Fact-checked by Grok 2 weeks ago

Mylonite

Mylonite is a cohesive, fine-grained characterized by a well-developed schistosity resulting from tectonic reduction of , typically through dynamic recrystallization during intense ductile shearing in fault zones. It forms deep in the under conditions of high (300–800 °C) and pressure, where rocks undergo crystal-plastic deformation rather than brittle fracturing, leading to the pulverization and recrystallization of original minerals into tightly intergrown, smaller grains. The of mylonite is distinctly foliated and often lineated, with fine-scale and stretched alignments that reflect the of ; it may contain rounded porphyroclasts—surviving larger grains from the parent rock—embedded in a of recrystallized material. Formation occurs primarily in shear zones associated with folding, faulting, and tectonic processes like mountain building or plate , where the rock experiences cataclastic or dynamic , breaking down pre-existing while recrystallizing them into a smooth, hard fabric. Colors vary from grey to black depending on the composition of the , which can range from igneous to sedimentary rocks, resulting in highly variable . Mylonites play a crucial role in understanding tectonic history, as their kinematic indicators—such as foliation drag or asymmetric fabrics—reveal the sense and magnitude of deformation, aiding studies of and . They also serve as fluid conduits in the crust, facilitating mineralization and influencing seismic activity by loading overlying faults. Notable occurrences include the Paparoa Metamorphic Core Complex and in , as well as shear zones in the of . In practical terms, mylonite is utilized as aggregate in construction and road building due to its durability.

Overview

Definition

Mylonite is a fine-grained, foliated formed primarily through dynamic recrystallization during intense ductile shearing in shear zones. This process involves and tectonic reduction of , resulting in a cohesive rock with a distinctive fabric. According to the (IUGS), mylonite is defined as "a fault rock which is cohesive and characterized by a well developed schistosity resulting from tectonic reduction of , and commonly containing rounded porphyroclasts and lithic fragments of similar composition to in the matrix. Fine scale layering and an associated or stretching lineation are commonly present. Brittle deformation of some may be present, but deformation is commonly by crystal plasticity." Key characteristics include a compact , significant reduction in grain size due to deformation, and the development of a pronounced known as mylonitic fabric. The term "mylonite" was introduced by Charles Lapworth in 1885 to describe such rocks observed in the Moine Thrust Zone of the Scottish Highlands. Lapworth's observations highlighted the rock's milled appearance from shearing, distinguishing it from other fault rocks.

Physical Properties

Mylonite exhibits a distinctive fine-grained texture, with matrix grain sizes typically reduced to less than 0.1 mm through dynamic recrystallization, imparting a compact and often cherty or flinty appearance that can resemble porcelain or glass in hand specimen. This extreme grain size reduction is most pronounced in ultramylonites, where the rock achieves a uniform, dark, and hard quality due to intense shearing. A well-developed foliation is a hallmark feature, oriented parallel to the shear direction and resulting from the alignment of recrystallized minerals, which gives the rock a streaked or banded look on weathered surfaces. These macroscopic traits aid in field identification, as the rock often forms linear outcrops along fault zones. In terms of mechanical properties, mylonite demonstrates high , enabling significant plastic deformation under without widespread fracturing, which is evident in its ability to accommodate large strains through crystal-plastic mechanisms. The rock is generally hard, with resistance to scratching varying based on its mineral composition, and it shows good resistance to due to its dense, recrystallized structure that limits fluid penetration. Optical properties under magnification reveal a silky or waxy luster in thin sections, but in bulk, the rock's streak is typically white, reflecting its dominant and components. A key distinction from cataclasites lies in mylonite's formation via ductile recrystallization, producing equidimensional or polygonal grains with sutured boundaries, in contrast to the angular, fractured grains characteristic of brittle deformation in cataclasites. This recrystallization process enhances mylonite's and compared to the more friable cataclasites.

Petrology and Mineralogy

Common Minerals

Mylonites typically exhibit mineral assemblages dominated by and , with micas such as and playing key roles in fabric development, alongside accessory minerals like or depending on the composition. often forms the matrix through dynamic recrystallization, producing elongated ribbons that contribute to the rock's linear fabric and enhance overall during deformation. , particularly and K-feldspar, commonly appears as porphyroclasts—larger, rounded grains that resist full recrystallization and fracture brittlely, creating and structures indicative of sense. Micas, including and , align parallel to the plane, promoting its development through slip and reaction softening, which localizes strain in weak layers. Accessory minerals such as occur in mafic-influenced compositions, where they fragment and contribute to foliated aggregates, while appears in pelitic variants as porphyroblasts that preserve pre-deformational textures. Phyllosilicates like micas are particularly influential in fabric evolution, as their preferred orientation defines the mylonitic and facilitates rheological weakening. In mica-rich variants known as phyllonites, these minerals dominate the matrix, intensifying the planar fabric. Mineral assemblages in mylonites vary according to the , reflecting inherited compositions modified by deformation. Granitic mylonites are typically quartz-rich with abundant porphyroclasts and biotite-muscovite matrices, derived from plutonic precursors. In contrast, metasedimentary mylonites from calcareous feature dominant , often recrystallized into fine-grained, elongated crystals that form a ductile , with minor or . These variations influence the resulting fabric, with quartz- systems favoring ribbon-like structures and calcite-dominated ones promoting homogeneous flow.

Protoliths and Compositional Variations

Mylonite forms through intense ductile deformation of a variety of rocks, which can be igneous, sedimentary, or pre-existing metamorphic types. Common igneous protoliths include , , and , which are typically quartzofeldspathic in composition and undergo significant grain size reduction during ing. Sedimentary protoliths such as , , and dolostone also contribute, with quartz-rich sandstones producing mylonites dominated by recrystallized ribbons, while carbonate rocks like limestone yield finer-grained, calcite-rich varieties. Metamorphic protoliths, including derived from earlier limestones, further diversify the range, as these rocks enter shear zones already altered by prior . The compositional spectrum of mylonites reflects that of their protoliths, spanning from silicic quartzofeldspathic end-members to more or pelitic variants. Silicic protoliths, such as granites or arkosic sandstones, result in mylonites rich in and , which promote plastic deformation through mechanisms like dislocation creep, leading to well-developed and reduced rock strength. compositions, often from gabbroic intrusions, produce rarer mylonites under greenschist facies conditions, characterized by localized strain and or porphyroclasts, though these exhibit less pervasive fabric development due to higher rigidity. Pelitic protoliths, typically shales or mudrocks high in aluminosilicates, generate micaceous mylonites or phyllonites with abundant and , enhancing ductility via slip and resulting in finer, more aligned fabrics. These compositional differences directly influence the deformability and resulting mylonite characteristics; for instance, quartz-rich silicic facilitate stronger, more coherent fabrics through dynamic recrystallization, whereas pelitic varieties develop micaceous alignments that accommodate more readily, often leading to ultramylonitic textures in high-strain zones. In cases, the higher limits widespread mylonitization, confining deformation to narrow bands. Such variations underscore how protolith chemistry controls the mechanical response to tectonic , without significant alteration of bulk during mylonitization in most settings.

Formation

Tectonic Settings

Mylonites primarily form in ductile zones within , where intense is localized during regional deformation events. Examples include the Himalayan , where mylonitization occurs along structures like the South Tibetan Detachment and the Panjal Thrust, and the Sanandaj-Sirjan Zone in , associated with between the Arabian and Iranian plates. These settings involve syn-orogenic processes that lead to crustal thickening and dynamothermal . They also develop in fault zones at mid-crustal depths, such as the Woodroffe and Thrusts in the Musgrave Ranges, , where mylonitic deformation affects high-grade gneisses and granulites over widths up to 1 km. In these environments, mylonites mark the transition from brittle faulting in the upper crust to distributed ductile flow at depth. faults represent another key primary setting, particularly in extensional regimes, as exemplified by the mylonite zone beneath the northern Snake Range décollement in the . In terms of , mylonites are closely linked to convergent margins, where they form during and subsequent collision, as in the Neotethys-related deformation in the Sanandaj-Sirjan Zone. Transcurrent faults, such as dextral strike-slip systems in the same zone, host mylonites along NW-SE trending shear zones during transpressional regimes. Extensional core complexes, driven by continental rifting, further associate mylonites with low-angle normal faults that exhume ductilely deformed footwalls. These tectonic environments typically involve confining pressures of 200–600 MPa and temperatures ranging from 300–700°C, conditions that promote ductile behavior under greenschist to amphibolite facies metamorphism at depths of 10–20 km. This range corresponds to the brittle-ductile transition in the crust, where mylonites serve as indicators of mid-crustal deformation loci.

Deformation Mechanisms

Mylonite develops primarily through crystal-plastic deformation mechanisms that accommodate ductile strain in the lower crust or upper mantle, where high temperatures and confining pressures suppress brittle failure. These mechanisms include dislocation creep, diffusion creep, and grain-boundary sliding, which collectively reduce grain size and develop a strong foliation under sustained shear. Dislocation creep dominates in coarser-grained mylonites, involving the glide and climb of within mineral lattices, often leading to hardening that is relieved by dynamic recrystallization. This produces lattice preferred orientations (LPOs) and subgrain formation, particularly in and , at temperatures exceeding 400°C. In finer-grained ultramylonites, and grain-boundary sliding become prevalent, enabling viscous flow without strong LPOs, as grain boundaries act as pathways for atomic . Grain-boundary sliding is often accommodated by dislocation motion at triple junctions, facilitating superplastic-like deformation in polymineralic aggregates. Dynamic recrystallization is central to mylonite evolution, occurring via subgrain rotation, where low-angle boundaries evolve into high-angle grain boundaries, or grain-boundary migration, which sweeps dislocations into less deformed regions to form strain-free grains. Bulging recrystallization may initiate at lower temperatures, producing small, irregular grains along porphyroclast margins. These processes progressively reduce from millimeters to micrometers, enhancing . The transition from cataclasis to mylonitization reflects a shift from brittle fracturing in shallower, cooler conditions to ductile flow at greater depths, where cataclastic deformation overprints early mylonitic fabrics during uplift. Mylonitization requires high confining pressures, typically around 300–400 , to promote intracrystalline over . Deformation in mylonites occurs at low strain rates of approximately 10^{-14} to 10^{-12} s^{-1}, consistent with tectonic processes in continental shear zones at crustal depths of 10–20 km. These rates, combined with temperatures of 300–700°C, allow for prolonged shear localization and fabric .

Classification

Textural Types

Mylonites are categorized into textural types primarily based on the proportion of fine-grained relative to relict porphyroclasts and the extent of grain size , which reflect increasing intensity of ductile deformation in shear zones. This emphasizes the progressive of a foliated through mechanisms such as dynamic recrystallization and cataclasis, serving as indicators of deformation progression. Protomylonites represent the initial stage of mylonitization, characterized by less than 50% fine-grained matrix, where relict porphyroclasts from the remain dominant and original textures are partially preserved. In these rocks, deformation is evident through minor and sigma structures around porphyroclasts, but the matrix grains are coarser (>10 μm), indicating limited reduction. The predominance of porphyroclasts, often exceeding 50% of the rock volume, highlights the transitional nature from undeformed to more intensely sheared mylonites. Mylonites, sometimes subdivided into mesomylonites for intermediate forms, feature 50-90% fine-grained , with a between relict porphyroclasts and newly recrystallized grains that define a well-developed . The typically consists of equidimensional grains around 1-10 μm in size, resulting from moderate dynamic recrystallization, while porphyroclasts (10-50% volume) exhibit and asymmetric tails indicative of sense. This textural equilibrium underscores the peak of balanced brittle-ductile deformation processes in many shear zones. Ultramylonites exhibit extreme deformation, with over 90% fine-grained and minimal porphyroclasts, leading to a cherty or glassy appearance due to pervasive grain size reduction to sub-micrometer scales (<1 μm). The rock's uniform, streaky foliation arises from intense shear, where most original grains are obliterated, and the dominates with minimal visible porphyroclasts (<10% volume). Such textures often form in the cores of high-strain shear zones, where grain thresholds signal advanced deformation intensity. Blastomylonites develop under conditions where extensive dynamic recrystallization and neomineralization accompany deformation, producing a coarse, sugary texture with minimal tectonic banding and prominent ribbon-like quartz aggregates. Unlike standard mylonites, these rocks show significant post-deformational grain growth, resulting in larger matrix grains (up to 0.25 mm) and a less pronounced foliation, often in quartz-rich compositions. This variant highlights the role of metamorphic reactions in modifying mylonitic fabrics during prolonged shearing.

Compositional Variants

Mylonites exhibit a range of compositional variants that reflect the mineralogical and chemical characteristics of their protoliths, influencing their deformation behavior and fabric development. These variants are distinguished primarily by dominant mineral phases rather than degree of textural reduction. Phyllonites represent a subtype of mylonite characterized by a high abundance of phyllosilicates, typically exceeding 50% by volume, which imparts a schistose fabric and enhanced ductility. This composition arises from protoliths rich in clay minerals, such as pelitic metasediments or slates, where intense shearing promotes the alignment and neocrystallization of fine-grained muscovite, chlorite, and biotite within a quartz matrix. Key microstructural features include pervasive foliation defined by oriented phyllosilicates and evidence of crystal-plastic deformation, such as undulose extinction in quartz grains. Augen mylonites are defined by the presence of large, eye-shaped porphyroclasts, or augen, primarily composed of feldspar, embedded in a finer-grained, recrystallized matrix. These structures form from granitic or granitoid protoliths, where resistant feldspar crystals undergo partial flattening and rotation during ductile shear, while the surrounding quartz and biotite matrix undergoes dynamic recrystallization to produce fluxion banding. The augen, often several millimeters to centimeters in length, serve as kinematic indicators, with asymmetric tails revealing shear sense, and the overall fabric highlights the contrast between competent porphyroclasts and the ductile matrix. Calc-mylonites are carbonate-dominated mylonites, comprising 70-90% calcite, derived from limestone or calcareous metasedimentary protoliths such as Paleozoic strata. Deformation in these rocks features prominent twinning in calcite grains, alongside dynamic recrystallization that reduces grain sizes to 4-30 micrometers, fostering strong crystallographic preferred orientations with c-axes perpendicular to the foliation plane. Associated minerals may include minor quartz, dolomite, or siliceous phases from interbedded protoliths, and the fabric often records simple shear parallel to regional detachments, with synkinematic veining enhancing localization. Mafic mylonites develop from basaltic or gabbroic protoliths, resulting in rocks enriched in mafic minerals such as amphibole (e.g., actinolite) and relict pyroxene, alongside plagioclase (albite) and epidote. These variants exhibit fine-grained matrices (10-20 micrometers) formed through diffusion creep and grain-boundary sliding, with amphibole displaying strong crystallographic preferred orientations that define the stretching lineation. Protoliths like metabasalts undergo greenschist-facies overprinting, leading to hydration and weakening, as seen in rift-related shear zones where mafic layers accommodate distributed strain.

Microstructure

Fabrics and Textures

Mylonitic fabrics at the microscopic scale are characterized by pervasive foliation and lineation resulting from intense ductile deformation in shear zones. The primary fabric elements include S-planes, which represent the main foliation defined by aligned, elongated mineral aggregates such as quartz and feldspar, and C-planes, which are discrete shear bands or surfaces of concentrated slip that intersect the S-planes at acute angles, forming characteristic S-C fabrics indicative of non-coaxial shear. Lineations arise from the elongation of minerals, particularly quartz and feldspar, parallel to the direction of maximum shear, often plunging at moderate angles and aligning with the overall transport direction in the shear zone. Distinctive textures in mylonites include sigma (σ) and delta (δ) porphyroclasts, which are rigid, larger crystals or clasts of or surrounded by finer-grained, recrystallized matrix tails that display asymmetric shapes due to differential rotation and strain, with σ types showing more continuous tails and δ types exhibiting wing-like extensions.90056-9) consist of elongated, ribbon-like aggregates of dynamically recrystallized grains that define the foliation and contribute to lineation, often showing oblique grain-shape preferred orientations relative to the shear direction.90160-2) are lozenge-shaped porphyroclasts of white (muscovite or ) embedded in a finer matrix, with asymmetric tails formed by pressure shadows or dragged foliation, commonly aligned parallel or oblique to the C-planes.00231-2) These fabrics and textures typically develop under plane strain conditions in ductile shear zones, where the finite strain ellipsoid exhibits no significant shortening perpendicular to the shear plane, resulting in a well-developed foliation that lies parallel to the XY plane of the strain ellipsoid and the shear plane itself. Such elements, observable in thin sections, also function as kinematic indicators for determining shear sense in mylonites.

Grain Size Reduction Processes

Grain size reduction is a fundamental process in the formation of mylonites, transforming coarse-grained protoliths into fine-grained rocks through intense ductile deformation under high strain rates and temperatures typically in the range of 250–700°C. This reduction enables strain localization and weakening, as smaller grains promote diffusion-based deformation mechanisms over dislocation creep. The primary mechanisms driving grain size reduction include pressure solution, intragranular fracturing, and dynamic recrystallization. Pressure solution involves the dissolution of mineral material at grain boundaries under differential stress, leading to mass transfer and progressive grain boundary migration that refines grain size. Intragranular fracturing creates microcracks within grains, fragmenting larger crystals into smaller fragments that serve as nuclei for further refinement, particularly in feldspar-rich compositions. Dynamic recrystallization, often through subgrain rotation or bulging, subdivides porphyroclasts into equidimensional new grains, significantly decreasing average grain diameters. These processes commonly reduce grain sizes to 10–50 μm, a scale observed in quartz and other matrix minerals within mylonitic shear zones. Fluids play a critical role in enhancing these mechanisms by facilitating diffusion and promoting dissolution-precipitation creep, where dissolved ions are transported and reprecipitated to form finer-grained aggregates, accelerating overall reduction. Over progressive deformation, the rock evolves from a protolith with coarse grains (>100 μm) to a -dominated texture, where the fine-grained constitutes the majority of the volume. In ultramylonites, this exceeds 90% of the rock, with porphyroclasts comprising less than 10%, marking extreme localization. This textural evolution contributes to the development of characteristic mylonitic fabrics, such as S-C structures, through ongoing refinement.

Geological Significance

Kinematic Indicators

Kinematic indicators in mylonites are microstructural and mesostructural features that reveal the direction and sense of tectonic , primarily through their asymmetric geometries developed during non-coaxial deformation. These indicators assume a dominance of simple within the , where displacement occurs parallel to the mylonitic foliation and stretching lineation, allowing inference of the vector and overall flow . Asymmetric porphyroclasts, relic grains larger than the surrounding matrix, serve as key indicators via their recrystallized tails, classified into sigma (σ) and delta (δ) types based on tail geometry and symmetry. Sigma-type porphyroclasts feature wedge-shaped or stair-stepping tails that step in the direction of shear, indicating top-to-the-right or top-to-the-left sense depending on the observed asymmetry when viewed in sections perpendicular to the lineation; δ-types show narrow, bent tails crossing a reference plane, similarly revealing shear sense through tail curvature and embayments. These structures form under simple shear conditions, with tail development controlled by the ratio of recrystallization rate to shear strain rate, and their consistency with other indicators reaches up to 95% in homogeneous fabrics. C/S fabrics, consisting of schistosity (S) planes defined by aligned minerals and shear (C) planes as discrete slip surfaces, provide robust evidence of shear sense as C planes obliquely transect S planes in a consistent direction. In top-to-the-right shear, C planes rotate clockwise relative to S, forming an acute angle (typically 15–30°) that back-rotates the foliation; the opposite occurs for top-to-the-left shear. These fabrics develop in type II S-C mylonites during progressive simple shear, where S relates to finite strain and C to incremental displacement, and are best observed in mica-rich or phyllonitic variants. Shear bands, including C' and antithetic types, act as localized extensional features that offset the at low (20–45°), with synthetic bands indicating the dominant sense—e.g., top-to-the-right when bands in that direction and offset markers accordingly. Under simple assumptions, these bands form conjugate sets or single synthetic arrays parallel to the plane, though their reliability decreases in zones with boundary-parallel anisotropies deviating from pure simple . Analysis of these indicators involves thin-section microscopy to examine orientations and asymmetries in planes normal to the lineation and parallel to the , combined with field measurements of foliation-lineation geometry to construct ellipsoids and infer overall . These methods, often corroborated by c-axis fabrics from the mylonite's textural development, enable reconstruction of the shear zone's tectonic transport direction without requiring advanced instrumentation.

Rheological and Geochronological Implications

Mylonites serve as key indicators of rheological behavior in the , particularly in ductile shear zones where deformation occurs under conditions of high and . These rocks form in regions of localized , exhibiting low due to grain-size sensitive mechanisms, such as and , which dominate in fine-grained matrices. This results in mylonites acting as weak zones that accommodate a significant portion of tectonic , often channeling displacement in continental margins. For quartz-rich mylonites, the flow behavior is commonly described by a power-law equation of the form \dot{\epsilon} = A \sigma^n \exp(-Q/RT), where \dot{\epsilon} is the rate, \sigma is the differential , A is a material constant, n is the exponent (typically 3-5 for ), Q is the , R is the , and T is ; this formulation highlights how mylonites facilitate enhanced at rates of $10^{-12} to $10^{-14} s^{-1}. Geochronological studies of mylonites provide critical insights into the timing and duration of deformation events, enabling reconstruction of tectonic histories. Direct dating methods include U-Pb on accessory minerals like and , which record crystallization or recrystallization during mylonitization, and ^{40}Ar/^{39}Ar dating on white mica phases such as and , which capture cooling through argon closure temperatures around 350-450°C. These techniques have been refined to account for partial resetting during protracted deformation, allowing resolution of mylonite evolution over millions of years. Recent advances , such as in-situ U-Pb dating of pseudotachylytes in mylonites from the , have provided new constraints on the timing of deformation and associated seismic events. The rheological properties and geochronological records of mylonites have profound implications for understanding crustal dynamics, including strain localization that promotes the development of narrow zones and influences overall plate motion. As strain accumulates, mylonites can mark the from ductile to brittle failure at depths of 10-15 km, where increasing leads to faulting and potential . This is vital for assessment, as mylonite zones often underlie major fault systems, providing proxies for rupture propagation and long-term slip rates in regions like the system.

Occurrences

Major Examples

One of the classic examples of mylonite formation is found in the Moine Thrust Zone of northwest , where it represents a key component of the during the Silurian-Devonian period. This zone features a progressive sequence of fault rocks, transitioning from protomylonites with preserved original fabrics and minor shear strain, through mylonites with significant grain size reduction and foliation development, to ultramylonites exhibiting extreme strain localization and matrix-supported porphyroclasts. These mylonites developed under greenschist to amphibolite facies conditions, recording the northwest-directed thrusting of Moine Supergroup metasediments over foreland Lewisian gneisses and Torridonian sandstones, with total displacement estimates exceeding 100 km. The mylonitic fabrics, including S-C structures, indicate a consistent top-to-the-northwest sense of shear throughout the deformation history. In the system of , mylonites occur in the deeper ductile roots, particularly within exhumed shear zones like the Eastern Peninsular Ranges Mylonite Zone and the Santa Rosa Mylonite Zone. These mylonites, which formed primarily during the and were subsequently incorporated into the fault system highlighting long-term strike-slip motion since the , derived from granitic and metamorphic protoliths, display intense , dynamic recrystallization, and porphyroclastic textures that record dextral shear strains of up to several hundred percent, transitioning upward into brittle cataclasites at shallower levels. The ductile deformation, occurring at depths of 10-20 km and temperatures of 500-700 °C, accommodates the ongoing transform boundary between the Pacific and North American plates, with mylonitic fabrics preserving evidence of strain localization along narrow shear bands. This progression from ductile mylonite formation to brittle faulting underscores the fault's vertical rheological stratification. The Oman Mountains host prominent mylonites associated with the Semail Ophiolite, formed during the Late Cretaceous obduction of oceanic crust onto the Arabian continental margin. These mylonites, particularly in the basal shear zones and metamorphic sole, include mafic variants such as amphibolite-grade mylonites derived from gabbroic and basaltic protoliths, exhibiting fine-grained recrystallized matrices, stretched amphibole and plagioclase porphyroclasts, and well-developed foliation parallel to the obduction direction. The deformation involved high-strain top-to-the-southeast thrusting, with temperatures reaching 800-900°C near the ophiolite base, cooling rapidly during emplacement over ~100 km. Mafic mylonites in the Samail Thrust highlight the role of hydration and weakening in facilitating ophiolite obduction, contrasting with more siliceous mylonites in the underlying continental margin sequences. Extensional mylonites are well exemplified by the South Tibetan Detachment system in the , a series of low-angle normal faults active since the that accommodated ~100-200 km of north-south extension atop the orogenic wedge. In zones like the and segments, these mylonites form ductile shear zones in leucogranites and metasediments, characterized by top-to-the-north sense of shear, asymmetric fabrics such as sigma clasts, and reduction to sub-micron scales under to conditions at depths of 10-15 km. The mylonites overlie the Greater Himalayan Crystalline complex and underlie Tibetan sedimentary sequences, with kinematic indicators like C'-shears confirming normal faulting that exhumed mid-crustal rocks during post-collisional collapse. This detachment system facilitated rapid uplift and cooling of the High , integrating within a compressional orogen.

Recent Research

Recent microstructural studies have revealed novel features in ultramylonites, such as strain shadow megapores that form synkinematically around porphyroclasts, providing transient reservoirs for fluids that enhance the granular fluid pump mechanism during deformation. These megapores, observed via three-dimensional in mid-crustal samples, can reach volumes exceeding 50,000 μm³ and facilitate localized fluid transfer, addressing previous gaps in understanding development in high-strain environments. Experimental investigations into micaceous mylonites have further elucidated their , demonstrating that high strains lead to phase mixing and grain size reduction through dynamic recrystallization, transitioning from interconnected layers to fine-grained ultramylonitic matrices that significantly lower rock . Advancements in have enabled direct dating of mylonitic overprinting events, particularly in zones along NE-SW trending boundaries, where multi-isotope analyses of mylonites reveal partial resetting of pre-existing isotopic signatures during deformation. In the Moine Thrust region, updated U-Pb of accessory phases in mylonites indicates fluid-assisted alteration and multiple metamorphic episodes, integrating inductively coupled plasma mass spectrometry with petrographic data to constrain deformation timings from breakup onward. These multi-method approaches have resolved age ambiguities in shear zones, linking mylonite formation to specific tectonic phases. Extensions of the Hyndman hypothesis in 2025 have refined models of thermal controls on megathrust rupture limits, incorporating mylonitic fabrics to delineate updip boundaries at ~100–150°C where transitions occur, and downdip limits influenced by serpentinization in the mantle wedge. Studies on pseudotachylyte-mylonite transitions highlight their role in interseismic , where mylonites formed during ductile are overprinted by frictional melts during coseismic rupture, as evidenced by microstructural overprinting in fault rocks. These findings address key gaps through (EBSD) integration for quantitative fabric analysis, revealing crystallographic preferred orientations that quantify strain partitioning in mylonites. Recent subduction models further emphasize fluid roles, with of subducted sediments generating fluids that weaken mylonitic shear zones via hydrofracturing, influencing and element mobility.

References

  1. [1]
    mylonite
    IUGS definition of mylonite: "Fault rock that is cohesive and characterized by a well-developed schistosity resulting from tectonic reduction of grain size, ...
  2. [2]
    Mylonite - Geology - rocks and minerals - University of Auckland
    Mylonite is a metamorphic rock formed by ductile deformation during intense shearing encountered during folding and faulting.Missing: definition | Show results with:definition
  3. [3]
    Features from the Field: Shear Zones and Mylonites - EGU Blogs
    Jan 25, 2021 · Inside a shear zone, deformation forms spectacular well foliated, deformed and commonly lineated rocks called mylonite. The term mylonite comes ...
  4. [4]
    Types of Metamorphism
    Apr 12, 2018 · Mylonites: Mylonites are cataclastic metamorphic rocks that are produced along shear zones deep in the crust. They are usually fine-grained, ...
  5. [5]
    [PDF] 5. Structural terms including fault rock terms
    The definitions presented are systematic and general. As might be expected, mylonite proved difficult to define. Since its original definition by. Lapworth ...
  6. [6]
    [PDF] Cataclastic Rocks - USGS Publications Warehouse
    In his definition of mylonite, Lapworth (1885, p. 559 see p. 7 this paper), referred to secondary crystals of quartz and mica in mylonites, and noted that the.
  7. [7]
    Mylonite - ALEX STREKEISEN
    A mylonite is a foliated and usually lineated rock that shows evidence for strong ductile deformation and normally contains rounded porphyroclasts and lithic ...
  8. [8]
    [PDF] The geometry and microstructure of a range of QP-mylonite zones
    The most easily measured of th dynamically recrystallized grainsize, a dynamic recrystallization in the QP reg grainsize refinement in mylonites, Whit. 1973 ...
  9. [9]
    Properties of Mylonite | Physical | Thermal - Compare Rocks
    The hardness of Mylonite is 3-4 whereas its compressive strength is 1.28 N/mm2. Streak is the color of rock when it is crushed or powdered. The streak of ...Missing: ductility | Show results with:ductility
  10. [10]
    [PDF] Introduction to Faults (PDF) - Find People
    Their polygonal to sutured grain boundaries differ from fine-grained cataclasites, in which the grains. have the sharp, angular shape characteristic of brittle ...
  11. [11]
    [PDF] From tonalite to mylonite: coupled mechanical and chemical ...
    Abstract: Microstructural and chemical processes interacted in the transformation of a hornblende- biotite tonalite to a mylonite in an approximately 28-m ...
  12. [12]
    Mineralogy, petrology and microfabric analysis of the Eilrig Shear ...
    The mylonites and garnet-phyllonites define a previously undescribed major ductile shear zone, here referred to as the Eilrig Shear Zone, which has an ...
  13. [13]
    Petrophysical properties of a granite-protomylonite-ultramylonite ...
    Mar 13, 2015 · The results show that the degree of deformation of mylonitic rocks can be characterized by petrophysical properties, in order to shed light on ...Missing: Mohs | Show results with:Mohs
  14. [14]
    Dating mylonitic overprinting of ancient rocks - Nature
    Feb 23, 2023 · Biotite and muscovite are generally oriented parallel to the mylonitic foliation and well-developed S/C structures, linking them to shearing ...
  15. [15]
    BGS Rock Classification Scheme - Details forMylonitic-rock
    Other minerals, for example feldspar and garnet, may resist ductile deformation or fracture in a brittle manner and remain significantly larger than the ...<|control11|><|separator|>
  16. [16]
    Mylonite - an overview | ScienceDirect Topics
    Mylonite is defined as a fine-grained, partially recrystallized metamorphic rock formed by dynamic recrystallization under intense shearing during ...Missing: resistance | Show results with:resistance
  17. [17]
    [PDF] Insights from the Kuckaus Mylonite Zone, Namibia - -ORCA
    Aug 1, 2020 · 4.1. Wall Rocks and Protomylonites. The different protoliths contain feldspar, quartz, biotite, muscovite, chlorite, amphi- bole, and accessory ...
  18. [18]
    The role of calcite-rich metasedimentary mylonites in localizing ...
    Jan 30, 2018 · A marble mylonite sample from the southwestern end of the core complex records an average calcite grain size of ∼125 µm. As in all other parts ...
  19. [19]
    Calcite mylonites in the Central Alpine “root zone” - ResearchGate
    Aug 6, 2025 · Progressive mylonitization—by dynamic recrystallization—results in a microstructure with elongated calcite crystals (long axis 20–50 μm, axial ...
  20. [20]
    https://www.sciencedirect.com/science/article/pii/B9780128205853000077
  21. [21]
    [PDF] gsa today - Geological Society of America
    Mylonite was first defined by Lapworth (1885) from his observations along the Moine and Arnabol thrusts in. Scotland. Many geologists since have considered ...
  22. [22]
    Metamorphic Rocks - ALEX STREKEISEN
    Metamorphism is a process involving changes in a rock's mineral content/composition and/or microstructure, mainly in the solid state.Missing: silicic | Show results with:silicic
  23. [23]
    https://www.sciencedirect.com/science/article/pii/B9780444538024001196
  24. [24]
    https://doi.org/10.1134/S001685211603002X
  25. [25]
    https://doi.org/10.1029/2009TC002632
  26. [26]
    Estimates of stress and strain rate in mylonites based on the ...
    Mar 20, 2012 · A transition in the dominant deformation mechanism from dislocation creep to grain-boundary sliding (GBS) occurred between mylonites and ...
  27. [27]
    Rheology, deformation mechanisms, and mylonites
    Grain-boundary diffusion or Coble Creep. Crystal changes shape by migration of atoms along grain boundaries. This works better at small grain sizes because the ...Missing: plastic | Show results with:plastic
  28. [28]
    Dynamic recrystallization of quartz: correlation between natural and ...
    The resulting dynamic recrystallization microstructures are characteristic of bulging recrystallization, subgrain rotation recrystallization and grain boundary ...
  29. [29]
    [PDF] Estimates of the rates of microstructural changes in mylonites
    strain-rates of 10 10 s-~ and 10 -12 s -1 respec- tively using the rates calculated for decreasing differential stress and strain rate. These esti- mated ...
  30. [30]
    https://www.sciencedirect.com/science/article/pii/B9780124095489090497
  31. [31]
    BGS Rock Classification Scheme - Details forBlastomylonite
    A type of mylonitic-rock. Blastomylonites are formed where extensive recrystallisation and mineral growth accompanied deformation.
  32. [32]
    Phyllonite - an overview | ScienceDirect Topics
    Phyllite is defined as a type of metamorphic rock characterized by a fine-grained texture and a foliation that is primarily composed of quartz and muscovite, ...
  33. [33]
    The nature and importance of phyllonite development in crustal ...
    Phyllonites potentially play a key role in facilitating long-term weakening along crustal-scale faults.Missing: definition geology
  34. [34]
    6 Metamorphic Rocks – An Introduction to Geology - OpenGeology
    Mylonites are metamorphic rocks created by dynamic recrystallization caused by directed shear forces. During mylonitization, mineral grains are commonly ground ...
  35. [35]
    Calcite fabric development in calc-mylonite during progressive ...
    Feb 9, 2024 · Calcite fabric development in calc-mylonite during progressive shallowing of a shear zone: An example from the South Tibetan Detachment system ( ...
  36. [36]
    Slow‐to‐Fast Deformation in Mafic Fault Rocks on an Active Low ...
    Oct 1, 2020 · One effect of dissolution of epidote and actinolite was bleaching of the foliated cataclasite relative to the mafic mylonite from which it was ...
  37. [37]
    [PDF] Transforming eclogite into mafic mylonite (Songshugou, Qinling Belt ...
    The mafic mylonite shows amphibole-rich cleavage domains and stretched ribbons of plagioclase with minor am- phibole and clinozoisite. The principle results ...
  38. [38]
    https://doi.org/10.1016/0191-8141(89)90035-7
  39. [39]
    https://doi.org/10.1016/j.jseaes.2016.10.002
  40. [40]
    https://doi.org/10.1029/2004TC001643
  41. [41]
    Ultramylonite generation via phase mixing in high‐strain experiments
    Feb 7, 2017 · Mylonitization is characterized by the reduction of grain-size, typically via dynamic recrystallization, and is also associated with the ...
  42. [42]
    [PDF] Grain size reduction by dynamic recrystallization - MIT
    Abstract It is widely believed that grain size reduc- tion by dynamic recrystallization can lead to major rheological weakening and associated strain local-.
  43. [43]
    Fluid-assisted grain size reduction leads to strain localization in ...
    Jul 10, 2023 · Grain size reduction during deformation is enhanced by dissolution of coarser pyroxene grains in presence of fluid and contextual precipitation ...
  44. [44]
    [PDF] Brittle grain-size reduction of feldspar, phase mixing and strain ...
    Mar 9, 2016 · Extensive grain-size reduction and weakening of feldspars is attained in the East Pernambuco mylonites mainly via fracturing which would trigger ...
  45. [45]
    Evidence for dominant grain-boundary sliding deformation in ...
    For a grain size range of about 10–50 μm commonly observed in natural ultramylonites, the deformation maps predict that diffusion-controlled creep is dominant ...
  46. [46]
    None
    ### Summary of Kinematic Indicators in Shear Zones and Mylonites
  47. [47]
    [PDF] Porphyroclast systems as kinematic indicators - Tectonophysics
    A porphyroclast system in a mylonite develops when the relatively weak dynamically recrystallized grain aggregate in the porphyroclast mantle changes its shape ...
  48. [48]
    S-C Mylonites - ScienceDirect.com
    S-C mylonites have S-surfaces related to finite strain and C-surfaces related to displacement. Type II S-C mylonites have mica trails and oblique foliations.
  49. [49]
    Orthogneiss, mylonite and non coaxial deformation of granites
    Orthogneiss, mylonite and non coaxial deformation of granites: the example of the South Armorican Shear Zone. Author links open overlay panel. D. Berthé
  50. [50]
    [PDF] A precautionary note on shear bands as kinematic indicators
    A mylonitic foliation is developed parallel to the contact of the tectonic com- plexes, and a variably strong stretching lineation trends. SE-NW in the ...
  51. [51]
    Unifying structural, kinematic, and textural analysis in ...
    Feb 6, 2019 · During asymmetric shearing, mylonites develop microstruc- tures that reflect the conditions of deformation and shear zone kinematics, in-.
  52. [52]
    Fault Rocks of the Moine Thrust Zone: A Guide to Their Nomenclature
    Aug 5, 2025 · The sequence, with increasing shear strain is country rock–protomylonite–blastomylonite–mylonite–ultramylonite if the rock has a well developed ...Missing: ultramylonites | Show results with:ultramylonites
  53. [53]
    Deformation temperatures, vorticity of flow and strain symmetry in ...
    Aug 5, 2025 · The Moine Thrust zone (MTZ) marks the Caledonian foreland-to-hinterland transition zone at the base of the Scandian (c. 430 Ma) orogenic wedge.
  54. [54]
    [PDF] Some characteristics of the eastern Peninsular Ranges mylonite zone
    and water of the Gulf of California. Live faults of the San Andreas system, particularly two strands of the to fault zone dextrally offset the mylonite belt, ...
  55. [55]
    [PDF] Deformation of mylonites in Palm Canyon, California, based on ...
    Rosa mylonites was produced in flattening, during emplacement of the partially solidified batholith. The large. deformation may have produced folds that have ...
  56. [56]
    (PDF) Strain localization along the San Andreas Fault - ResearchGate
    Aug 10, 2025 · ... deformation operate in ductile shear zones with the production of mylonite series rocks possessing strong tectonite fabrics. In some cases, ...
  57. [57]
    (PDF) Tectonic setting, origin, and obduction of the Oman ophiolite
    Aug 6, 2025 · The Semail ophiolite in the Oman Mountains is the world's largest and best preserved thrust sheet of oceanic crust and upper mantle.Missing: variants | Show results with:variants
  58. [58]
    (PDF) Texture and Shape Analysis of Quartzite Mylonites of the ...
    Oct 15, 2025 · The Oman Mountains formed by late Cretaceous obduction of the Tethys-derived Semail Ophiolite. This study concerns the postobductional ...Missing: variants | Show results with:variants
  59. [59]
    Structural and Thermal Evolution of an Infant Subduction Shear Zone
    Beneath the Samail Ophiolite in Oman, metamorphic sole rocks crop out as discontinuous lenses along its entire ∼550 km length (Figure 1). In this study, we ...Missing: variants | Show results with:variants
  60. [60]
    [PDF] USGS Open-File Report 2010-1099, Tripathi
    The South Tibetan Detachment (STD) is a system of low-angle normal faults that separates the High. Himalayan Crystallines from metasedimentary rocks of the ...
  61. [61]
    Low-angle normal faults in the compressional Himalayan orogen
    The Annapurna Detachment (AD) is a low- angle (~20°–30° dip), north-dipping normal fault and ductile high-strain shear zone in calc-mylonites, and forms ...
  62. [62]
    The South Tibetan Detachment and the Manaslu Leucogranite
    The South Tibetan Detachment (STD) System comprises both ductile shear zones and brittle low‐angle extensional faults bounding the upper (northern) margin ...
  63. [63]
    Strain shadow “megapores” in mid-crustal ultramylonites | Geology
    Jun 2, 2023 · Here we present microstructural observations from a mid-crustal ultramylonite with very large pores that occupy the strain shadows of albite ...
  64. [64]
    U-Pb geochronology from the Moine Supergroup rocks of northern ...
    Aug 6, 2025 · Accessory phase geochronology records several phases of metamorphism that affected Moine metasedimentary rocks in the Northern Highlands ...
  65. [65]
    Thermal control on the updip and downdip extents of megathrust ...
    The Hyndman hypothesis links megathrust earthquake rupture to thermal control, with updip and downdip limits controlled by thermal fields. The updip limit is ...
  66. [66]
    Pseudotachylyte-Mylonites Record of Transient Creep From Inter ...
    Jun 21, 2022 · Mylonite is a type of fault rock in the ductile shear zone formed by plastic deformation. Pseudotachylyte is a solidified melt produced during ...
  67. [67]
    Making sense of shear zone fabrics that record multiple episodes of ...
    Apr 19, 2023 · We present a new method of linking microstructures, electron backscatter diffraction (EBSD)–derived crystallographic vorticity axis (CVA) ...
  68. [68]
    Tracing the Scale of Fluid Flow in Subduction Zone Forearcs
    Aug 5, 2024 · To estimate the fluid budget and scale of fluid circulation in subducted sediments, we assess the distribution and retention of fluid-mobile elements (FME)