Thursday, October 29, 2020

THE BLUE IRON MAGNESIUM PHOSPHATES: SCORZALITE AND LAZULITE


It was a beautiful bright autumn day, with air like cider and a sky so blue you could drown in it.   Diana Gabaldon 

Some of my Blog readers know that I am partial to blue minerals, and to phosphate minerals.  And if the phosphate minerals are blue, that is even better.  Most of my minimal understanding of phosphates come from minerals found in Precambrian rocks of the Black Hills, and by conversations with Tom Loomis at Dakota Matrix.

Like many of the interesting phosphate minerals at localities around the world, the numerous pegmatites in the Black Hills produce most of the phosphate minerals. Perhaps the pegmatite most studied in the Hills is one exposed at the Tip Top Mine in the Custer Mining District. This former beryllium mine is the Type Locality for something like 12 colorful phosphate minerals and tens of others are mostly hidden away in vugs and fractures; most are microscopic, but all seem to have beautiful crystals.  I have written about several of these phosphates in this Blog.  A couple of years ago I had a personal tour of the Tip Top with noted mineralogist and mine owner, Tom Loomis.  I was looking for some of the tiny Tip Top phosphates but no luck—lots of triphylite and rockbridgeite but no nifty sprays of tiptopite!

A section of the Tip Top Pegmatite. near Custer, South Dakota.

Due to the Covid-19 pandemic I missed my fall trip to the Black Hills; however, I keep reading what geological information  I can acquire on both the Hills, and on phosphate minerals from other localities in the U. S.  One place that tweaked my interest was New Hampshire, home of several pegmatites along the west side of the state. I have had an opportunity to roam around New Hampshire enjoying the camping, mountains, and scenery, but that was in my soft rocks days and I was not really interested in mines and minerals.  So, I did not take the opportunity to explore the mines scattered around in the Grafton Pegmatite Field.  Like the Black Hills, the Grafton pegmatites are a hotbed for finding phosphate minerals, including the Palermo #1 pegmatite where something like 159 minerals, many of them phosphates, have been identified (MinDat.org).

Rather than feeling sorry for myself about the exile in the basement: I nabbed some coffee for my mug, pulled up my big boy pants, put a sparkle in my eye and a smile on my unshaven face, and decided that yep, I'm ready for the day.  Bring on the phosphates. 

So, I started rummaging around my collection during the constant self-quarantine time looking for phosphates to sort.  All phosphates have the PO4 anion with an oxidation state of 3- (phosphorus with a 5+ and  4 oxygens each with a 2- state leaves a total anion state of 3-).  Among rocks and minerals (to differentiate from chemically synthesized forms) primary phosphates crystalize from fluids in late stage magmatic crystallization, for example the mineral triphylite (a lithium iron phosphate). Secondary phosphates form many colorful specimens from the primary phosphates that are altered by aqueous solutions into minerals like strengite (hydrated iron phosphate). Sedimentary phosphates form at low temperatures from phosphorus-bearing organic material in ocean basins, epeiric seas, continental shelves and even a few fresh waters (see September 4, 2020 Post). Many of these organic phosphorites include large amounts of Apatite Group minerals.

What I came up with in my fumbling around was a specimen containing the blue, secondary phosphate, scorzalite, collected from the Palermo #1 Mine.  The Grafton Pegmatite Field, with the Palermo Pegmatites, is located in the Acadian Orogenic Belt, a tectonic area that represents the Devonian (~420Ma --~360 Ma) uplift of mountains in the northern section of the Appalachian Orogen, around southern Virginia to Newfoundland. This uplift was the result of plate movement as a microcontinent named Avalonia (parts of Europe) was banging against Laurentia (proto North America), and being accreted (the terrane was sticking to Laurentia) while the proto Atlantic Ocean was being subducted under the Laurentian continental plate. Of course, the orogenic event was much more complex that this explanation!  What we also know is that the active tectonic zone supplied magmatic plutons, volcanos, hydrothermal fluids, and lots of heat for metamorphic transformation of preexisting rocks.  I always had much respect for the New England geologists tromping through the vegetation and trying to decipher the stratigraphy and tectonic sequences, especially those early field workers who did not have knowledge of plate tectonics.


Cartoon x-section of events in the Acadian Orogeny, New England.  Sketch courtesy of Fichter and Baedke at http://csmgeo.csm.jmu.edu. 

In the above sketch, the Taconic rocks are roots of  Ordovician orogenic events where microcontinent(s) (generally referred to as Taconic Terrane)  banged into proto North America creating mountains and accretion.  The Acadian terrane is the Avalonia Microcontinent being shoved up and accreted to proto North America.  The Catskill rocks are a large clastic wedge of sediments shed off the rising Acadian Mountains.  The Acadian rocks (Avalon terrane) were instrumental in the early days of defining "Continental Drift."  By the Permian addition rocks and terranes had banged into, and stuck to, proto North America (the Alleghenian Orogeny) helping to create the Pangaea Supercontinent.  By the Triassic Pangaea was breaking apart and in proto North America the split sent part of the Avalon rocks with proto Europe and part stayed with North America.  Early geologists noted that some North American rocks were identical to European rocks and suggested that at one time they were connected and later "drifted" apart (Continental Drift).  At that time geologists did not understand the mechanism for "drifting."  Today we know much about plate tectonics and sea floor spreading.   

The pegmatites within the area of Palermo mines #1, #2, and #3 are quite complex but have as their primary phosphates triphylite (Li, Fe) AND/OR lithiophylite (Li, Mn), and montebrasite (Li, Al) AND/OR ambygonite (Li, Al, F) (Nizamoff, 2006).  These primary minerals then interacted with post-magmatic aqueous fluids to produce several tens of secondary phosphate minerals including scorzalite. Nizamoff (2006) also determined that primary montebrasite [LiAl(PO4)(OH,F)] and/or triphylite (lithium iron phosphate) PLUS muscovite (to add alumnium) were subjected to high temperatures, ~500oC—300oC,  by infusions of hydrothermal fluids.  These fluids also leached out lithium and fluorine and left behind iron, magnesium, aluminum, and hydroxyl ions and the result was the formation of the iron aluminum phosphate, scorzalite [FeAl2(PO4)2(OH)2], and/or its magnesium analogue, lazulite [MgAl2(PO4)2(OH)2]. So, the primary phosphates were heated by hot fluids which also leached out some of the elements and left behinds others producing the often colorful secondary phosphates.



Photomicrographs of blue scorzalite from the Palermo #1 Mine.  Width FOV top ~1.0 cm, middle and bottom ~ 9 mm.

Scorzalite has a blue color of some sort—blue-green, light blue, dark blue—but mostly a light sky blue with a resinous or subvitreous or even a dull luster.  It may appear something less than transparent but darker shades are opaque. The hardness is ~6.0 (Mohs) and specimens will produce a white streak. Crystals may be observed in some specimens; however, they are quite small.  Most specimens are granular or massive blue blotches.

As I noted above scorzalite [FeAl2(PO4)2(OH)2] has a magnesium analogue named lazulite [MgAl2(PO4)2(OH)2] and they are in a solid solution relationship. As best that I can tell lazulite is usually a darker blue color, at times a midnight blue, and has larger and better formed crystals.  I am unaware of intermediate minerals.


Two photomicrographs picking up the dark blue color of lazulite crystals, each has a maximum width of ~ 3 mm. Specimen from Rapid Creek, Yukon Territory, Canada.

 According to webmineral.com, the magnesium  and iron elements are shown below:

Molecular Weight = lazulite 302.23 gm    
Magnesium    8.04 %  Mg       
Aluminum    17.86 %  Al       
Phosphorus  20.50 %  P        
Hydrogen     0.67 %  H         
Oxygen      52.94 %  O               

Molecular Weight = scorzalite 325.88 gm
   Magnesium    1.86 %  Mg    
   Aluminum    16.56 %  Al   
   Iron        12.85 %  Fe   
   Phosphorus  19.01 %  P    
   Hydrogen     0.62 %  H     
   Oxygen      49.10 %  O

 

   

Pseudo-octahedral crystal of an iron manganese phosphate, perhaps  kryzhanovskite, a pseudomorph after phosphoferrite. Width specimen ~.75 cm.  

The specimen from Palermo #1 also held a bonus mineral that took me some time to identify--the iron manganese phosphate, phosphoferrite [(Fe,Mn)3(PO4)2-3H2O]. And boy was it a surprise--read on.  As noted, I had this nifty crystal pegged as phosphoferrite due to physical properties including those displayed in photographs.  Many specimens are some sort of a brown to reddish brown (the oxidized forms) to green colors and are transparent to translucent.  They belong to the Orthorhombic Crystal System and often occur as tabular to pseudo octahedral crystals.  They are soft at ~3.0+ (Mohs) with a vitreous to resinous luster.  The twist is that I continued to study the fantastic tome by Nizamoff, (2006) and could not locate his description of phosphoferrite in the Palermo #2 Mine (next door to #1).  Instead, he noted that Moore (1971) and Moore and others (1980) suggested that the mineral kryzhanovskite [(Fe,Mn)3(PO4)2(OH,H2O)3] may form from the oxidation of phosphoferrite. With this information Nizamoff  (2006) noted "it appears that at Palermo #2 phosphoferrite crystallized in the non-oxidizing assemblage with vivianite, ludlamite and fairfieldite group minerals and was subsequently oxidized to kryzhanovskite. Consequently in the observed assemblage at Palermo #2, kryzhanovskite has a pseudomorphic relationship with phosphoferrite."  


REFERENCES CITED 

Moore, P.B., 1971, The Fe2+3(H2O)n(PO4)2 homologous series: crystal-chemical relationships and oxidized equivalents: American Mineralogist, vol. 56.

Moore, P.B., T. Araki, and A.R. Kampf, A.R., 1980, Nomenclature of the phosphoferrite structure type: refinements of landesite and kryzhanovskite: Mineralogical Magazine, vol. 43.  

Nizamoff, J., 2006, The Mineralogy, Geochemistry and Phosphate Paragenesis of the Palermo #2 Pegmatite, North Groton, New Hampshire: University of New Orleans Theses and Dissertations. 398.

New Hampshire is one of the birthplaces of American freedom and independence - a place with a love and a passion for liberty. Marsha Blackburn


Sunday, October 25, 2020

SYLVANITE: Au! IT'S GOLD

 Even on my best days I do not pretend to be any sort of a “real” mineralogist.  Yes, I have learned to enjoy minerals after giving up my career as a paleontologist/stratigrapher and administrator, and certainly try to learn as much as possible;however, there are many things about the formation of minerals that are beyond the scope of my limited abilities.  One of these areas of confusion remains the formation of the gold deposits in the Cripple Creek Mining District southwest of Colorado Springs.  I probably should leave any musings about Cripple Creek minerals to my friend Bob Carnein up at Lake George.  However, I recently picked up a specimen of sylvanite collected by one S. Willman in 1981 from Cripple Creek (anything more definitive than Cripple Creek is unknown).  Sylvanite [(AuAg)2Te4] is a mineral composed of silver, gold, and tellurium and that makes it even more interesting.

The element tellurium is a silver-white metalloid (possesses properties of both metals and non-metals) with the symbol Te and the atomic number of 52 (number of protons in the nucleus of the atom). It is a critical raw material used in the solar industry, copper and steel alloys, and semiconductors but its extraction also poses environmental risks for our planet (Missenab and others, 2020).

Tellurium exhibits oxidation states of 6+, 5+, 4+, 3+, 2+. 1+, 1-, 2-; however, only 6+, 4+ and 2- are stable. Tellurium can act as a cation with a 4+ oxidation state (a tellurite; IV) as in the uncommon mineral tellurite, TeO2, or with a 6+ oxidation state (a tellurate; VI) as in jensenite, Cu3TeO6-2H2O.   The telluride anion with a charge of 2- can combine with gold and silver cations in the minerals calaverite [AuTe2], krennerite [Au2AgTe8], and sylvanite [(AuAg)2Te4]; all form major gold ores at Cripple Creek, Colorado.  In fact, Eckel and others (1997) noted that other than Cripple Creek, where krennerite and calaverite are the major sources of gold, sylvanite is probably the most valuable of the gold minerals in the other telluride gold deposits of Colorado. 

Although mineralogists have recognized eight gold-silver telluride minerals (calaverite, krennerite, sylvanite, petzite, muthmannite, empressite, hessite, and stuetzite), the gold-rich telluride species—calaverite, krennerite and sylvanite—are the most common and economically important minerals of the group (Zhao and Pring, 2019). Work by Cabri (1965) identified the following amounts of silver in each: krennerite 3.4 to 6.2 wt % Ag; sylvanite 6.7 to 13.2 wt % Ag; and calaverite 0 to 2.8 wt % Ag. Krennerite and calaverite both have over 40% gold while sylvanite somewhere in the mid-30s. However, native gold is the most common gold-bearing mineral, and the most valuable.  Since native gold is rare at Cripple Creek early miners roasted the ore to volatize the tellurium, a process that left rather pure gold as blisters or “sponge.”  See photos below. The current Cresson Pit uses a heap leach process.

Sylvanite has about a 1:1 to 3:1 gold to silver ratio.  In sylvanite [(AuAg)2Te4] the oxidation state of gold is 3+ while silver is 1+ [X 2 = 8+] while Te is 2- X [4 = 8-] and things balance out.  Since it is a metal, sylvanite is opaque and has a shiny, metallic luster with a silver-white streak. It comes in a variety of metal-like colors—white, silver-white, gray, sort of yellow, and is quite soft at ~1.5-2.0 (Mohs).  Crystals vary from platy to prismatic to granular.  My specimen has very tiny crystals and numerous non-descript grains.





Streaks and scattered grains/crystals of silver-gray to silver-yellow sylvanite.  The grains/crystals are submillimeter and are not very distinguishable.  Width FOV top: ~5 mm, bottom: ~4mm.

MinDat notes that sylvanite mostly is associated with low-temperature hydrothermal veins; however, it is also a late forming mineral in medium to high-temperature hydrothermal veins and is usually among the last minerals to form. But, the magmatic-hydrothermal processes causing the tellurium and gold enrichment in epithermal deposits (deposition by warm water shallow crustal environment associated with volcanic activity) is not well understood (Keith and others, 2020). Cripple Creek, with its deposits of gold tellurides, is a notable crustal laboratory for the study of epithermal deposits.   

Since it is near Halloween it is worth mentioning that the type locality of sylvanite is Baia de Aries, Romania. Now think or werewolves, vampires, and Vlad Dracula all living in in this Romanian region of Transylvania.  The name sylvanite comes from Transylvania. Just a little spooky trivia.

REFERENCES CITED

Eckel, E. B. and others, 1997 (original 1961), Minerals of Colorado: Putnam Press and Friends of Mineralogy-Colorado Chapter, Golden.

Cabri, L.J., 1965, Phase relations in the Au-Ag-Te system and their mineralogical significance: Economic Geology, Vol. 60.

Keith, Manuel, D. J., Smith, K. Doyle, D. A. Holwell, G. R.T. Jenkin, T. L. Barry, J. Becker and J. Rampee, 2020, Pyrite chemistry: A new window into Au-Te ore-forming processes in alkaline epithermal districts, Cripple Creek, Colorado: Geochimica et Cosmochimica Acta, Vol. 274.

Missenab, O.P., R. Rama, S.J. Millsb, B. Etschmanna, F. Reithcd, J. Shustercd, D.J. Smithe, and J. Bruggera, 2020, Love is in the Earth: A review of tellurium (bio)geochemistry in surface environments: Elsevier Earth-Science Reviews, Vol. 204, 103150.

Zhao, J. and A. Pring, 2019, Mineral transformations in gold-(silver) tellurides in the presence of fluids: nature and experiment: Minerals, Vol. 9, No. 3 (in  The Special Issue Mineral Surface Reactions at the Nanoscale).

And thinking of Transylvania and Dracula reminds me of my favorite Wm. Shakespeare quote:

 Eye of newt, and toe of frog,

Wool of bat, and tongue of dog,

Adder's fork, and blind-worm's sting,

Lizard's leg, and owlet's wing,—

For a charm of powerful trouble,

Like a hell-broth boil and bubble.

Double, double toil and trouble;

Fire burn, and caldron bubble.