There seems to be a bit of confusion among many
introductory geology students, some of the general public, and even rockhounds
about “chlorite minerals.” I often
confused many of my introductory geology students (not on purpose) by asking
them to name a common chlorite group mineral.
The most common answer was halite or salt, a sodium chloride
(NaCl). Halite, and a variety of other
minerals, contains the element chlorine (Cl), a member of the halogen
group. In the free-state chlorine is a
gas; however, it has a very high electron affinity and often gains an electron
and becomes the negatively charged anion.
This ion then is able to combine with the positively charged cations and
forms a number of compounds (like halite).
However, the chlorite minerals (name from the Greek
chloros or khloros meaning green) do not contain the element chlorine (normally
a green gas and also named for chloros or khloros)) and hence the common
confusion between chlorite and chloride.
The second confusing fact is that “chlorite” is not a recognized
mineral! But, it is often used, in a
generic sense, for any soft, commonly green, micaceous, clay-like mineral. I
certainly use the term---as in chlorite schist or quartz with chlorite
inclusions.
The
general formula for the Chlorite Group is X4-6Y4O10(OH,O)8
where X represents one or more of aluminum, iron, lithium, magnesium,
manganese, nickel, zinc or rarely chromium. The Y represents aluminum, silicon,
boron or iron but mostly aluminum and silicon. (www.galleries.com).
Www.mindat.org notes
the occurrence of 12 different Chlorite Group minerals. Most are rare or uncommon with clinoclore
(Mg, Fe) pennantite (Mn, Al) and chamosite (Fe, Mg) being the most common
types. Cookeite (Li, Al), described in
the previous post, is rare to uncommon.
Clinochlore, the
subject of this small post, is interesting in that a particular variety,
seraphinite, is polished and used as a semi-precious gemstone, and the red to
pink variety known as kammereite forms beautiful specimens.
Clinochlore [(Mg,Fe++)5Al2Si3O10(OH)8],
a magnesium ferrous iron aluminum silicate is magnesium rich (more than the
iron) and forms a solid solution series with chamosite, the iron-rich end
member [(Fe++,Mg)5Al2Si3O10(OH)8].
My specimen is labeled “Clinochlore collected from the Barenfall Dam, Pinzgau,
near Salzburg, Austria.” That particular
locality produces clinochlore rather than chamosite (www.mindat.org), otherwise my identification of one mineral
or the other would be dubious!
Pseudohexagonal
crystals of stacked tabs of dark greenish-brownish-black clinochlore. Width of specimen ~9 mm.
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Larger plates of clinochlore collected from near Lancaster, Pennsylvania. Width of cluster ~1.1 cm. |
Clinochlore platy crystals collected from near Lancaster, PA. Plate just above center has a width of ~3 mm. |
Clinochlore is the
result of metamorphic and hydrothermal alteration of iron- and magnesium-rich silicates
such as amphiboles and pyroxenes, and especially of oceanic basalts. Weathering of clinochlore produces the
silicate mineral vermiculite and several clay minerals belonging to the Smectite
Group. In fact, some authors classify
Chlorite Group minerals as “clay minerals”. Clinochlore platy crystals collected from near Lancaster, PA. Plate just above center has a width of ~3 mm. Larger plates on same Pennsylvania specimen. Width of cluster ~1.1 cm.
I mentioned above a
particular variety of crimson red to pink clinochlore called kammereite with
chromium chromophores. Although too soft
(~2.5 Mohs) for faceting and cabbing, the specimens are quite collectible. The other collectible variety of clinochlore is
seraphinite, a fine grained and quite dense mixture of dark clinochlore and silvery
muscovite often creating an optical reluctance (if highly polished). The name comes from the resemblance of the
clinochlore inclusions to the “feathery” wings of the biblical seraphim
angles. It is rather uncommon variety and
seems limited to a locality or two in eastern Siberia where some limestones
were metamorphosed by intrusive granite.
Cut, but not
polished, slab of seraphinite—note angle wings.
Total width ~2.3 cm.
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As a couple of side notes,
I have a fairly clear, terminated quartz crystal collected from southern
Oklahoma in the Ouachita Mountains—see Posting July 21, 2014. Upon inspection it is easy to observe
numerous green inclusions of a Chlorite Group mineral; the exact mineral is
unknown to me.
Terminated clear
quartz crystal with inclusions of a Chlorite Group mineral. Collected from Ouachita Mountains, southeastern
Oklahoma. Height of crystal ~2.1 cm.
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At a small rock and
mineral show several years ago I was visiting with a dealer near the end of the
event and purchased a few specimens. The
dealer threw in a larger perky box and said it was nothing but an ugly chlorite schist
that no one wanted to purchase. In
reality, the specimen is sort of interesting with not only the micaceous
Chlorite Group mineral arranged in platy alignment but numerous tiny green, prismatic crystals of epidote and a few nicely formed magnetite octahedrons. It was labeled “Missouri” and my guess is the Silvermine District in
Madison, County.
Magnetite octahedron
in “chlorite schist.” Maximum width of exposed
face ~5 mm.
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Photomicrograph: Group
(~7 mm) of micaceous and platy aligned Chlorite Group mineral in a “chlorite
schist” from Missouri.
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Photomicrograph: Group
(2 mm) of tiny epidote crystals in the “chlorite schist.”
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If nothing else,
these last two posts have introduced me to the complex mineralogy of Chlorite
Group minerals and taught me that the adjectives chlorite, chloritic or
chloritoid should be used in a generic sense.