Mica (muscovite. sericite or biotit

Mica (muscovite. sericite or
biotite) schist
Rock type: Foliated,

regional metamorphic
Texture: Medium to coarse-
grained, sometimes with
porphyroblasts. Thin
schistoselayering of mica
flakes always marked.
Structure: Typically folded,

on a small or large scale.
Colour: Light grey, greenish
(biotite schist is brown~l').
Composition: Quartz and
mica (usually muscovite). plus
kyanite, sillimanite, chlorite,
graphite, garnet, staure'ite.
Protolith: Mainly mudrocks
such as shale.
Temperature: Moderate.

Press'ure: Moderate.
Notable occurrences:
Connemara, Ireland;
Scotland; Scandinavia;
Alps, Switzerland. Black
Forest.Germany;
Quebec; Duchess Co,
NY; New Hampshire.
Amphibole schist is schistose like mica
schist, but the layers are formed not by
flakes of mica but by parallel bands of
long, thin amphibole crystals. If the crystals
are not parallel, the rock is not schistose
and is called amphibolite. The amphibole
in amphibole schist is usually hornblende,
and the rock is called hornblende schist,
but it can also be actinolite or tremolite.
All amphibole schists are much richer in
feldspar than amphibolite. Other
minerals in hornblende schist include
chlorite, epidote, pyroxene and garnet.
Garnet often forms dark red
porphyroblasts.
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Dark amphibolite
crystal
Amphibole (hornblende)
schist
Rock type: Foliated,
regional metamorphic.
Texture: Medium- to coarse-
grained, sometimes with
porphyroblasts. Thin
schistose layering of
amphibole needles
alwaysmarked.
Structure: Typically folded, on
a small or large scale.
Colour: Dark black or brown,
often streaked or flecked with
white or red.
Cgmposition: Hornblende
(or'~tinolite or tremolitel.
plagioclase feldspar, quartz
and biotite mica, plus
pyroxene, epidote, muscovite
mica and garnet.
Protolith: Basalt and

dole rite, as well
as mudrocks.
Temperature.
Moderate
Pressure.Moderate.
Notable occurrences:
Connemara.Ireland;
Scotland; Tyrol,
Austria/Italy; St
Gotthard MaSSif.
SWitzerland; Quebec;
Mitchell Co, North Carolina.



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METAMORPHIC ROCKS: Non•foliated and Foliated
GNEISS AND GRANULITE

The word gneiss (pronounced 'nice') comes from an old Slavonic word for 'sparkling', and that's exactly
what gneiss does. Under a microscope it can be seen to be made of tightly packed, iridescent crystals
forged by the most intense metamorphism of all. Gneiss and granulite are incredibly tough rocks and are
found together in terranes that are the most ancient rock formations on Earth.
Gneiss
Identification: Gneiss can
often be identified by its
humbug stripes of dark and
light minerals and its crystal
fabric (see Texture, right). It is
also incredibly tough, found in
the most ancient and time-
worn landscapes, such as the
vast Canadian Shield and
Scotland's Hebridean
islands.

Unlike schist, gneiss is not dominated by long, planar crystals. But
it can often be the most markedly striped of all rocks, composed
of alternating bands of light and dark minerals. In most cases
these bands are just 2mm/0.08in thick, but they can be as wide as
1 m/39in. The bands in gneiss are not like the layers in schist,
which are made from sheets of mica, nor does gneiss split easily in
the same way. The high temperatures it takes to create gneiss tend
to destroy mica, and the banding is formed in an entirely different
way- as minerals separate out and form into distinct bands.
The light-coloured bands are formed by light-
coloured, typically felsic, minerals such as
quartz, feldspar and white mica (usually
muscovite). The dark bands are made of
dark, typically mafic, minerals like
amphibole, pyroxene and biotite mica.
Compositional bands like these form
only at very high temperatures when
minerals almost melt and so can move freely
before recrystallizing. Gneisses form deep in the

Earth in subduction zones or under the roots of fold
mountains, and are bought to the surface only by massive tectonic
movements, or the slow erosion of the overlying mountains.
Compositional bands in gneiss can also form when variations

in the original rock survive through all the stages of
metamorphism. A rock originally made of alternate narrow
beds of shale and sandstone may be transformed by
metamorphism into gneiss made of alternate bands of
quartzite and mica.
Some gneisses, however, derive their bands in

an entirely different way. These gneisses get their
bands when thin floods of granitoid magma
ooze their way in between layers of the
protolith, or when there is local melting. These
gneisses blend into migrnarites, and have led
some geologists to conclude that many
ancient gneisses formed from granodiorite
and tonalite magmas in this way. Such

gneisses are closely linked to ancient greenstone
belts, and often merge into them.
Gneiss is an incredibly tough rock, perhaps the toughest of all,
andvast quantities of it have survived since the very early part of
the Earth's history. Large areas of Greenland are made from
gneisses at least three billion years old. The world's oldest known
rock is Acasta gneiss from northern Canada, which has been
dated to 3,900 million years ago.
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