Title from John Ruskin
Ask the average Joe or Joette on the street what comes
to their mind when thinking about the color blue. Probably the first thing that
pops up is something about the color of a beautiful sky (something that has
been rare this winter here in the Wisconsin woods). Others may talk about the
blue ocean (again not always the case) and the interviewer might wonder if they
really know that water absorbs colors, like a filter, in the red spectrum of
light more efficiently than in the blue spectrum? But things are quite black in
ocean depths greater than about 600 feet—not much light penetration. So, does
this mean that the ocean is not really blue? What it means is that our eyes see
the color blue when rather clear, low-nutrient, low sediment load, water is
scattered by sunlight.
More “happy” philosophical Joes and Joettes might
think that blue is a relaxing color and indicates stability and serenity and
wisdom while those “down in the dumps” might associate the color with the noun blues
meaning a less that happy, sadder, emotion. Now an artistic sort of hipster
would define blues as a musical genre, something with a “blues scale”
containing twelve bars and three cords in a particular order. Think B.B. King
or John Belushi and Dan Alkaroad.
Now, ask an ole rockhound like me about what comes to
mind with “blue” and out pops azurite.
You know, the copper carbonate mineral that seems to define a color to those of
us in the know—a soft, deep blue we refer to as azure-blue. Every rockhound in
the world can picture and define azure-blue—a perfect color associated with
copper minerals like azurite, or water contaminated with dissolved copper
minerals leaving copper sulfate (Cu2+ ).
A specimen of azure-blue azurite om matrix from the "Bisbee Mine" in Arizona. Width FOV ~18 mm.
Somewhere a factoid once popped into my mind that said
the copper-iron sulfide chalcopyrite was the most common copper mineral. Well,
azurite is the most common copper mineral that the average Joe/Joette can
identify. In a beginning mineralogy class azurite, with a chemical formula of
Cu3(CO3)2(OH)2, is used to study
positive cations combing with negative anions to create a mineral. The divalent
copper II cation combines with a carbonate anion and a hydroxide anion, and
voila, out pops the beautiful azure-blue azurite.
Azurite, with its magnificent blue color has been
known to the world for centuries. For example, around 2500 BCE Egyptians used
the mineral in painting projects. In the early years of the AD, Pliny the
Elder, a Roman jack-of-all trades, wrote the thirty-seven volume, encyclopedic Naturalis
Historia and described what we now know as azurite: a deep blue mineral
associated with copper deposits and used as a pigment. Today azurite is still
used as an artistic painting pigment and is one of the most collectable
minerals, especially in the southwestern U.S. where passing tourists seem to
associate the color with the local Native Americans. Other rockhounds like me
just collect it for its beauty and color.
So, we all know about blue azurite but what about
other, less common, blue minerals. Well, first of all, check out the December
2020 issue of the Pick & Pack https://www.csms1936.com/wp-content/uploads/2021/02/12Dec2020.pdf
) or a revised Blog version on October 24, 2024. But now I want to introduce
you to: lemanskitte, lavendulan, and gibbsite.
Gibbsite, an aluminum hydroxide [Al(OH)3],
is one of the major components of the aluminum ore, bauxite—more on that later.
Gibbsite has an interesting, seemingly simple, crystal structure with stacked
sheets of linked octahedra. Each of the octahedrons has an aluminum ion bonded
to six hydroxide groups (hydroxide equals one oxygen atom covalently bonded to
one hydrogen atom). The stacked octahedrons are weakly bonded, and the mineral
has perfect cleavage (001) similar to the micas; however, rockhounds rarely
observe the cleavage due to the fine size of the gibbsite particles
(mindat.org). Gibbsite is a mineral of many colors from white to green to
yellow to shades of blue and purple. It usually is very soft and earthy
(clay-like) with only rare crystals observable. Masses of gibbsite often form
spherical or clumpy aggregates that are difficult to break apart and seem
easily confused in hand specimens with masses of clay minerals.
Most gibbsite is produced by the weathering of
aluminum-rich minerals (perhaps micas, feldspars, corundum and nepheline) and
therefore is commonly found in weathering profiles that form in tropical and
subtropical environments. Here “water” leaches out soluble materials such as
silica and leaves behind iron and aluminum-rich oxides. The common sedimentary
rock formed in these weathering profiles is bauxite, the major ore of
aluminum., composed of gibbsite, Böhmite [AlO(OH)],
and its dimorph diaspore [AlO)OH)]. Mix the three minerals together with
copious amounts of the clay mineral kaolinite and the “mixed up mess” is called
bauxite and it is terribly difficult to identify individual minerals in hand
specimens.
Gibbsite can also form in lateritic environments
without combining with other bauxite-forming minerals, sort of a “stand alone”
mineral. In deeply weathered igneous and metamorphic rocks, especially granite,
gibbsite can form from the weathering of feldspars and micas. However, most gibbsites
are formed in areas of high rainfall and warm temperatures where aluminum-rich
rocks are located.
My specimen, ~11 x 20 mm, is from the Wenshan area of
China and is part of a recent discovery, ca 2012 of attractive display
specimens. Composed of aggregates of botryoidal sky blue to aquamarine colors.
Mineral dealers believe the Wenshan deposits may be the best intensely colored
gibbsite in the world.
Lavendulan and lemanskitte are what my mother from
rural Kansas would term Kissin’ Cousins, something that is of a very
similar character to another thing of the same type (Oxford Languages).
Lemanskiite is a “blue” mineral, mostly with a dark sky
blue color and streak, occurring as groups or aggregates of thin tetragonal plates or prismatic,
needle-like crystals, on some type of matrix, although more massive material is
found filling fractures. It is a soft mineral, ~2-3 (Mohs), and has a vitreous
luster. The type locality is a sulfide-rich, epithermal deposit in the famous
El Guanaco Mining District, Chile. Lemanskiite is a hydrous
copper, calcium, and sodium chloroarsenate: NaCaCu5(AsO4)4Cl · 3H2O.
A 6 mm cluster of rare, beautiful, blue crystals of lemanskiite collected from the Type Locality, Guanaco Mine, Taltal, Antofagasta Province, Antofagasta, Chile.So, its cousin lavendulan, a Monoclinic mineral
(lemanskiite is Tetragonal), is a slightly different blue color described as
pale blue and/or greenish blue, a pale blue streak, and also quite soft with a
vitreous to waxy luster. It often occurs as thin crusts of quite tiny radiating
fibers as a secondary mineral in copper-arsenate deposits (such as Gold Hill in
Utah), hence a hydrous copper, calcium, and sodium chloroarsenate: NaCaCu5(AsO4)4Cl
· 5H2O. The specimen below is from the obscure. poly-metallic
(mostly copper), Alice Mary Mine, Kundip, Raventhorp Shire, western
Australia.
Pale blue, almost massive, smear of minute lavendulan crystals
Sub millimeter cluster of minute lavendulan crystals.
Lavendulan has an interesting history as the mineral
was named for the lavender color of the original type specimen by Johann
Breithaupt in 1837 found near Annaberg in the “Ore Mountains” near the
German-Czech Republic boundary (current geography). Nearly two centuries later work by Ondruš and
others (2006) and Giester and others (2007) determined Breithaupt’s original
type specimen was a mixture of different minerals and unrelated to the current
definition/determination of lavendulan. Therefore, the second located specimen
of lavendulan was found near Jachymov,
also in the “Ore Mountains” of the Czech Republic and the Type Locality was moved
to that location from Annaberg.
If that is not confusing enough, lemanskiite was
originally described as a polymorph of lavendulan—sharing the same mineral
formula but having different internal crystal structures, in this case Tetragonal
and Monoclinic Systems. But along came Zubrovka and others in 2018 and
determined that chloroarsenate lemanskiite had only three “waters” in its
chemical makeup in contrast with five “waters” in lavendulan. (Bet you missed
that in reading the above chemical compositions!!!Check it out.
Three waters or five waters or more, many blue
minerals are very difficult to identify in micromounts. I found that it is best
to look at the localities as noted in MinDat and identify blue minerals from
their list and go from there. For example, lavendulan and lemanskiite, those
pesky “how many waters” minerals, don’t often occur together and lavendulan is a
much more common mineral, especially in copper arsenic mines.
The theme of the upcoming Tucson event is Red,
White, and Blue; therefore, I expect to see some quite magnificent blue specimens.
REFERENCES
CITED
Giester, G., U.
Kolitsch, P. Leverett, P. Turner, P. Williams, 2007, The crystal structures of
lavendulan, sampleite, and a new polymorph of sampleite: European Journal of
Mineralogy, Vol. 19. No.1,
Ondruš, P., D., Veselovský, F., Skála, R., Sejkora, J.,
Pažout, R., Fryda, J., GabaÅ¡ová, A., Vajdak, J., 2006, Lemanskiite, NaCaCu5(AsO4)4Cl·5H2O,
a new mineral species from the Abundancia mine, Chile: The Canadian
Mineralogist, Vol.44, No. 2.
Zubkova, N. V.,
Pekov, I. V., Chukanov, N. V., Kasatkin, A. V., Ksenofontov, D. A., Yapaskurt,
V. O., Britvin, S. N., Pushcharovsky, D. Yu, 2018, Redefinition of lemanskiite:
new mineralogicald data, crystal structure, and revised formula NaCaCu5(AsO4)4Cl
· 3H2O: Geology of Ore Deposits, Vol. 60, No. 7.
