Associations
provided by BioImages, the virtual fieldguide, UK
Foodplant / gall
hypophyllous Adelges cooleyi causes gall of live, yellowing shoot tip of Picea sitchensis
In Great Britain and/or Ireland:
Foodplant / mycorrhiza / ectomycorrhiza
fruitbody of Amanita muscaria var. aureola is ectomycorrhizal with live root of Picea sitchensis
Remarks: Other: uncertain
Foodplant / pathogen
Armillaria mellea s.l. infects and damages Picea sitchensis
Foodplant / pathogen
pycnidium of Ascochyta coelomycetous anamorph of Ascochyta piniperda infects and damages defoliated shoot of Picea sitchensis
Foodplant / parasite
hypophyllous telium of Chrysomyxa abietis parasitises live needle of Picea sitchensis
Remarks: season: 3-5
Foodplant / parasite
amphigenous aecium of Chrysomyxa ledi var. rhododendri parasitises live needle of Picea sitchensis
Remarks: season: 7-9
Other: unusual host/prey
Foodplant / sap sucker
Cinara piceae sucks sap of Picea sitchensis
Foodplant / saprobe
fruitbody of Coniophora prasinoides is saprobic on decayed bark of Picea sitchensis
Foodplant / false gall
crowded pseudothecium of Cucurbitaria piceae causes swelling of characteristically twisted, swollen bud of Picea sitchensis
Foodplant / saprobe
fruitbody of Diplomitoporus lindbladii is saprobic on fallen, dead log (large) of Picea sitchensis
Foodplant / sap sucker
Elatobium abietinum sucks sap of live, yellowed then shed leaf of Picea sitchensis
Remarks: season: (1-)3-5(-12)
Other: major host/prey
Foodplant / saprobe
effuse colony of Endophragmiella dematiaceous anamorph of Endophragmiella resinae is saprobic on old wound of Picea sitchensis
Remarks: season: 9
Foodplant / saprobe
fruitbody of Fomitopsis pinicola is saprobic on dead log (large) of Picea sitchensis
Foodplant / saprobe
fruitbody of Globulicium hiemale is saprobic on decayed wood of Picea sitchensis
Plant / associate
fruitbody of Hebeloma populinum is associated with Picea sitchensis
Foodplant / saprobe
hysterothecium of Lophium mytilinum is saprobic on dead, old, decorticate log of Picea sitchensis
Remarks: season: 7-8
Other: minor host/prey
Foodplant / saprobe
apothecium of Lophodermium piceae is saprobic on dead, attached needle of Picea sitchensis
Remarks: season: 5
Foodplant / saprobe
erumpent apothecium of Micraspis tetraspora is saprobic on dead, decorticated wood of Picea sitchensis
Remarks: season: 10-11
Foodplant / pathogen
amphigenous colony of Mycocentrospora anamorph of Mycocentrospora acerina infects and damages live leaf of Picea sitchensis
Foodplant / saprobe
erumpent stroma of Nectria fuckeliana is saprobic on dead twig of Picea sitchensis
Remarks: season: 3-8
Foodplant / sap sucker
Pachypappa sucks sap of live root of Picea sitchensis
Foodplant / sap sucker
Pachypappella sucks sap of live root of Picea sitchensis
Foodplant / pathogen
fruitbody of Phaeolus schweinitzii infects and damages live root of Picea sitchensis
Foodplant / gall
gallicola nymph of Pineus similis causes gall of Picea sitchensis
Foodplant / saprobe
erumpent apothecium of Pseudophacidium piceae is saprobic on dead, old but not decayed log of Picea sitchensis
Remarks: season: 5
Foodplant / saprobe
superficial, clustered, hypophyllous pycnidium of Rhizosphaera coelomycetous anamorph of Rhizosphaera kalkhoffii is saprobic on dead needle of Picea sitchensis
Remarks: season: late winter to early spring
Foodplant / saprobe
erumpent, shortly stalked apothecium of Tryblidiopsis pinastri is saprobic on dead, attached twig of Picea sitchensis
Remarks: season: 5-7
Foodplant / saprobe
Tubulicium vermiferum is saprobic on dead wood of debris of Picea sitchensis
Other: unusual host/prey
Comments
provided by eFloras
Picea sitchensis intergrades extensively with P . glauca in the river inlets of north coastal British Columbia and coastal Alaska. The name P . ´ lutzii Little is applied to hybrids between the two species (R.Daubenmire 1968).
Sitka spruce ( Picea sitchensis ) is the state tree of Alaska.
- license
- cc-by-nc-sa-3.0
- copyright
- Missouri Botanical Garden, 4344 Shaw Boulevard, St. Louis, MO, 63110 USA
Description
provided by eFloras
Trees to 80m; trunk to 5m diam.; crown narrowly conic. Bark grayish brown to orange-brown. Branches somewhat drooping; twigs not pendent, rather stout, pinkish brown, glabrous. Buds reddish brown, 5--10mm, apex rounded. Leaves (1.2--)1.5--2.5(--3)cm, flattened or broadly triangular in cross section (abaxial surface rounded or slightly angular), rather rigid, blue-green to light yellow-green, abaxial surface darker green with stomatal bands very narrow or absent, adaxial surface glaucous with conspicuous stomatal bands separated by ridge, apex sharp-pointed. Seed cones 5--9(--10)cm; scales variable, elliptic to narrowly diamond-shaped, 15--22 ´ 12--16mm, rather rigid, margin at apex erose, apex extending 4--8mm beyond seed-wing impression. 2 n =24.
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- cc-by-nc-sa-3.0
- copyright
- Missouri Botanical Garden, 4344 Shaw Boulevard, St. Louis, MO, 63110 USA
Habitat & Distribution
provided by eFloras
Pacific coastal forests; 0--900m; B.C.; Alaska, Calif., Oreg., Wash.
- license
- cc-by-nc-sa-3.0
- copyright
- Missouri Botanical Garden, 4344 Shaw Boulevard, St. Louis, MO, 63110 USA
Synonym
provided by eFloras
Pinus sitchensis Bongard, Mém. Acad. Imp. Sci. Saint-Pétersbourg, Sér. 6, Sci. Math. 2: 164. 1832 (Aug.); Abies falcata Rafinesque; A. menziesii (Douglas ex D. Don) Lindley 1835, not Mirbel 1825; Picea falcata (Rafinesque) Suringar; P. menziesii (Douglas ex D. Don) Carrière; Pinus menziesii Douglas ex D. Don
- license
- cc-by-nc-sa-3.0
- copyright
- Missouri Botanical Garden, 4344 Shaw Boulevard, St. Louis, MO, 63110 USA
Brief Summary
provided by EOL authors
Picea sitchensis, Sitka spruce, is a large coniferous tree in the Pinaceae (pine family) that is the largest of the world's spruces and is one of the most prominent forest trees in stands along the northwest coast of North America. Also known as tideland spruce, coast spruce, and yellow spruce, this coastal species is seldom found far from tidewater, where moist maritime air and summer fogs help to maintain humid conditions necessary for growth. Throughout most of its range from northern California to Alaska, Sitka spruce is associated with western hemlock (Tsuga heterophylla) in dense stands where growth rates are among the highest in North America. It is a valuable commercial timber species for lumber, pulp, and various specialty products, and is the State Tree of Alaska. Sitka spruce grows in a narrow strip along the north Pacific coast from latitude 61° N. in southcentral Alaska to 39° N. in northern California. The most extensive portion of the range in both width and elevation is in southeast Alaska and northern British Columbia, where the east-west range extends for about 210 km (130 mi) to include a narrow mainland strip and the many islands of the Alexander Archipelago in Alaska and the Queen Charlotte Islands in British Columbia. In Washington, the range includes a narrow mainland strip along the Strait of Georgia, around Puget Sound, up valleys to the east, and on the Olympic Peninsula. On the west side of the Olympic Peninsula, the range broadens to include the extensive coastal plain and seaward mountain slopes. It narrows southward along the Washington and Oregon coast but extends inland for several kilometers along the major rivers. In northern California, the range is more attenuated and becomes discontinuous. A disjunct population in Mendocino County, CA, marks the southern limit of the range. Sitka spruce usually grows in mixed stands, less often in pure stands. Pure stands usually occur in early successional situations and as tidewater stands influenced by salt spray. Sitka spruce is commonly associated with western hemlock throughout most of its range. Toward the south, other conifer associates include Douglas-fir (Pseudotsuga menziesii), Port-Orford-cedar (Chamaecyparis lawsoniana), western white pine (Pinus monticola), and redwood (Sequoia sempervirens). Sitka spruce is commercially harvested as pulpwood and for lumbers. High strength-to-weight ratio and resonant qualities of clear lumber are attributes that have traditionally made Sitka spruce wood valuable for specialty uses, such as sounding boards for high-quality pianos; guitar faces; ladders; construction components of experimental light aircraft; oars, planking, masts, and spars for custom-made or traditional boats; and turbine blades for wind energy conversion systems.
- bibliographic citation
- Harris, A.S. 1990. <i>Picea sitchensis</i> (Bong.) Carr., Sitka Spruce. In Burns, Russell M., and Barbara H. Honkala, tech. coords. 1990. <i>Silvics of North America: Vol. 1. Conifers</i>. Agriculture Handbook 654. U.S. Department of Agriculture, Forest Service, Washington, DC.
- author
- Jacqueline Courteau (Jacqueline Courteau)
Common Names
provided by Fire Effects Information System Plants
Sitka spruce
tideland spruce
coast spruce
yellow spruce
silver spruce
western spruce
Menzies' spruce
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Cover Value
provided by Fire Effects Information System Plants
More info for the terms:
cover,
woodlandSitka spruce forests provide hiding and thermal cover for a large
variety of mammals. Old-growth Sitka spruce forests in Alaska and
British Columbia are critical winter habitat for the Sitka deer. Old
growth provides thermal cover and acts as a snow screen, allowing easier
access to browse species [
25,
51]. Sitka deer require large blocks of
old growth from sea level to the alpine and subalpine environments for
migrational movements from summer to winter range [
51]. Sitka spruce
forests also provide habitat for Roosevelt elk, woodland caribou [
19],
Alaskan brown bear, and mountain goat [
42].
Sitka spruce provides good nesting and roosting habitat for avifauna
[
52,
56]. Snags and live trees with broken tops provide nesting habitat
for primary and secondary cavity nesters [
27]. The bald eagle uses
primarily (greater than 90 percent) Sitka spruce for nesting trees on
Admiralty Island [
42], and also uses them as roosting trees to survey
the incoming breakers for food [
5]. The peregrine falcon in coastal
British Columbia uses Sitka spruce for platform nesting and secondary
cavity nesting [
9].
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Description
provided by Fire Effects Information System Plants
More info for the terms:
forest,
monoecious,
treeSitka spruce is a native, long-lived (greater than 800 years),
evergreen, monoecious tree [
24,
55]. Female strobili are produced at the
ends of primary branches near the top, while the male strobili are
positioned lower in the tree on secondary branches [
24].
Sitka spruce is the world's largest spruce. It can obtain heights of
greater than 210 feet (65 m) with a d.b.h. of 16 feet (5 m) on better
sites [
24]. The base of the bole is buttressed [
55]. When forest grown
the bole is long and free of lower limbs [
23].
The root system of Sitka spruce is shallow and platelike with long
lateral roots with few branchings. On deep well-drained soils the root
system may reach depths of 6.5 feet (2 m), especially on alluvial soils.
Root grafting often occurs between roots of the same tree and adjacent
trees [
22,
24].
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Distribution
provided by Fire Effects Information System Plants
More info for the term:
naturalSitka spruce's natural range is a narrow strip of land along the
northern Pacific coast from south-central Alaska to northern California.
Its widest distribution (130 miles [210 km] inland) occurs in
southwestern Alaska and northern British Columbia. Its southern
boundary is defined by a disjunct population in Mendocino County,
California [
23,
24].
Sitka spruce has been extensively introduced into the British Isles
[
35,
57].
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Fire Ecology
provided by Fire Effects Information System Plants
More info for the term:
fire regimeFire is not an important factor in the ecology of Sitka spruce [
1]. Its
thin bark and a shallow root system make it very susceptible to fire
damage [
5,
8]. Sitka spruce forests have a fire regime of long-interval
(150 to 350+ years) severe crown or surface fires which result in total
stand replacement [
44].
FIRE REGIMES : Find fire regime information for the plant communities in which this
species may occur by entering the species name in the
FEIS home page under
"Find FIRE REGIMES".
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Fire Management Considerations
provided by Fire Effects Information System Plants
More info for the terms:
competition,
fire exclusion,
forest,
seedArguments for and against slash burning in spruce forests recur
throughout the literature. The strategy chosen will yield different
results, depending on latitude.
In the northern portion of Sitka spruce's range broadcast burning will
favor Sitka spruce over western hemlock, but unless Sitka spruce is
planted, seedling establishment will be delayed until the next seed crop
[
14,
26,
48,
49]. Ruth and Harris [
49] list the advantages of slash
burning as follows:
(1) Reduces fire hazard
(2) Destroys advance regeneration *
(3) Changes timber type
* This can have both positive and negative ramifications. It reduces
competition with western hemlock, but growth of Sitka spruce seedlings
in one study was reduced [
14].
In the southern portion of its range broadcast burning will favor the
establishment of Douglas-fir (Pseudotsuga menziesii) mixed forest, while
long-term fire exclusion will result in loss of Douglas-fir from the
overstory. This is advantageous due to the increased stumpage value of
Douglas-fir and the negative impacts of the spruce weevil [
44,
49].
In the coastal area of Alaska, broadcast burning has been recommended to
reduce the negative aesthetic value of large quantities of slash from
clearcut old-growth Sitka spruce forests [
53].
However, removal of the slash by burning in Sitka spruce forests is not
required because of the to rapid decay in that moist environment [
48].
Burning is not recommended on steep slopes and where water quality may
be degraded [
48,
53].
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Growth Form (according to Raunkiær Life-form classification)
provided by Fire Effects Information System Plants
More info on this topic. More info for the term:
phanerophytePhanerophyte
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Habitat characteristics
provided by Fire Effects Information System Plants
Sitka spruce occurs in the hypermaritime to maritime cool mesothermal
climates [
32,
33]. It occurs from shoreline to timberline in the
northern portion of its range but is restricted to shoreline in the
southern portion of its range [
6]. Sitka spruce grows best on sites
with deep, moist, well-drained soils [
22]. It can tolerate the salty
ocean spray of seaside dunes, headlands, and beaches, and the brackish
water of bogs [
34]. Sitka spruce is limited to areas of high annual
precipitation with cool, moist summers [
16,
23].
Soil: Sitka spruce has a stong affinity for soils high in calcium,
magnesium, and phosphorus in the soil orders Entisols, Spodosols,
Inceptisols, and Histosols. These soils are usually acidic with pH
typically ranging from 4.0 to 5.7 [
24].
Elevation: Sitka spruce grows from sea level to timberline in Alaska (0
to 3,900 feet (0-1,189 m)) [
55] with elevational limitations of 2,000
feet (600 m) in Washington and 1,500 feet (450 m) in Oregon and
California [
5].
Associates: In addition to those listed under Distribution and
Occurrence, Sitka spruce's overstory associates include mountain hemlock
(Tsuga mertensiana), Alaska-cedar (Chamaecyparis nootkatensis),
lodgepole pine (Pinus contorta), and western white pine (P. monticola)
[
24].
Understory associates include western swordfern (Polystichum munitum),
false lily-of-the-valley (Maianthemum dilatatum), stream violet (Viola
glabella), evergreen violet (V. sempervirens), red huckleberry
(Vaccinium parvifolium), devils club (Oplopanax horridus), salmonberry
(Rubus spectablis), and thimbleberry (R. parviflorus) [
24].
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Habitat: Cover Types
provided by Fire Effects Information System Plants
More info on this topic. This species is known to occur in association with the following cover types (as classified by the Society of American Foresters):
221 Red alder
222 Black cottonwood - willow
223 Sitka spruce
224 Western hemlock
225 Western hemlock - Sitka spruce
227 Western redcedar - western hemlock
228 Western redcedar
229 Pacific Douglas-fir
230 Douglas-fir - western hemlock
231 Port-Orford-cedar
232 Redwood
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Habitat: Ecosystem
provided by Fire Effects Information System Plants
More info on this topic. This species is known to occur in the following ecosystem types (as named by the U.S. Forest Service in their Forest and Range Ecosystem [FRES] Type classification):
FRES20 Douglas-fir
FRES23 Fir - spruce
FRES24 Hemlock - Sitka spruce
FRES27 Redwood
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Habitat: Plant Associations
provided by Fire Effects Information System Plants
More info on this topic. This species is known to occur in association with the following plant community types (as classified by Küchler 1964):
More info for the term:
forestK001 Spruce - cedar - hemlock forest
K002 Cedar - hemlock - Douglas-fir forest
K006 Redwood forest
K029 California mixed evergreen forest
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Immediate Effect of Fire
provided by Fire Effects Information System Plants
More info for the term:
treeThe immediate effect of a cool to hot fire is damage to the cambium
layer, usually resulting in death of the tree [
5,
8].
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Importance to Livestock and Wildlife
provided by Fire Effects Information System Plants
More info for the term:
successionSitka spruce forests in various phases of succession provide habitat, in
many cases critical habitat, for a large variety of mammals, game and
nongame birds, reptiles, and amphibians [
7,
19,
43]. Its value as a
browse species for large ungulates is poor [
11], while it has fair to
good value for some game birds [
42].
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Key Plant Community Associations
provided by Fire Effects Information System Plants
More info for the terms:
association,
forest,
naturalSitka spruce is listed as a dominant overstory species in the following
published classifications:
Natural vegetation of Oregon and Washington [
16].
Plant association and management guide: Siuslaw National Forest [
27].
Preliminary classification of forest vegetation of the Kenai
Peninsula, Alaska [
46].
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Life Form
provided by Fire Effects Information System Plants
More info for the term:
treeTree
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Management considerations
provided by Fire Effects Information System Plants
More info for the terms:
phase,
shrub,
treeSitka spruce, as one of the most important timber species and components
of old-growth habitat, has recently been the center of many management
concerns. Proposals for changes in timber harvest areas and methods
have been explored by Nyberg and others [
43] and Schoen and Kirchhoff
[
51]. They provide in-depth information and management alternatives.
Wildlife habitat: Even-aged management of the species results in
reduced habitat for the black-tailed deer. Shrub fields created after
clearcutting are of limited use to deer in the winter. The depth of
snow accumulation is greater, and snow persists longer in the clearcuts,
reducing the time available for browsing. The forage in clearcuts is
less digestible than that grown in the shade of the preharvest stands.
Also, the large amount of slash resulting from clearcutting old-growth
Sitka spruce impedes movement of large ungulates, especially during
winter migration. Lastly, once the regeneration has reached canopy
closure (20 to 30 years), the understory production is greatly reduced
for at least the next 100 years, compared to old-growth stands with
their various stages of regeneration [
19,
25].
Alaback [
2] studied ways to reduce the negative impact of clearcutting
on Sitka deer. Thinning the stands prior to canopy closure (less than
25 years) seems to be the best method for areas already cut. Thinning
to 12 x 12 feet (3.5 x 3.5 m) spacing results in the most diverse
vegetation. Once canopy closure has occurred (greater than 30 years),
uneven-aged management practices can result in the creation of gaps in
the canopy, which in turn will allow for a more diverse understory [
3].
Damaging agents: Sitka spruce is susceptible to Sitka spruce weevil, or
white pine weevil (Pissodes strobi)), spruce aphid (Elatobium
abietinum), spruce beetle (Dendroctonus rufipennis), and root rot by
Armillaria millea and Heterobasidian annosum [
24].
The Sitka spruce weevil has such a detrimental effect on Sitka spruce in
the lower portion of its range, from southern British Columbia to
northern California, that Sitka spruce is not actively managed for
regeneration there. The F1 generation of the hybrid, Lutz spuce, yields
a tree 100 percent resistant to weevil attack, but growth rate is
sacrificed. Back-crossing the F1 generation with Sitka spruce increases
the growth rate, but up to 50 percent of the progeny are susceptible to
weevil attack [
41]. Also, although Lutz spruce is less susceptible to
the Sitka spruce weevil, it is more susceptible than Sitka spruce to the
spruce beetle [
29].
Sitka spruce is susceptible to wind throw, which can account for up to
80 percent of the mortality within stands. Regeneration from gap phase
replacement, however, is rapid [
15].
Control: Chemical shrub control is often required to regenerate Sitka
spruce successfully following harvest [
18,
36].
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Occurrence in North America
provided by Fire Effects Information System Plants
AK CA HI OR WA BC YT
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Other uses and values
provided by Fire Effects Information System Plants
Native Americans have used Sitka spruce for various purposes. The roots
can be woven to produce baskets and rain hats. The pitch was used for
calking canoes [
5], for chewing, and medicinal purposes [
47].
Pioneers split Sitka spruce into shakes for roofing and siding [
5].
Sitka spruce also has limited food value for humans, for the inner bark
and young shoots may be eaten as emergency food. Tea can be made from
the young shoots [
47].
In the first half of this century Sitka spruce provided most of the wood
for structural components of World War I and II aircraft [
5,
55]. More
recently it has been used as the nose cones for missiles and space craft
[
50].
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Palatability
provided by Fire Effects Information System Plants
Sitka spruce is slightly palatable to large ungulates. It is browsed
only in the spring, and then only the new growth [
5,
11]. In Alaska and
British Columbia the needles comprise up to 90 percent of the winter
diet of blue grouse [
42].
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Phenology
provided by Fire Effects Information System Plants
More info on this topic. More info for the terms:
fruit,
seedFlowering and seed dispersal dates for Sitka spruce in Alaska and Oregon
are as follows [
22,
50]:
Flowering Fruit Ripens Seed Dispersal
Alaska April to June late Aug. to mid-Sept. Starts in Oct
Oregon May Aug Oct. to Spring
Seed dispersal is moisture dependent; when the ripe cones dry dispersal
begins. The majority (73 percent) of seed are dispersed in the first 6
weeks; the remainder are released over the next year [
22].
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Plant Response to Fire
provided by Fire Effects Information System Plants
More info for the terms:
seed,
treeSitka spruce will invade a burned site via wind-dispersed seed from
adjacent unburned forests [
49]. Wind-dispersed seed travels 33 to 880
yards (30-792 m) from the parent tree [
24].
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Post-fire Regeneration
provided by Fire Effects Information System Plants
Secondary colonizer - offsite seed
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Regeneration Processes
provided by Fire Effects Information System Plants
More info for the terms:
epigeal,
forest,
layering,
seedSitka spruce reproduces both sexually and asexually. Sexual maturity
varies from 20 to 40 years. Dispersal of seeds is moisture dependent;
when the ripe cones dry the seed is dispersed, and when the cones become
wet again they close. To avoid loss of seed, cones should be collected
soon after ripening [
50]. The seeds are small with a mean of 210,000
cleaned seeds per pound (467,000/kg) [
24]. The germination rate is 54
percent, but this can be raised to 66 percent by moistening the
germination medium with a 0.2 percent potassium nitrate (KNO3) solution
[
50].
Germination is epigeal. Sitka spruce seed will germinate on almost any
substrate, although mineral soil or a mixture of mineral soil and organic
soil are considered the best seedbeds [
24]. The "nurse log syndrome"
has a key role in the regeneration of Sitka spruce in its wetter
environs [
12,
15,
20]. Germination and seedling survival are greater on
rotting logs then on the forest floor. In a germination study less than
1 percent of the seeds in a moss mat germinated, and of these 38 percent
were killed within a month by fungi [
21]. Nurse log syndrome results in
a "colonnade" where there are several trees in a row with the roots
supporting the bole in mid-air after the nurse log has rotted away [
5].
Seedling establishment and growth can be enhanced with the inoculation of
the mycorrhizal fungi, Thelephora terrestris [
10,
40].
Sitka spruce shows strong trends in hardiness and growth in relation to
geographic origination. These trends can be used to increase growth
rate, but they can also have adverse effects on survival [
22,
38].
Lester and others [
38] provide information on seed sources, outplanting
results, hardiness, and growth rate trends.
Sitka spruce reproduces asexually by layering. This usually takes place
in moist areas or at timberline [
22,
24,
31,
55]. Cuttings from current
year's growth root more readily than older branches [
24].
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Regional Distribution in the Western United States
provided by Fire Effects Information System Plants
More info on this topic. This species can be found in the following regions of the western United States (according to the Bureau of Land Management classification of Physiographic Regions of the western United States):
1 Northern Pacific Border
2 Cascade Mountains
3 Southern Pacific Border
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Successional Status
provided by Fire Effects Information System Plants
More info on this topic. More info for the term:
climaxSitka spruce is a shade-intolerant species [
33] that is both a pioneer
and a climax species [
22]. Sitka spruce acts as an early pioneer on the
undeveloped soils of landslides, sand dunes, uplifted beaches, and
deglaciated terrain; it is a climax species in the coastal forests [
22].
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Taxonomy
provided by Fire Effects Information System Plants
More info for the term:
introgressionThe scientific name of Sitka spruce is Picea sitchensis (Bongard)
Carriere (Pinaceae) [
28,
50].
Species within the genus Picea form hybrid swarms at the interface of
their ranges. Sitka spruce naturally hybridizes with white spruce (P.
glauca) to produce Lutz spruce (Picea X lutzii Little) [
22,
23,
24,
55].
It is often difficult to identify Picea X lutzii by morphological
chacteristics in stands with low levels of introgression [
23].
Sitka spruce in plantations will also hybridize with Yezo spruce (Picea
jezoensis), Serbian spruce (P. omorika), and Engelmann spruce (P.
engelmannii) [
22,
23,
24].
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Value for rehabilitation of disturbed sites
provided by Fire Effects Information System Plants
Sitka spruce is a pioneer species which colonizes glacial moraines as
the glaciers retreat. On the Juneau Icefield, Sitka spruce has
colonized "nunatacks" (rocky peaks) protruding through the icefield [
6].
Sitka spruce also acted as an aggressive pioneer on uplifted terrain
from the 1964 earthquake [
4].
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Wood Products Value
provided by Fire Effects Information System Plants
Sitka spruce is the most important timber species in Alaska [
5]. The
wood, with its high strength to weight ratio, is valuable for use as
turbine blades for wind-driven electrical generators, masts for sail
boats, ladders, oars [
24], boats, and racing sculls [
55]. Sitka
spruce's high resonant quality makes it valuable in the manufacture of
piano sounding boards and guitars. The wood from Sitka spruce is also
used in saw timber, high-grade wood pulp, and plywood [
30,
55].
- bibliographic citation
- Griffith, Randy Scott. 1992. Picea sitchensis. In: Fire Effects Information System, [Online]. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory (Producer). Available: http://www.fs.fed.us/database/feis/
Associated Forest Cover
provided by Silvics of North America
Sitka spruce is commonly associated with western hemlock throughout most
of its range. Toward the south, other conifer associates include
Douglas-fir (Pseudotsuga menziesii), Port-Orford-cedar (Chamaecyparis
lawsoniana), western white pine (Pinus monticola), and redwood
(Sequoia sempervirens). Shore pine (P. contorta var. contorta)
and western redcedar (Thuja plicata) are also associates that
extend into southeast Alaska. Toward the north, conifer associates also
include Alaska-cedar (Chamaecyparis nootkatensis), mountain
hemlock (Tsuga mertensiana), and subalpine fir (Abies
lasiocarpa)-trees that are usually found only at higher elevations
toward the south. In central and northern British Columbia and Alaska,
however, these species are found with Sitka spruce from sea level to
timberline. White spruce (Picea glauca) is also associated with
Sitka spruce in Alaska, and hybrids occur. The most important hardwood
associates are red alder and bigleaf maple (Acer macrophyllum) in
the south and red alder and Sitka alder toward the north. Black cottonwood
(Populus trichocarpa) is an associate throughout the range.
Stands stocked with at least 80 percent Sitka spruce are identified as
the forest cover type Sitka Spruce (Society of American Foresters Type
223) (6). Sitka spruce is also a component of 10 other forest cover types:
221 Red Alder
222 Black Cottonwood-Willow
224 Western Hemlock
225 Western Hemlock-Sitka Spruce
227 Western Redcedar-Western Hemlock
228 Western Redcedar
229 Pacific Douglas-Fir
230 Douglas-Fir-Western Hemlock
231 Port-Orford-Cedar
232 Redwood
Sitka spruce usually grows in mixed stands, less often in pure stands.
Pure stands usually occur in early successional situations and as
tidewater stands influenced by salt spray. The most extensive pure stands
are found on the Kodiak-Afognak Archipelago at the extreme west extension
of the range. Sitka spruce is the only conifer present on this group of
islands. A relatively recent invader there, spruce is expanding its range
to the southwest, invading a tundra complex at the rate of about 1.6 km (1
mi) per century (14).
In Oregon and Washington, common understory species associated with
Sitka spruce include swordfern (Polystichum munitum), Oregon
oxalis (Oxalis oregana), false lily-of-the-valley (Maianthemum
dilatatum), western springbeauty (Montia sibirica), three-leaved
coolwort (Tiarella trifoliata), evergreen violet (Viola
sempervirens), stream violet (V. glabella), Smith fairybells
(Disporum smithii), red huckleberry (Vaccinium parvifolium),
and rustyleaf menziesia (Menziesia ferruginea). On drier
sites, salal (Gaultheria shallon), Pacific rhododendron (Rhododendron
macrophyllum), and evergreen huckleberry (Vaccinium ovatum) are
common. On wetter forest sites, the previously mentioned species are
found, along with devilsclub (Oplopanax horridum), ladyfern (Athyrium
filix-femina), deerfern (Blechnum spicant), mountain woodfern
(Dryopteris austriaca), and Pacific red elder (Sambucus
callicarpa) (11).
In Alaska, the more common understory plants include devilsclub,
skunkcabbage (Lysichitum americanum), ovalleaf huckleberry (Vaccinium
ovalifolium), red huckleberry, Alaska blueberry (V. alaskaense),
rustyleaf menziesia, salmonberry (Rubus spectabilis), five-leaf
bramble (R. pedatus), thimbleberry (R. parviflorus), bunchberry
(Cornus canadensis), stink currant (Ribes bracteosum), and
trailing black currant (R. laxiflorum) (32). Cryptogams are
abundant throughout the range of Sitka spruce. The Olympic Peninsula is
especially noted for mosses, many of which occur as epiphytes on living
trees.
In Oregon and Washington within the Sitka spruce forest zone, important
plant communities include Tsuga heterophylla-Picea
sitchensis/Gaultheria shallon/Blechnum spicant, Tsuga-Picea/Oplopanax
horridum/Athyrium filix-femina, or Tsuga-Picea/Polystichum
munitum-Oxalis oregana (11). Similar communities can be found in
southern British Columbia within the "fog western hemlock/Sitka
spruce subzone" (23). In Alaska, some of the more common communities
include Picea sitchensis/Oplopanax horridum-Rubus spectabilis/Cornus
canadensis, Picea sitchensis-Tsuga heterophylla/Lysichiton
americanum/Sphagnum spp., and Tsuga heterophylla-Picea
sitchensis-(Thuja plicata)/Vaccinium ovalifolium-V.
alaskaense/Rhytidiadelphus loreus (32).
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Climate
provided by Silvics of North America
Sitka spruce is restricted to an area of maritime climate with abundant
moisture throughout the year, relatively mild winters, and cool summers.
Summer temperatures decrease northward and lack the extremes found in more
continental locations. In terms of growing degree days, annual heat sums
(based on a threshold of 5° C or 41° F) range from 2511° C
(4,552° F) at Brookings, OR (lat. 41° 03' N.) to 851° C
(1,564° F) at Cordova, AK (lat. 60° 30' N.) (8). The number of
frost-free days varies locally but generally declines northward; averages
range from about 294 days at Brookings, OR, to 111 days at Cordova, AK
Annual precipitation varies within the range of Sitka spruce and is
influenced greatly by local topography. Annual precipitation of 2950 mm
(116 in) at Forks, WA, and 5615 mm (221 in) at Little Port Walter, AK,
contrasts with 635 mm (25 in) at Anacortes, WA, and 660 mm (26 in) at
Skagway, AK Summer precipitation is greater toward the north, where light
drizzle and fog are frequent. At Cordova, AK, from June to September, at
least a trace of precipitation occurs during 22 to 24 days each month. In
contrast, at Otis, OR, a trace or more of precipitation occurs on only 8
to 15 days each month. Toward the south, fog and moist maritime air are
important in maintaining moisture conditions needed for growth; most
winter precipitation is in the form of rain. Depth of snowfall increases
northward. Average annual snowfall at sea level is 1 em (0.5 in) at
Brookings, OR; 58 cm (23 in) at Quatsino, BC; and 340 cm (134 in) at
Cordova, AK
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Damaging Agents
provided by Silvics of North America
Blowdown is probably the most serious damaging
agent of Sitka spruce, but the species is attacked by a number of
pests-insects, disease organisms, and animals. In general, problems tend
to be more severe toward the south. The white pine weevil (Pissodes
strobi) is the most serious insect pest in Oregon, Washington, and
southern British Columbia; weevil damage has been the most serious
deterrent to management of Sitka spruce in the southern part of its range.
Damage is most severe on young trees 3 to 6 in (10 to 20 ft) tall. The
weevil is not a problem on the Queen Charlotte Islands or in Alaska,
possibly because there is insufficient summer heat to allow its
development (22). The spruce aphid (Elatobium abietinum) feeds on
Sitka spruce from California to Alaska and is a pest of ornamental trees.
Epidemics are sporadic and short lived. A root-collar weevil (Steremnius
carinatus) girdles l- and 2-year-old seedlings, causing some losses.
The spruce beetle (Dendroctonus rufipennis) periodically damages
stands throughout the range and is a major pest of spruce in British
Columbia. In addition, damage from a number of defoliators and other
insects is common (13).
Sitka spruce is highly susceptible to decay when injured (18). In the
past, most emphasis has been on studies of decay in old-growth stands, but
currently interest is shifting to young, managed stands. Some of the
organisms causing decay in old growth (for example, Heterobasidion
annosum and Armillaria mellea) can also cause root rot in
young stands. Heterobasidion annosum infects freshly cut stump
surfaces, and in Europe the tendency for plantation-grown Sitka spruce to
develop H. annosum butt rot is well known.
Foliage and stem diseases are usually of minor importance. Several rusts
cause occasional light to moderate defoliation, witches' brooms, or loss
of cones. Seed and seedling diseases are probably most important in
production of containerized seedlings in greenhouses.
Sitka spruce is damaged at various locations by animals such as elk,
bear, deer, porcupines, rabbits, hares, and squirrels. In general, these
problems are more serious in the southern part of the range. Deer are
generally more troublesome in the southern part, porcupines in the
northern part (25). Spruce is often less damaged than its associates.
Few growth abnormalities have been reported, although large tumorlike
growths on stems have been reported in Washington, and they occur in
Alaska as well. The causal agent is not known.
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Flowering and Fruiting
provided by Silvics of North America
Individual Sitka spruce may occasionally
produce cones before 20 years of age, but cone bearing in stands usually
does not begin until ages 20 to 40 (24). Sitka spruce is monoecious;
female strobili (cones) are usually produced at the ends of primary
branches near tops of trees; male strobili are usually produced at the
ends of secondary branches lower in trees. Both may be on the same branch.
Reproductive buds are initiated in early summer of the year preceding
pollination and seed ripening, and heavy cone crops have been explained in
terms of early summer drought the preceding year. Cones ripen in the year
they were pollinated. Pollen is shed from the last week in April in the
southern portion of the natural range through early June in the extreme
northwest part of the range. Time of flowering is mainly related to
temperature.
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Genetics
provided by Silvics of North America
In addition to the clinal latitudinal difference in growth rate, cone
characteristics such as size, length-to-width ratio, angle of sterigma,
and phylotaxy also vary with latitude (4).
Variation in wood characteristics has been reported by provenance,
region, site, and individual trees. Although no comprehensive heritability
studies have been completed, Sitka spruce shows considerable variation in
wood density, tracheid length, and grain angle. Improvement in these
characteristics through breeding appears feasible. Selection for vigor
tends to favor trees of lower-than-average specific gravity but has no
effect on tracheid length (15).
Provenance studies show that- at a given planting site- northern,
inland, and high-elevation sources are the first and the most variable in
breaking dormancy. Dormancy appears to be influenced by photoperiod, and
northern provenances are the first to enter dormancy. Total seasonal
height growth is positively correlated with the time interval between
flushing and dormancy. When moved north, introduced southern sources make
better height growth, but they may be subject to frost damage if moved too
far or planted on exposed sites. Once dormant, Sitka spruce is able to
endure very low temperatures without damage. Sitka spruce from northern
provenances may be more resistant to freezing than those from southern
provenances. Dormant leaves from a Bellingham, WA, source withstood
temperatures to -30° C (-22° F), whereas a Juneau, AK, source
withstood temperatures to -40° C (-40° F). Twigs of the two
sources withstood temperatures to -40° C and -60° C (-40° F
and -76° F), respectively (27).
Only limited data are available on genetic variation between individual
trees. Assessment of first-year characteristics of progeny from a diallel
cross among six trees showed that characters affecting tree form were
inherited in a predominantly additive fashion; characters reflecting tree
vigor were under "additive, dominance, and maternal control"
(28). Self-pollinated progeny showed growth depression caused by
inbreeding (28).
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Growth and Yield
provided by Silvics of North America
Height growth is slow for the first few years
but increases rapidly thereafter. On average sites in southeast Alaska,
trees can be expected to reach about 27 m (90 ft) in height within 50
years after attaining breast height (7). Average site index at elevations
near sea level varies inversely with latitude, declining from 48 m (158
ft) at base age 100 years in Lincoln County, OR, to 33 m (108 ft) in
southeast Alaska, at the rate of about 1 m (3 ft) per degree of latitude
(8). Observations within the natural range of spruce show that growth rate
also declines with increasing elevation.
Height growth of Sitka spruce and western hemlock are nearly equal
during the period of most rapid growth, but spruce grows more rapidly in
diameter. Consequently, thinning from below tends to favor spruce. Spruce
continues to maintain height growth longer than hemlock and lives longer.
Few hemlock live more than 500 years; Sitka spruce may live to 700 or 800
years. Very old spruces eventually assume a dominant position in
old-growth hemlock-spruce stands.
Sitka spruce trees often attain great size. In Alaska, mature trees near
sea level may exceed 61 m (200 ft) in height and 3 m (10 ft) in d.b.h. In
Oregon, a tree 87 m (286 ft) tall was reported (24). The largest tree on
record is located near Seaside, OR. It is 5.1 m (16.7 ft) in d.b.h. and
65.8 m (216 ft) tall and has a crown spread of 28 m (93 ft) (17).
Stands in which Sitka spruce is a major component tend to be dense, and
yields are high (21,30). Stand volumes can be impressive. One plot in a
147-year-old hemlock-spruce stand in coastal Oregon contained, on an area
basis, 188 spruce and 32 hemlock/ha (76 spruce and 13 hemlock/acre). Total
volume was 2380 m³/ha (34,000 ft³/acre). Spruce averaged 64 m
(210 ft) in height and 86 cm (34 in) in d.b.h., and hemlock averaged 44 m
(144 ft) in height and 46 cm (18 in) in d.b.h (24).
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Reaction to Competition
provided by Silvics of North America
Sitka spruce is more tolerant of shade
than Douglas-fir but less tolerant than hemlock. Depending on latitude,
Sitka spruce has been described as being in the tolerant and intermediate
shade-tolerant classes. Overall, it probably can most accurately be
classed as tolerant of shade. Since reproduction under mixed stands is
predominantly hemlock, there is a tendency for this more tolerant species
to eventually dominate the site. Few climax stands proceed to pure
hemlock, however; in time, small openings, usually caused by blowdowns,
develop, allowing reproduction of spruce. The combination of greater
stature, greater longevity, and occasional stand disturbance is enough to
assure a scattering of spruce in the overstory of most climax
hemlock-spruce stands.
Sitka spruce is one of the few conifers that develop epicormic branches
along the stem. Production of these sprouts is related to light intensity,
and roadside trees often develop dense new foliage from base to crown.
Thinning stimulates epicormic branching and could decrease the quality of
the wood, although this is not a problem in production of pulp or
dimension lumber. In deep shade, lower limbs soon die, decay, and break
off, but the resinous branch stubs remain for many years.
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Rooting Habit
provided by Silvics of North America
Roots will grow where moisture, fertility,
aeration, and mechanical soil properties are favorable. Consequently,
there is great variability in root form-from flat platelike roots to deep,
narrow-spreading roots (12). Where soils are shallow, soil temperature and
fertility low, and water tables high, shallow rooting is by far the most
common form. Deeper rooting does occur, however, where soils have good
drainage and depth to water table. Rooting to depths of 2 m (6 ft) has
been reported (5).
Sitka spruce commonly produces long lateral roots with few branches and
rapid elongation (20). Annual elongation rates of 42 to 167 cm (16 to 66
in) have been reported (3). Lateral roots up to 23 m (75 ft) in length
have been observed in Alaska (15). Root grafting occurs between roots of
the same tree and between adjacent trees. It is fairly common to find
living stumps sustained by root grafts from adjacent trees. Adventitious
roots develop on trees growing along streams where alluvium is deposited
by periodic flooding. Roots are vulnerable, however, to compaction and
lack of aeration. Spruce are frequently killed by permanent flooding
caused by beavers, and often valuable ornamental and roadside trees are
killed when landfill is deposited around them. Containerized nursery stock
has been successfully inoculated with the mycorrhizal fungi, Laccaria
laccata and Cenococcum geophilum (29).
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Seed Production and Dissemination
provided by Silvics of North America
Seeds of Sitka spruce are
small, averaging 463,000/kg (210,000/lb) (26). Seeds ripen in southeast
Alaska during late August or early September, and dispersal usually begins
in October. Cones open during dry weather, release seed, and reclose
during wet weather. One study showed that 73 percent of the seed was
released within 6 weeks of the first dispersal date, and the remainder was
released over 1 year (15). Good crops occur at 3- to 5-year intervals in
the southern part of the range and at 5- to 8-year intervals in Alaska.
Cone and seed production in seed orchards can be increased by treating
trees with gibberellin (31). Dispersal distance depends on several
factors, including height and location of the seed source, local
topography, and wind conditions. Reported dispersal distances range from
0.8 km (0.5 mi) when a seed source was on high ground, to 30 m (100 ft)
when seed was released from the edge of a clearcut area (15).
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Seedling Development
provided by Silvics of North America
Under natural conditions, seed germinates
on almost any seedbed, but survival may be low. Germination is epigeal
(26). A mineral soil or mixed mineral and organic soil seedbed is usually
considered best for germination, especially under light shade, as long as
drainage is adequate and the soil provides sufficient nutrients for tree
growth. Fine-textured soils combined with a high water table are suitable
for germination but may be unsuitable for seedling establishment because
of frost heaving. Coarse-textured mineral soils in unshaded conditions may
dry out excessively but may improve after invasion by hair mosses that
bind the soil surface and provide shade. Organic seedbeds are suitable in
shade but are unsuitable in the open if subject to severe moisture
fluctuations. On alluvial sites having high water tables and subject to
frequent flooding, where competition from brush is severe, rotten wood may
be the only suitable seedbed.
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Soils and Topography
provided by Silvics of North America
Sitka spruce grows on Entisols, Spodosols, Inceptisols, and Histosols,
on soils derived from a wide variety of parent material. The species
requires relatively high amounts of available calcium, magnesium, and
phosphorus, and grows best where soils are derived from rocks rich in
calcium and magnesium (19). Best development is on deep, moist,
well-aerated soils. Drainage is an important factor, and growth is poor on
swampy sites. Sitka spruce commonly occupies alluvial soils along streams,
sandy or coarse-textured soils, or soils having a thick accumulation of
organic material. Soils are usually acidic, and pH values of 4.0 to 5.7
are typical. Spruce is an early pioneer on immature soils recently exposed
by glacial retreat or uplift from the sea. It is more tolerant of ocean
spray than are associated trees and often occupies a prominent position on
exposed headlands and beaches along the outer coast (2). In Oregon and
Washington, spruce follows lodgepole pine (Pinus contorta) in
succession on coastal sand dunes as they become stabilized by vegetation.
On highly disturbed sites, it frequently becomes established concurrently
with red alder (Alnus rubra) or Sitka alder (A. sinuata), gradually
succeeding the alder as stands are eventually overtopped.
Sitka spruce grows from sea level to treeline in Alaska, at elevations
ranging from 910 m (3,000 ft) in southeast Alaska to 300 m (1,000 ft) in
Prince William Sound. High mountains of the coast ranges lie close to the
sea, forming a barrier to moist, onshore winds and providing abundant
moisture during the growing season. Spruce is limited in elevation by the
short growing season at treeline. South of northern British Columbia,
spruce is restricted to low elevations near the sea where moist maritime
air and fog help provide moisture during summer. For the most part, high
mountains that otherwise might offer suitable habitat lie farther inland
where more continental conditions of summer drought and warmer
temperatures are unsuitable for growth. Exceptions are on the Olympic
Peninsula and in valleys in the Cascade Range off Puget Sound in
Washington, and on isolated peaks in Oregon. On the Olympic Peninsula,
Sitka spruce rarely grows above 610 rn (2,000 ft) in elevation (1).
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Special Uses
provided by Silvics of North America
High strength-to-weight ratio and resonant qualities of clear lumber are
attributes that have traditionally made Sitka spruce wood valuable for
specialty uses, such as sounding boards for high-quality pianos; guitar
faces; ladders; construction components of experimental light aircraft;
oars, planking, masts, and spars for custom-made or traditional boats; and
turbine blades for wind energy conversion systems.
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Vegetative Reproduction
provided by Silvics of North America
Asexual reproduction by layering occurs
under natural conditions and in plantations, but layering is most likely
to occur on very moist sites at the edges of bogs or near timberline.
Asexual propagation can be done by air-layering or rooting of stem
cuttings. Clones differ in their ability to root or graft, and clones that
graft easily do not necessarily root easily and vice versa. Cuttings from
shoots of the current year root more easily than cuttings from older
branches (15).
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Physical Description
provided by USDA PLANTS text
Tree, Evergreen, Monoecious, Habit erect, Trees without or rarely having knees, Tree with bark rough or scaly, Young shoots 3-dimensional, Buds resinous, Buds not resinous, Leaves needle-like, Leaves alternate, Needle-like leaf margins entire (use magnification), Leaf apex acute, Leaves < 5 cm long, Leaves < 10 cm long, Leaves yellow-green above, Leaves yellow-green below, Leaves blue-green, Leaves not blue-green, Needle-like leaves flat, Needle-like leaves triangular, Needle-like leaves not twisted, Needle-like leaf habit erect, Needle-like leaf habit drooping, Needle-like leaves per fascicle mostly 1, Needle-like leaf sheath early deciduous, Needle-like leaf sheath persistent, Twigs glabrous, Twigs viscid, Twigs not viscid, Twigs with peg-like projections or large fascicles after needles fall, Berry-like cones orange, Woody seed cones > 5 cm long, Bracts of seed cone included, Seeds red, Seeds brown, Seeds winged, Seeds unequally winged, Seed wings prominent, Seed wings equal to or broader than body.
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Picea sitchensis
provided by wikipedia EN
Picea sitchensis, the Sitka spruce, is a large, coniferous, evergreen tree growing to almost 100 meters (330 ft) tall,[2] with a trunk diameter at breast height that can exceed 5 m (16 ft). It is by far the largest species of spruce and the fifth-largest conifer in the world (behind giant sequoia, coast redwood, kauri, and western red cedar),[3] and the third-tallest conifer species (after coast redwood and coast Douglas fir). The Sitka spruce is one of the few species documented to exceed 90 m (300 ft) in height.[4] Its name is derived from the community of Sitka in southeast Alaska, where it is prevalent. Its range hugs the western coast of Canada and the US, continuing south into northernmost California.
Description
The bark is thin and scaly, flaking off in small, circular plates 5–20 centimeters (2–8 in) across. The inner bark is reddish-brown.[5] The crown is broad conic in young trees, becoming cylindric in older trees; old trees may not have branches lower than 30–40 meters (98–131 ft). The shoots are very pale buff-brown, almost white, and glabrous (hairless), but with prominent pulvini. The leaves are stiff, sharp, and needle-like, 15–25 millimeters long, flattened in cross-section,[5] dark glaucous blue-green above with two or three thin lines of stomata, and blue-white below with two dense bands of stomata.
Foliage, mature seed cone, and (center) old pollen cone
The cones are pendulous, slender cylindrical, 6–10 cm (2+1⁄2–4 in) long[6] and 2 cm (3⁄4 in) broad when closed, opening to 3 cm (1+1⁄4 in) broad. They have thin, flexible scales 15–20 mm (5⁄8–3⁄4 in) long; the bracts just above the scales are the longest of any spruce, occasionally just exserted and visible on the closed cones. They are green or reddish, maturing pale brown 5–7 months after pollination. The seeds are black, 3 mm (1⁄8 in) long, with a slender, 7–9 mm (1⁄4–3⁄8 in) long pale brown wing.
Size
More than a century of logging has left only a remnant of the spruce forest. The largest trees were cut long before careful measurements could be made. Trees over 90 m (300 ft) tall may still be seen in Pacific Rim National Park and Carmanah Walbran Provincial Park on Vancouver Island, British Columbia (the Carmanah Giant, at 96 m (315 ft) tall, is the tallest tree in Canada),[7] and in Olympic National Park, Washington and Prairie Creek Redwoods State Park, California (United States); two at the last site are just over 96 m tall.[8] The Queets Spruce is the largest in the world with a trunk volume of 346 m3 (12,200 cu ft), a height of 74.6 m (244 ft 9 in), and a 4.4 m (14 ft 5 in) dbh.[9] It is located near the Queets River in Olympic National Park, about 26 km (16 mi) from the Pacific Ocean. Another specimen, from Klootchy Creek Park, Oregon, was previously recorded to be the largest with a circumference of 15 metres (49 ft) and height of 66 metres (217 ft).[10]
Age
Sitka spruce is a long-lived tree, with individuals over 700 years old known. Because it grows rapidly under favorable conditions, large size may not indicate exceptional age. The Queets Spruce has been estimated to be only 350 to 450 years old, but adds more than a cubic meter of wood each year.[11]
Root system
Because it grows in extremely wet and poorly-drained soil, the Sitka spruce has a shallow root system with long lateral roots and few branchings. This also makes it susceptible to wind throw.[12]
Taxonomy
DNA analysis[13][14] has shown that only P. breweriana has a more basal position than Sitka spruce to the rest of the spruce. The other 33 species of spruce are more derived, which suggests that Picea originated in North America.[13]
Distribution and habitat
Sitka spruce is native to the west coast of North America, with its northwestern limit on Kenai Peninsula, Alaska, and its southeastern limit near Fort Bragg in northern California.[15] It is closely associated with the temperate rainforests and is found within a few kilometers of the coast in the southern portion of its range. North of Oregon, its range extends inland along river floodplains, but seldom does its range extend more than around 80 km (50 mi) from the Pacific Ocean and its inlets.[5] It is situated at about 2,500 m (8,200 ft) above sea level in Alaska and generally below 450 m (1,480 ft) further south.[5]
Forests with the species average between 200 and 500 cm (79 and 197 in) of rain annually.[5] It is tolerant to salty spray common in coastal dune habitat, such as at Cape Disappointment State Park in Washington, and prefers soils high in magnesium, calcium, and phosphorus.[12]
Sitka spruce has been introduced to Europe as a lumber tree, and was first planted there in the 19th century. Sitka spruce plantations have become a dominant forest type in Great Britain and Ireland, making up 25% of forest cover in the former and 52% in the latter. Sitka spruce woodland is also present in France and Denmark, and the plant was introduced to Iceland and Norway in the early 20th century.[16][17] Observations of Sitka spruce along the Norwegian coast have shown the species to be growing 25-100% faster than the native Norway spruce there, even as far north as Vesterålen, and Sitka spruces planted along the southwest coast of Norway are growing fastest among the Sitka plantations in Europe.[18][19]
A 9-metre-tall, 100-year-old Sitka spruce growing in the middle of the permanently uninhabited sub-antarctic Campbell Island has been recognised by the Guinness World Records as the "most remote tree in the world".[20]
Ecology
Value to wildlife
Sitka spruce provides critical habitat for a large variety of mammals, birds, reptiles, and amphibians. Its thick, sharp needles are poor browse for ungulates, and only the new spring growth is eaten. However, in Alaska and British Columbia the needles of Picea sitchensis comprise up to 90% of the winter diet of blue grouse.[12]
Lichen-forming fungi Helocarpon lesdainii is found on Picea sitchensis trees in Harris Beach State Park, Oregon, USA.[21]
It provides cover and hiding places for a large variety of mammals, and good nesting and roosting habitat for birds. Sitka deer require old-growth Sitka spruce forests for winter habitat, as the extensive foliage holds a significant percentage of fallen snow in a given area, thus allowing for better understory browsing and easier migration for terrestrial animals. Cavity nesting birds favor Sitka spruce snags, and the tree is used by bald eagles,[5] and peregrine falcons as nesting habitat.
Successional status
Sitka spruce is shade tolerant but not as much as its competitors,[5] preferring full sun if possible. It is a pioneer on landslides, sand dunes, uplifted beaches, and deglaciated terrain. However, it is a climax species in coastal forests, where it can become dominant.[12]
Fire ecology
Due to the prevalence of Sitka spruce in cool, wet climates, its thin bark and shallow root system are not adapted to resist fire damage and it is thus very susceptible. Sitka spruce forests have a fire regime of severe crown or surface fires on long intervals, (150 to 350+ years) which results in total stand replacement. Sitka spruce recolonizes burned sites via wind-dispersed seed from adjacent unburned forests.[12]
Uses
The root bark of Sitka spruce trees is used in Native Alaskan basket-weaving designs[22] and for rain hats. The pitch was used for caulking, chewing, and its medicinal properties.[12] Native Americans heated and plied the roots to make cord.[5] The resin was used as glue and for waterproofing.[5] Natives and pioneers split off shakes for construction use.[5] The wood is light and relatively strong.[5]
Sitka spruce is of major importance in forestry for timber and paper production. Outside its native range, it is particularly valued for its fast growth on poor soils and exposed sites where few other trees can prosper; in ideal conditions, young trees may grow 1.5 m (5 ft) per year. It is naturalized in some parts of Ireland and Great Britain, where it was introduced in 1831 by David Douglas,[23] and New Zealand, though not so extensively as to be considered invasive. Sitka spruce is also planted extensively in Denmark, Norway, and Iceland.[24][25] In Norway, Sitka spruce was introduced in the early 1900s. An estimated 50,000 hectares (120,000 acres) have been planted in Norway, mainly along the coast from Vest-Agder in the south to Troms in the north. It is more tolerant to wind and saline ocean air, and grows faster than the native Norway spruce.[26] But in Norway, the Sitka spruce is now considered an invasive species, and effort to get rid of it is being made.[27][28]
The resonant wood[5] is used widely in piano, harp, violin, and guitar manufacture, as its high strength-to-weight ratio and regular, knot-free rings make it an excellent conductor of sound. For these reasons, the wood is also an important material for sailboat spars, and aircraft wing spars (including flying models). The Wright brothers' Flyer was built using Sitka spruce, as were many aircraft before World War II; during that war, aircraft such as the British Mosquito used it as a substitute for strategically important aluminium.
Newly grown tips of Sitka spruce branches are used to flavor spruce beer and are boiled to make syrup.[29][30]
Culture
A unique specimen with golden foliage that used to grow on Haida Gwaii, known as Kiidk'yaas or "The Golden Spruce", is sacred to the Haida First Nations people. It was illegally felled in 1997 by Grant Hadwin, although saplings grown from cuttings can now be found near its original site.
Chemistry
The stilbene glucosides astringin, isorhapontin, and piceid can be found in the bark of the Sitka spruce.[31][32]
Burls
In the Olympic National Forest in Washington, Sitka spruce trees near the ocean sometimes develop burls.
According to a guidebook entitled Olympic Peninsula, "Damage to the tip or the bud of a Sitka spruce causes the growth cells to divide more rapidly than normal to form this swelling or burl. Even though the burls may look menacing, they do not affect the overall tree growth."[33]
See also
References
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^ Farjon, A. (2013). "Picea sitchensis". IUCN Red List of Threatened Species. 2013: e.T42337A2973701. doi:10.2305/IUCN.UK.2013-1.RLTS.T42337A2973701.en. Retrieved 19 November 2021.
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^ Rushforth, Keith (1986) [1980]. Bäume [Pocket Guide to Trees] (in German) (2nd ed.). Bern: Hallwag AG. ISBN 3-444-70130-6.
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^ "Agathis australis". Conifers. Retrieved 9 April 2012.
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^ "Tallest Sitka Spruce". Landmark Trees. Retrieved 9 April 2012.
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^ a b c d e f g h i j k l Arno, Stephen F.; Hammerly, Ramona P. (2020) [1977]. Northwest Trees: Identifying & Understanding the Region's Native Trees (field guide ed.). Seattle: Mountaineers Books. pp. 83–91. ISBN 978-1-68051-329-5. OCLC 1141235469.
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^ "Picea sitchensis". Oregon State University. Retrieved 9 April 2012.
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^ Stoltmann, Randy, 1962- (1996). Hiking the ancient forests of British Columbia and Washington. Vancouver, B.C.: Lone Pine. ISBN 1551050455. OCLC 35161377.
{{cite book}}: CS1 maint: multiple names: authors list (link) -
^ "Picea sitchensis". Gymnosperm Database. Retrieved 15 July 2019. This tree also has a sign nearby proclaiming it to be 'the world's largest spruce'. The two tallest on record, 96.7 m and 96.4 m, are in Prairie Creek Redwoods State Park, California
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^ Van Pelt, Robert. (2015). Champion trees of washington state. Seattle, Washington, USA: Univ of Washington Press. ISBN 978-0295997452. OCLC 921868759.
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^ Traver, Robert (1985). America's Wild Woodlands. National Geographic Society. p. 12. ISBN 9780870445422.
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^ Van Pelt, Robert (2001). Forest Giants of the Pacific Coast. University of Washington Press. ISBN 0295981407.
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^ a b c d e f "Index of Species Information: Picea sitchensis". Fire Effects Information System. U.S. Forest Service. Retrieved 3 July 2015.
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^ a b Ran, JH; Wei, XX; Wang, XQ (2006). "Molecular phylogeny and biogeography of Picea (Pinaceae): Implications for phylogeographical studies using cytoplasmic haplotypes". Mol Phylogenet Evol. 41 (2): 405–19. doi:10.1016/j.ympev.2006.05.039. PMID 16839785.
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^ Sigurgeirsson, A; Szmidt, AE (1993). "Phylogenetic and biogeographic implications of chloroplast DNA variation in Picea". Nordic Journal of Botany. 13 (3): 233–246. doi:10.1111/j.1756-1051.1993.tb00043.x.
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^ Griffin, JR; Critchfield, WB (1976). Distribution of forest trees in California. USDA Forest Service Research Paper. pp. 23–24, 75. PSW-82.
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^ Bill, Mason; Perks, Michael P. (21 March 2011). "Sitka spruce (Picea sitchensis) forests in Atlantic Europe: changes in forest management and possible consequences for carbon sequestration". Scandinavian Journal of Forest Research. 26 (S11): 72–81. doi:10.1080/02827581.2011.564383. S2CID 85059411.
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^ Houston Durrant, T.; A., Mauri; D., de Rigo; Caudullo, G. (2016). "Picea sitchensis in Europe: distribution, habitat, usage and threats" (PDF). Forest.jrc. European Commission. Retrieved 11 July 2020.
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^ "Vestlandsk sitkagran vokser best i Europa". 29 September 2014.
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^ "Ligg unna sitkagrana i klimaskogen min". 10 March 2019.
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^ Morwood, Maddy How the world's loneliest tree is helping scientists advance climate change research ABC News, 5 September, 2022. Retrieved 5 September, 2022.
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^ "Helocarpon lesdainii | Oregon Digital". oregondigital.org. Retrieved 11 January 2023.
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^ Kallenbach, Elizabeth. "Tlingit Spruce Root Baskets". University of Oregon, Museum of Natural and Cultural History. Archived from the original on 18 September 2016. Retrieved 29 November 2013.
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^ Mitchell, A (1978). Trees of Britain & Northern Europe. Collins Field Guide. London: HarperCollins. ISBN 0-00-219213-6.
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^ Dammert, L (2001). "Dressing the landscape: afforestation efforts on Iceland]". Unasylva. 52 (207).
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^ Hermann, R (1987). "North American Tree Species in Europe" (PDF). Journal of Forestry. Archived from the original (PDF) on 18 September 2006. Retrieved 11 March 2010. Efforts to remove this species have been initiated in Norway as the Sitka spruce dominates the native ecology with few native species managing to compete or thrive in its shadow.
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^ Vadla, Kjell. "Sitkagran - utbredelse, egenskaper og anvendelse" [Sitka spruce - propagation, properties and uses]. Norwegian Forest and Landscape Institute (in Norwegian).
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^ "Vil utrydde granskog på Vestlandet og i Nord-Norge". Aftenposten. Retrieved 29 September 2017.
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^ "Her svir de av øyene nord for Herdla". Askøyværingen. Retrieved 29 September 2017.
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^ "Picea sitchensis: "Sitka Spruce, Tideland Spruce"". Collections. San Francisco Botanical Garden. Archived from the original on 19 September 2016. Retrieved 29 November 2013.
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^ "Alaska State Tree: Sitka Spruce". Alaskan Nature. Retrieved 29 November 2013.
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^ Masakazu Aritomi; Dervilla M.X. Donnelly (1976). "Stilbene glucosides in the bark of Picea sitchensis". Phytochemistry. 15 (12): 2006–2008. doi:10.1016/S0031-9422(00)88881-0.
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^ Claudia D. Toscano Underwood & Raymond B. Pearce (1991). "Astringin and isorhapontin distribution in Sitka spruce trees". Phytochemistry. 30 (7): 2183–2189. doi:10.1016/0031-9422(91)83610-W.
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^ Sedam, Michael T. (2002). The Olympic Peninsula: The Grace & Grandeur. Voyageur Press. p. 109. ISBN 978-0896584587.
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Picea sitchensis: Brief Summary
provided by wikipedia EN
Picea sitchensis, the Sitka spruce, is a large, coniferous, evergreen tree growing to almost 100 meters (330 ft) tall, with a trunk diameter at breast height that can exceed 5 m (16 ft). It is by far the largest species of spruce and the fifth-largest conifer in the world (behind giant sequoia, coast redwood, kauri, and western red cedar), and the third-tallest conifer species (after coast redwood and coast Douglas fir). The Sitka spruce is one of the few species documented to exceed 90 m (300 ft) in height. Its name is derived from the community of Sitka in southeast Alaska, where it is prevalent. Its range hugs the western coast of Canada and the US, continuing south into northernmost California.
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