Associations
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Foodplant / parasite
aecium of Coleosporium asterum parasitises live Pinus ponderosa
Foodplant / parasite
pycnium of Cronartium flaccidum parasitises live branch of Pinus ponderosa
Comments
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This species is economically important and is grown for its fine timber.
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Comments
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Pinus ponderosa is the most economically important western yellow pine. Its wood is more similar in character to the white pines, and it is often referred to as white pine. The taxonomy of this complex is far from resolved.
Ponderosa pine ( Pinus ponderosa ) is the state tree of Montana.
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Description
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Trees to 70 m tall; trunk to 2.5 m d.b.h. in native range; bark yellow- to red-brown, deeply and irregularly furrowed into broadly oblong, scaly plates; crown broadly conical to rounded; branchlets orange-brown, aging darker, stout, rough; winter buds red-brown, ovoid, very resinous, scales white fringed at margin. Needles tufted at apex of branchlets, spreading to erect, (2 or)3(-5) per bundle, deep yellow-green, slightly twisted, 7-25(-30) cm × (1-)1.2-2 mm, pliant, stomatal lines present on all surfaces, base with persistent sheath 1.5-3 cm, margin serrulate. Seed cones solitary or rarely paired, sessile or subsessile, mostly reddish brown, broadly ovoid when open, symmetric or asymmetric, 5-15 cm, maturing in 2 years, then soon shedding seeds, leaving rosettes of scales on branchlets. Apophyses dull or lustrous, thickened, variously raised, cross keeled; umbo usually pyramidal or truncate, rarely depressed or with a reflexed prickle. Seeds brown or yellow-brown, often mottled darker, ellipsoid-obovoid, 3-9 mm; wing 1.5-2.5 cm.
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Description
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Trees to 72m; trunk to 2.5m diam., straight; crown broadly conic to rounded. Bark yellow- to red-brown, deeply irregularly furrowed, cross-checked into broadly rectangular, scaly plates. Branches descending to spreading-ascending; twigs stout (to 2cm thick), orange-brown, aging darker orange-brown, rough. Buds ovoid, to 2cm, fully 1cm broad, red-brown, very resinous; scale margins white-fringed. Leaves 2--5 per fascicle, spreading to erect, persisting (2--)4--6(--7) years, 7--25(--30)cm ´ (1--)1.2--2mm, slightly twisted, tufted at twig tips, pliant, deep yellow-green, all surfaces with evident stomatal lines, margins serrulate, apex abruptly to narrowly acute or acuminate; sheath 1.5--3cm, base persistent. Pollen cones ellipsoid-cylindric, 1.5--3.5cm, yellow or red. Seed cones maturing in 2 years, shedding seeds soon thereafter, leaving rosettes of scales on branchlets, solitary or rarely in pairs, spreading to reflexed, symmetric to slightly asymmetric, conic-ovoid before opening, broadly ovoid when open, 5--15cm, mostly reddish brown, sessile to nearly sessile, scales in steep spirals (as compared to Pinus jeffreyi ) of 5--7 per row as viewed from side, those of cones just prior to and after cone fall spreading and reflexed, thus well separate from adjacent scales; apophyses dull to lustrous, thickened and variously raised and transversely keeled; umbo central, usually pyramidal to truncated, rarely depressed, merely acute, or with a very short apiculus, or with a stout-based spur or prickle. Seeds ellipsoid-obovoid; body (3--)4--9mm, brown to yellow-brown, often mottled darker; wing 15--25mm.
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Habitat & Distribution
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Cultivated. Henan (Jigong Shan), Jiangsu (Nanjing Shi), Jiangxi (Lu Shan), Liaoning [native to W North America]
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Associated Forest Cover
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Ponderosa pine can be either a climax or a seral species (18,27,47,61).
It is a climax species at the lower limits of the coniferous forests, and
a seral species in higher elevation mesic forests where more competitive
conifers are capable of growing. In climax forests, ponderosa pine stands
often contain many small, even-aged groups rather than a true uneven-aged
structure.
Fires have had a profound effect on the distribution of ponderosa pine.
Although the seedlings are readily killed by fire, larger trees possess
thick bark, which offers effective protection from fire damage. Competing
tree species, such as grand fir (Abies grandis) and Douglas-fir,
are considerably less fire tolerant, especially in the sapling and pole
size classes. Ponderosa pine, therefore, was able to maintain its position
as a dominant seral species on large areas of middle-elevation forests in
the West. Because of successful fire control during the past 50 years,
many of these stands have developed understories of Douglas-fir and true
firs. Type conversion has been accelerated by harvest of the ponderosa
pine, leaving residual stands composed of true fir, Douglas-fir or
lodgepole pine (Pinus contorta var. latifolia) (15,20). In
the Pacific Northwest, forest cover types on about 2 million ha (5 million
acres) are believed to have changed in the last 25 years (3).
Ponderosa pine is an integral component of three forest cover types in
the West: Interior Ponderosa Pine (Society of American Foresters Type
237), Pacific Ponderosa Pine-Douglas-Fir (Type 244), and Pacific Ponderosa
Pine (Type 245) (18). Interior Ponderosa Pine is the most widespread type,
covering most of the range of the species from Canada to Mexico, and from
the Plains States to the Sierra Nevada, and the east side of the Cascade
Mountains. Ponderosa pine is also a component of 65 percent of all western
forest cover types south of the boreal forest.
Major associated tree species are as follows:
Northwest. Rocky Mountain Douglas-fir (Pseudotsuga menziesii
var. glauca), lodgepole pine, grand fir, and western larch
(Larix occidentalis).
California. California white fir (Abies concolor var.
lowiana), incense-cedar, Jeffrey pine (Pinus jeffreyi), sugar
pine, coast Douglas-fir (Pseudotsuga menziesii var. menziesii),
California black oak (Quercus kelloggii), and western juniper
(Juniperus occidentalis).
Rocky Mountains and Utah. Rocky Mountain Douglas-fir, blue
spruce (Picea pungens), lodgepole pine, limber pine (Pinus
flexilis), and quaking aspen (Populus tremuloides).
Black Hills. Quaking aspen, white spruce (Picea glauca),
and paper birch (Betula papyrifera).
Arizona and New Mexico. White fir (Abies concolor var.
concolor), Rocky Mountain Douglas-fir, blue spruce, quaking aspen,
Gambel oak (Quercus gambelli), and southwestern white pine (Pinus
strobiformis) at higher elevations; Rocky Mountain juniper (Juniperus
scopulorum), alligator juniper (J. deppeana), and Utah juniper
(J. osteosperma) at lower elevations.
Genera of understory vegetation frequently found in ponderosa pine
forests are as follows:
Shrubs. Arctostaphylos, Ceanothus, Purshia, Artemisia, Quercus,
Rosa, Prunus, Spiraea, Symphoricarpos, Physocarpus, and Berberis.
Grasses. Agropyron, Andropogon, Bouteloua, Festuca, Muhlenbergia,
and Poa.
Community composition varies widely with geographic location, soils,
elevation, aspect, and successional status. Specific information is
available in descriptions of various habitat and community type
classifications (1,20,23,27,35,47,61,63).
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Climate
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Throughout the range of ponderosa pine, soil moisture is the variable
most often limiting growth, especially in summer when rainfall is
deficient. For the east slope of the Rockies, the Black Hills, Utah, and
the Southwest, however, summer rains occur, although the Southwest
regularly experiences scanty May-June precipitation. In eastern Oregon and
Washington, average annual precipitation ranges from 355 to 760 mm (14 to
30 in), much of it snow (30). July, August, and September are dry; average
rainfall is less than 25 mm (1 in). In Montana, east of the Continental
Divide, average annual precipitation in ponderosa pine forests ranges from
280 to 430 mm (11 to 17 in), with 125 to 250 mm (5 to 10 in) received
during the May-to-August period (1). In the Black Hills of South Dakota,
average annual precipitation is 410 to 710 mm (16 to 28 in), with up to
330 mm (13 in) received from May to August (67). In northern Arizona, 150
mm. (6 in) of the total growing season precipitation of 205 mm (8 in)
occurs in July and August, after the May-June dry period. The west slope
of the northern Sierra Nevada in California, where annual rainfall reaches
1750 mm (69 in), may be the wettest area supporting ponderosa pine in any
quantity (13).
The extent of the seasonal rainfall deficiency is evident from the July
and August precipitation, usually about 25 mm (1 in) or less; in some
places, as in California, July and August precipitation is often lacking.
Except on coarse-textured soils, summer showers probably provide scant
moisture useful to young seedlings. Total growing season precipitation may
mean little because of the distribution pattern (13).
Regardless of the location where ponderosa pine grows, average annual
temperatures are between 5° and 10° C (41° and 50° F),
and average July-August temperatures are between 17° and 21° C
(62° and 70° F). Average frost-free seasons for ponderosa pine
range from 90 to 154 days in eastern Montana and South Dakota (1,63) to
more than 200 days in central California. Annual extremes are from -40°
to 43° C (-40° to 110° F).
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Damaging Agents
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Rabbits and hares injure or kill many
seedlings, and pocket gophers are especially destructive. In areas where
pocket gopher populations are high all seedlings and many saplings may be
destroyed. Squirrels and porcupines attack sapling and pole-size trees
and, although rarely killing them, deform the stems on which they feed.
Repeated browsing by deer has stunted seedlings for 50 years or more
(13,55). In the absence of regulation, sheep and cattle have damaged
reproduction by trampling, bedding, and occasional browsing (13).
At least 108 species of insects attack P. ponderosa var. ponderosa,
and 59 species attack P. ponderosa var. scopulorum (13).
The most damaging of the tree-killing insects are several species of Dendroctonus.
Trees die from the combined effects of a blue stain fungus transmitted
by the beetle and extensive larval consumption of the phloem. The western
pine beetle (D. brevicomis) is a common cause of mortality in
overmature, decadent trees within the range of ponderosa pine from Baja
California, north into Oregon, Washington, western Canada, Idaho, and
western Montana. During epidemics, however, apparently healthy, vigorous
trees are also killed. During the drought years of the 1930's, losses from
western pine beetle in the Pacific Northwest were so heavy that many
foresters feared for the pine stands' continued existence. The mountain
pine beetle (D. ponderosae) is the most destructive and aggressive
enemy in the central and southern Rocky Mountains. During the 1894-1908
outbreak in the Black Hills of South Dakota, this insect killed between
5.7 and 11 million m³ (1 and 2 billion/fbm) of ponderosa pine (13).
Tree killing by D. ponderosae has increased with the conversion of
old-growth to young-growth stands in the Pacific Northwest. High stand
density is believed to reduce vigor of some of the larger trees in a stand
and, therefore, is an underlying factor in the occurrence of bark beetle
outbreaks. D. adjunctus, D. approximatus, and D. valens are
other species of the genus that often kill ponderosa pines.
Among bark beetles, Ips species are second in destructiveness
only to Dendroctonus (21). Ips are present naturally in all
stands, where they usually breed in slash. In abundant slash from forestry
activities, Ips can kill vigorous ponderosa pine up to 66 cm (26
in) in d.b.h. when populations reach explosive levels. Eleven species of
Ips have been found attacking ponderosa pine. Of these, I.
latidens, I. emarginatus, I. pini, I. lecontei, and I.
paraconfusus have the most impact.
Several insects mine buds and shoots, primarily of young trees. Although
seldom killed, trees are retarded in growth when infestations are severe.
Pine tip moths (Rhyacionia spp.) and the gouty pitch midge
(Cecidomyia piniinopis) kill the buds and shoots they mine. A more
insidious pest, until recently overlooked and overrated, is the western
pineshoot borer (Eucosma sonomana) (21). Larvae of this species
bore within the pith of the terminal shoot, stunting but seldom killing
them. Shoots that are potentially more robust are more likely to be
infested than are weaker shoots. Accordingly, direct comparisons of
infested vs. uninfested shoot lengths will underestimate actual growth
loss. Each terminal shoot infested by a larva that developed to maturity
was reduced in length that year by more than 25 percent in one study (59).
The pine reproduction weevil (Cylindrocopturus eatoni), a native
of California and, presumably, Oregon, can be a threat to slow-growing
plantations. Its impact has declined, however, with the improvement in
planting stock and control of competing vegetation.
Defoliating insects, such as the pine butterfly (Neophasia menapia)
and the pandora moth (Coloradia pandora), periodically cause
damage over extensive areas. The pine needle sheathminer (Zelleria
haimbachi) can be locally severe in young stands.
Dwarf mistletoe (Arceuthobium vaginatum ssp. vaginatum in
the Southwest, and A. campylopodium in California and the
Northwest) is ponderosa pine's most widespread disease, absent only in the
Black Hills (25). It seems to be particularly devastating in the
Southwest, where it infects trees on about one-third of the commercial
acreage. At Fort Valley Experimental Forest in northern Arizona, dwarf
mistletoe has caused up to 36 percent of the mortality (55). On trees not
killed, the parasite is responsible for a significant loss in growth,
primarily in height, and is reported to reduce seed viability as much as
20 percent. In the Northwest, A. campylopodium has little effect
on vigorous, young trees because height growth will usually exceed its
upward spread, relegating the parasite to the lower crown (5).
Several diseases attack ponderosa pine roots. Black stain root disease
[Leptographium (syn. Verticicladiella) wageneri] causes a
diffuse dark staining of the root wood and kills roots (6). Heterobasidion
annosum causes an insidious lethal root disease that is spread by
airborne spores to the surfaces of freshly-cut stumps. It and L.
wageneri kill trees of all ages and usually result in group mortality
that is sometimes mistaken for the work of bark beetles, which are
frequently secondary invaders. Armillaria sp., previously
considered weak root and butt decayers, are causing increased mortality in
young plantations and thinned stands where the disease can build up in
dead root systems (3). Active infection centers of L. wageneri and
H. annosum spread about 1 m (3 ft) per year. The rate is usually
less for Armillaria sp.
The most damaging heart rot in the southern Rocky Mountains and the
Black Hills is western red rot caused by Dichomitus squalens (25).
It is a major cause of loss of sound wood in commercial stands. Because
ponderosa pines older than 100 years have substantially greater defect,
shorter rotation ages should eliminate much of the heart rot. Phellinus
pini is the major heart rot in the Pacific Coast States.
A needle cast, Elytroderma deformans, found throughout ponderosa
pine's wide range, is the most serious foliage disease (6). It is unique
among the needle casts in being perennial and in its capacity to infect
the host twigs, which enables it to maintain its populations even under
adverse environmental conditions. Although less destructive than the
alarming appearance of affected trees suggests, it can slow growth and
kill trees of sawtimber size. Bark beetles are prompt to attack infected
trees. Severe damage from E. deformans was reported on the Ochoco
National Forest in Oregon, where 555,900 m³ (98,148,000 fbm) of dying
and dead trees were removed from 1946 to 1950 (13).
Several rusts of the Cronartium coleosporioides complex are
damaging to ponderosa pine. Locally, especially in the Southwest, limb
rust (Peridermium filamentosum) attacks middle or upper crowns of
mature trees, killing branches in both directions as it spreads (46). The
western gall rust (Endocronartium harknessii) attacks ponderosa
pine from the Black Hills to the Pacific Northwest (25). It infects all
ages, resulting in round and pear-shaped galls, distortions, and trunk
lesions. Young trees may be killed. Comandra blister rust (Cronartium
comandrae) is found in all states west of the Rocky Mountains but is
most common in California, Idaho, Montana, Utah, and Wyoming. It causes
scattered mortality in well-stocked sapling and small pole stands. In
thinned stands, however, the disease may cause substantial damage (3).
Air pollution is an increasing and vexing source of foliar damage to
ponderosa pine. Ozone is the major plant-damaging constituent of
photochemical oxidant air pollution. Ozone becomes concentrated enough to
cause damage near the border of air basins and in the predominant summer
downwind direction from heavily populated areas. Because ponderosa pine,
especially var. ponderosa, is susceptible, and because it grows
near areas heavily polluted, ozone damage can be great. Typical injury is
a chlorotic mottling accompanied by premature abscission of old needles
(6). Moderately or severely injured trees are attacked more frequently by
bark beetles and Heterobasidion annosum root disease (28).
Basal fire scars are common on the thick-barked stems in old-growth
ponderosa pine forests. Uncontrolled fire was common before European
colonization. These surface fires consumed branches, fallen trees,
understory vegetation, and some living trees. The fires burned from 1 to
47 years apart, with most at 5- to 20-year intervals (3). Low-intensity
fires kept many pine forests open and parklike. They also helped to
maintain ponderosa pine in areas where more tolerant climax species would
have attained dominance, because saplings or larger-sized ponderosa pine
are more fire resistant than many of the true firs and Douglas-fir.
Survival and growth of ponderosa pine usually are affected little if 50
percent or less of the crown is scorched in a fire. Six years after a fire
in Arizona, however, no poles and only 5 percent of the sawtimber-size
trees were living if more than 60 percent of the crown had been destroyed
(13). Low tree vigor and cambium damage increase the likelihood of
mortality. Vigorous young trees have survived, on occasion, when 100
percent of their crowns were scorched. Because buds are protected by thin
long scales, late season fires cause less mortality. Continued
accumulation of food reserves after diameter growth ceases in late summer
also increases the ability of the tree to withstand fire injury. When
crowns are scorched, young, fast-growing trees on good sites have the best
chance of survival and old, slow-growing trees on poor sites the poorest
chance.
Snow often injures saplings and larger trees. Stem bending and breaking
from unusually wet snowfalls that overload tree crowns can seriously
damage dense pole-size stands (49). Stem deformation by snow pressure and
movement on mountain slopes is a threat to sapling stands (38), especially
where ponderosa pine is planted above its optimum elevational limit.
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Flowering and Fruiting
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Ponderosa pine is monoecious. At
pollination the male strobili, borne in short, dense clusters, are 2 to 3
cm (0.8 to 1.2 in) long and female conelets are 2.5 cm (1 in) long. In
western Montana, central Idaho, and eastern Oregon, at elevations from 910
to 1830 m (3,000 to 6,000 ft), flowering generally begins between May 1
and 10. Pollen is shed May 25 to June 15, cones reach a full size of 8 to
15 cm (3 to 6 in) July 20 to August 10 of the next year, seed is ripe
August 20 to September 5, cones begin to open September 1 to 13, and seed
is shed until November. On the east and west sides of the Sierra Nevada in
California, at an elevation of 1830 m (6,000 ft), however, cones develop
about 2 weeks later (13). In northern Arizona, near Flagstaff, pollen is
shed between June 10 and 20 (55), but at an elevation of 910 m (3,000 ft)
on the west slope of California's Sierra Nevada, pollen has been collected
as early as April 15; May 11 was average for a 7-year period. Also on the
west slope of the Sierra Nevada, pollen is shed an average of 8 days later
for each 300 m (1,000 ft) rise in elevation (13).
In Colorado, at 2710-m (8,900-ft) elevation, during a 9-year period,
female conelets emerged on or about June 18 and only about 36 percent of
them survived until the beginning of the second year. Flowering is
correlated closely with the passing of freezing weather (13).
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Genetics
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Population Differences
Ponderosa pine shows distinct geographic variations over its widespread
range. Within and between var. ponderosa and var. scopulorum,
provenance studies (51,65,66) have shown genetic variation in growth,
stem form, needle length, survival, initiation of leader growth, seasonal
pattern of root growth potential, ability to germinate under moisture
stress (41), biotic and abiotic damage (17,26,52), monoterpene production
(58), nutrient status (29,68), and isozymes (10). This wealth of
information on genetic diversity was summarized and interpreted recently
(10). It suggests that var. ponderosa consists of three major
geographic races and var. scopulorum of two major geographic
races. Within var. ponderosa, the Pacific race is found in
California northward from the Transverse Ranges and west of the Sierra
Nevada and Cascade Range into northern Oregon. Pacific race pines have
relatively large needles, cones, and seeds, and are rapid growing and
least cold hardy in tests to date. The North Plateau race extends
northward along the eastside of the Sierra Nevada and Cascade Range and
east to the Continental Divide in Montana. Like the Pacific race, it has
open, plume-like foliage, 3-needle fascicles and isozyme characteristics.
But the North Plateau race has needles with thickened layers of hypoderm
and sunken stomata, and is indistinguishable from the Rocky Mountain race
in monoterpene characteristics. Least well understood, but distinct in
monoterpene production, is the Southern California race.
Within var. scopulorum, the Rocky Mountain race comprises the
northeast portion of the species' range. It is characterized by compact
foliage, 2-needle fascicles, and better growth in trials east of its
natural range. The Rocky Mountain race joins the Southwestern race along a
broad, ill-defined front through southern Colorado, Utah, and Nevada. The
Southwestern race has relatively open foliage, low proportions of 2-needle
fascicles, and resins with distinctive monoterpene composition.
Results from a provenance study of 45-year-old trees in northern Idaho
and a study of 30-year-old trees in Oregon and Washington (60) showed that
36 percent of the variation in the height of the trees was associated with
seed source. A clinal variation was evident in the increase of height from
sources in an east-to-west direction. This variation was related to
September-through-June precipitation. Clinal variation in a latitudinal
and altitudinal direction was related to April-May temperatures. Incidence
of animal damage and of frost injury was related, also, to seed source.
Ponderosa pine varies markedly in its resistance to cold. In a test of
298 individual tree progenies planted in Michigan, all 2-year-old
seedlings of California origin suffered severe injury from cold (66).
Progenies from British Columbia, Washington, eastern Oregon, Arizona, and
southern New Mexico suffered light damage. No damage was reported for
progenies from the remainder of the species' range. Essentially the same
pattern was found in the northern Idaho study in 10- to 15-year-old trees
(65).
Elevational. variation has been studied intensively in central Idaho
(53) and in California (9). On the west slope of the Sierra Nevada in
California, seeds collected from trees growing at elevations of 40 to 2130
m (125 to 7,000 ft) were planted at altitudes of 290, 830, and 1720 m
(950, 2,730, and 5,650 ft) above sea level. The general trend was that
early growth was most rapid for mid-elevation sources and least rapid for
high-elevation sources, regardless of the elevation of the plantation. But
by 29 years, at the high-elevation plantation, sources from high
elevations had overtaken sources from low elevations and had nearly caught
up to sources from middle elevations. Middle and low elevation sources,
especially the latter, suffered stem and leader damage from snow and wind,
which significantly reduced their growth superiority. Wood specific
gravity decreased with increasing elevation of parent source regardless of
where the source was planted (16). No elevational effect was discerned in
tracheid length, although individual differences were found. Differences
were recognized, also, in total height and diameter, and in the seasonal
growth pattern (42) for families within elevational zones. Genetic
diversity among populations, both in California and central Idaho, was
readily interpretable as adaptive variation. Results of both studies
suggest that for selective breeding of a wide-ranging species with
distinct elevational differentiation, such as ponderosa pine, superior
progenies can be obtained from selection within the optimum elevational
zone of best geographic sources. In central Idaho, the recommended
elevational zone is ± 180 m (600 ft).
Hybrids
Natural crosses of ponderosa pine with Jeffrey pine have been observed
in California where their ranges overlap, but they are rare. Where the two
species grow in the same stand, different flowering times and other
reproductive barriers restrict crossing (11). Ponderosa pine crosses with
Pinus montezumae and P. arizonica, and rarely with P.
engelmannii (45). Introgressive hybridization has been observed with
P. washoensis.
In addition to the natural hybrids, artificial crosses have been
obtained with a number of other hard pine species, including P.
durangensis.
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Growth and Yield
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Ponderosa pine grows to impressive size. Stems
263 cm (103.5 in) in d.b.h. and 70.7 m (232 ft) in height have been
recorded (13). Diameters at breast height of 76 to 127 cm (30 to 50 in)
and heights of 27.4 to 39.6 m (90 to 130 ft) are common throughout most of
its range. Trees often reach ages of 300 to 600 years.
Diameter growth can be rapid and remain fairly constant for long periods
provided trees are given adequate growing space. In California, on
productive sites, free-growing trees can reach 66 cm (26 in) in d.b.h. in
30 years or 22 cm. (8.7 in) per decade (data on file at Pacific Southwest
Forest and Range Experiment Station, Redding, CA). In central Oregon,
where sites are less productive, trees 13 to 51 cm (5 to 20 in) in d.b.h.
and from 19 to 36 years old can grow 12 cm (4.9 in) in d.b.h. per decade
if free of intertree competition (3). Trees in a virgin stand in Arizona
grew 29 mm (1.14 in) on the average during a 10-year period, but trees in
a cutover stand grew 43 mm (1.68 in) (55).
Vegetative competition can restrict diameter growth markedly whether it
be from neighboring trees or understory shrubs. In the central Oregon
study, trees completely surrounded by understory shrubs grew only 9 cm
(3.5 in) per decade. Those trees with no competitive ground cover averaged
12 cm (4.7 in) of growth per decade. In California on a droughty, skeletal
soil, severe shrub competition reduced diameter growth to less than half
that of competition-free trees. Insect damage, which was greater on the
trees competing with shrubs, accounted for some of the growth depression
(44). Stagnation in diameter, and often in height, represents a serious
problem in densely stocked stands throughout the species' range, but
especially on poor sites.
Height growth is most rapid in the pole and young sawtimber size classes
to about 60 years. In the Pacific Northwest, dominant trees in stands of
moderate density grow from 0.24 to 0.46 m (0.8 to 1.5 ft) annually between
the ages of 20 to 60 years on timber-producing sites (2). Rate of growth
declines gradually at older ages. Arizona trees of 160 years or older
(determined at breast height) grow little in height (55). Height growth
increases with site productivity and is more sensitive to stand density
than was once believed.
Representative yields of ponderosa pine from a normal yield table for
sites of various productivities are given in table 1 (39). For extensive
natural stands, table values should be reduced by 25 percent or more
because of roads, rock outcrops, steep slopes, openings, and other
unproductive areas.
Table 1- Total volume inside bark of ponderosa pine 1.5
cm (0.6 in) and larger in d.b.h. (39)
Site index at base age
100 years¹
Age
18 m or 60 ft
27 m or 90 ft
37 m or 120 ft
46 m or 150 ft
yr
m³/ha
20
28
94
168
262
40
122
238
396
588
60
192
340
570
861
80
238
413
696
1060
100
273
472
794
1204
120
308
518
868
-
140
336
556
928
-
yr
ft³/acre
20
400
1,350
2,400
3,750
40
1,750
3,400
5,650
8,400
60
2,750
4,850
8,150
12,300
80
3,400
5,900
9,950
15,150
100
3,900
6,750
11,350
17,200
120
4,400
7,400
12,400
-
140
4,800
7,950
13,250
-
¹Height of
dominant and codominant trees of average d.b.h.
Old-growth ponderosa pine produces clear, high-grade lumber, but young
trees typically are limby. Natural pruning develops slowly. An average
clear length of only 3.5 m (11.5 ft) was recorded in 250-year-old stands
in central Idaho (13).
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Reaction to Competition
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In the Sierra Nevada mixed conifer type
in California, growth of advance regeneration of ponderosa pine was
compared to that of associates beneath various overstory stand densities
(data on file at Pacific Southwest Forest and Range Experiment Station,
Redding, CA). Even beneath a light overstory stand casting 47 percent
shade, ponderosa pine saplings grew only about half as rapidly as their
associates (Douglas-fir, sugar pine, white fir, and incense-cedar) and
about half of that expected for fully lighted pines. Relative to
associates elsewhere within its range, ponderosa pine is more shade
tolerant than western larch but less tolerant than grand fir and western
white pine (40). Overall, it is most accurately classed as intolerant of
shade.
Because of ponderosa pine's intolerance of shade, it tends to grow in
even-aged stands and is usually managed by that method. Uneven-aged stands
might appear common throughout the drier portion of its range but are in
reality a mosaic of even-aged groups. Ponderosa pines lose vigor in dense
stands. On drier sites in the Pacific Northwest, trees in pole-size stands
with basal area stand densities above 34.4 m²/ha (150 ft²/acre)
become subject to attack by bark beetles (54).
Ponderosa pine remains physiologically young and responds to release up
to age 200 in Arizona. Elsewhere, stagnated sapling stands 70 to 100 years
old usually respond to thinning and seem to grow as rapidly as unstagnated
trees, when crowns grow to sufficient size to take advantage of the
additional growing space (3,7).
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Rooting Habit
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The ability of ponderosa pine seedlings to grow
vigorous taproots is one reason for their tenacity on severe sites where
associated species often fail. Within a few months of germination, roots
can penetrate to depths of 50 cm (20 in) or more in loosened and watered
soil (32). This rapid root growth is essential to ponderosa pine's
apparent adaptation to the climate of the Southwest. There, seeds do not
germinate until the soil is continuously warm and moist. These conditions
are not present until summer rains begin, usually in July. Root growth was
uninhibited by grass as long as moisture was abundant (34). Taproots
penetrate to about half that depth or less under average conditions in the
field. Annually, for the next 2 years, lateral roots may double or triple
in length.
Mature ponderosa pines put down a root to depths of more than 2 m (6 ft)
in porous soils, but seldom more than 1 m (3 ft) in heavy clay soils.
Exceptions occur in soils underlain by rock with deep fissures, where
roots have been observed along cut banks at depths of 11 to 12 m (35 to 40
ft). In open stands, lateral roots may extend 46 m (150 ft). In dense
stands, however, they are limited more to the crown width. The main mass
of roots is concentrated within the top 60 cm (24 in) of the soil mantle.
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Seed Production and Dissemination
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No regular periodicity has
been observed in the seed production of ponderosa pine over its entire
range. In California, west of the Sierra Nevada, medium seed crops are
borne on an average of every 2 to 3 years. The average interval between
heavy cone crops is 8 years. Good cone crops are produced every 3 years in
the Black Hills (7), every 3 to 4 years in the Southwest (55), and every 4
to 5 years in the Pacific Northwest (3). Observations over 23 years in
Montana show ponderosa pine to be a poor seeder west, and a fair seeder
east, of the Continental Divide, with only one good crop. The species
bears cones as early as 7 years and continues to produce good seeds to at
least 350 years. Seeds from trees aged 60 to 160, however, are more viable
than those of younger or older trees. In California, trees more than 64 cm
(25 in) in d.b.h. were the best producers. In central Idaho, mature and
overmature trees growing at an elevation of 1680 m (5,500 ft) produced
lower quality seeds than similar trees at 1220 m (4,000 ft), and open
grown trees produced heavier crops of larger cones than stand grown trees
(13).
In eastern Washington, Idaho, and western Montana, 16 species of insects
have been identified as causing seed losses of ponderosa pine (14). They
destroyed up to 95 percent of the cone crop, but most areas sampled
suffered losses ranging from 30 to 60 percent. In central Arizona,
abortion, ponderosa pine cone beetles (Conophthorus ponderosae), and
ponderosa pine coneworms (Dioryctria sp.) were the three
most important causes of cone mortality (57). Usually the proportion of
seeds lost to insects is highest when crops are small.
Ponderosa pine seeds are consumed by a great many birds and small
mammals such as mice, chipmunks, and tree squirrels. In years of low cone
production, the potential seed crop may be severely reduced. Squirrels
clip many of the cone bearing twigs, destroying flowers and conelets (13).
Specific gravity of cones containing ripe seed can be predicted. Cone
collectors should consult local authorities before picking, however,
because specific gravity of ripe cones varies from 0.80 in Arizona to 1.00
in the Black Hills.
The number of seeds per cone varies greatly among regions and ranges
from only 31 seeds in northern Arizona (55) to 70 in central California
(13). Weight of cleaned seeds varies from 15,200 to 50,700/kg (6,900 to
23,000/lb) and averages 26,500/kg (12,000/lb) (31).
Ponderosa pine seeds are not disseminated naturally over extensive
distances. In central Oregon, seedfall at 37 m (120 ft) was only 22
percent of the seedfall at the west edge of a cleared area, and at 120 m
(396 ft) it was only 8 percent (3). Nearly all seeds are disseminated by
early November. In a good seed year as many as 852,050 seeds per hectare
(345,080/acre) may reach the ground (19).
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Seedling Development
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Throughout ponderosa pine's range, except
in the Black Hills and the west side of the Sierra Nevada, natural
regeneration is sporadic. Successful natural regeneration is thought to be
the result of the chance combination of a heavy seed crop and favorable
weather during the next growing season. Soil texture, plant competition,
and seedbed conditions are other common determinants of survival of young
seedlings (13).
Germination of ponderosa pine is epigeal (31). Moisture stress reduces
seed germination as well as initial seedling survival and growth. In an
Arizona study, seed germination, root penetration, root dry weight, and
cotyledon length decreased as the stress increased beyond 0.7 MPa (7 bars)
(55). Older seedlings, however, are able to cope with limited moisture
supplies by reducing transpiration and by vigorously extending their root
systems. Transpiration rate declines at soil water potentials of -0.1 to
-0.2 MPa (-1 to -2 bars). At -1.0 MPa (-10 bars) the transpiration rate is
only 12 percent of maximum (37). Ponderosa pine has the capacity for root
growth in relatively dry soil. Nursery stock lifted in January in
California had appreciable root elongation even when planted in soil with
a water potential of less than -0.9 MPa (-9 bars) (62) and has survived,
at least for short periods, water potentials of less than -8.0 MPa (-80
bars) in the Southwest (24).
The significance of competing vegetation as a deterrent to early
survival and development of young seedlings has been clearly demonstrated.
In central Idaho, soil moisture remained above the wilting point at depths
below 15 cm (6 in) on areas free of competing vegetation throughout the
growing season but dropped to or below that critical point on most
vegetated plots (13). In loamy soils in the White Mountains in Arizona,
drought is normally not a major variable in seedling survival beyond age
2, except where there is grass cover (30). Shrub competition reduced the
height and diameter growth of ponderosa pine planted in northern
California (43); similar growth reductions have been reported for stands
in Oregon (4).
Air and soil temperatures often affect growth. Seedlings grown from seed
collected in Arizona, California, and South Dakota had the best root
growth in 15° C (59° F) air temperature and 23° C (73°
F) soil temperature. Height growth was greatest at 23° C (73° F)
temperature for air and soil (33).
On the western slopes of the Sierra Nevada, height growth of ponderosa
pine started significantly later with each increase of 610 m (2,000 ft) in
elevation, and the length of the growing season was significantly shorter
with a 910 m (3,000 ft) increase in elevation. Rates of height and radial
growth did not vary with elevation during the period of growth. At an
elevation of 1520 m (5,000 ft), a 6-year average showed that ponderosa
pine started radial growth on March 23 and height growth on April 26. The
period of radial growth lasted 177 days; that of height growth, 97 days.
Ponderosa pine started height growth before sugar pine, incense-cedar, and
white fir, but not before lodgepole pine (13).
Many variables cause seedling mortality. Ponderosa pine seedlings less
than 36 days old were more susceptible to minimum night temperatures
(lower than -5° C (23° F)) than were lodgepole pine seedlings.
But by 2 months of age, differences in tolerance did not exist (8). During
winters with little snow cover, 1- and 2-year-old seedlings suffered
damage and killing from frost. In the Southwest, natural regeneration on
fine-textured soils is almost non-existent because of frost-heaving (24).
Damage is lessened by heavy cover and early summer germination of seeds,
which gives a longer establishment period. Ordinarily, older seedlings are
hardy in severe winter temperatures, but occasionally they suffer "winter
killing" of foliage (a desiccation process) if the temperature drops
suddenly when drying winds and frozen ground are present. Also, 1- to
3-month-old seedlings are killed by stem temperatures of about 54° C
(130° F) and higher. Ponderosa pine is more successful in resisting
high soil surface temperature with increasing age; 110-day-old seedlings
can successfully withstand instantaneous temperatures of 58° to 82°
C (136° to 180° F) (13). Also, it can withstand higher
temperatures than its associates in the Northwest-Douglas-fir, grand fir,
and Engelmann spruce (Picea engelmannii) (56).
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Soils and Topography
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Ponderosa pine grows on soils derived from igneous, metamorphic, and
sedimentary parent materials, including quartzite, argillite, schist,
shale, basalt, andesite, granite, cinders, pumice, limestone, and
sandstone. This results in a variety of soil orders including Entisols,
Inceptisols, Mollisols, Alfisols, and Ultisols on which the species is
found throughout its extensive range.
Its distribution on drier sites is related closely to supplies of
available soil moisture which, in turn, are related to soil textures and
depth (13,20,22). In Wyoming, for instance, at the lower limits of
coniferous forest, ponderosa pine is found only on coarse-textured soils
of sandstone origin where the limited moisture is more readily available
than on fine-textured soils of limestone origin (27). In Oregon and
Washington, higher survival and growth rates of ponderosa pine have been
reported for coarse-textured sandy soils than for fine-textured clayey
soils (20).
Ponderosa pine stands, 51, 75, and 78 years old, growing in coarse-,
medium-, and fine-textured soils in Montana, had their greatest root
development in the medium-textured soils and the least in the
fine-textured soils. Root concentration was more uniform in the
medium-textured soils and concentration dropped off abruptly below a soil
depth of 46 cm (18 in) in the fine-textured soils (13).
Depending on the locality and the horizon of the samples, soils vary
from pH 4.9 to pH 9.1. The pH in the surface horizon frequently is from
6.0 to 7.0 (13).
Foliar concentrations of nitrogen and phosphorus needed for adequate
growth are low in ponderosa pine compared with the associated conifers in
California-Douglas-fir (Pseudotsuga menziesii), white fir (Abies
concolor), sugar pine (Pinus lambertiana), and incense-cedar
(Libocedrus decurrens). Foliar concentrations of 0.9 percent for
nitrogen and 0.08 percent for phosphorus mark critical boundaries between
nutrient deficiency and sufficiency (42). Correcting nitrogen deficiency
in California and central Oregon stands has increased volume growth 30
percent (50). Because critical levels of foliar nitrogen and phosphorus
are lower in ponderosa pine, while early biomass gains generally are
greater, this species is judged superior in satisfying its nutritional
needs on soils that by other species' standards are infertile.
Ponderosa pine is found at elevations from sea level to 3050 m (10,000
ft). From north to south the species grows at progressively higher
altitudes and within more restricted elevational limits (1, 13,20,67). In
Washington, the elevations for ponderosa pine are sea level to 1220 m
(4,000 ft); in the Blue Mountains of northeastern Oregon, 910 to 1520 m
(3,000 to 5,000 ft); in the south-central Oregon pumice area, 1460 to 2010
m (4,800 to 6,600 ft); in the northern Rocky Mountains, from 300 to 1830 m
(1,000 to 6,000 ft); in the middle Rockies up to 2590 m (8,500 ft); and in
the southern Rockies, up to 3050 m (10,000 ft). In California, ponderosa
pine is usually found at elevations from 150 to 1070 m (500 to 3,500 ft)
in the north, and from 1610 to 2230 m (5,300 to 7,300 ft) in the south.
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Special Uses
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In ponderosa pine forests, timber production, livestock grazing, and
recreation are the principal land uses. Ponderosa pine forests are found
at low elevations offering year-round recreation, and they frequently
border forest highways where esthetic values are high. They provide
habitats for various wildlife species. Abert's and Kaibab squirrels
usually live in the ponderosa pine forests (55). Snags in the mature pine
forest provide a large number of species with nesting and roosting sites.
Big game, such as deer and elk, also use the pine forests for food and
shelter.
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Vegetative Reproduction
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Ponderosa pine does not reproduce
naturally by vegetative methods. It can be propagated by rooting and
grafting, but success decreases rapidly when scions are taken from trees
older than 5 years (64).
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Brief Summary
provided by Silvics of North America
Pinaceae -- Pine family
William W. Oliver and Russell A. Ryker
Ponderosa pine (Pinus ponderosa), also called western yellow
pine, is one of the most widely distributed pines in western North
America. A major source of timber, ponderosa pine forests are also
important as wildlife habitat, for recreational use, and for esthetic
values. Within its extensive range, two varieties of the species currently
are recognized: Pinus ponderosa var. ponderosa (Pacific
ponderosa pine) (typical) and var. scopulorum (Rocky Mountain
ponderosa pine) (10). Arizona pine (P. arizonica), sometimes
classified as a variety of ponderosa pine (12,36,51), is presently
recognized as a separate species (45).
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Distribution
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The range of ponderosa pine extends from southern Canada into Mexico,
and from the Plains States of Nebraska and Oklahoma to the Pacific Coast.
Pacific ponderosa pine (var. ponderosa) ranges from latitude 52°
N. in the Fraser River drainage of southern British Columbia, south
through the mountains of Washington, Oregon, and California, to latitude
33° N. near San Diego. In the northeast part of its range it extends
east of the Continental Divide to longitude 110° W. in Montana, and
south to the Snake River Plain, in Idaho (1,51).
Rocky Mountain ponderosa pine (var. scopulorum) extends east of
the Continental Divide from latitude 48° N. in north-central Montana,
southeasterly into North and South Dakota, eastern Wyoming, and as far
east as north-central Nebraska. Within this area, ponderosa pine grows on
the discontinuous mountains, plateaus, canyons, and breaks of the plains,
with the most extensive stands found in the Black Hills of South Dakota
and Wyoming (51). South of Wyoming, Rocky Mountain ponderosa pine extends
south on both sides of the Continental Divide, west to Arizona, and the
eastern edge of the Great Basin in Nevada, east to Texas west of the Pecos
River, New Mexico, extreme northwestern Oklahoma, Colorado, and northern
Mexico (36). Within this wide range, ponderosa pine is absent from a large
area that includes southwestern Montana, western Wyoming, southern Idaho,
and part of the Great Basin (12,61). A possible explanation for the
absence is that the distribution of rainfall during the summer months
prevents seedling establishment except at higher elevations, where the
species has little tolerance for the shorter growing season (61).
Arizona pine (var. arizonica) is found primarily in the
mountains of extreme southwestern New Mexico, southeastern Arizona, and
northern Mexico (36).
- The native range of ponderosa pine.
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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, Leaves needle-like, Leaves alternate, Needle-like leaf margins finely serrulate (use magnification or slide your finger along the leaf), Leaf apex acute, Leaves > 5 cm long, Leaves < 10 cm long, Leaves > 10 cm long, Leaves yellow-green above, Leaves yellow-green below, Leaves not blue-green, Needle-like leaves somewhat rounded, Needle-like leaves twisted, Needle-like leaf habit erect, Needle-like leaves per fascicle mostly 2, Needle-like leaves per fascicle mostly 3, Needle-like leaf sheath persistent, Twigs glabrous, Twigs viscid, Twigs not viscid, Twigs without peg-like projections or large fascicles after needles fall, Berry-like cones orange, Woody seed cones > 5 cm long, Seed cones bearing a scarlike umbo, Umbo with obvious prickle, Bracts of seed cone included, Seeds brown, Seeds yellow, Seeds winged, Seeds unequally winged, Seed wings prominent, Seed wings equal to or broader than body.
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- Stephen C. Meyers
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Pinus ponderosa
provided by wikipedia EN
Pinus ponderosa, commonly known as the ponderosa pine,[2] bull pine, blackjack pine,[3] western yellow-pine,[4] or filipinus pine[5] is a very large pine tree species of variable habitat native to mountainous regions of western North America. It is the most widely distributed pine species in North America.[6]: 4
Pinus ponderosa grows in various erect forms from British Columbia southward and eastward through 16 western U.S. states and has been successfully introduced in temperate regions of Europe, and in New Zealand. It was first documented in modern science in 1826 in eastern Washington near present-day Spokane (of which it is the official city tree).[7][8] On that occasion, David Douglas misidentified it as Pinus resinosa (red pine). In 1829, Douglas concluded that he had a new pine among his specimens and coined the name Pinus ponderosa[9] for its heavy wood. In 1836, it was formally named and described by Charles Lawson, a Scottish nurseryman.[10] It was adopted as the official state tree of Montana[11] in 1949.[12]
Description
Pinus ponderosa is a large coniferous pine (evergreen) tree. The bark helps to distinguish it from other species. Mature to over-mature individuals have yellow to orange-red bark in broad to very broad plates with black crevices.[13] Younger trees have blackish-brown bark,[13] referred to as "blackjacks" by early loggers. Ponderosa pine's five subspecies, as classified by some botanists, can be identified by their characteristically bright-green needles (contrasting with blue-green needles that distinguish Jeffrey pine). The Pacific subspecies has the longest—7+3⁄4 inches (19.8 centimetres)—and most flexible needles in plume-like fascicles of three. The Columbia ponderosa pine has long—4+3⁄4–8 in (12–20.5 cm)—and relatively flexible needles in fascicles of three. The Rocky Mountains subspecies has shorter—3+1⁄2–5+3⁄4 in (9.2–14.4 cm)—and stout needles growing in scopulate (bushy, tuft-like) fascicles of two or three. The southwestern subspecies has 4+1⁄2–7+3⁄4 in (11.2–19.8 cm), stout needles in fascicles of three (averaging 2+3⁄4–3+1⁄2 in or 68.5–89 millimetres). The central High Plains subspecies is characterized by the fewest needles (1.4 per whorl, on average); stout, upright branches at narrow angles from the trunk; and long green needles—5+3⁄4–7 in (14.8–17.9 cm)—extending farthest along the branch, resembling a fox tail. Needles are widest, stoutest, and fewest (averaging 2+1⁄4–2+3⁄4 in or 56–71 mm) for the species.[14][15][16]
The egg-shaped cones, which are often found in great number under trees, are 3–5 in (8–13 cm) long. They are purple when first chewed off by squirrels, but become more brown and spherical as they dry.[13] Each scale has a sharp point.[13]
Sources differ on the scent of P. ponderosa. Some state that the bark smells of turpentine, which could reflect the dominance of terpenes (alpha- and beta-pinenes, and delta-3-carene).[17] Others state that it has no distinctive scent,[18] while still others state that the bark smells like vanilla if sampled from a furrow of the bark.[19] Sources agree that the Jeffrey pine is more strongly scented than the ponderosa pine.[18][20] When carved into, pitch-filled stumps emit a scent of fresh pitch.[13]
Size
The National Register of Big Trees lists a ponderosa pine that is 235 ft (72 metres) tall and 27 ft (8.2 m) in circumference.[21] In January 2011, a Pacific ponderosa pine in the Rogue River–Siskiyou National Forest in Oregon was measured with a laser to be 268 ft 4 in (81.79 m) high. The measurement was performed by Michael Taylor and Mario Vaden, a professional arborist from Oregon. The tree was climbed on October 13, 2011, by Ascending The Giants (a tree-climbing company in Portland, Oregon) and directly measured with tape-line at 268 ft 3 in (81.77 m) high.[22][23] As of 2015, a Pinus lambertiana specimen was measured at 273 ft 9+1⁄2 in (83.45 m),[24] which surpassed the ponderosa pine previously considered the world's tallest pine tree.[25]
Taxonomy
Modern forestry research has identified five different taxa of P. ponderosa, with differing botanical characters and adaptations to different climatic conditions. Four of these have been termed "geographic races" in forestry literature. Some botanists historically treated some races as distinct species. In modern botanical usage, they best match the rank of subspecies and have been formally published.[14][15]
Subspecies and varieties
-
Pinus ponderosa subsp. brachyptera Engelm. – southwestern ponderosa pine.[26]
- Four corners transition zone including southern Colorado, southern Utah, northern and central New Mexico and Arizona, westernmost Texas, and a single disjunct population in the far northwestern Oklahoma panhandle.[27] The Gila Wilderness contains one of the world's largest and healthiest forests.[28] Hot with bimodal monsoonal rainfall; wet winters and summers contrast with dry springs and falls; mild winters.
-
Pinus ponderosa subsp. critchfieldiana Robert Z. Callaham subsp. novo – Pacific ponderosa pine.
- Western coastal parts of Washington State; Oregon west of the Cascade Range except for the southward-extending Umpqua–Tahoe Transition Zone; California except for both that transition zone and the Transverse-Tehahchapi Mountains Transition zone in southern California and Critchfield's far Southern California Race. Mediterranean hot, dry summers in California; mild wet winters with heavy snow in mountains.
-
Pinus ponderosa var. pacifica J.R. Haller & Vivrette – Pacific ponderosa pine.[29][30]
- 100–2,700 m (330–8,860 ft) on coastal-draining slopes of major mountain ranges in California, and in southwestern Oregon, Washington.[29]
-
Pinus ponderosa subsp. ponderosa Douglas ex C. Lawson – Columbia ponderosa pine, North plateau ponderosa pine.[31]
- Southeast British Columbia, eastern Washington State and Oregon east of the Cascade Range, 1,200–1,900 m (3,900–6,200 ft) in northeastern California, northwestern Nevada, Idaho and west of the Helena, Montana, transition zone. Cool, relatively moist summers; very cold, snowy winters (except in the very hot and very dry summers of central Oregon, most notably near Bend, which also has very cold and generally dry winters).[32][33]
-
Pinus ponderosa subsp. readiana Robert Z. Callaham subsp. novo – central High Plains ponderosa pine.
- Southern South Dakota and adjacent northern Nebraska and far eastern Colorado, but neither the northern and southern High Plains nor the Black Hills, which are in P. p. scopulorum. Hot, dry, very windy summers; continental cold, wet winters.
-
Pinus ponderosa var. scopulorum (Engelm. in S.Watson) E. Murray, Kalmia 12:23, 1982 – Rocky Mountains ponderosa pine.[34]
- East of the Helena, Montana, transition zone, North & South Dakota, but not the central high plains, Wyoming, Nebraska, northern and central Colorado and Utah, and eastern Nevada. Warm, relatively dry summers; very cold, fairly dry winters.
-
Pinus ponderosa var. washoensis (H. Mason & Stockw.) J.R. Haller & Vivrette – Washoe pine.[35]
- Predominantly in northeastern California, and into Nevada and Oregon, at 2,000–3,000 m (6,600–9,800 ft), upper mixed-conifer to lower subalpine habitats.[36][37]
Distributions of the subspecies in the United States are shown in shadow on the map. Distribution of ponderosa pine is from Critchfield and Little.[38] The closely related five-needled Arizona pine (Pinus arizonica) extends southward into Mexico.
Before the distinctions between the North Plateau race and the Pacific race were fully documented, most botanists assumed that ponderosa pines in both areas were the same. When a botanist and a geneticist from California found in 1948 a distinct tree on Mt. Rose in western Nevada with some marked differences from the ponderosa pine they knew in California, they described it as a new species, Washoe pine Pinus washoensis. Subsequent research determined this to be one of the southernmost outliers of the typical North Plateau race of ponderosa pine.[14]: 30–31 [39][40][41] Its current classification is Pinus ponderosa var. washoensis.[35][36][37]
An additional variety, tentatively named P. p. var. willamettensis, found in the Willamette Valley in western Oregon, is rare.[42] This is likely just one of the many islands of Pacific subspecies of ponderosa pine occurring in the Willamette Valley and extending north to the southeast end of Puget Sound in Washington.
Distinguishing subspecies
The subspecies of P. ponderosa can be distinguished by measurements along several dimensions:[14]: 23–24 [15]: 17
Notes
Names of taxa and transition zones are on the map.
Numbers in columns were derived from multiple measurements of samples taken from 10 (infrequently fewer) trees on a varying number of geographically dispersed plots.
Numbers in each cell show calculated mean ± standard error and number of plots.
Distribution
Pinus ponderosa is a dominant tree in the Kuchler plant association, the ponderosa shrub forest. Like most western pines, the ponderosa generally is associated with mountainous topography. However, it is found on banks of the Niobrara River in Nebraska. Scattered stands occur in the Willamette Valley of Oregon and in the Okanagan Valley and Puget Sound areas of Washington. Stands occur throughout low level valleys in British Columbia reaching as far north as the Thompson, Fraser and Columbia watersheds. In its Northern limits, it only grows below 4,300 feet (1,300 m) elevation, but is most common below 2,600 feet (800 m). Ponderosa covers 1 million acres (4,000 km2), or 80%,[44] of the Black Hills of South Dakota. It is found on foothills and mid-height peaks of the northern, central, and southern Rocky Mountains, in the Cascade Range, in the Sierra Nevada, and in the maritime-influenced Coast Range. In Arizona, it predominates on the Mogollon Rim and is scattered on the Mogollon Plateau and on mid-height peaks in Arizona and New Mexico.[45] Arizona pine (P. arizonica), found primarily in the mountains of extreme southwestern New Mexico, southeastern Arizona, and northern Mexico and sometimes classified as a variety of ponderosa pine, is presently recognized as a separate species.[46]
Ecology
The fire cycle for ponderosa pine is 5 to 10 years, in which a natural ignition sparks a low-intensity fire.[47] Low, once-a-decade fires are known to have helped specimens live for half a millennium or more.[13] The tree has thick bark and its buds are protected by needles, allowing even some younger individuals to survive weaker fires.[13] In addition to being adapted to dry, fire-affected areas, the species often appears on the edges of deserts as it is comparatively drought resistant, partly due to the ability to close its leaf pores.[13] It can also draw some of its water from sandy soils.[13] Despite being relatively widespread in the American West, it is intolerant of shade.[13]
Pinus ponderosa needles are the only known food of the caterpillars of the gelechiid moth Chionodes retiniella.[48] Blue stain fungus, Grosmannia clavigera, is introduced in sapwood of P. ponderosa from the galleries of all species in the genus Dendroctonus (mountain pine beetle), which has caused much damage. Western pine and other beetles can be found consuming the bark.[49] The seeds are eaten by squirrels, chipmunks, quail, grouse, and Clark's nutcracker, while mule deer browse the seedlings.[50] American black bears can climb up to 12 feet up a ponderosa.[13]
Pathology
Pinus ponderosa is affected by Armillaria, Phaeolus schweinitzii, Fomes pini, Atropellis canker, dwarf mistletoe, Polyporus anceps, Verticicladiella, Elytroderma needlecast and western gall rust.[49]
As an invasive species
Pinus ponderosa is classed as a "wilding pine", and spreads as an invasive species throughout the high country of New Zealand, where it is beginning to take over, causing the native species of plants not to be able to grow in those locations.[51][52] It is also considered a "weed" in parts of Australia.[53]
Uses
Native Americans consumed the seeds and sweet inner bark. They chewed the dried pitch, which was also used as a salve. They used the limbs and branches as firewood and building material, and the trunks were carved into canoes. The needles and roots were made into baskets. The needles were also boiled into a solution to treat coughs and fevers.[13]
In the 19th and 20th centuries, old-growth trees were widely used by settlers as lumber, including for railroads. Younger trees are of poor quality for lumber due to the tendency to warp.[13]
Cultivation
Cultivated as a bonsai, Ponderosas are prized for their rough, flaky bark, contorted trunks, flexible limbs and dramatic deadwood. Collected specimens can be wildly sculpted by their environment, resulting in beautiful twisted trunks, limbs and deadwood. In the mountains they can be found growing in pockets in the rock, stunting their growth. The main challenge for this species in bonsai cultivation, is the natural long length of its needles, which takes years of training and care to reduce.[54]
Pinus ponderosa as
bonsai. This tree is estimated to be over 40 years old. The long length of the needles is the main challenge when training this species as bonsai.
This species is grown as an ornamental plant in parks and large gardens.[55]
In nuclear testing
During Operation Upshot–Knothole in 1953, a nuclear test was performed in which 145 ponderosa pines were cut down by the United States Forest Service and transported to Area 5 of the Nevada Test Site, where they were planted into the ground and exposed to a nuclear blast to see what the blast wave would do to a forest. The trees were partially burned and blown over.[56]
Culture
Pinus ponderosa is the official state tree of Montana. In a 1908 poll to determine the state tree, Montana schoolchildren chose the tree over the Douglas fir, American larch, and cottonwood. However, the tree was not officially named the state tree until 1949.[57]
See also
References
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^ Farjon, A. (2013). "Pinus ponderosa". IUCN Red List of Threatened Species. 2013: e.T42401A2977432. doi:10.2305/IUCN.UK.2013-1.RLTS.T42401A2977432.en. Retrieved 12 November 2021.
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^ USDA, NRCS (n.d.). "Pinus ponderosa". The PLANTS Database (plants.usda.gov). Greensboro, North Carolina: National Plant Data Team. Retrieved 31 January 2016; with distribution map.
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^ Moore, Gerry; Kershner, Bruce; Tufts, Craig; Mathews, Daniel; Nelson, Gil; Spellenberg, Richard; Thieret, John W.; Purinton, Terry; Block, Andrew (2008). National Wildlife Federation Field Guide to Trees of North America. New York, New York: Sterling. p. 89. ISBN 978-1-4027-3875-3.
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^ BSBI List 2007 (xls). Botanical Society of Britain and Ireland. Archived from the original (xls) on 2015-06-26. Retrieved 2014-10-17.
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^ Marcus, M, P (1969). United States Pines, Local Nomenclatures and Their Origins. Bonanza Books. pp. 420–422.
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^ Safford, H.D. 2013. Natural Range of Variation (NRV) for yellow pine and mixed conifer forests in the bioregional assessment area, including the Sierra Nevada, southern Cascades, and Modoc and Inyo National Forests. Unpublished report. USDA Forest Service, Pacific Southwest Region, Vallejo, CA, [1]
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^ "Ponderosa pine named Spokane's official city tree | The Spokesman-Review". www.spokesman.com. Retrieved 2021-02-04.
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^ Groover, Heidi. "Hey, Spokane, you now have a city tree". Inlander. Retrieved 2021-02-04.
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^ Lauria, F. (1996). "The identity of Pinus ponderosa Douglas ex C. Lawson (Pinaceae)" (PDF). Linzer Biologische Beitraege.
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^ The agriculturist's manual: being a familiar description of agricultural plants cultivated in Europe. Edinburgh U.K.: William Blackwood and Sons. 1836.
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^ Dickson, Tom. "Ponderosa Pine". Montana Outdoors. Montana Fish, Wildlife & Parks. Retrieved February 18, 2015.
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^ "American Profile". March 13, 2021.
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^ a b c d e f g h i j k l m Arno, Stephen F.; Hammerly, Ramona P. (2020) [1977]. Northwest Trees: Identifying & Understanding the Region's Native Trees (field guide ed.). Seattle: Mountaineers Books. pp. 49–57. ISBN 978-1-68051-329-5. OCLC 1141235469.
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^ a b c d Callaham, Robert Z. (September 2013). "Pinus ponderosa: A Taxonomic Review with Five Subspecies in the United States" (PDF). USDA Forest Service. PSW RP-264.
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^ a b c Callaham, Robert Z. (September 2013). "Pinus ponderosa: Geographic Races and Subspecies Based on Morphological Variation" (PDF). USDA Forest Service. PSW RP-265.
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^ Eckenwalder, James (2009). Conifers of the World. Portland, Oregon: Timber Press. ISBN 978-0-88192-974-4.
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^ Smith, Richard H. (1977). Monoterpenes of ponderosa pine in Western United States. USDA Forest Service. Tech. Bull. 1532.
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^ a b Schoenherr, Allan A. (1995). A Natural History of California. University of California Press. p. 111.
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^ Kricher, John C (1998). A field guide to Rocky Mountain and southwest forests. Houghton Mifflin. p. 194.
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^ Kricher, John C. (1998). A field guide to California and Pacific Northwest forests. Houghton Mifflin. p. 107.
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^ "Pacific ponderosa pine". National Register of Big Trees. American Forests.
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^ Earle, Christopher J., ed. (2018). "Pinus ponderosa subsp. benthamiana". The Gymnosperm Database. Retrieved January 9, 2018.
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^ Fattig, Paul (January 23, 2011). "Tallest of the tall". Mail Tribune. Medford, Oregon. Retrieved January 27, 2011.
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^ "Pinus lambertiana". Gymnosperm Database. Retrieved 2021-04-24.
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^ Riggs, Keith. "Oregon Forest Home for World's Tallest Living Pine Tree". US Forest Service. Retrieved 2021-04-24.
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^ USDA, NRCS (n.d.). "Pinus ponderosa subsp. brachyptera". The PLANTS Database (plants.usda.gov). Greensboro, North Carolina: National Plant Data Team; with distribution map.
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^ "Pinus ponderosa, ponderosa pine". Catalog of the Woody Plants of Oklahoma. Oklahoma Biological Survey.
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^ "Arizona Mountains forests". Terrestrial Ecoregions. World Wildlife Fund.
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^ a b Jepson Flora Project (ed.). "Pinus ponderosa var. pacifica". Jepson eFlora. The Jepson Herbarium, University of California, Berkeley. Retrieved January 9, 2018.
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^ "Pinus ponderosa var. pacifica". Calflora. Berkeley, California: The Calflora Database.
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^ "Pinus ponderosa var. ponderosa". Calflora. Berkeley, California: The Calflora Database.
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^ Jepson Flora Project (ed.). "Pinus ponderosa subsp. ponderosa". Jepson eFlora. The Jepson Herbarium, University of California, Berkeley. Retrieved January 9, 2018.
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^ USDA, NRCS (n.d.). "Pinus ponderosa var. ponderosa". The PLANTS Database (plants.usda.gov). Greensboro, North Carolina: National Plant Data Team; with distribution map.
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^ USDA, NRCS (n.d.). "Pinus ponderosa var. scopulorum". The PLANTS Database (plants.usda.gov). Greensboro, North Carolina: National Plant Data Team; with distribution map.
{{cite web}}: CS1 maint: postscript (link) -
^ a b "Pinus ponderosa var. washoensis". Calflora. Berkeley, California: The Calflora Database.
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^ a b Jepson Flora Project (ed.). "Pinus ponderosa var. washoensis". Jepson eFlora. The Jepson Herbarium, University of California, Berkeley. Retrieved January 9, 2018.
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^ a b USDA, NRCS (n.d.). "Pinus ponderosa var. washoensis". The PLANTS Database (plants.usda.gov). Greensboro, North Carolina: National Plant Data Team; with distribution map.
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^ Critchfield, WB; Little, EL (1966). Geographic distribution of the pines of the world. USDA Forest Service. Miscellaneous Publication 991, p. 16 (Map 47).
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^ Haller, JR (1961). "Some recent observations on ponderosa, Jeffrey, and Washoe pines in northeastern California". Madroño. 16: 126–132.
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^ Haller, JR (1965). "Pinus washoensis: taxonomic and evolutionary implications". American Journal of Botany. 52 (6): 646. JSTOR 2440143.
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^ Lauria, F (1997). "The taxonomic status of (Pinus washoensis) H. Mason & Stockw". Annalen des Naturhistorischen Museums in Wien. 99B: 655–671.
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^ Ryan, Catherine (March 19, 2012). "Loggers give unique Oregon ponderosa pine a lifeline". High Country News. Paonia, Colorado. Retrieved March 28, 2012.
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^ Smith, R. H. (1981). "Variation in cone color of immature ponderosa pine (Pinaceae) in northern California and southern Oregon". Madroño 28: 272–275.
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^ Meierhenry, Mark (March 2008). "The Old Growth Pines". South Dakota Magazine.
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^ Perry, JP Jr. (1991). Pines of Mexico and Central America. Portland, Oregon: Timber Press.
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^ Oliver, William W; Ryker, Russell A (1990). "Pinus ponderosa". In Burns, Russell M.; Honkala, Barbara H. (eds.). Conifers. Silvics of North America. Washington, D.C.: United States Forest Service (USFS), United States Department of Agriculture (USDA). Vol. 1. Retrieved 2020-03-12 – via Southern Research Station.
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^ Stecker, Tiffany; ClimateWire (March 22, 2013). "U.S. Starts Massive Forest-Thinning Project". Scientific American. Retrieved April 19, 2014.
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^ Furniss, RL; Carolin, VM (1977). Western Forest Insects. US Department of Agriculture Forest Service. p. 177. Miscellaneous Publication 1339.
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^ a b Patterson, Patricia A. (1985). Field Guide to the Forest Plants of Northern Idaho (PDF). United States Department of Agriculture Forest Service. p. 20.
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^ Peattie, Donald Culross (1953). A Natural History of Western Trees. New York: Bonanza Books. pp. 83–84, 86.
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^ "GISD". www.iucngisd.org. Retrieved 2021-03-10.
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^ Wilding Pines, Quick ID (October 2018). "Wilding Conifer:Quick ID Guide" (PDF). wildingconifers.org.nz. Retrieved March 10, 2021.
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^ Victorian Resources Online, Agriculture Victoria. "Ponderosa pine (Pinus ponderosa)". vro.agriculture.vic.gov.au. Retrieved 2022-03-11.
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^ "Ponderosa Pines (Pinus ponderosa) as a Bonsai – East Bay Bonsai Society".
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^ "Ponderosa Pine - Pacific and Columbia sub species - Potted tree seedling - Landscape, Timber Tree, Bonsai".
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^ Finkbeiner, Ann (May 31, 2013). "How Do We Know Nuclear Bombs Blow Down Forests?". Slate.com. Retrieved May 31, 2013.
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^ "Ponderosa Pine: Montana State Tree". State Symbols USA. 14 October 2014. Retrieved 13 February 2020.
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Pinus ponderosa: Brief Summary
provided by wikipedia EN
Pinus ponderosa, commonly known as the ponderosa pine, bull pine, blackjack pine, western yellow-pine, or filipinus pine is a very large pine tree species of variable habitat native to mountainous regions of western North America. It is the most widely distributed pine species in North America.: 4
Pinus ponderosa grows in various erect forms from British Columbia southward and eastward through 16 western U.S. states and has been successfully introduced in temperate regions of Europe, and in New Zealand. It was first documented in modern science in 1826 in eastern Washington near present-day Spokane (of which it is the official city tree). On that occasion, David Douglas misidentified it as Pinus resinosa (red pine). In 1829, Douglas concluded that he had a new pine among his specimens and coined the name Pinus ponderosa for its heavy wood. In 1836, it was formally named and described by Charles Lawson, a Scottish nurseryman. It was adopted as the official state tree of Montana in 1949.
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