e Harlow W M Harrar E S 1950 Textbook of Dendrology 3rd ed McGraw Hill New York NY 555 p Hosie R C 1969 Native Trees of Canada 7th ed Can Dep Fish For Can For Serv Ottawa ON 380 p Hale J D 1955 Thickness and density of bark Pulp and Paper Mag Canada Dec 3 7 Chang Y P 1954 Bark structure of North American conifers USDA For Serv Tech Bull 1095 86 p Hammerbacher A Ralph S G Bohlmann J Fenning T M Gershenzon J Schmidt A 2011 Biosynthesis of the Major Tetrahydroxystilbenes in Spruce Astringin and Isorhapontin Proceeds via Resveratrol and is Enhanced by Fungal Infection Plant Physiology 157 2 876 890 doi 10 1104 pp 111 181420 PMC 3192583 PMID 21865488 Picea glauca whole genome shotgun sequencing project 2015 03 13 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help Picea glauca whole genome shotgun sequencing project 2016 01 12 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help Picea glauca isolate WS77111 chloroplast complete genome 2019 01 29 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help Warren RL Keeling CI Yuen MMS Raymond A Taylor GA Vandervalk BP Mohamadi H Paulino D Chiu R Jackman SD Robertson G Yang C Boyle B Hoffmann M Weigel D Nelson DR Ritland C Isabel N Jaquish B Yanchuk A Bousquet J Jones SJM Mackay J Birol I Bohlmann J 2015 Improved white spruce Picea glauca genome assemblies and annotation of large gene families of conifer terpenoid and phenolic defense metabolism Plant J 83 189 212 Jackman S D Warren R L Gibb E A Vandervalk B P Mohamadi H Chu J Birol I 2015 Organellar Genomes of White Spruce Picea glauca Assembly and Annotation Genome Biology and Evolution 8 1 29 41 https doi org 10 1093 gbe evv244 Lin Diana Coombe Lauren Jackman Shaun D Gagalova Kristina K Warren Rene L Hammond S Austin Kirk Heather Pandoh Pawan Zhao Yongjun Moore Richard A Mungall Andrew J 2019 06 06 Rokas Antonis ed Complete Chloroplast Genome Sequence of a White Spruce Picea glauca Genotype WS77111 from Eastern Canada Microbiology Resource Announcements 8 23 e00381 19 mra 8 23 MRA 00381 19 atom doi 10 1128 MRA 00381 19 ISSN 2576 098X PMC 6554609 PMID 31171622 a b c d Rowe J S 1972 Forest regions of Canada Can Dep Environ Can For Serv Ottawa ON Publ 1300 172 p Forestry Branch 1961 Native Trees of Canada 6th ed Canada Dep Northern Affairs and National Resour For Branch Ottawa ON Bull 61 291 p Bell R 1881 The northern limits of the principal forest trees of Canada east of the Rocky Mountains p 38c 56c in Geological and Natural History Survey of Canada Ottawa ON Report 1879 1880 a b Collins G L Sumner L 1953 Northeast Arctic the last great wilderness Sierra Club Bull 38 13 26 Inventory and Analysis Environment and Natural Resources Government of Northwest Territories Archived from the original on 2015 01 20 Lafond A 1966 Notes sur l ecologie de quatre coniferes du Quebec Picea mariana P glauca Abies balsamea et Pinus banksiana Naturaliste Canadien Quebec 93 823 842 a b c Sargent C S 1922 Manual of the Trees of North America 2nd corrected ed Houghton and Mifflin Boston 510 p reprinted 1961 in 2 volumes Dover Publications New York NY Vol 1 433 p E3999 bib gives 910 p a b Scoggan H J 1957 Flora of Manitoba Can Dep Northern Affairs and National Resources Nat Museum Can Ottawa ON Bull 140 619 p Cypress Hills Alberta Web site a b Munns E N 1938 The distribution of important forest trees of the United States USDA For Serv Washington DC Misc Publ 287 176 p Fernald M L 1950 Gray s Manual of Botany 8th ed Amer Book New York NY 1632 p Cook D B Smith R H 1959 A white spruce outlier at Shushan New York Ecology 40 333 337 Arno S F amp Hammerly R P 1984 Timberline Mountain and Arctic Forest Frontiers The Mountaineers Seattle ISBN 0 89886 085 7 a b c d Fowells H A 1965 Picea spruces p 287 327in Silvics of Forest Trees of the United States H A Fowells Compiler USDA Forest Service Washington DC Agric Handbook No 271 Sutton R F 1969 Silvics of white spruce Picea glauca Moench Voss Can Dep Fish For For Branch Ottawa ON Publ 1250 57 p Cited in Coates et al 1994 Hustich I 1966 On the forest tundra and the northern tree lines Annales Univ Turku A II Vol 36 7 47 Wilton R F 1964 The forests of Labrador Can Dep For For Res Branch Ottawa ON Publ 1066 72 p a b Hustich I 1953 The boreal limits of conifers Arctic 6 149 162 a b Halliday W E D Brown A W A 1943 The distribution of some important forest trees in Canada Ecology 24 353 373 a b Bryson R A Irving W H Larson J A 1965 Radiocarbon and soil evidence of former forest in the southern Canadian tundra Science 147 3653 46 48 Tyrell J B 1897 Geol Surv Can Ottawa ON Ann Rep 1896 Vol 9 Cited by Bryson et al 1965 orig not seen Drew J V Shanks R E 1965 Landscape relationships of soils and vegetation in the forest tundra ecotone Upper Firth River Valley Alaska Canada Ecol Monogr 35 285 306 Dame L L Brooks H 1901 Handbook of the Trees of New England Ginn Boston MA 196 p a b c Nisbet J 1905 The Forester Blackwood and Sons Edinburgh and London U K Vol 1 506 p Tubbs C H 1976 Effect of sugar maple root exudate on seedlings of northern conifer species USDA For Serv Res Note NC 213 2 p Hereman S 1868 Paxton s Botanical Dictionary Revised and corrected Bradbury Evans London U K 623 p Jackson A B 1948 The Identification of Conifers Arnold London U K 152 p Sabroe A S 1954 Forestry in Denmark 3rd ed Danish Heath Soc Copenhagen 118 p Troup H S 1932 Exotic Forest Trees in the British Empire Clarendon Press Oxford U K 268 p Guillebaud W H Steven H M Marsden R E 1920 Rate of growth of conifers in the British Isles Forestry Commission HMSO London U K Bull 3 84 p Selby P J 1842 A history of British forest trees Van Voorst London 540 p Anon C P J 1879 Fir pp 222 225 in vol IX Encyclopaedia Britannica 9th ed United Kingdom Forestry Commission 1920 Beaufort estate p 57 62 in Programme British Empire For Conf London U K Edlin H L 1962 A modern sylva or a discourse of forest trees 3 The spruces Quart J For 56 292 300 Fraser G K 1933 Studies of certain Scottish Moorlands in relation to tree growth For Commission HMSO London U K 112 p a b c Trainor Sarah 2010 11 02 Meeting Alaska s Fire Science and Climate Information Needs for Forest Managers PDF Forest Wisdom 16 Santa Fe NM Forestry Guild 4 5 Retrieved 2010 11 11 Whitney Stephen 1985 Western Forests The Audubon Society Nature Guides New York Knopf p 406 ISBN 0 394 73127 1 Halliday W E D 1937 A forest classification for Canada Can Dep Mines and Resources Dominion For Serv Ottawa ON Bull 89 50 p a b c Wilde S A Wilson F G White D P 1949 Soils of Wisconsin in relation to silviculture Wisconsin Conserv Dep Madison WI Publ 525 49 171 p a b Wilde S A Voigt G K Pierce R S 1954 The relationship of soils and forest growth in the Algoma district of Ontario Canada J Soil Sci 5 22 38 a b c d e Nienstaedt H 1957 Silvical characteristics of white spruce Picea glauca USDA For Serv Lake States For Exp Sta St Paul MN Pap 55 24 p Jameson J S 1963 Comparison of tree growth on two sites in the Riding Mountain Forest Experimental Area Can Dep For For Res Branch Ottawa ON Publ 1019 36 p Jeffrey W W 1961 Origin and structure of some white spruce stands on the lower Peace River Can Dep For For Res Branch Ottawa ON Tech Note 103 20 p a b Jeffrey W W 1964 Forest types along lower Liard River Northwest Territories Can Dep For For Res Branch Ottawa ON Publ 1035 103 p Lacate D S Horton K W Blyth A W 1965 Forest conditions on the Lower Peace River Can Dep For For Res Branch Ottawa ON Publ 1094 53 p Viereck L A 1973 Wildfire in the taiga of Alaska Quaternary Res 3 465 495 a b Sargent C S 1898 The Silva of North America A description of the trees which grow naturally in North America exclusive of Mexico Vol XII Coniferae Houghton Mifflin Riverside Press Cambridge Boston MA 144 p Kenety W H 1917 Preliminary study of white spruce in Minnesota Univ Minnesota Cloquet Exp Sta MN Bull 168 30 p Heger L 1971 Site index soil relationships for white spruce in Alberta mixedwoods Can Dep Environ Can For Serv For Manage Instit Ottawa ON Inf Rep FMR X 32 15 p Kabzems A 1971 Growth and yield of well stocked white spruce in the mixedwood section Saskatchewan Saskatchewan Dep Nat Resour For Branch Prince Albert SK Tech Bull 5 75 p Cited in Coates et al 1994 Ritchie J C 1956 The vegetation of northern Manitoba I Studies in the southern spruce forest zone Can J Bot 34 4 523 561 MacLean D W 1960 Some aspects of the aspen birch spruce fir type in Ontario Can Dep Northern Affairs National Resources For Branch For Res Div Ottawa ON Tech Note 94 24 p a b Sutton R F 1968 Ecology of young white spruce Picea glauca Moench Voss Ph D thesis Cornell Univ Ithaca NY Univ Microfilms Ann Arbor Michigan MI 68 11645 500 p Heiberg S O White D P 1951 Potassium deficiency of reforested pine and spruce stands in northern New York Soil Sci Soc Amer Proc 15 369 376 Lafond A 1954 Les deficiences en potassium et magnesium des plantations de Pinus strobus Pinus resinosa et Picea glauca de la province de Quebec Assoc Ing For Prov Quebec Texte des Conf 34 Assemb Ann 65 82 McLeod J W 1956 Plantations of the Acadia Forest Experiment Station Can Dep Northern Affairs National Resour For Branch For Res Div Ottawa ON Tech Note 31 25 p MacArthur J D 1957 The effects of manure on a white and Norway spruce plantation at Grand Mere Quebec Can Dep Northern Affairs National Resour For Branch For Res Div Ottawa ON Tech Note 64 15 p lt br gt Paine L A 1960 Studies in forest pathology XXII Nutrient deficiencies and climatic factors causing low volume production and active deterioration in white spruce Can Dep Agric For Biol Div Ottawa ON Publ 1067 29 p Swan H S D 1960 The mineral nutrition of Canadian pulpwood species 1 The influence of nitrogen phosphorus potassium and magnesium deficiencies on the growth and development of white spruce black spruce jack pine and western hemlock seedlings grown in a controlled environment Pulp Paper Res Instit Can Montreal QC Woodlands Res Index No 116 Tech Rep 168 66 p a b Wilde S A 1966 Soil standards for planting Wisconsin conifers J For 64 6 389 391 a b Viereck L A 1970a Forest succession and soil development adjacent to the Chena River in interior Alaska Arctic Alp Res 2 1 1 26 wS BA51 76183 a b Viereck L A 1970b Soil temperatures in river bottom stands in interior Alaska p 223 233 in Proc Ecology of the Subarctic Regions July Aug 1966 Helsinki Finland UNESCO Nienstaedt and Zasada 1990 Viereck L A Dyrness C T Van Cleve K Foote M J 1983 Vegetation soils and forest productivity in selected forest types in interior Alaska Can J For Res 13 5 703 720 Brand D G Kehoe P Connors M 1986 Coniferous afforestation leads to soil acidification in central Ontario Can J For Res 16 6 1389 1391 Stoeckeler J H 1938 Soil adaptability of white spruce J For 36 1145 1147 USDA Forest Service 1938 White spruce on alkaline soils USDA For Serv Lake States For Exp Sta St Paul MN Tech Note 134 1 p Zasada J C Van Cleve K Werner R A McQueen J A Nyland E 1977 Forest biology and management in high latitude North American forests p 137 195in Proc North American Forest Lands at Latitudes North of 60 degrees Sympos Univ Alaska Fairbanks AK Sept 19 22 1977 Pelletier J R 1966 Tree breeding in Canada Commonw For Rev 45 1 9 10 Stiell W M 1976 White spruce artificial regeneration in Canada Dep Environ Can For Serv Ottawa ON Inf Rep FMR X 85 275 p La Roi G H Stringer M H 1976 Ecological studies in the boreal spruce fir forests of the North American taiga II Analysis of the bryophyte flora Can J Bot 54 619 643 Nienstaedt and Zasada 1990 Viereck E G 1987 Alaska s wilderness medicines healthful plants of the North Alaska Publishing Edmonds Washington WA 107 p Nienstaedt and Zasada 1990 Gill D 1975 Influence of white spruce trees on permafrost table microtopography Mackenzie River Delta Can J Earth Sci 12 2 263 272 Van Cleve K Yarie J 1986 Interaction of temperature moisture and soil chemistry in controlling nutrient cycling and ecosystem development in the taiga of Alaska pp 160 189 in Van Cleve K Chapin F S Flanagan P W Viereck L A Dyrness C T Eds 1986 Forest Ecosystems in the Alaskan Taiga Springer Verlag New York NY Sakai A Larcher W Eds 1987 Frost Survival of Plants Springer Verlag New York NY 321 p Glerum C 1985 Frost hardiness of coniferous seedlings principles and applications p 107 123 inDuryea M L Ed Proceedings Evaluating seedling quality principles procedures and predictive abilities of major tests Workshop October 1984 Oregon State Univ For Res Lab Corvallis OR Smith B J 1949 Silvicultural work at the Sault Ste Marie Division of Abitibi Power and Paper Co Ltd Can Pulp Paper Assoc Woodlands Section Woodlands Section Index No 1050 F 2 4 p Rowe J S 1955 Factors influencing white spruce reproduction in Manitoba and Saskatchewan Can Dep Northern Affairs and National Resources For Branch For Res Div Ottawa ON Project MS 135 Silv Tech Note 3 27 p McLeod J W 1964 Planting white spruce on wet brushy land Can Dep For For Res Branch Ottawa ON Publ 1067 4 p Sutton R F 1992 White spruce Picea glauca Moench Voss stagnating boreal old field plantations unresponsive to fertilization and weed control For Chron 68 249 258 a b Solomon A M West D C and Solomon J A 1981 Simulating the role of climate change and species imiigration in forest succession p 154 178 in West D C Shugart H H Botkin D B Eds Forest Succession Concepts and Application Springer Verlag New York NY Van Cleve K Dyrness R Viereck L 1980 Nutrient cycling in interior Alaska flood plains p 11 18 in Murray M Van Veldhuizen R M Eds Proc Workshop Fairbanks Alaska Nov 1979 USDA For Serv Pacific Northwest For Exp Sta Portland OR Gen Tech Rep PNW 107 52 p Heikinheimo O 1915 Der einfluss der brandwirtschaft auf die Walder Finnlands Kaskiviljelyksen Vaikutus Suomen Metsin Acta Forest Fenn 4 1 264 1 149 1 59 German summary p 1 59 Lutz H J 1956 Ecological effects of forest fires in the interior of Alaska USDA For Serv Washington DC Tech Bull 1133 121 p Gregory R A 1966 The effect of leaf litter upon establishment of white spruce beneath paper birch For Chron 42 251 255 Neiland B J Viereck L A 1977 Forest types and ecosystems p 109 136 in North American Forest Lands at Latitudes North of 60 Degrees Proc sympos Univ Alaska Fairbanks AK Sept 1977 a b c Dyrness C T 1980 Western forest cover types Northern Interior Boreal White spruce p 81 White spruce Aspen p 82 Black spruce White spruce p 84 and Black spruce Paper birch p 85 in Eyre F H Ed Forest Cover Types of the United States and Canada Soc Amer Foresters Washington DC Viereck L A 1975 Forest ecology of the Alaska taiga Circumpolar Conference on Northern Ecology Sept 1975 Ottawa ON National Res Council Ottawa ON Proc I 1 gt 22 Youngblood 1993 Search A abstr a b Eyre F H Ed 1980 Forest Cover Types of the United States and Canada Soc Amer Foresters Washington DC 148 p Payette S 1980 Eastern forest cover types Boreal Forest Region white spruce p 15 in Eyre F H Ed Forest Cover Types of the United States and Canada Soc Amer Foresters Washington DC 148 p The Spruce Beetle FIDL Na fs fed us Retrieved 2013 07 13 Switzer A L K 1960 Spruce management for the future For Chron 36 2 163 165 a b c Rose A H Lindquist O H 1985 Insects of eastern spruces fir and hemlock revised edition Gov t Can Can For Serv Ottawa For Tech Rep 23 159 p cited in Coates et al 1994 cited orig ed 1977 Fowells H A 1965 Picea spruces p 287 327 in Silvics of Forest Trees of the United States H A Fowells Compiler USDA Forest Service Washington DC Agric Handbook No 271 a b Ives W G H Wong H R 1988 Tree and shrub insects of the prairie provinces Gov t Can Can For Serv Edmonton AB Inf Rep NOR X 292 327 p Coates et al 1994 AGM Plants Ornamental PDF Royal Horticultural Society July 2017 p 78 Retrieved 25 April 2018 RHS Plantfinder Picea glauca Echiniformis Retrieved 25 April 2018 RHS Plantfinder Picea glaucavar albertiana Alberta Globe Retrieved 25 April 2018 RHS Plantfinder Picea glaucavar albertiana Conica Retrieved 25 April 2018 Arno Stephen F Hammerly Ramona P 2020 1977 Northwest Trees Identifying amp Understanding the Region s Native Trees field guide ed Seattle Mountaineers Books p 101 ISBN 978 1 68051 329 5 OCLC 1141235469 Farrar John 2017 Trees in Canada Fitzhenry amp Whiteside Limited p 103 ISBN 978 1 55455 406 5 Beer Before Hops Mapping the Flavours of Hidden Temple Gin 20 November 2020 PC Spruce Beer Soda Spruce Tips External links edit nbsp Media related to Picea glauca at Wikimedia Commons Retrieved from https en wikipedia org w index php title Picea glauca amp oldid 1219174624, wikipedia, wiki, book, books, library,

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