Transcript 礦物種類分子式含銅量
Magmatic deposits—sulfides (Ni and Cr) + PGE
Alkali feldspars at low pressures:
two complete solid solutions with a solvus
Immiscibility
field
礦物種類 分子式 含銅量(%)
自然銅 Native Copper Cu 100
黃銅礦 Chalcopyrite CuFeS2 34.5
斑銅礦 Bornite Cu5FeS4 63.3
輝銅礦 Chalcocite Cu2S 79.8
銅 藍 Covellite CuS 66.4
硫砷銅礦 Enargite Cu3AsS4 48.3
砷黝銅礦 Tetrahedrite (Cu,Fe)12As4S13 57.0
黝銅礦 Tennantite (Cu,Fe)12Sb4S13 52.1
赤銅礦 Cuprite Cu2O 88.8
黑銅礦 Tenorite CuO 79.8
孔雀石 Malachite CuCO3.Cu(OH)2 57.3
藍銅礦 Azurite2 CuCO3.Cu(OH)2 55.1
銅靛礬 Chalcocyanite CuSO4
膽礬 Chalcanthite CuSO4.5H2O
銅葉綠礬 Cuprocopiapite CuFe43+(SO4)6(OH)2.20H2O
矽孔雀石 Chrysocolla CuSiO3.2H2O 36.0
礦物名 化學式 鎳含量
針鎳礦 (Millerite) NiS
鎳黃鐵礦 (Pentlandite) (Fe,Ni)9S8 ( Co 達1-3%), Pt, Pd
紫硫鎳鐵礦 (Violarite) FeS.Ni2S3
紅砷鎳礦 (Nickeline) NiAs
輝砷鎳礦 (Gersdorffite) NiAsS
紅銻鎳礦 (Breithauptite) NiSb
鎳纖蛇紋石 (Garnierite) Ni(Si4O10)(OH)4.4H2O (NiO<46)
鎳綠泥石 (Nimite) (Ni,Mg)6(Si4O10)(OH)8
鎳綠高嶺石 (Ni-Nontronite) (NiO=1-2)
鎳華 (Anrabergite) Ni3(AsO4).8H2O (NiO=37)
Characteristics of PGE in magmatic processes
鉑族金屬(platinum group elements,簡稱PGE)包括釕(Ru)、銠(Rh)、
鈀(Pd)、鋨(Os)、銥(Ir)、鉑(Pt)六個元素。其中釕、銠、鈀為輕鉑族金屬
(比重11~12),鋨、銥、鉑稱為重鉑族金屬(比重21.4~22)。鉑族金屬
的合金具有耐高溫、耐磨擦的特性。在高溫下強度大,具有高延展性和
低膨脹系數,熱電的穩定性好。
鉑族元素具有親鐵性,鈀、鉑、銠還具有親硫性,尤以鈀最明顯,因此易
與鐵、鎳、鉛、銅、錫形成金屬鍵的化合物。Os、Ru、Ir高價離子易與
硫、砷、銻、鉍、碲、硒等形成離子鍵化合物。在自然界鉑族元素獨立礦
物較少,常見的有自然鉑和鉑族元素互化物。
鉑族元素在地函中含量較高,隕石內的含量平均為:Pt 2.0g/t,Pd 1.3g/t,
Os 1.0g/t,Ir 0.7g/t,Rh 0.5g/t,Ru 1.3g/t。在地殼中,鉑族元素多富集於
基性、超基性岩石中。在岩漿結晶分化作用過程中,鉑族金屬主要富集
於鎂鐵質橄欖岩及純橄欖岩中,與鉻鐵礦共生;在蘇長岩、輝長岩中則
與銅鎳硫化物緊密伴生。
Sudbury,
Ontario
SUDBURY MINING CAMP
To date, the Sudbury mining camp
has produced
in excess of 16 billion pounds of
nickel,
15 billion pounds of copper,
85 million ounces of silver,
17 million ounces of platinum, and
3 million ounces of gold and
remains, to this day, Canada’s
principal producer of platinum.
Currently, there are 35 producing
mines in the Sudbury Camp.
• GEOLOGY OF THE SUDBURY REGION
• The Sudbury region is dominated by a large 60 km
long by 30 km wide elliptical depression known as
the Sudbury Structure which lies at the junction of
three unique geological-structural provinces: the
granitic & gneissic basement rocks of the Archean
Superior Province to the north, the supracrustal
metasediments and metavolcanics of the EarlyProterozoic Southern Province to the south, and the
Middle-Proterozoic Grenville Front Tectonic Zone.
•
GEOLOGY OF THE SUDBURY
STRUCTURE
• The Sudbury Structure constitutes
the largest known concentrations
of nickel-copper-PGE bearing
sulfide minerals in the world. Due
to its economic importance, the
structure is one of the most
intensively studied and
documented regions of the
Canadian Shield.
• Stratigraphically, from top to
bottom, the Sudbury Structure
consists of the Whitewater Group
of sediments, the underlying
Sudbury Igneous Complex (“SIC”),
and brecciated footwall rocks
surrounding the SIC.
• The Whitewater Group
• Infilling the central depression of the Sudbury
Structure are the Whitewater Group sediments that
consist of, from top to bottom:
• the Chelmsford Formation greywacke,
• the Onwatin Formation manganese-rich slate,
• and the Onaping Formation volcaniclastic/breccia
sequence.
• The Sudbury Igneous Complex
Underlying the Whitewater Group is the Sudbury Igneous
Complex (“SIC”). The SIC consists of a lower zone of augitebearing norite; a thin middle layer (Transition Zone) consisting
of norite grading upwards into quartz gabbro; and an upper
zone of micropegmatite/granophyre. At the base of the lower
zone is a discontinuous zone of inclusion and sulfide-rich
norite-gabbro commonly known as the Contact Sublayer
(“Sublayer”). The Sublayer occurs as gently dipping sheets or
irregular lenses along the base of the SIC or as small bodies in
radial depressions or troughs in the base of the SIC called
embayments, and as steeply dipping dikes called offsets which
intrude into the adjacent footwall. The Sublayer is typically
gabbroic in the base of the SIC and in the embayments, and
typically quartz-diorite in the offset dikes. All Ni-Cu-PGE
deposits of the Sudbury Structure are contained within the
Sublayer and related structures such as the offset dikes.
•There are two types of offset dikes:
•1. radial, which appear to stem directly from the Sublayer
and intrude into the footwall rocks radially away from the SIC.
•2. concentric dikes, which are thought to be related to ring
faults and may be connected to the Sublayer at depth or
represent accumulations of melt rock associated with
pseudo-tachylyte formation.
• Origin of the Sudbury Structure
• Existing evidence for the origin of the Sudbury Structure
supports a meteorite impact. This includes: the irregular and
dike-like bodies of pseudo-tachylyte breccias (Sudbury and
Footwall breccias) up to 70 km from the margins of the
structure; shatter cones in rocks marginal to the structure; the
1.8 km-thick volcaniclastics/breccias of the Onaping formation
(interpreted as fallback breccia); and shock deformation
lamellae in quartz and feldspar in country rock inclusions
within the Onaping formation. The following summarizes the
evolution of the Sudbury area.
• MINERALIZATION AND DEPOSIT TYPES OF THE
SUDBURY STRUCTURE
• Sudbury ores are typically zoned. Fractional crystallization of
a monosulfide solid solution from a sulfide melt is believed to
have given rise to a cumulate phase rich in Fe, Co, Rh, Ru, Ir
and Os (pyrrhotite-rich ores) and a fractionated liquid rich in
Ni, Cu, Pt, Pd, and Au (chalcopyrite and PGE-rich ores). In
some cases, the liquid phase is then believed to have migrated
out from the Sublayer and further fractionated to form Cu and
PGE rich footwall ores.
• Common Ni and Cu-ore minerals consist of pyrrhotite,
pentlandite, chalcopyrite with minor pyrite, and cubanite
(CuFe2S3).
• Sudbury Ni-Cu-PGE sulfide mineralization occurs in three
deposit settings:
• Contact deposits or “embayment” deposits
• Located along the lower contact of the SIC in association with
the norite-gabbro inclusion-bearing Sublayer. The Sublayer
may be up to 100 metres thick. The greatest thicknesses are
found in kilometer-size radial embayments within which are
smaller, secondary troughs or “terraces”. The highest sulfide
concentrations in the Sublayer are found within these
embayments where sulfide distribution is further controlled by
the terraces. Large concentrations of sulfides and nickel are
often found in footwall deposits immediately adjacent to the
terraces. Cu/Ni ratios are typically lowest in the Sublayer and
increase towards the Footwall Breccia.
• The Sublayer constitutes a well defined exploration target and
has been a prolific producer over the years. Consequently
contact deposits comprise 21 of the 35 mines in the Sudbury
area. Contact deposits at the base of the SIC are still currently
being mined by both Falconbridge and Inco at the
Falconbridge, Garson and Levack mines.
• Footwall deposits
• Zones of sulfide mineralization in the form of stringers, veins,
massive sheets and/or disseminated sulfide which appear to
have migrated outwards from the Sublayer and/or Footwall
Breccia and penetrated deeply into the footwall rocks. The
Frood-Stobie Mine, which is estimated to have originally
contained a geologic resource of 450 to 500 million tonnes, is
the largest and best example of a footwall deposit. This mine
lies at the east end of the South Range Breccia Belt and is
situated almost 2 km into the footwall.
• Offset Dike deposits
• Associated with radial and concentric quartz-diorite dikes that
extend from the Sublayer into the footwall rocks.
Mineralization typically occurs as disseminated to massive
sulfides within the dikes. The massive sulfide bodies are often
rimmed by a halo of disseminated material that is often found
along the contacts of the dike. Examples of offset deposits
include Nickel Offsets along the Foy Offset dike, and the
Copper Cliff North and South mines and the Totten Mine
along the Copper Cliff Offset and Worthington Offset dikes,
respectively.
Great Dyke: 330 mile long, 4 mile wide, consists of layers of
ultrabasic rocks now largely altered to serpentine.
The dyke deposits are bands of chromite about 8 inches thick.
Stillwater, Montana: an E-W belt about 50 km long and 1 km wide.
Muskox, NW Territories: a Pre-Cambrian layered ultramafic complex.