As mentioned in previous Blogs on
millerite/polydymite and siegenite, nickel (metal) is produced either from
sulfide minerals or from laterite deposits.
These minor nickel sulfides noted above piqued my interest in nickel
minerals so I journeyed down to my favorite rock and mineral store, Ackley’s in
Colorado Springs. I actually was looking
for a sample of pentlandite, the most common nickel sulfide, and was unable to
find such. I wanted a sample of this
sulfide since several years ago I was with my family traveling and camping
across eastern and central Canada and so detoured through the city of Sudbury. Why Sudbury?
Well, I wanted to see the famous nickel mines and smelter, and also Sudbury
is situated in the second largest impact crater known on Earth. The meteor struck what is now part of
Ontario, Canada, about 1.85 Ga (Precambrian: Proterozoic). Many millions of years have elapsed since the
6-10 mile (diameter) fireball impact and the area has been subject to numerous
deformational and orogenic events, and weathering. Therefore, it is difficult for geologists to
define the original size of the crater; however, it was much larger than the
present size of about 40 mi x 20 mi. Debris from the impact may have been
scattered across the globe but is probably unrecognizable or destroyed after
such a long period of time.
At one time geologists speculated that the large
nickel deposits at Sudbury were part of the meteorite (as in iron-nickel meteorite). However, that is an erroneous conclusion
(although it sometimes still is floated around). The Sudbury nickel is found in a typical
pyrrhotite-pentlandite massive sulfide ore that is of mantle origin associated
with an intrusive event. The impact force
of the meteorite caused wholesale melting of the mantle, triggered the huge
intrusion, and emplaced the nickel deposit (Stefano, 2014, personal
correspondence). How much nickel? Canickel Mining Limited (2014) estimated that
over US$120 billion worth of nickel, copper and Platinum Group Minerals have
been produced from the region over the past 100 years!
Sudbury’s other claim to fame (probably a claim to
shame) was the tremendous pollution of the area by the mine and smelter. The
landscape reminded me of what I imagined the lunar landscape looked like. Even
my children wanted a bottled (out of area) drink. Virtually nothing was alive except people and
all the vegetation seemed dead or dying.
Keller (2014) noted that in the 1960s and 70s “air pollution from the nickel smelter was so bad it
literally blackened the earth: acid rain, along with mining operations,
stripped the land of vegetation, leaving 100,000 hectares of barren or
semi-barren moonscape. The water was exceptionally bad. More than 20,000 lakes
in Ontario were acidified to the point of ecosystem damage, 7,000 of them within
Sudbury’s immediate vicinity. Lakes within the city and beyond were some of the
most acidified, metal-contaminated lakes in the world.” I remember taking numerous slide photos to
show my intro geology classes about the effects of nickel smelting and mining running
amuck. The good news is that the community and mining operations took
reclamation seriously and today the remediation is quite noticeable---things
are looking much better. However, part of this remediation included building
the Inco Superstack (~1250 feet) to disperse SO2 gases and other
byproducts of the smelting process away from the city of Sudbury. The Superstack placed the gases high in the
air where they blew right past the city of Sudbury. While the Superstack
lowered the ground-level pollution in the city, it has dispersed sulfur and nitrogen
gases over a much larger area. In
fact, environmentalists estimate that the Superstack accounts for ~20% of all
of the arsenic emitted in North America, ~13% of the lead and ~30% of the
nickel.
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Superstack at Sudbury. Public Domain photo.
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So, mining and
smelting of nickel is one of those conundrums. Sort of dammed if you mine and dammed if you
don’t. Countries need the nickel in ever
increasing quantities; however, environmental damage may be extensive. I certainly don’t have the answer!
OK, back to the minerals. Although pentlandite was unavailable at
Ackley’s, the proprietors did have several samples of a nickel “mineral” called
garnierite, a substance completely unfamiliar to me. Well, pack it up and I will do some reading!
As I noted above, laterite deposits are the major
source of nickel in today’s world, and garnierite is a lateritic nickel
“mineral.” Laterites usually develop
within 20 degrees latitude of the equator in a tropical environment where
chemical weathering is most intense. The
most soluble elements of the country rock dissolve away leaving behind the
less-soluble minerals that are progressively redistributed throughout a series in
a more-to less-weathered profile. Certain
less soluble minerals often form a concentrated deposit within the profile
(Samama, 1986). These concentrated
elements/minerals vary in composition depending upon the makeup of the weathered
country rock. Often, nickel and cobalt lateritic deposits are formed from
weathering of serpentinite, dunite, peridotite and other ultrabasic rocks (low
silica, low potassium, dark colored high iron and magnesium content) that are nickel-
and cobalt- enriched. With exxtensive
weathering the more soluble calcium, silicon and magnesium are removed from the
profile while elements like manganese, copper, nickel, iron, zinc, aluminum,
titanium and some rare earth elements are concentrated (Brand and others, 1998).
The weathering profile of these laterites is
multifaceted and ranges in a continuum from the unweathered country rock through
deeply weathered, but in place country rock, through magnesium- and nickel-rich
silicates into clay layers and finally into various zones of iron oxide. Most of the concentrated cobalt is found in
the iron oxide zones while the enriched nickel is deeper in the profile in the
magnesium- and nickel-rich hydrous silicates.
Nickel-enriched lateritic ores are well-known and productive in Western
Australia, Cuba, New Caledonia, Greece and Russia (Marsh and Anderson, 2011). In the United States the Nickel Mountain
laterite deposit (Riddle District) in the Klamath Mountains of Oregon was a
producing mine until 1998 with an average grade of perhaps 1.4 % nickel. Around 25 million tons of nickel was produced
and at least that much of the metal remains.
In addition, the smelter near the mine closed shortly after the mine was
shuttered. However, as I understand it,
there are numerous mining claims in the Riddle District extending from Oregon
south into California.
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Map showing hypothetical active west coast of
U.S. Oceanic crust subducted under
continental crust. Sketch courtesy of
www.sjvgeology.org/geology/tectonics.html
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Map showing accretiated terrane (exotic terrane) in
western North America. These silvers of
land were once island arcs or pieces of oceanic crust that were “stuck” to the
continent during collision with the proto North America. Map courtesy of USGS at: http://pubs.usgs.gov/gip/dynamic/Pangaea.html
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The Riddle District laterites are the result, then,
of intense weathering of ultramafic rocks.
The question then becomes, at least to me, what is the source of these
ultramafic rocks? The geology of this
part of Oregon, and in fact much of the western U.S. Coast, is quite complex
since for long periods of recent geological history this edge of the continent
was active and colliding with oceanic terrane to the west. Some of the oceanic
terrane was subducted below the continental crust. However, other parts were accreted or “stuck
to” the continent. This later terrane is
mostly composed of oceanic ultramafic rocks and deep ocean sedimentary rocks. The
weathering of these terranes in the Riddle District is something like Miocene
in age. And, the laterite formation at
Riddle is an anomaly since the equator was not within 20 degrees.
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Garnierite: chalcedony infused with nickel
(chrysoprase?) and small nodules of concentrated nickel. Nodule from Nickel Mountain, Oregon. Width
~4.3 cm.
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| Garnierite a mixture of nickel silicates. Note some darker green nodules that probably contain a higher percentage of nickel. Nodule from Nickel Mountain, Oregon. Width ~ 6 cm. |
Although some of the nickel at Nickel Mountain was
enriched iron oxides most was contained in hydrous magnesium-and
nickel-enriched silicate termed garnierite.
At one time garnierite was considered to be a mineral but the official
name has been discredited and garnierite now refers to a variety of green nickel
ore with a varied composition and seemingly a quite complex chemical
history.
The green color in garnierite varies, seeming with
composition and depositional environment.
Pecora and others (1949) believed light colored garnierite was due to
the alteration of olivine-rich ultramafic rocks rich in clay minerals but poor
in nickel. The light green to bright
green garnierite resulted from the leaching of manganese oxide, magnesium,
nickel and iron from the original dark green garnierite, rich in nickel, which
was originally deposited by groundwater.
With newer instrumentation available (Extended X-ray Absorption Fine Structure) Roqué-Rosell and others
(2011) found that garnierite is actually a solid solution series between
sepiolite, a complex, magnesium-rich clay mineral [Mg4(Si6O15)(OH2)-6H2O)]
and falcondoite, the nickel rich analog of sepiolite [Ni3Mg(Si6O15)(OH2)-6H2O)]
with samples analyzed showing between 3 and 77 percent falcondoite.
In my advanced years I am often confused J So, I remain somewhat confused about
garnierite. The notation above indicates
the garnierite is a mixture of falcondoite and sepiolite. OK, I certainly can buy that explanation. However, if I go to my favorite mineral
website (MinDat.com), garnierite is listed as synonym of nepoulite,
willemseite, and pimelite of which only the latter is found in Oregon; all are
complex magnesium-nickel silicates. I have seen other references that indicate
some garnierite is chrysoprase, a nickel-enriched chalcedony. The best that I
can do is quote the “official” explanation from MinDat: “[Garnierite is the] generic
name for a green nickel ore which has formed as a result of lateritic
weathering of ultramafic rocks (serpentinite, dunite, peridotite). [It is] mostly a mixture of various Ni- and
Ni-bearing magnesium layer silicates.
[Garnierite] occurs in many nickel laterite deposits in the world.”
I’ll tell you what---I learn so much every day of my
life and for this I give credit and thanks to my early childhood teachers, and
to my parents. Although both paraphrased
the following quote, it was a mantra they instilled in their children: You can
teach a student a lesson for a day; but if you can teach him to learn by
creating curiosity, he will continue the learning process as long as he lives.
~Clay P. Bedford
REFERENCES
CITED
Allen, K., 2014, What Sudbury can teach China about
Air Pollution: www.TheStar.com/news, May10,
2014.
Brand, N.W., Butt, C.R.M., and Elias, M., 1998,
Nickel Laterites: Classification and Features: AGSO Journal of Australian
Geology and Geophysics, v. 17, no. 4.
Canickel Mining Limited (2014), Sudbury
Properties—Ontario: www.canickel.com.
Marsh, E. and E. Anderson, 2011, Ni-Co laterites: A
Deposit Model: USGS Open-File Report-1259.
Pecora, W.T., Hobbs, S.W. and Murata, J.K., 1949,
Variations in Garnierite from the Nickel Deposit near Riddle, Oregon: Economic
Geology v. 44.
Roqué-Rosell, J., Villanova-de-Benavent, C.,
Proenza, J.A., Tauler, E. and GalÃ,S., 2011, Distribution and Speciation of Ni
in Sepiolite-Falcondoite-type “Garnierite” by EXAFS: Macla, v. 15.
Samama, J., 1986, Ore Fields and Continental Weathering:
New York, Van Nostrand Reinhold Co., 326p.