Himalayan Leucogranites: A Minimal Role in Deformation

Matthew J. Kohn; Sean P. Long; T. Mark Harrison

doi:10.2138/gselements.20.6.381

Himalayan Leucogranites: A Minimal Role in Deformation

Matthew J. Kohn, Sean P. Long, T. Mark Harrison

Geosciences Department

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3 Scopus citations

Abstract

Apopular model of Himalayan metamorphic and structural evolution argues that partial melting of deeply buried rocks triggered crustal weakening,ductileflow,orogeniccollapse,andgenesisofleucogranites. Here, we review the origins and evolution of partial melts and leucogranites to demonstrate that they are largely incidental to deformation. Although a pulse of orogenic collapse and leucogranite crystallization occurred at 15–25 Ma, pervasive partial melts formed as much as 20 My earlier. Thus, leucogranites date extraction and transport, not necessarily melting onset. Extensional structures and distributed extensional strain occur in many rocks that lack partial melt and leucogranites, indicating these are not prerequisite to facilitate orogenic collapse. Most mass transfer appears to occur via thrusting, even in partially molten rocks.

Original language	English
Pages (from-to)	381-387
Number of pages	7
Journal	Elements
Volume	20
Issue number	6
DOIs	https://doi.org/10.2138/gselements.20.6.381
State	Published - Dec 2024

Keywords

channel flow
critical taper
geothermometry
Greater Himalayan Sequence
partial melt

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10.2138/gselements.20.6.381

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title = "Himalayan Leucogranites: A Minimal Role in Deformation",

abstract = "Apopular model of Himalayan metamorphic and structural evolution argues that partial melting of deeply buried rocks triggered crustal weakening,ductileflow,orogeniccollapse,andgenesisofleucogranites. Here, we review the origins and evolution of partial melts and leucogranites to demonstrate that they are largely incidental to deformation. Although a pulse of orogenic collapse and leucogranite crystallization occurred at 15–25 Ma, pervasive partial melts formed as much as 20 My earlier. Thus, leucogranites date extraction and transport, not necessarily melting onset. Extensional structures and distributed extensional strain occur in many rocks that lack partial melt and leucogranites, indicating these are not prerequisite to facilitate orogenic collapse. Most mass transfer appears to occur via thrusting, even in partially molten rocks.",

keywords = "channel flow, critical taper, geothermometry, Greater Himalayan Sequence, partial melt",

author = "Kohn, {Matthew J.} and Long, {Sean P.} and Harrison, {T. Mark}",

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doi = "10.2138/gselements.20.6.381",

language = "English",

volume = "20",

pages = "381--387",

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TY - JOUR

T1 - Himalayan Leucogranites

T2 - A Minimal Role in Deformation

AU - Kohn, Matthew J.

AU - Long, Sean P.

AU - Harrison, T. Mark

PY - 2024/12

Y1 - 2024/12

N2 - Apopular model of Himalayan metamorphic and structural evolution argues that partial melting of deeply buried rocks triggered crustal weakening,ductileflow,orogeniccollapse,andgenesisofleucogranites. Here, we review the origins and evolution of partial melts and leucogranites to demonstrate that they are largely incidental to deformation. Although a pulse of orogenic collapse and leucogranite crystallization occurred at 15–25 Ma, pervasive partial melts formed as much as 20 My earlier. Thus, leucogranites date extraction and transport, not necessarily melting onset. Extensional structures and distributed extensional strain occur in many rocks that lack partial melt and leucogranites, indicating these are not prerequisite to facilitate orogenic collapse. Most mass transfer appears to occur via thrusting, even in partially molten rocks.

AB - Apopular model of Himalayan metamorphic and structural evolution argues that partial melting of deeply buried rocks triggered crustal weakening,ductileflow,orogeniccollapse,andgenesisofleucogranites. Here, we review the origins and evolution of partial melts and leucogranites to demonstrate that they are largely incidental to deformation. Although a pulse of orogenic collapse and leucogranite crystallization occurred at 15–25 Ma, pervasive partial melts formed as much as 20 My earlier. Thus, leucogranites date extraction and transport, not necessarily melting onset. Extensional structures and distributed extensional strain occur in many rocks that lack partial melt and leucogranites, indicating these are not prerequisite to facilitate orogenic collapse. Most mass transfer appears to occur via thrusting, even in partially molten rocks.

KW - channel flow

KW - critical taper

KW - geothermometry

KW - Greater Himalayan Sequence

KW - partial melt

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U2 - 10.2138/gselements.20.6.381

DO - 10.2138/gselements.20.6.381

M3 - Article

AN - SCOPUS:85211180301

SN - 1811-5209

VL - 20

SP - 381

EP - 387

JO - Elements

JF - Elements

IS - 6

ER -

Himalayan Leucogranites: A Minimal Role in Deformation

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Keywords

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