Cathedral Peak Granodiorite

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Cathedral Peak Granodiorite
Stratigraphic range: 88-87 Ma
Matterhorn Peak California.jpg
Matterhorn Peak consists of Cathedral Peak Granodiorite
Type Geological formation
Lithology
Primary Granodiorite
Location
Region Yosemite National Park
CountryUnited States
Type section
Named for Cathedral Peak
Map of Cathedral Peak Granodiorite.svg
A geologic map of Yosemite National Park

The Cathedral Peak Granodiorite (CPG) was named after its type locality, Cathedral Peak in Yosemite National Park, California. The granodiorite forms part of the Tuolumne Intrusive Suite (Tuolumne Batholith), one of the four major intrusive suites within the Sierra Nevada. It has been assigned radiometric ages between 88 and 87 million years and therefore reached its cooling stage in the Coniacian (Upper Cretaceous).

Contents

Geographic situation

The Cathedral Peak Granodiorite forms part of the central eastern Sierra Nevada in California. It is exposed in glaciated outcrops from the upper Yosemite Valley into the high Sierra Divide. It covers large parts of Mariposa County and Tuolumne County and also touches Madera County and Mono County. At its northern end it includes Tower Peak and Matterhorn Peak, at 12,264 feet (3743 m) its highest elevation. In its southwestern section rises the Cathedral Range with the 10,911 feet Cathedral Peak (3326 m) above Tuolumne Meadows. California State Route 120 traverses the granodiorite in its southern half. Due to the block-faulting and tilting of the Sierra Nevada to the west its drainage system is oriented to the west and follows mainly southwesterly courses, especially in the northern section.

The shape of the intrusion is a drawn-out rectangle or ellipse oriented roughly in the NNW-SSE-direction. Its long dimension measures about 30 miles (48 km), its width hardly reaches 12 miles (19 km) at the northern end. The surface area amounts to about 230 square miles (600 km2), roughly half of the total area of the Tuolumne Intrusive Suite. The granodiorite completely engulfs the Johnson Granite Porphyry in the south. It is surrounded in the southeast, southwest and northwest by the Half Dome Granodiorite. In its central belt region it touches the Kuna Crest Granodiorite. In the north and northeast it comes into contact with weakly metamorphosed country rocks, mainly Paleozoic and Jurassic metavolcanics and metasediments.

The Cathedral Range is shaped from Cathedral Peak Granodiorite. Cathedral Range.jpg
The Cathedral Range is shaped from Cathedral Peak Granodiorite.

Geological overview

Geologic map of the Yosemite National Park: .mw-parser-output .legend{page-break-inside:avoid;break-inside:avoid-column}.mw-parser-output .legend-color{display:inline-block;min-width:1.25em;height:1.25em;line-height:1.25;margin:1px 0;text-align:center;border:1px solid black;background-color:transparent;color:black}.mw-parser-output .legend-text{} Cathedral Peak Granodiorite Map of Cathedral Peak Granodiorite.svg
Geologic map of the Yosemite National Park:
  Cathedral Peak Granodiorite

The Cathedral Peak Granodiorite is the third and most important intrusive pulse of the Tuolumne Intrusive Suite. The intrusions of this magmatic suite were spaced out over quite a long period. They started in the Turonian at about 93.5 million years BP and lasted right to the beginning of the Santonian at 85.4 million years BP. Radiometric dating of the cooling ages of the Cathedral Peak Granodiorite yielded 88.1 ± 0.2 down to 87.0 ± 0.7 million years BP, i.e. Coniacian.

The Tuolumne Intrusive Suite is accompanied by other major intrusive complexes in the Sierra Nevada: the John Muir and Mount Whitney intrusive suites, both further south and the Sonora Plutonic Complex to the north. The surface area of these four complexes surpasses 970 square miles (2,500 km2).

The Tuolumne Intrusive Suite was constructed over a long time span of 8.1 million years by the following magmatic pulses (ordered by increasing age):

This magmatic sequence shows the following geochronological and geochemical trends:

Petrological description

The immediately apparent trait of the grey-white Cathedral Peak Granodiorite is its porphyritic habit with very large megacrysts of alkali feldspar commonly reaching 10, occasionally even 20 centimeters. The grain size of the groundmass stays in the 5 millimeter range.

Mineralogy

The Cathedral Peak Granodiorite is modally composed of the following minerals:

Chemical composition

The following analyses by Bateman & Chappell [1] and an average value from 18 analyses by Burgess & Miller [2] are meant to demonstrate the chemical composition of the Cathedral Peak Granodiorite:

Oxide
Weight %		Bateman & ChappellAverage
Burgess & Miller		 CIPW Norm
Percent		Bateman & ChappellAverageTrace elements
ppm		Average
Burgess & Miller
SiO269,6070,29 (67,0–72,0)Q24,5225,58Pb17,5 (15–20)
TiO20,380,41 (0,3–0,6)Or21,6720,64Cu4,9 (3,2 – 6,9)
Al2O315,3415,37 (15,0–16,5)Ab36,7935,81Ni3,0 (0,7 – 6)
Fe2O31,301,40An11,8512,57Cr3,3 (0–24)
FeO0,951,03Di0,570,37V41,4 (23–50)
MnO0,060,06 (0,5–0,8)Hy1,631,82Zr135,9 (82–165)
MgO0,700,72 (0,6–0,9)Mt1,872,01Y8,3 (4,9 – 11)
CaO2,682,82 (2,2–3,2)Il0,730,77Sr633,2 (487–758)
Na2O4,314,24 (4,0–4,5)Ap0,320,36Ba748,0 (410–1182)
K2O3,643,50 (2,8–4,2)Rb132,5 (114–166)
P2O50,140,16 (0,12–0,20)Nb7,8 (4,9 – 10)
Mg#0,550,54Sc3,6 (1,7 – 4,5)
A'/F0,080,11Ga20,9 (19–23)
Al/K+Na+Ca0,960,97Zn57,8 (38–65)

Compared with an average granodiorite the Cathedral Peak Granodiorite has a much higher silica content, shows elevated alkali values and is therefore a member of the shoshonitic high-K series. The rock is metaluminous, rich in sodium and belongs to the intrusive, mantle source-derived I-type granitoids. It is a typical calc-alkaline rock from the root zone of an ancient volcanic arc and associated with a subduction-type environment.

The trace elements demonstrate an enrichment in barium and strontium, nickel and chromium on the other hand have very low concentrations. The light rare earth elements LREE are also elevated but without a europium anomaly.

Another source gives: Estimates from petrographic observation of average mineral proportion of non-layered rocks of Half Dome Granodiorite: [3]

MineralIts percentage
Plagioclase 45%
Quartz 28%
Biotite 5%
K-feldspar 20%(15% megacryst, 5% interstitial) %
Hornblende 1%
Titanite 0.5%
Magnetite 0.5%

Structures

The Cathedral Peak Granodiorite reveals the following structures of magmatic origin:

Structures that imply tectonic movements are signs of cataclasis:

Structures that strongly hint at later-stage metasomatic changes are:

Taken together all these structural phenomena reveal a very complex evolution of the Cathedral Peak Granodiorite showing the succession of magmatic, tectonic and metasomatic stages – and most likely their occasional synergy and interdependence.

Formation and origin

Thin section view of cataclastically broken, albite-twinned plagioclase is invaded by microcline Plagioclase Replacement.jpg
Thin section view of cataclastically broken, albite-twinned plagioclase is invaded by microcline

Originally petrologists favoured a single magma chamber model for the genesis of the Tuolumne Intrusive Suite which underwent fractional crystallization and successively produced the different rock types like the Cathedral Peak Granodiorite. This somewhat simplistic model is now being questioned as underlined by the following facts:

Isotope ratios favour the mixing of two magmas, one with mantle affinities and another one with more felsic compositions approaching the Johnson Granite Porphyry in composition.

Thermobarometric data document an intrusion depth of 6 kilometers and a crystallization temperature range between 750 and 660 °C.

Feldspars, hornblende, biotite and magnetite often show unmixing in the lower temperature subsolidus region.

The Cathedral Peak Granodiorite cannot always be clearly distinguished from the porphyritic Half Dome Granodiorite in the field, at some places it shows gradual merging over about a hundred meters and apophyses are observed branching into the Half Dome rocks. The geochemical parameters of the two granodiorites also overlap, differences are mainly textural. They form a continuum and therefore cannot be clearly separated as two distinctive intrusive pulses. [6] The contact relationships with the Johnson Granite Porphyry are on the other hand sharp. [7]

The origin of the microcline in shear zones poses another problem. M.D. Higgins favours the possibility of recrystallization based on Ostwald ripening via metasomatic fluids. [8] L.G. Collins supports a metasomatic subsolidus growth (potassium- and silica-metasomatism) that has been initiated by ongoing tectonic cataclasis. [9] To be fully effective this process is dependent on the cataclastic breaking-up of the original crystals as realized in a ductile shear zone along the eastern edge of the Cathedral Peak Granodiorite (Gem Lake Shear Zone).

See also

Related Research Articles

<span class="mw-page-title-main">Dacite</span> Volcanic rock intermediate in composition between andesite and rhyolite

Dacite is a volcanic rock formed by rapid solidification of lava that is high in silica and low in alkali metal oxides. It has a fine-grained (aphanitic) to porphyritic texture and is intermediate in composition between andesite and rhyolite. It is composed predominantly of plagioclase feldspar and quartz.

<span class="mw-page-title-main">Trachyte</span> Extrusive igneous rock

Trachyte is an extrusive igneous rock composed mostly of alkali feldspar. It is usually light-colored and aphanitic (fine-grained), with minor amounts of mafic minerals, and is formed by the rapid cooling of lava enriched with silica and alkali metals. It is the volcanic equivalent of syenite.

<span class="mw-page-title-main">Diorite</span> Igneous rock type

Diorite is an intrusive igneous rock formed by the slow cooling underground of magma that has a moderate content of silica and a relatively low content of alkali metals. It is intermediate in composition between low-silica (mafic) gabbro and high-silica (felsic) granite.

<span class="mw-page-title-main">Aplite</span> Fine-grained intrusive igneous rock type similar to granite

Aplite is an intrusive igneous rock in which the mineral composition is the same as granite, but in which the grains are much finer, under 1 mm across. Quartz and feldspar are the dominant minerals. The term aplite or aplitic is often used as a textural term to describe veins of quartz and feldspar with a fine to medium-grain "sugary" texture. Aplites are usually very fine-grained, white, grey or pinkish, and their constituents are visible only with the help of a magnifying lens. Dykes and veins of aplite are commonly observed traversing granitic bodies; they occur also, though less frequently, in syenites, diorites, quartz diabases, and gabbros.

<span class="mw-page-title-main">Quartz monzonite</span> Type of igneous rock

Quartz monzonite is an intrusive, felsic, igneous rock that has an approximately equal proportion of orthoclase and plagioclase feldspars. It is typically a light colored phaneritic (coarse-grained) to porphyritic granitic rock. The plagioclase is typically intermediate to sodic in composition, andesine to oligoclase. Quartz is present in significant amounts. Biotite and/or hornblende constitute the dark minerals. Because of its coloring, it is often confused with granite, but whereas granite contains more than 20% quartz, quartz monzonite is only 5–20% quartz. Rock with less than five percent quartz is classified as monzonite. A rock with more alkali feldspar is a syenite whereas one with more plagioclase is a quartz diorite. The fine grained volcanic rock equivalent of quartz monzonite is quartz latite.

<span class="mw-page-title-main">Granodiorite</span> Type of coarse grained intrusive igneous rock

Granodiorite is a coarse-grained (phaneritic) intrusive igneous rock similar to granite, but containing more plagioclase feldspar than orthoclase feldspar.

<span class="mw-page-title-main">Monzonite</span> Igneous intrusive rock with low quartz and equal plagioclase and alkali feldspar

Monzonite is an igneous intrusive rock, formed by slow cooling of underground magma that has a moderate silica content and is enriched in alkali metal oxides. Monzonite is composed mostly of plagioclase and alkali feldspar.

<span class="mw-page-title-main">Myrmekite</span> Tiny intergrowths of quartz and feldspar in rocks

Myrmekite is a vermicular, or wormy, intergrowth of quartz in plagioclase. The intergrowths are microscopic in scale, typically with maximum dimensions less than 1 millimeter. The plagioclase is sodium-rich, usually albite or oligoclase. These quartz-plagioclase intergrowths are associated with and commonly in contact with potassium feldspar. Myrmekite is formed under metasomatic conditions, usually in conjunction with tectonic deformations. It has to be clearly separated from micrographic and granophyric intergrowths, which are magmatic.

<span class="mw-page-title-main">Monzogranite</span> Biotite granite rocks that are considered to be the final fractionation product of magma

Monzogranites are biotite granite rocks that are considered to be the final fractionation product of magma. Monzogranites are characteristically felsic (SiO2 > 73%, and FeO + MgO + TiO2 < 2.4), weakly peraluminous (Al2O3/ (CaO + Na2O + K2O) = 0.98–1.11), and contain ilmenite, sphene, apatite and zircon as accessory minerals. Although the compositional range of the monzogranites is small, it defines a differentiation trend that is essentially controlled by biotite and plagioclase fractionation. (Fagiono, 2002). Monzogranites can be divided into two groups (magnesio-potassic monzogranite and ferro-potassic monzogranite) and are further categorized into rock types based on their macroscopic characteristics, melt characteristics, specific features, available isotopic data, and the locality in which they are found.

Syenogranite is a fine to coarse grained intrusive igneous rock of the same general composition as granite. They are characteristically felsic.

The Piégut-Pluviers Granodiorite is situated at the northwestern edge of the Variscan Massif Central in France. Its cooling age has been determined as 325 ± 14 million years BP.

<span class="mw-page-title-main">Half Dome Granodiorite</span> Half Dome Granodiorite is granodiorite (see also granite) found in Yosemite National Park

Half Dome Granodiorite is granodiorite found in a region on and near Half Dome, in Yosemite National Park, California, United States. The granodiorite forms part of the Tuolumne Intrusive Suite, one of the four major intrusive suites within the Sierra Nevada.

<span class="mw-page-title-main">El Capitan Granite</span> El Capitan Granite is a type of granite (also see granodiorite), Yosemite National Park

El Capitan Granite is a type of granite, in a large area near El Capitan, in Yosemite National Park, California, United States. The granite forms part of the Tuolumne Intrusive Suite, one of the four major intrusive suites within the Sierra Nevada.

<span class="mw-page-title-main">Kuna Crest Granodiorite</span> Kuna Crest Granodiorite, Granodiorite of Glen Aulin is a granodiorite found Yosemite National Park

Kuna Crest Granodiorite, is found, in Yosemite National Park, United States. The granodiorite forms part of the Tuolumne Intrusive Suite, one of the four major intrusive suites within the Sierra Nevada. Of the Tuolumne Intrusive Suite, it is the oldest and darkest rock.

<span class="mw-page-title-main">Sentinel granodiorite</span> Sentinel granodiorite is a type of granodiorite found Yosemite National Park


Sentinel granodiorite is a type of granodiorite found in Yosemite National Park. It is a poorly understood western "outlier" of the ~93-85-Ma Tuolumne Intrusive Suite of the Sierra Nevada batholith. It is only slightly older than the undated Yosemite Creek Granodiorite and the Kuna Crest Granodiorite.

<span class="mw-page-title-main">Tuolumne Intrusive Suite</span> One of several intrusive suites in Yosemite National Park

The Tuolumne Intrusive Suite is the youngest and most extensive of the intrusive suites of Yosemite National Park, and also comprises about 1/3 of the park's area. The Suite includes Half Dome Granodiorite, Cathedral Peak Granite, and Kuna Crest Granodiorite.

<span class="mw-page-title-main">Intrusive Suite of Sonora Pass</span> Intrusive Suite of Sonora Pass is one of several intrusive suites in Yosemite National Park

The Intrusive Suite of Sonora Pass is one of several intrusive suites in Yosemite National Park. These also include

  1. Fine Gold Intrusive Suite
  2. Intrusive Suite of Buena Vista Crest
  3. Intrusive Suite of Jack Main Canyon
  4. Intrusive Suite of Merced Peak
  5. Intrusive Suite of Yosemite Valley
  6. Tuolumne Intrusive Suite
<span class="mw-page-title-main">Lilesville Granite</span> Body of granitic rock

The Lilesville Granite, also referred to as the Lilesville pluton, is a ring-shaped body of granitic rock that spans about 94 square miles (240 km2) in Anson, Richmond, and Montgomery Counties in southern North Carolina.

Johnson Granite Porphyry is found in Tuolumne Meadows, Yosemite National Park.

References

  1. Bateman, P.C. & Chappell, B.W. (1979). Crystallization, fractionation and solidification of the Tuolumne intrusive series. Yosemite National Park, California. Geological Society of America Bulletin, 90: 465–482
  2. Burgess, S., and Miller, J., (2008) Construction, solidification and internal differentiation of a large felsic arc pluton: Cathedral Peak granodiorite, Sierra Nevada Batholith, in Annen, C., and Zellmer, G. F., eds., Dynamics of crustal magma transfer, storage and differentiation: London, Geological Society, p. 203-234.
  3. F. Solgadi, E. W. Sawyer, Formation of Igneous Layering in Granodiorite by Gravity Flow: a Field, Microstructure and Geochemical Study of the Tuolumne Intrusive Suite at Sawmill Canyon, California, Journal of Petrology, Volume 49, Issue 11, November 2008, Pages 2009–2042
  4. Coleman, D.S., Gray, W. & Glazner, A.F. (2004). Rethinking the emplacement and evolution of zoned plutons: geochronologic evidence for incremental assembly of the Tuolumne Intrusive Suite, California. Geology, 32, 433–436.
  5. Kistler, R.W., Chappell, B.W., Peck, D.L. & Bateman, P.C. (1986). Isotopic variation in the Tuolumne intrusive suite, central Sierra Nevada, California. Contributions to Mineralogy and Petrology, 94, 205–220.
  6. Gray, W., Glazner, A.F., Coleman, D.S. & Bartley, J.M. (2008). Long-term geochemical variability of the Late Cretaceous Tuolumne Intrusive Suite, central Sierra Nevada, California. In: Annen, C. & Zellmer, G.F. Dynamics of Crustal Magma Transfer, Storage and Differentiation. Geological Society Special Publication 304.
  7. Titus, S.J., Clark, R. & Tikoff, B. (2005). Geologic and geophysical investigation of two fine-grained granites, Sierra Nevada Batholith, California; evidence for structural controls on emplacement and volcanism. Geological Society of America Bulletin, 117, 1256–1271.
  8. Higgins, M. D., 1999, Origin of megacrysts in granitoids by textural coarsening: A Crystal Size Distribution (CSD) Study of Microcline in the Cathedral Peak Granodiorite, Sierra Nevada, California., in Fernandez, C., and Castro, A., eds., Understanding Granites: Integrating Modern and Classical Techniques. Special Publication 158: London, Geological Society of London, p. 207-219.
  9. Collins, L.G. and Collins, B.J. (2002). K-metasomatism of plagioclase to produce microcline megacrysts in a shear zone of the Cathedral Peak granodiorite, Sierra Nevada, California, USA
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