Alpine orogenic evolution from subduction to collisional thermal overprint: The 40Ar/39Ar age constraints from the Valaisan Ocean, central Alps

Michael Wiederkehr; Masafumi Sudo; Romain Bousquet; Alfons Berger; Stefan Schmid

Alpine orogenic evolution from subduction to collisional thermal overprint: The 40Ar/39Ar age constraints from the Valaisan Ocean, central Alps

Michael Wiederkehr, Masafumi Sudo, Romain Bousquet, Alfons Berger, Stefan Schmid

Geology

55 Citations (Scopus)

Abstract

The investigated HP/LT metasedimentary units
of the Valaisan and adjacent European domains occupy
a key position in the Alpine belt for understanding
the transition from early subduction-related HP/LT
metamorphism to collision-related Barrovian overprint
and the evolution of mountain belts in general. The
timing of high-pressure metamorphism, subsequent
retrogression and following Barrow-type overprint was
studied by 40Ar/39Ar dating of biotite and several white
mica generations that are well characterized in terms
of mineral chemistry, texture and associated mineral
assemblages. Four distinct age populations of white
mica record peak pressure conditions (42–40 Ma) and
several stages of subsequent retrograde metamorphic
evolution (36–25 Ma). Biotite isotopic analyses yield
consistent apparent ages that cluster around 18–16 Ma for
the Barrow-type thermal overprint. The recorded isotopic
data reveal a significant time gap in the order of some
20 Ma between subduction-related HP/LT metamorphism
and collision-related Barrovian overprint, supporting the
notion of a polymetamorphic evolution associated with
a bimodal P-T path

Original language	English
Journal	Tectonics
Volume	28
Issue number	TC6009
Number of pages	28
ISSN	0278-7407
Publication status	Published - 2009

Cite this

@article{6089990acab44d01a20d01ea2fe1b4d8,

title = "Alpine orogenic evolution from subduction to collisional thermal overprint: The 40Ar/39Ar age constraints from the Valaisan Ocean, central Alps",

abstract = "The investigated HP/LT metasedimentary unitsof the Valaisan and adjacent European domains occupya key position in the Alpine belt for understandingthe transition from early subduction-related HP/LTmetamorphism to collision-related Barrovian overprintand the evolution of mountain belts in general. Thetiming of high-pressure metamorphism, subsequentretrogression and following Barrow-type overprint wasstudied by 40Ar/39Ar dating of biotite and several whitemica generations that are well characterized in termsof mineral chemistry, texture and associated mineralassemblages. Four distinct age populations of whitemica record peak pressure conditions (42–40 Ma) andseveral stages of subsequent retrograde metamorphicevolution (36–25 Ma). Biotite isotopic analyses yieldconsistent apparent ages that cluster around 18–16 Ma forthe Barrow-type thermal overprint. The recorded isotopicdata reveal a significant time gap in the order of some20 Ma between subduction-related HP/LT metamorphismand collision-related Barrovian overprint, supporting thenotion of a polymetamorphic evolution associated witha bimodal P-T path",

author = "Michael Wiederkehr and Masafumi Sudo and Romain Bousquet and Alfons Berger and Stefan Schmid",

year = "2009",

language = "English",

volume = "28",

journal = "Tectonics",

issn = "0278-7407",

publisher = "Wiley-Blackwell",

number = "TC6009",

}

TY - JOUR

T1 - Alpine orogenic evolution from subduction to collisional thermal overprint: The 40Ar/39Ar age constraints from the Valaisan Ocean, central Alps

AU - Wiederkehr, Michael

AU - Sudo, Masafumi

AU - Bousquet, Romain

AU - Berger, Alfons

AU - Schmid, Stefan

PY - 2009

Y1 - 2009

N2 - The investigated HP/LT metasedimentary unitsof the Valaisan and adjacent European domains occupya key position in the Alpine belt for understandingthe transition from early subduction-related HP/LTmetamorphism to collision-related Barrovian overprintand the evolution of mountain belts in general. Thetiming of high-pressure metamorphism, subsequentretrogression and following Barrow-type overprint wasstudied by 40Ar/39Ar dating of biotite and several whitemica generations that are well characterized in termsof mineral chemistry, texture and associated mineralassemblages. Four distinct age populations of whitemica record peak pressure conditions (42–40 Ma) andseveral stages of subsequent retrograde metamorphicevolution (36–25 Ma). Biotite isotopic analyses yieldconsistent apparent ages that cluster around 18–16 Ma forthe Barrow-type thermal overprint. The recorded isotopicdata reveal a significant time gap in the order of some20 Ma between subduction-related HP/LT metamorphismand collision-related Barrovian overprint, supporting thenotion of a polymetamorphic evolution associated witha bimodal P-T path

AB - The investigated HP/LT metasedimentary unitsof the Valaisan and adjacent European domains occupya key position in the Alpine belt for understandingthe transition from early subduction-related HP/LTmetamorphism to collision-related Barrovian overprintand the evolution of mountain belts in general. Thetiming of high-pressure metamorphism, subsequentretrogression and following Barrow-type overprint wasstudied by 40Ar/39Ar dating of biotite and several whitemica generations that are well characterized in termsof mineral chemistry, texture and associated mineralassemblages. Four distinct age populations of whitemica record peak pressure conditions (42–40 Ma) andseveral stages of subsequent retrograde metamorphicevolution (36–25 Ma). Biotite isotopic analyses yieldconsistent apparent ages that cluster around 18–16 Ma forthe Barrow-type thermal overprint. The recorded isotopicdata reveal a significant time gap in the order of some20 Ma between subduction-related HP/LT metamorphismand collision-related Barrovian overprint, supporting thenotion of a polymetamorphic evolution associated witha bimodal P-T path

M3 - Journal article

SN - 0278-7407

VL - 28

JO - Tectonics

JF - Tectonics

IS - TC6009

ER -

Alpine orogenic evolution from subduction to collisional thermal overprint: The 40Ar/39Ar age constraints from the Valaisan Ocean, central Alps

Abstract

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