Why should things be easy to understand?
Thomas Pynchon
Scapolite is one of those
minerals that sort of rings a bell somewhere in the recesses of your mind;
however, you cannot quite pinpoint the location! About the only thing that
finally surfaced in my mind came from basic mineralogy and pointed out that
scapolite is usually an alteration product of feldspar (which one?), and is a
metamorphic mineral (which facies?)! I
sort of left it at that point until a few years ago when I saw some beautiful
faceted gemstones labeled “scapolite.”
Perhaps my mineralogy factoids were a figment of my imagination for those
faceted gems looked nothing like some less-than-spectacular specimens I
remembered from class.
Perhaps I could
forgive my mind since I was a third-year college student trying to reconcile
memorizing mineral crystal systems with understanding the bombing of the 16th
Street Baptist Church in Birmingham and the assassination of President Kennedy
in Dallas. In fact, the assassination of
Kennedy is one of those moments in history that persons of my age have
imprinted on their minds--- I was heading to Mineralogy class! Why did the crystal systems matter when young
girls and presidents were being murdered?
I guess the short answer is that I did not want to return to my home
town and work in my father’s gasoline station.
And then, there were rumors about “goings-on” in southeast Asia with the
military draft picking up and men of my age learning a new trade. So, back to learning about Monoclinic and
Hexagonal minerals (and I never really understood the Systems and became a
paleontologist). And, scapolite became
lost!
Age is an issue of mind over matter. If you don’t mind, it doesn’t matter.
Mark Twain
Scapolite reappeared in my
mind back in 2012 when I was working on a post describing
idocrase/vesuvianite. The latter mineral
was named by the famous German mineralogist Abraham Gottlob Werner and an
informal variety of scapolite is called werernite. Long story---read the November 18, 2012 Blog posting. At any rate, I then took
scapolite from the back recesses and shoved it toward the front of my mind and
four years later am finally getting around to describing some specimens that I
picked up along the way!
Scapolite is a silicate but
is not really an individual mineral! It
is a solid solution series between end members marialite (sodium chloride rich)
and meionite (calcium carbonate rich): Na4Al3Si9O24Cl
to Ca4Al6Si6O24CO3. The sodium and calcium are interchangeable
with each other as are the chlorine and the carbonate radical, therefore
leaving an infinite number of chemical compositions. In addition, the calcium
may include some strontium while the sodium may include potassium. And SO4
may substitute for some CO3 (Evans and others, 1969). It appears that “pure” end members never
occur in nature so intermediate compositions are the norm; however, these
intermediate members vary considerably in chemical composition and remain
unnamed. Members of the solid solution
series are essentially indistinguishable (visual) from each other and therefore
scapolite is simply used for all.
Scapolite comes in a variety
of spectral colors ranging from colorless to white and yellow, purple, blue,
red, green, pink, brown, gray, orange and various mixed compositions. However, all varieties have a white streak.
The transparency ranges from completely opaque to translucent to completely
transparent while the luster ranges from vitreous to dull and pearly. As scapolite weathers to “mica” the luster
becomes dull and the diaphaneity becomes opaque. The hardness of ~5.5-6.0
(Mohs) makes gemmy varieties more suitable for pendants rather than rings. Scapolite crystals are Tetragonal and
generally come in two distinct forms: short and fat, or long and
prismatic. Gemmy varieties are usually
prismatic and commonly striated. A
couple of my specimens show masses of non-gemmy and opaque crystals. Many times, crystals fluoresce under both
short and long wave UV.
Scapolite is one of the few
minerals that have a “square” cross-section that helps in identification. Compare photos below of a weathered crystal
from Monmouth Township, Ontario, Canada, with a crystal diagram from the
Goldschmidt atlas and found on www.mindat.org and courtesy of www.smorf.nl.
 |
| Cross-sectional view of scapolite crystal, non-terminated, collected from Grenville Terrane near Bancroft, Ontario. Note square shape of crystal and compare with sketch below. Width of crystal ~1.6 cm; length ~2.3 cm. |
 |
| Crystal diagram of scapolite from the Goldschmidt atlas and found on www.mindat.org and courtesy of www.smorf.nl. Note square shape. |
I thought scapolite was
perhaps a mineral indicative of a specific metamorphic facies. However, I have learned the “mineral” occurs
in a variety of metamorphic conditions ranging from regionally metamorphosed
schists and gneisses to higher temperature and pressure amphibolites and granulites
(usually as an alteration of feldspar minerals and producing non-gemmy
crystals). In addition, scapolite, at
times gemmy, is found in marble produced by contact metamorphism. At other
times scapolite in these calc-silicate rocks contain inclusions of
clinopyroxene, quartz, titanite and calcite (Ocean Drilling Program). It is
also found, at times, in pegmatites associated with contact metamorphism, and
basalt ejected from volcanos. I
certainly am far from a mineralogist/petrologist but have spent numerous hours
reading “lots of articles” concerning scapolite, and trying better to
understand the chemistry and genesis. I
have somewhat failed in my understanding and concluded that it is a very
complex mineral found in several different environments and is quite difficult
to identify as to a specific mineral.
Just because we don't understand doesn't mean that
the explanation doesn't exist.
Madeleine L’Engle
My collection includes two
specimens composed of a non-gemmy mass of opaque crystals collected from around
Bancroft, Ontario, Canada. Also from
near Bancroft is a single, squat weathered crystal.
 |
| Above two photos are masses of opaque, non-gemmy scapolite crystals. Note nice terminations on crystals with T pointer and nice square shape with SQ pointer.. Width FOV top ~4.0 cm, bottom ~4.3 cm. Both specimens have tiny crystals of an amphibole (katnophorite/hornblende??) and ferroan phlogophite on reverse. |
 |
| Map of proto-North America showing addition of crust (yellow) to continent in late Precambrian by plate collision tectonics (Grenville Orogen). High temperature and pressure accompanies these collision events and creates large expanses of metamorphic rocks and allows for the formation of minerals like scapolite. Map from Karlstrom and others (1999). |
The Bancroft area of
Ontario, part of the Grenville Province, is thought to have been the margin of
North America during the Proterozoic part of the Precambrian. The rocks are composed of two tectonic
elements: 1) high-grade gneisses that were part of the 1.7-1.4 Ga continental
margin; and 2) a package of volcanic, plutonic, and sedimentary rocks that are
thought to be a collage of arc components accreted at ca. 1.17 Ga (island arc
material stuck onto the early continent by plate collision) (Keck Geology
Consortium, 2011).
From the Dara-i-Pech
pegmatite field, Chapa Dara District, Konar Province, Afghanistan, I have several small gemmy crystals lavender in
color. The crystals are prismatic in
nature and have at least one terminated end.
The location of the crystal mine is in the northeastern part of the
country where lower Paleozoic rocks are intruded by Cretaceous-Tertiary granite
and granodiorite intrusions (creating contact metamorphism--cooking the limestone). Due to
political instability in Afghanistan, specifics about gemstone localities are
difficult to ascertain.
 |
| Nice gemmy scapolite crystals. length of longest crystal is ~1.1 cm. |
I also have a partial violet crystal from the Marble Occurrence, Morogoro
Region, Uluguru Mountains, Tanzania. As
best that I can determine, the area is the site of plate collisions in the
latest Precambrian. Metamorphism and
thrust faulting left small patches of marble on older rocks (Fritz and others
2009). If you have the inclination to
read about some really complex geology, check out the Fritz article!
 |
| Partial crystal of gemmy scapolite with undetermined inclusions. maximum width of crystal ~1.1 cm. |
And finally, I have a
beautiful, free form cab of crystal-clear, gemmy scapolite collected from Espirito
Santo, Brazil (along with a second specimen, a nice gemmy, prismatic crystal). Espirito Santo is a coastal Brazilian state
north of Rio de Janeiro and east of the famous mineral-producing state of Minas
Gerais. It was difficult to acquire much
information about the area except that really gem quality aquamarines are mined
from the Mimoso do Sul Mine. The gem
bearing rocks are latest Precambrian in age (100 Ga to 54 Ga) and seem related
to the Aracuai Orogeny and include a wide variety of metamorphic rocks and
igneous intrusions. The Aracuai Orogeny
added crustal rock to the local Brazilian Craton. I presume, but remain
uncertain, that the gem scapolite came from some of the marble units.
 |
| Prismatic, gemmy, clear with yellow tint, scapolite crystal. Length ~3.0 cm. |
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| Gemmy, clear with yellow tint, free-form cab of scapolite. The X is beneath the cab to show the transparent nature of the crystal (thickness 6 mm.). Length ~2.3 cm. |
So, when it comes to
scapolite: I don't think I'm old enough or experienced enough to give anyone any
guidance. All I would like say is that as long as you're having fun, I think
you're doing the right thing.
Sania Mirza
REFERENCES CITED
Evans, B.W., D.M. Shaw, and D.R. Haughton, 1969, Scapolite stoichiometry: Contributions to Mineralogy
and Petrology, v. 24, issue 4.
Fritz, H., V. Tenczer, C. Hauzenberger, E. Wallbrecher and S. Muhongo,
2009, Hot granulite nappes—Tectonic styles and thermal evolution of the
Proterozoic belts in East Africa: Tectonophysics, v. 477.
Karlstrom, K.E., S.S.
Harlan, M.L. Williams, J. McLelland, J.W. Geissman, Karl-Inge Åhäll, 1999,
Refining Rodinia: Geologic Evidence for the Australia–Western U.S. connection
in the Proterozoic: GSA Today, v. 9, No.
10.
Keck Geology Consortium, 2011, Anatomy
of a mid-crustal suture: Geology of the Central Metasedimentary Belt boundary
thrust zone, Grenville Province, Ontario:
http://www.keckgeology.org/2011-ontario-canada.
Ocean Drilling Program, Unknown date, Macroscopic description of
calc-silicate rocks: http://www.odp.tamu.edu/publications/161_SR/chap_18/c18_3.htm