<H1>Geography 111 - Metamorphism and metamorphic rocks</H1>

Geography 111 - Principles of Geology

Notes on metamorphism and metamorphic rocks - chapter 8

Metamorphic rocks, like igneous and sedimentary rocks, contain clues that can be read in order to decipher something about their history. The texture and composition of an igneous rock tell us about the source of the magma and the environment in which the rock crystallized. The texture, composition, and sedimentary structures of a sedimentary rock tell us something about the source of the sediment, the way it was transported, and the processes at work in the depositional environment. Although the processes are different, the textural characteristics of a metamorphic rock and the particular assemblage of minerals found in that rock may provide important clues that tell us about the environment in which metamorphism took place. Typically the metamorphic environment, unlike the sedimentary environment, is located at some depth beneath the earth's surface, most often in the midst of a subduction zone, a region of continental collision, a fault zone, or in close proximity to an intruding magma body. Although we generally cannot observe the processes of metamorphism at work, the intensity and style of deformation tells us something about the forces that have affected the rock. As pre-existing rocks are subjected to metamorphism under conditions of elevated temperature or pressure or both, chemical reactions may occur that lead to crystallization of new minerals that are in equilibrium with those conditions.The particular assemblage of minerals, and the extent to which some of the pre-existing mineral grains have recrystallized or grown together, can also tell us something about the temperature and pressure conditions under which the rock evolved.

Location of metamorphism: usually at depths of 10-30 km beneath earth's surface, sometimes deeper or shallower
Factors involved in metamorphism:

elevated temperature
elevated pressure/stress (force per unit area)

high confining pressure: non-directional, compressive stress causing reduction in volume, favoring more compact, higher-density crystal structures
directed or directional stress, causing distortion and deformation of rock; possible effects include compression, elongation, and rotation or shearing of the rock

chemical reactions involving hot fluids circulating through the pores in the rock and reacting with mineral grains

where do these hydrothermal fluids come from?

seawater circulating through hot basaltic rocks along divergent plate boundaries where sea-floor spreading is occurring
chemically bound water from clay minerals in sedimentary rocks is driven off as minerals recrystallize

Kinds of metamorphism:

Regional: high temperatures and pressures, especially near subduction zones and along convergent plate boundaries
Contact: along zones where hot magma "bakes" the rock with which it comes into contact and causes recrystallization at relatively low pressures
Cataclastic or fault-zone: high pressure, moderate to low temperatures, usually at fairly shallow depth associated with crushing and shearing motion in a fault zone (formation of mylonites) [these first three are the ones emphasized in the textbook and are most important for our discussion]
Burial: low-intensity metamorphism caused by exposure of rocks to moderate temperatures and pressures as a result of burial under the weight of overlying sediments; may cause some growth of metamorphic minerals
Hydrothermal or metasomatism: involving formation of new minerals resultng from chemical reactions between the original rock and hot intergranular fluids circulating through pore spaces in the rock
Impact metamorphism: very localized result of high-speed impact by meteorites; usually identified by "pulverized, shattered, and sometimes melted rock" - evidence is fragmentary and mostly found in small particles ejected from the site of the impact

Metamorphic textures:

Foliation: linear features or banding, resembling bedding in sedimentary rocks but caused by directional stresses, leading to compression of mineral grains in one direction and elongation in the other direction; slaty cleavoge, schistosity, gneissic texture
Sequences of foliated rocks (increasing degree of foliation, increasing size of mica crystals, increasingly coarse foliation or banding):

starting with basalt or shale
slate
phyllite
schist
gneiss
amphibolite (mentioned in the book as a variety of gneiss formed from basaltic rock rich in amphibole)

Nonfoliated metamorphic rocks: (we only looked at the first two in class)

marble
quartzite
hornfels (associated with contact metamorphism) [we skipped this!]
greenstone (not mentioned in the book)

Metamorphic grade (intensity zones based on which metamorphic minerals are present)

index minerals as indicators of increasing intensity of metamorphism:

chlorite-muscovite-biotite-garnet-staurolite-kyanite-sillimanite (starting with shale) - see fig. 7-21 and 7-22 [this is the primary sequence discussed in the textbook, but kyanite is left out of the sequence]]
chlorite-zeolite-epidote-amphibole-garnet-pyroxene [starting with basalt; this sequence of index minerals wasn't discussed in class and is not mentioned in the text]
mapping of regional metamorphism based on distribution of different metamorphic minerals

concept of metamorphic facies as indicative of the metamorphic environment, just as sedimentary facies are indicative of the depositional environment [we didn't cover this!]

blueschist (high-P, low-T) and hornfels (high T, low-P) facies; greenschist (moderate T, moderate P); granulite (high T, high P)
[see http://www.science.ubc.ca/~geol202/meta/metacon.html]
migmatites: transitional between igneous and metamorphic rocks
relation between plate tectonics and metamorphic zones

continental shields: ancient metamorphic landscapes, mostly with little topographic expression, flanked by younger deformed mountainous areas