the john muir exhibit - writings - studies_in_the_sierra - chapter 2
Studies in the Sierra
by John Muir
II
Mountain Sculpture
Origin of Yosemite Valleys
All the valleys and cañons of the western flank of the
Sierra, between 36° and 39° north latitude, naturally
classify themselves under two genera, each containing two species.
One genus comprehends all the slate valleys, the other all that
are built of granite. The latter is far the more important, both
on account of the greater extent of its geographical range and
the grandeur and simplicity of its phenomena. All the valleys
of both genera are valleys of erosion. Their chief distinguishing
characteristic may be seen in the following descriptions:
Slate Valleys
1. Cross-sections, V-shaped, or somewhat rounded at
bottom, walls irregular in structure, shattered and weak in
appearance, because of the development of slaty cleavage planes and
joints, which also prevent the formation of plane-faced precipice.
Bottom showing the naked bed-rock, or covered by rocky debris,
and sloping in the direction of the trend. Nearly all of the foothill
valleys belong to this species.
Some of the older specimens are smoothly covered with soil,
but meadows and lakes are always wanting.
2. More or less widened, branching at the head. Bottom,
with meadows, or groves or lakelets, or all together. Sections
and wads about as in No. 1. Fine examples of this species occur
on the head-waters of the San Joaquin.
Granite Valleys
1. Cross-sections narrowly or widely V-shaped. Walls
seldom interrupted by side cañons, magnificently simple
in structure and general surface character, and presenting plane
precipices in great abundance. Bottom sloping in the direction
of the trend, mostly bare, or covered with unstratified glacial
and avalanche bowlders. Groves and meadows wanting.
2. Branching at head, with beveled and heavily abraded lips
at foot. Bottom level meadowed, laked, or groved.
Walls usually very high, often interrupted by side cañons.
Sections as in No. 1. To this species belongs the far-famed
Yosemite who origin we will now discuss.
We will henceforth make use of the word Yosemite both as a specific
and geographical term.
Yosemite Valley is on the main Merced, in the middle region of
the range. It is about seven miles long from east to west, with
an average width at bottom of a little more than half a mile,
and at the top of a mile and a half. The elevation of the bottom
above sea level is about 4,000 feet. The average height of the
walls is about 3,000 feet, made up of a series of sublime rock
forms, varying greatly in size and structure, partially separated
from one another by small side cañons. These immense wall-rocks,
ranged picturesquely together, do not stand in line. Some advance
their sublime fronts far out into the open valley, others recede.
A few are nearly vertical, but far the greater number are inclined
at angles ranging from twenty to seventy degrees. The meadows
and sandy flats outspread between support a luxuriant growth of
sedges and ferns, interrupted with thickets of azalea, willow
and briar-rose. The warmer sloping ground along the base
of the walls is planted with noble pines and oaks, while countless
alpine flowers fringe the deep and dark side cañons, through
which glad streams descend in falls and cascades, on their way
from the high fountains to join the river. The life-giving
Merced flows down the valley with a slow, stately current, curving
hither and thither through garden and grove, bright and pure as
the snow of its fountains. Such is Yosemite, the noblest of Sierra
temples, everywhere expressing the working of Divine harmonious
law, yet so little understood that it has been regarded as "an
exceptional creation," or rather exceptional destruction
accomplished by violent and mysterious forces. The argument
advanced to support this view is substantially as follows: It
is too wide for a water-eroded valley, too irregular for
a fissure valley, and too angular and local for a primary valley
originating in a fold of the mountain surface during the process
of upheaval; therefore, a portion of the mountain bottom must
have suddenly fallen out, letting the super-incumbent domes
and peaks fall rumbling into the abyss, like coal into the bunker
of a ship. This violent hypothesis, which furnishes a kind of
Tophet for the reception of bad mountains, commends itself to
the favor of many, by seeming to account for the remarkable sheerness
and angularity of the walls, and by its marvelousness and obscurity,
calling for no investigation, but rather discouraging it. Because
we can not observe the bed-rock to ascertain whether or not
it is fractured, this engulfment hypothesis seems to rest safely
under cover of darkness, yet a film of lake gravel and a meadow
blanket are its only concealments, and, by comparison with exposed
sections in other Yosemites where the sheer walls unite with the
solid, unfissured bottom, even these are in effect removed. It
becomes manifest, by a slight attention to facts, that the hypothetical
subsidence must have been
limited to the valley proper, because both at the head and foot
we find the solid bed-rock.
The breaking down of only one small portion of the mountain floor,
leaving all adjacent to it undisturbed, would necessarily give
rise to a very strongly marked line of demarcation, but no such
line appears; on the contrary, the unchanged walls are continued
indefinitely, up and down the river cañon, and lose their
distinguishing characteristics in a gradual manner easily accounted
for by changes in the structure of the rocks and lack of concentration
of the glacial energy expended upon them. That there is comparatively
so small a quantity of debris at the foot of Yosemite walls is
advanced as an argument in favor of subsidence, on the grounds
that the valley is very old, and that a vast quantity of debris
must, therefore, have fallen from the walls by atmospheric agencies,
and that the hypothetical "abyss" was exactly required
to furnish storage for it. But the Yosemite Valley is not very
old. It is very young, and no vast quantity of debris has ever
fallen from its walls. Therefore, no abyss was required for its
accommodation.
If, in accordance with the hypothesis, Yosemite is the only valley
furnished with an abyss for the reception of debris, then we might
expect to find all abyssless valleys choked up with the great
quantity assumed to have fallen; but, on the contrary, we find
their debris in the same condition as in Yosemite, and not more
abundant. Indeed, in some portions of valleys as deep and sheer
as Yosemite there is absolutely no talus, and that there never
has been any is proved by both walls and bottom being solid
and ice-polished. Many examples illustrative of this
truth may be seen in the great Tuolumne and Kings River valleys.
Where the granite of Yosemite walls is intersected with feldspathic
veins, as in the lowest of the Three Brothers and rocks near Cathedral
Spires, large masses are loosened, from time to time, by the action
of the atmosphere, and hurled to the bottom with such violence
as to shake the whole valley; but the aggregate quantity which
has been thus weathered off, so far from being sufficient to fill
any great abyss, forms but a small part of the debris slopes
actually found on the surface, all the larger angular taluses
having been formed simultaneously by severe earthquake shocks
that occurred three or four hundred years ago, as shown by their
forms and the trees growing upon them. The attentive observer
will perceive that wherever a large talus occurs, the wall
immediately above it presents a scarred and shattered surface
whose area is always proportional to the size of the talus,
but where there is no talus the wall is invariably moutonée
or striated, showing that it is young and has suffered little
change since it came to light at the close of the glacial period.
On the 23rd of March, 1872, I was so fortunate as to witness the
sudden formation of one of these interesting taluses by the precipitation
of the Yosemite Eagle Rock by the first heavy shock of the Inyo
earthquake, whereby their local character and simultaneity of
formation was fully accounted for. This new earthquake gave
rise to the formation of many new taluses throughout the
adjacent valleys, corresponding in every particular with the older
and larger ones whose history we have been considering.
As to the important question, What part may water have played
in the formation of Sierra valleys? we observe that, as far as
Yosemite is concerned, the five large streams which flow through
it are universally engaged in the work of filling it up. The
granite of the region under consideration is but slightly susceptible
of water denudation. Throughout the greater portion of the main
upper Merced Valley the river has not eroded its channel to a
depth exceeding three feet since it first began to flow at the
close of the glacial epoch, although acting under every advantage
of concentration and quick descent. The highest flood-mark
the young river has yet recorded upon the clean glacial tablets
of its banks is only seven or eight feet above the present level,
at ordinary stages. Nevertheless, the aggregate annual quantity
that formerly passed down these cañon valleys was undoubtedly
far greater than passes at the present time, because on the gradual
recession of the glaciers at the dose of the period, the supply
would necessarily be more constant, from their melting all through
the seasons. The evidence, however, is incontestable, which shows
that the highest floods of Sierra rivers in the upper and middle
regions of the range never much exceeded those of the present
time.
Five immense glaciers from five to fifteen hundred feet in depth
poured their icy floods into Yosemite, uniting to form one huge
trunk, moved down through the valley with irresistible and never-ceasing
energy, crushing and breaking up its strongest rocks, and scattering
them in moraines far and near. Many, while admitting the possibility
of ice having been the great agent in the production of Yosemite
valleys, conjecture that earthquake fissures, or cracks from cooling
or upheaval of the earth's crust, were required to enable the
glaciers to make a beginning and to guide them in the work. We
have already shown [in the earlier chapter about mountain sculpture]
that cleavage planes and joints exist in a latent or developed
condition in all the granite of the region, and that these exert
immense influence on its glacial erodibility. During five years'
observation in the Sierra, I have failed to discover a single
fissure of any kind, although extensive areas of clean-swept
glacial pavements afford ample opportunity
for their detection, did they exist. Deep slots, with regular
walls, appearing as if sawed, or mortised, frequently occur. These
are formed by the disintegration of soft seams a few inches or
feet in thickness, contained between walls of stronger granite.
Such is the character of the so-called fissure said to exist
in a hard portion of the south wall of Yosemite, opposite the
Three Brothers, so frequently quoted in speculations upon the
valley's origin.
The greatest effects of earthquakes on the valley we have already
noticed in avalanche taluses, which were formed by the precipitation
of weak headlands, that fell like ripe fruit. The greatest obstacle
in the way of reading the history of Yosemite valleys is not its
complexity or obscurity, but simply the magnitude of the characters
in which it is written. It would require years of enthusiastic
study to master the English alphabet if it were carved upon the
flank of the Sierra in letters sixty or seventy miles long, their
bases set in the foothills, their tops leaning back among the
glaciers and shattered peaks of the summit, often veiled with
forests and thickets, and their continuity often broken by cross-gorges
and hills. So also the sculptured alphabet cañons of the
Sierra are magnificently simple, yet demand years of laborious
research for their apprehension. A thousand blurred fragments
must be conned and brooded over with studious care, and kept vital
and formative on the edges, ready to knit like broken living bones,
while a final judgment is being bravely withheld until the entire
series of phenomena has been weighed and referred to an allunifying,
all-explaining law. To one who can leisurely contemplate
Yosemite from some commanding outlook, it offers, as a whole,
a far more natural combination of features than is at all apparent
in partial views obtained from the bottom. Its stupendous domes
and battlements blend together and manifest delicate compliance
to law, for the mind is then in some measure emancipated from
the repressive and enslaving effects of their separate magnitudes,
and gradually rises to a comprehension of their unity and of the
poised harmony of their general relations.
Nature is not so poor as to possess only one of anything, nor
throughout her varied realms has she ever been known to offer
an exceptional creation whether of mountain or valley. When, therefore,
we explore the adjacent Sierra, we are not astonished to find
that there are many Yosemite valleys identical in general characters,
each presenting on a varying scale the same species of mural precipices,
level meadows, and lofty waterfalls. The laws which preside over
their distribution are as constant and apparent as those governing
the distribution of forest trees. They occur only in the middle
region of the chain, where the declivity is considerable and where
the
granite is Yosemitic in its internal structure. The position of
each valley
upon the Yosemitic zone indicates a marked and inseparable relation to
the ancient glaciers, which, when fully deciphered, amounts to cause and
effect. So constant and obvious is this connection between the various
Yosemites and the névé amphitheatres which
fountained the ancient ice-rivers, that an observer, inexperienced
in these phenomena, might easily
anticipate the position and size of any Yosemite by a study of the glacial
fountains above it, or the position and size of the fountains by a study of
their complementary Yosemite. All Yosemites occur at the junction of two
or more glacial cañons. Thus the greater and lesser
Yosemites of the Merced,
Hetch Hetchy, and those of the upper Tuolumne, those of Kings
River, and the San Joaquin, all occur immeditely below the confluence
of their ancient glaciers. If, in following down the cañon channel of the
Merced Glacier, from its origin in the névé
amphitheatres of the Lyell
group, we should find that its sudden expansion and deepening
at Yosemite occurs without a corresponding union of glacial tributary
cañons
and without any similar expansion elsewhere, then we might well be
driven to the doctrine of special marvels. But this emphatic deepening and
widening becomes harmonious when we observe smaller Yosemites
occurring at intervals all the way down, across the Yosemitic zone,
wherever
a tributary cañon unites with the trunk, until,
on reaching Yosemite
where the enlargement is greatest, we find the number of confluent
glacier-cañons is also greatest,
as may be observed by reference
to Fig. 1.
![[Fig. 1--Tuolumne Yosemite]](2-1.gif)
Fig. 1--Tuolumne Yosemite.
(A A A, Glaciers.)
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![[Fig. 2.--Kings River Yosemite]](2-2.gif)
Fig. 2.--Kings River Yosemite.
(B B B B, Glaciers.)
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![[Fig. 3.--Merced Yosemite glaciers]](2-3.gif)
Fig. 3.--Merced Yosemite glaciers.
(A, Yosemite Creek; B, Hoffman;
C, Tenaya; D, South Lyell;
E, Illilouette; F, Pohono.)
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Still further, the aggregate areas of their cross-sections is approximately
equal to the area of the cross-sections of the several resulting Yosemites
just as the cross-section of a tree trunk is about equal to the sum of the
sections of its branches.
Furthermore, the trend of Yosemite valleys is
always a direct resultant of the sizes, directions, and declivities
of their
confluent cañons, modified by peculiarities of
structure in their rocks. Now
all the cañons mentioned above are the abandoned channels of glaciers,
therefore, these Yosemites and their glaciers are inseparably related.
Instead of being local in character, or formed by obscure and lawless forces,
these valleys are the only great sculpture phenomena whose existence and
exact positions we may confidently anticipate.
Depth of Yosemite
Much stress has been laid on the mere uncompared arithmetical depth
of Yosemite, but this is a character of no consequence to the consideration
of its origin. The greatest Merced Yosemite is 3,000 feet deep;
the Tuolumne, 2,000; another, 1,000; but what geologist would
be so unphilosophical
as to decide against the identity of their origin from difference
in depth only. One pine tree is 100 feet high, lean and crooked,
from repressing winds and the poverty of the soil which nourished
it; while another, more fortunate in the conditions of its life,
is 200 feet high, erect and vigorous. So, also, one Yosemite is
3,000 feet deep because of the favorable structure of its rocks
and the depth and number of ice-rivers that excavated it;
another is half as deep, because of the strength of its rocks,
or the scantiness of the glacial force exerted upon it. What would
be thought of a botanist who should announce that our gigantic
Sequoia was not a tree at all, offering as a reason that
it was too large for a tree, and, in describing it, should confine
himself to some particularly knotty portion of the trunk? In Yosemite
there is an evergreen oak double the size of ordinary oaks of
the region, whose trunk is craggy and angular as the valley itself,
and colored like the granite bowlders on which it is growing.
At a little distance this trunk would scarcely be recognized as
part of a tree, until viewed in relation to its branches, leaves
and fruit. It is an admirable type of the craggy Merced cañon-tree,
whose angular Yosemite does not appear as a natural portion thereof
until viewed in its relation to its wide-spreading branches,
with their fruit and foliage of meadow and lake.
We present a ground-plan of three Yosemite valleys, showing
the positions of their principal glaciers, and the relation of
their trends and areas to them. The large arrows in Figs. 1, 2,
3 show the positions and directions of movement of the main confluent
glaciers concerned in the erosion of three Yosemites. With regard
to the number of their main glaciers, the Tuolumne Yosemite may
be called a Yosemite of the third power; the Kings River
Yosemite, of the fourth power; and the Merced Yosemite, of the
fifth power. The granite in which each of these three Yosemites
is excavated is of the same general quality; therefore, the differences
of width, depth, and trend observed, are due almost entirely to
the number, magnitude, declivity and mode of combination of the
glacial system of each. The similarity of their ground-plans
is obvious from a single glance at the figures; their cross-sections
are no less similar. One of the most characteristic from each
of the valleys under consideration is shown in Figs. 4, 5 and
6, drawn on the same scale.
![[Fig. 4.--Section across the Hetch Hetchy Valley]](2-4.gif)
Fig. 4.--Section across the
Hetch Hetchy Valley, or
lower Tuolumne Yosemite
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![[Fig. 5.--Section across the Kings River Yosemite]](2-5.gif)
Fig. 5.--Section across the
Kings River Yosemite
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![[Fig. 6.--Section across Merced Yosemite]](2-6.gif)
Fig. 6.--Section across
Merced Yosemite
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![[Fig. 7.--Idealized section across Merced Yosemite]](2-7.gif)
Fig. 7.--Idealized section
across Merced Yosemite
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The perpendicularity of Yosemite walls is apt to be greatly over-estimated.
If the slopes of the Merced Yosemite walls were to be carefully
measured with a clinometer at intervals of say 100 yards, it would
be found that the average angle they make with the horizon is
less than 50°, as shown in Fig. 7. It is not possible that
the bottom could drop out of a
valley thus shaped, no matter how great the upheaval or down-heaval,
or side-heaval.
Having shown that Yosemite, so-called, is not unique in its
ground-plan or cross-sections, we will now consider
some of the most remarkable of its rock forms. The beautiful San
Joaquin Dome in the cañon of the San Joaquin, near the
confluence of the south fork, looking south (Fig. 9),
shows remarkable resemblance to the Yosemite Half Dome, as seen
from Tenaya Cañon (Fig. 8).
![[Fig. 8]](2-8.gif)
Fig. 8
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![[Fig. 9]](2-9.gif)
Fig. 9
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They are similarly situated
with reference to the glaciers that denuded them, Half Dome having
been assailed by the combined Tenaya and Hoffman glaciers on the
one side, and by the South Lyell or Merced Glacier on the other;
the San Joaquin Dome, by the combined glaciers of the middle and
north forks, on one side, and by the glaciers of the south fork
on the other. The split dome of Kings River Yosemite is a worthy
counterpart of the great Half Dome of the Merced Yosemite. They
occur at about the same elevation, and are similarly situated
with reference to the ancient glacial currents, which first overswept
them and then glided heavily by on either side, breaking them
up in chips and slabs, until fashioned and sculptured to their
present condition. The
Half Dome is usually regarded as being
the most mysterious and unique rock form in the valley, or, indeed,
in the world, yet when closely approached and studied, its history
becomes plain.
![[Fig. 10.--North Face of Half Dome, Yosemite Valley]](2-10.gif)
Fig. 10.--North Face of Half Dome,
Yosemite Valley
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From A to B, Fig. 10, the height is about 1,800 feet; from A to
the base, 3,000. The upper portion is almost absolutely plain
and vertical, the lower is inclined at an angle with the horizon
of about 37°. The observer may ascend from the south side
to the shoulder of the dome at D, and descend along the face toward
A H. In the notch at F a section of the dome may be seen, showing
that it is there made up of immense slabs set
on edge. These evidently have been produced by the development
of cleavage planes, which, cutting the dome perpendicularly, have
determined the plane of its face, which is the most striking characteristic
of the rock. Along the front toward A H may be seen the stumps
of slabs which have been successively split off the face. At H
may be seen the edges of residual fragments of the same slabs.
At the summit we perceive the cut edges of the concentric layers
which have given the curved dome outline, B B. At D, a small gable
appears, which has been produced by the development of diagonal
cleavage planes which have been cut in front by vertical planes.
After the passage of the main Tenaya Glacier in the direction
of the arrows, small glacierets seem to have flowed down in front,
eroding shallow groove channels in the direction of greatest declivity;
and even before the total recession of the main glacier a wing-shaped
ice-slope probably leaned back in the shadow, and with slow
action eroded the upper portion of the dome. All the rocks forming
the south walls of deep
Yosemite cañons exhibit more or less of this light after-sculpture,
effected in the shade after the north sun-beaten rocks were
finished.
![[Fig. 11.--North Face of Half Dome of Kings River Yosemite Valley]](2-11.gif)
Fig. 11.--North Face of Half Dome
of Kings River Yosemite Valley
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The south side of the dome has been heavily
moutonée
by the Lyell
Glacier, but is, nevertheless, nearly as vertical as the north
split side. The
main body of the rock corresponds in form and attitude with every
other rock similarly situated with reference to ice-rivers,
and to elevation above sea level, the special split dome-top
being, as we have seen, a result of special structure in the granite
out of which it was formed. Numerous examples of this interesting
species of rock may be culled from the various Yosemites, illustrating
every essential character on a gradually changing scale.
Fig. 12 is a view of the back or south side of Half Dome, Yosemite,
showing its moutonée condition; Fig. 13 represents
El Capitan of Yosemite, situated on the north side of the valley;
Fig. 14, El Capitan of Big Tuolumne Cañon, near the middle,
situated on the north side; Fig. 15, El Capitan of Big Tuolumne
Cañon, near the head, situated on the north side.
![[Fig. 12]](2-12.gif)
Fig. 12
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![[Fig. 13]](2-13.gif)
Fig. 13
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![[Fig. 14]](2-14.gif)
Fig. 14
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![[Fig. 15]](2-15.gif)
Fig. 15
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The far-famed El Capitan rock presents a sheer cleaved front,
over three thousand feet high, and is scarcely less impressive
than the great dome. We have collected fine specimens of this
clearly defined rock form from all the principal Yosemites of
the region. Nevertheless, it also has been considered exceptional.
Their origin is easily explained. They are simply split ends
of ridges which have been broken through by glaciers.
For their perfect development the granite must be strong, and
have some of its vertical cleavage planes well developed, nearly
to the exclusion of all the others, especially of those belonging
to the diagonal and horizontal series. A powerful trunk glacier
must sweep past in front
nearly in the direction of its cutting planes, with small glaciers,
tributary to the first, one on each side of the ridge out of which
the Capitan is to be made.
![[Fig. 16]](2-16.gif)
Fig. 16
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This arrangement is illustrated in
Fig. 16, where A represents a horizontal section of a Capitan
rock, exposing the edges of the cleavage planes which determined
the character of its face; B, the main glacier
sweeping down the valley in front; and C C, the tributaries isolating
it from the adjacent softer granite. The three Capitans figured
stand thus related to the glaciers of the region where they are
found. I have met with many others, all of which are thus situated,
though in some instances one or both of the side glaciers had
been wanting, leaving the resulting Capitan less perfect, considering
the bold advancing Yosemite Capitan as a typical form.
When the principal surface features of the Sierra were being blocked
out, the main ice-sheet was continuous and moved in a southerly
direction, therefore the most perfect Capitans are invariably
found on the
north sides of valleys trending east and west. The reason will
be readily perceived by referring to Fig. 8 of Chapter I.
![[Fig. 17]](2-17.gif)
Fig. 17
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![[Fig. 18]](2-18.gif)
Fig. 18
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To illustrate still further how fully the split fronts of rocks
facing deep cañons have the angles at which they stand
measured by their cleavage planes, we give two examples (Figs.
17 and 18) of leaning fronts from the cañon of the north
fork of the San Joaquin River. Sentinel and Cathedral rocks also
are found in other glacial cañons, and in every instance
their forms, magnitudes, and positions are obviously the necessary
result of the internal structure and general mechanical characters
of the rock; out of which they were made, and of the glacial energy
that has beer brought to bear on them. The abundance, therefore,
of lofty angular rocks instead of rendering Yosemite unique, is
the characteristic which unites it most intimately with all the
other similarly situated valleys in the range.
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