Dating brittle tectonic movements with cleft monazite: fluid-rock interaction and formation of REE minerals

Alfons Berger; E. Gnos; E. Janots; M. Whitehouse; M. Soom; Robert Frei; Tod Earle Waight

doi:10.1002/tect.20071

Dating brittle tectonic movements with cleft monazite: fluid-rock interaction and formation of REE minerals

Alfons Berger, E. Gnos, E. Janots, M. Whitehouse, M. Soom, Robert Frei, Tod Earle Waight

Geology

19 Citations (Scopus)

Abstract

Two millimeter-sized hydrothermal monazites from an open fissure (cleft) that developed late during a dextral transpressional deformation event in the Aar Massif, Switzerland, have been investigated using electron microprobe and ion probe. The monazites are characterized by high Th/U ratios typical of other hydrothermal monazites. Deformation events in the area have been subdivided into three phases: (D₁) main thrusting including formation of a new schistosity, (D₂) dextral transpression, and (D₃) local crenulation including development of a new schistosity. The two younger deformational structures are related to a subvertically oriented intermediate stress axis, which is characteristic for strike slip deformation. The inferred stress environment is consistent with observed kinematics and the opening of such clefts. Therefore, the investigated monazite-bearing cleft formed at the end of D₂ and/or D₃, and during dextral movements along NNW dipping planes. Interaction of cleft-filling hydrothermal fluid with wall rock results in rare earth element (REE) mineral formation and alteration of the wall rock. The main newly formed REE minerals are Y-Si, Y-Nb-Ti minerals, and monazite. Despite these mineralogical changes, the bulk chemistry of the system remains constant and thus these mineralogical changes require redistribution of elements via a fluid over short distances (centimeter). Low-grade alteration enables local redistribution of REE, related to the stability of the accessory phases. This allows high precision isotope dating of cleft monazite. ²³²Th/²⁰⁸Pb ages are not affected by excess Pb and yield growth domain ages between 8.03 ± 0.22 and 6.25 ± 0.60 Ma. Monazite crystallization in brittle structures is coeval or younger than 8 Ma zircon fission track data and hence occurred below 280°C. Key Points Isotope dating of cleft monazite allow dating of brittle structures Monazite crystallization is coeval or younger than zircon fission track data

Original language	English
Journal	Tectonics
Volume	32
Issue number	5
Pages (from-to)	1176–1189
Number of pages	14
ISSN	0278-7407
DOIs	https://doi.org/10.1002/tect.20071
Publication status	Published - Sept 2013

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10.1002/tect.20071

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@article{796f60205ddc40eb9ac2257b3ee41222,

title = "Dating brittle tectonic movements with cleft monazite: fluid-rock interaction and formation of REE minerals",

abstract = "Two millimeter-sized hydrothermal monazites from an open fissure (cleft) that developed late during a dextral transpressional deformation event in the Aar Massif, Switzerland, have been investigated using electron microprobe and ion probe. The monazites are characterized by high Th/U ratios typical of other hydrothermal monazites. Deformation events in the area have been subdivided into three phases: (D1) main thrusting including formation of a new schistosity, (D2) dextral transpression, and (D3) local crenulation including development of a new schistosity. The two younger deformational structures are related to a subvertically oriented intermediate stress axis, which is characteristic for strike slip deformation. The inferred stress environment is consistent with observed kinematics and the opening of such clefts. Therefore, the investigated monazite-bearing cleft formed at the end of D2 and/or D3, and during dextral movements along NNW dipping planes. Interaction of cleft-filling hydrothermal fluid with wall rock results in rare earth element (REE) mineral formation and alteration of the wall rock. The main newly formed REE minerals are Y-Si, Y-Nb-Ti minerals, and monazite. Despite these mineralogical changes, the bulk chemistry of the system remains constant and thus these mineralogical changes require redistribution of elements via a fluid over short distances (centimeter). Low-grade alteration enables local redistribution of REE, related to the stability of the accessory phases. This allows high precision isotope dating of cleft monazite. 232Th/208Pb ages are not affected by excess Pb and yield growth domain ages between 8.03 ± 0.22 and 6.25 ± 0.60 Ma. Monazite crystallization in brittle structures is coeval or younger than 8 Ma zircon fission track data and hence occurred below 280°C. Key Points Isotope dating of cleft monazite allow dating of brittle structures Monazite crystallization is coeval or younger than zircon fission track data",

author = "Alfons Berger and E. Gnos and E. Janots and M. Whitehouse and M. Soom and Robert Frei and Waight, {Tod Earle}",

year = "2013",

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language = "English",

volume = "32",

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issn = "0278-7407",

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TY - JOUR

T1 - Dating brittle tectonic movements with cleft monazite

T2 - fluid-rock interaction and formation of REE minerals

AU - Berger, Alfons

AU - Gnos, E.

AU - Janots, E.

AU - Whitehouse, M.

AU - Soom, M.

AU - Frei, Robert

AU - Waight, Tod Earle

PY - 2013/9

Y1 - 2013/9

N2 - Two millimeter-sized hydrothermal monazites from an open fissure (cleft) that developed late during a dextral transpressional deformation event in the Aar Massif, Switzerland, have been investigated using electron microprobe and ion probe. The monazites are characterized by high Th/U ratios typical of other hydrothermal monazites. Deformation events in the area have been subdivided into three phases: (D1) main thrusting including formation of a new schistosity, (D2) dextral transpression, and (D3) local crenulation including development of a new schistosity. The two younger deformational structures are related to a subvertically oriented intermediate stress axis, which is characteristic for strike slip deformation. The inferred stress environment is consistent with observed kinematics and the opening of such clefts. Therefore, the investigated monazite-bearing cleft formed at the end of D2 and/or D3, and during dextral movements along NNW dipping planes. Interaction of cleft-filling hydrothermal fluid with wall rock results in rare earth element (REE) mineral formation and alteration of the wall rock. The main newly formed REE minerals are Y-Si, Y-Nb-Ti minerals, and monazite. Despite these mineralogical changes, the bulk chemistry of the system remains constant and thus these mineralogical changes require redistribution of elements via a fluid over short distances (centimeter). Low-grade alteration enables local redistribution of REE, related to the stability of the accessory phases. This allows high precision isotope dating of cleft monazite. 232Th/208Pb ages are not affected by excess Pb and yield growth domain ages between 8.03 ± 0.22 and 6.25 ± 0.60 Ma. Monazite crystallization in brittle structures is coeval or younger than 8 Ma zircon fission track data and hence occurred below 280°C. Key Points Isotope dating of cleft monazite allow dating of brittle structures Monazite crystallization is coeval or younger than zircon fission track data

AB - Two millimeter-sized hydrothermal monazites from an open fissure (cleft) that developed late during a dextral transpressional deformation event in the Aar Massif, Switzerland, have been investigated using electron microprobe and ion probe. The monazites are characterized by high Th/U ratios typical of other hydrothermal monazites. Deformation events in the area have been subdivided into three phases: (D1) main thrusting including formation of a new schistosity, (D2) dextral transpression, and (D3) local crenulation including development of a new schistosity. The two younger deformational structures are related to a subvertically oriented intermediate stress axis, which is characteristic for strike slip deformation. The inferred stress environment is consistent with observed kinematics and the opening of such clefts. Therefore, the investigated monazite-bearing cleft formed at the end of D2 and/or D3, and during dextral movements along NNW dipping planes. Interaction of cleft-filling hydrothermal fluid with wall rock results in rare earth element (REE) mineral formation and alteration of the wall rock. The main newly formed REE minerals are Y-Si, Y-Nb-Ti minerals, and monazite. Despite these mineralogical changes, the bulk chemistry of the system remains constant and thus these mineralogical changes require redistribution of elements via a fluid over short distances (centimeter). Low-grade alteration enables local redistribution of REE, related to the stability of the accessory phases. This allows high precision isotope dating of cleft monazite. 232Th/208Pb ages are not affected by excess Pb and yield growth domain ages between 8.03 ± 0.22 and 6.25 ± 0.60 Ma. Monazite crystallization in brittle structures is coeval or younger than 8 Ma zircon fission track data and hence occurred below 280°C. Key Points Isotope dating of cleft monazite allow dating of brittle structures Monazite crystallization is coeval or younger than zircon fission track data

U2 - 10.1002/tect.20071

DO - 10.1002/tect.20071

M3 - Journal article

SN - 0278-7407

VL - 32

SP - 1176

EP - 1189

JO - Tectonics

JF - Tectonics

IS - 5

ER -

Dating brittle tectonic movements with cleft monazite: fluid-rock interaction and formation of REE minerals

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