Pisolitic bauxite from Arkansas. Width ~4.1 cm.
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Many
CSMS members have been to the State of Arkansas on a collecting trip, most
likely to collect quartz crystals and dabble in the diamond mine. I would be interested in meeting someone who
actually has collected a diamond in the State Park! However, there are many other really
interesting minerals in Arkansas that offer some collecting opportunities.
One
of these “minerals” that Colorado rocks do not offer is bauxite. Now, I don’t know much about bauxite except
that it: 1) is an ore of aluminum; 2) forms in a tropical to subtropical
environment; 3) occurs as small to large oolites; and 4) is mined in
Arkansas (and elsewhere). I learned all of these facts
in a grade school geography class! What
I later learned as a geology student is that bauxite is not really a “mineral”
but is a composite of several different aluminum-rich minerals:
[gibbsite—Al(OH)3, diaspore-AlO(OH), boehmite-ALO(OH)], a couple of iron oxides [hematite-Fe2O3, goethite- FE3O(OH)], and a clay mineral [kaolinite-Al2(Si2O5)(OH)4].
Bush
(2007) described the formation of Arkansas bauxite as lateritic weathering and
leaching of alumina and silica from intrusions of nepheline syenite (lots of
nepheline and sodium/potassium feldspars) exposed during the Tertiary in what
is now Pulaski and Saline Counties in the Gulf Coastal Plain. These rocks (nepheline syenite), rather rare
in the U.S., are alumina-rich and quartz-poor and evidently were intruded
during the Late Cretaceous as the old Reelfoot Rift was reactivated. Later in the Tertiary, intense weathering in
a tropical environment allowed precipitation of the alumina-rich minerals. Actually bauxite is an ancient soil and
Harder (1948) noted its stratigraphic importance as marking “long periods of emergence,
quiescence, nondeposition, and subaerial weathering”.
Bauxite
ore has been mined in Arkansas since ~1896 and reached peaks during World War I
and II. Major companies abandoned mining in ~1991 but a smaller company still
operates a small mine (I think).
I
once collected several pieces of bauxite; however, I mostly added them to a
university collection that was lacking specimens and only one small piece remains.
OK,
here is the story that goes with bauxite.
The mineral nepheline (Na3KAl4Si4O16),
last seen in my blog on Black Hills phonolite (9-5-13), is a feldspathoid, a fairly rare group of
minerals with a very low silica content.
Nepheline is related to leucite, lazurite, sodalite and others. As I
understand it, nepheline does/can not exist with free quartz in nature (as with
all feldspathoids). Rockhounds usually
find nepheline in the above-mentioned intrusive rock, nepheline syenite, and
its extrusive equivalent, fine-grained phonolite. I really never understood, in my mineralogy
and petrology classes, the genesis of nepheline-rich rocks! Were they the result of a segregated magma or
did they form in a completely separate magma?
Of course, I don’t understand much about even stranger feldspathoid rocks
such as the leucite-bearing, lamproite volcanic rocks in the Leucite Hills of
southwestern Wyoming! A field trip
leader tried to explain it to me one time in my youth. However, I recollect it was a very hot and
windy day and my mind was on a cold adult beverage waiting for the group in
Rock Springs. At any rate, the U.S. has
those aluminum-rich rocks in Arkansas because of the presence of nepheline syenite.
The
other related story concerns the Reelfoot Rift, an ancient rift system that is currently
buried under what is now the Mississippi River from about Cairo, Illinois,
south to the Gulf. The rifting of the
early Paleozoic proto- North American continent was probably most active in the Cambrian. The exact cause of rifting is not well
understood but perhaps that area of the continent was situated over a hot spot—a
mantle-derived plume developed along the boundary of two old Precambrian terranes
(Csontos and others, 2008). As the continent split the resulting down-dropped
rift basin filled with several thousand feet of Early Cambrian clastic,
non-marine sediments overlain by a thick sequence of Cambrian and Ordovician
marine rocks. Then some weird things
begin to happen and these “things” lasted throughout the Paleozoic. Although the rift seemed to fail in the early
Paleozoic, the basin still accumulated Paleozoic marine sediments during times
of continental “quietness” but every time some tectonic mass along the east
coast (current direction and location) bumped into the continent the rift area was squeezed and somewhat pushed up.
Geologists know these bumps as the Taconic
(mostly Ordovician), Acadian (mostly Devonian) and late Paleozoic Alleghenian
(or Appalachian) orogenies. So, many of
the mid- to late Paleozoic rocks are missing from the rift basin (absence also partially
due to later erosion in the early/mid Cretaceous). Sometime in the mid- to late Cretaceous the
rift was reactivated and marine waters reached far to the north (~Cairo) and
essentially received sediments, off and on, throughout the late Mesozoic and
Cenozoic—the Mississippi Embayment or Mississippi trough was born. Paleocene (Midway) and Eocene (Wilcox,
Claiborne, Jackson) marine incursions also reached far to the north while Oligocene,
Miocene and Pliocene marine rocks are restricted to more southern states like
Louisiana and the modern Gulf Coast.
There
are a number of faults associated with the rift system and they seem the cause
of the many seismic events in the region (for example the New Madrid earthquake). In addition, the faults allowed magma to rise
toward the surface and some of that magma cooled into nepheline syenite. So, if it were not for a failed rift my grade
school geography class would not have produced a lesson on mining aluminum in
the U.S. Although this factoid may seem trivial,
lessons like this whetted my appetite for learning more about rocks and minerals
and eventually resulted in a career.
REFERENCES CITED
Bush,
W. V., 2007, History of Bauxite in Arkansas: Arkansas Geological Survey AGES
Brochure Series 003.
Csontos,
R., R. Van Arsdale, R. Cox and B. Waldron, 2008, Reelfoot Rift and its Impact
on Quaternary Deformation in the Central Mississippi River Valley: Geosphere,
v. 4, no. 1.
Harder,
E. C., 1948, Stratigraphy and Origin of Bauxite Deposits: Bulletin of the
Geological Society of America, v. 60, no. 5.
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