Greisens and Related Ore Deposits PDF

Summary

This document provides a description of greisens and related ore deposits, focusing on their formation, types, and characteristics. The text details the hydrothermal processes involved in the formation of these deposits and highlights their association with specific metal mineralizations. Examples of greisen deposits from various locations are also included.

Full Transcript

GEOL3051A
L15 Greisens and related
ore deposits

Dr Linda Iaccheri
School of Geosciences
[email protected]
Greisen

2
3 Types of hydrothermal ore deposits:

1. Deposits that have a close spatial and temporal association
to magmatic activity

2. Deposits that form during periods of regional magmatism and
tectonism, but are not clustered close to or around magmatic
centres

3. Deposits that lack widespread or temporally related
magmatic activity
 Greisens and their mineralisation
Greisen = hydrothermal alteration of granitic rocks by
hot magmatic fluids

assemblage of quartz + mica which can be
accompanied by other minerals typically including
fluorite +/- topaz +/- tourmaline.

Greisen systems are typically associated with Sn, W,
Mo, Be, Bi, Li and F mineralisation.

Greisens have been a major source for Sn cassiterite
(SnO2), also tungsten scheelite (CaWO4), wolframite
(Fe,Mn)WO4

they are generally small deposits associated with
4
granites.
 Hydrothermal alteration assemblage of granitic rocks
Main silicate minerals: quartz + Muscovite
Minor minerals: fluorite, tourmaline, topaz

Greisens are similar to phyllic alteration of the porphyry
copper deposits, but here hydrothermal fluids are rich in
F and B, and deposits and alteration halos are much
smaller

Greisens often form aureoles around late-stage veins,
particularly quartz- cassiterite- wolframite veins
The greisens can either be enclosed within the granite
(endo-greisen) or can be within the roof-rocks to the
granite (exo-greisen) or sometimes both endo and exo.
5
A greisen is a hydrothermal
assemblage of minerals formed
from altered granite or pegmatite
by late stage magmatic fluids
exsolved from a granite magma.

Metals are likely to be transported in the fluid by either Cl- or F-
complexes

Gangue minerals include:
Quartz-mica (muscovite, lepidolite, Li-Fe biotites) ± topaz, tourmaline,
fluorite
The process of greisen formation is greisenisation

Tourmaline W-bearing vein
Cligga Head,
with greisenisation
Cornwall, UK
alteration halo
Examples of Greisen deposits:
Cornwall (UK),
Erzgebirge-Krusne hory (Germany-Czech
Republic),
Zaaiplaats (Bushveld, S. Africa),
Nigerian A-type granites,
Mt. Bishoff (Tasmania, Australia).

Deposits are typically
hosted in vein systems
(Cornwall) or may be
disseminated within the
granite (Zaaiplaats) or both
(Kinta Valley, Malaysia)
Greisen deposits are smaller than porphyry copper deposits

Important source of Sn (tin) in cassiterite and W
By products: Cu, Zn, Bi and Mo

Example: ZAAITPLAAS Tin Mine in South Africa
 Mineralisation in the Bushveld granites
 Mineralisation in the Bushveld granites

ZAAIPLAAS Tin mineralisation

The Bushveld Complex
2060-2054 Ma

Within the Lebowa Granite Suite of the Bushveld Complex
The Rustenburg Layered Suite
 Granites
RUSTENBERG LAYERED SUITE Lebowa Granite Suite

2000 m thick
Belong to Bushveld granites and
overlie the Rustenburg Layered
Suite

4000 m thick Considered A-type (anorogenic)
granites: produced from mantle
melting with variable amounts of
crustal contamination.
400 - 1000 m thick
chromitites
800 m thick

0 - 1600 m thick
Lebowa Granite Suite:

Bobbejaankop Granite: coarse-grained, miarolitic, disseminated ore,
mineralised pipes.
Lease Granite: fine-grained, miarolitic, low-grade ore, mineralised pipes;

They are overlain by the Rashoop Granophyre Suite
ZAAIPLAAS Tin mineralisation hosted in:

The exsolved magmatic-hydrothermal fluids crystallise within the upper
part of the intrusion and alter the intrusion itself:
 Greisen mineralisation
Exsolved magmatic hydrothermal fluids crystallise within the pluton forming:

- pockets and/or pipes of highly fractionated part of the granitic suite +
mineralisation within the intrusion
- Disseminated mineralisation occurs within the centre part of the granitic
intrusions (cassiterite SnO2) in a zone beneath the Lease Granite
N Mogalakwena Mine

Lease Granite
 View on the old processing
and concentration plant

Old workings on
the Bobbejaankop
granite
ZAAIPLAAS Tin mineralisation
hosted in:

pockets and/or pipes in the
Lease Granite
Disseminated mineralisation
lower part of the Lease
Granite
 Deposits may also include alteration and veins that extend from
greisens into rocks that have different alteration assemblages

Take the form of lenticular bodies, irregular patches or sheeted veins with
low grade ore e.g. 0.25% Sn

Sometimes disseminated ore may be mineable
Pipe-like body in
Bobbejaankop Granite Why are
there holes?

What is that
Miarolitic Bobbejaankop Granite
halo?
Tourmaline pipes and greisen

Greisen Alteration zoning:
 Pipe-like body in Bobbejaankop Granite
Miarolitic Bobbejaankop Granite at
the type locality

Taylor (2005)

Vonopartis (2021)
Unaltered
Bobbejaankop Sericite &
Outer silicic Tourmaline + Cassiterite
core
alteration Quartz alteration
zone
 Greisenisation

Process of hydrothermal alteration of
primary granite minerals (feldspar and
muscovite) to aggregates of quartz and
tourmaline
 Cassiterite-tourmaline-sulphide association at Zaaiplaats

Zoning Outer silicic zone
High grade cassiterite occurs in
Core of sericite of bleached granite
tourmaline-rich ore pipes and in ore
and cassiterite
pockets
Extend from Bobbejaankop granite to
Lease granite
Pipe-like form (0.1-3 m diameter)
and in circular in plan view
May be horizontal or vertical with
richest ore in vertical pipes
Sericitic alteration common
Tourmaline and
Sulphides, scheelite and molybdenite
quartz
are also present
Formation of the Zaaiplaats Tin Granites

a. Early separation of a H2O-NaCl-CO2
fluid enriched in boron to produce
pipe-like conduits by collection and
upward flow beneath crystallisation
fronts.

b. Accumulation of fluorine-rich fluids
evolved at a more advanced stage
beneath downward advancing
crystallization fronts to produce
strongly miarolitic zones within the
Lease Granite containing Vonopartis (2022)

disseminated cassiterite.
Formation of the Zaaiplaats Tin Granites

c. Accumulation of fluorine-rich
hydrothermal fluids producing a
disseminated cassiterite
mineralisation zone

d. Pervasive alteration of the
granites accompanied by filling of
miarolitic cavities and pipes

Vonopartis (2022)
In Summary

Granite related Sn-W deposits are commonly associated with greisenisation.
Greisenisation can occur within and outside a granitic body.
Metals are carries within magmatic-hydrothermal fluids within metal-Cl
complexes.
The magmatic-hydrothermal fluids interact with the wall-
rocks/meteoric fluids. This causes alteration and changes the
composition of the fluids – resulting in precipitation of metals.
Greisenisation is an acidic reaction that commonly produces white-
micas.
Uses of tin Major producers
Tin plating China
Solder Thailand
Bronze, brass and pewter Malaysia
Chemicals for paint and glass Indonesia
industry, plastics and insecticide Brazil
Bolivia
Linda Iaccheri
School of Geosciences
[email protected]
3 Types of hydrothermal ore deposits:

1. Deposits that have a close spatial and temporal association
to magmatic activity

2. Deposits that form during periods of regional magmatism
and tectonism, but are not clustered close to or around
magmatic centres

3. Deposits that lack widespread or temporally related
magmatic activity
 VOLCANOGENIC MASSIVE SULPHIDE (VMS or VHMS) DEPOSITS

 Massive sulphides mineralisation hosted in mafic volcanic rocks

 Not magmatic, but due to hydrothermal processes on mafic oceanic crust

 Complex ore deposits

 Cu-bearing massive pyrite deposits

 by-product Au, Ag, Pb, and Zn
Major VMS deposits in the world
 Characteristics of VMS deposits

VMS deposits occur worldwide throughout geological time

Associated with altered volcanic mafic rocks (basalts)

comprise massive sulphides (> 60%) which occur in lens-like or tabular
bodies parallel to the volcanic stratigraphy or bedding

The deposits usually zoned with massive syngenetic sulphide ores above
an epigenetic footwall stockwork of vein and stringer sulphide
mineralisation and hydrothermal alteration
VMS deposits are usually zoned:
massive syngenetic
sulphide ores

Altered basalt (host-
rock)
Epigenetic footwall of
stockwork
mineralisation and
sulphides stringers
Zoning in the massive
syngenetic sulphide ores

 Core: chalcopyrite + pyrite +
pyrrhotite + magnetite

 Grading upward: pyrite ±
sphalerite ± galena

 Then: sphalerite ± galena ±
pyrite ± barite

Au, Ag usually are highest in the fringes with barite and cherty silica as common
gangue accessory minerals
 Modern massive sulphides

Submarine Alvin in 1977 in deep-sea on
the East Pacific Rise, at 21°N, found 300°C
hot springs emerging in plumes along the
oceanic ridge, 2500 m below sea level

- BLACK SMOKERS
 minerals precipitated out of the solution as soon as it emerged
around the vents was a blanket of sulphides
a modern analogue of Volcanic Massive Sulphides deposits found in old
orogenic belts
scientists discovered populations of previously unknown organisms living
near the vents
 modern massive sulphides
modern deposits are important because conditions of formation can be measured directly,
and they show how little time is needed to produce appreciable tonnages of 'ore‘.

Their rapid oxidation and destruction show the transitory nature of these deposits.
Cross-section of a black smokers and massive sulphides
Locations of formation of modern VMS deposits

Schulz 2012. USGS Report. Modified after Schmincke (2004) and Galley and others (2007).
https://www.interridge.org/
VMS deposits are related to the formation of Black smokers on
oceanic floors
“Black smokers” – a modern analogue for VMS deposit formation

□ Black smokers are hot (up to 400 °C), metal charged, reduced, and slightly acidic
hydrothermal fluids that vent onto the sea floor, usually in zones of extension and
active volcanism along mid-ocean ridges

□ The fluids originate from cold (2 °C), alkaline, oxidizing, and metal-deficient seawater.

□ The fluids circulate through the basaltic ocean crust and, in so doing, scavenge
metals to form the hydrothermal fluids

□ Precipitation of base metals (mainly Cu and Zn transported as chloride complexes;
Scott, 1997) and, in certain cases, precious metals (Au transported as a gold–bisulfide
complex; Scott, 1997) is virtually instantaneous as the ore fluids mix with an
essentially infinite volume of very cold (2–4 °C) seawater.

1
5
“Black smokers” – a modern analogue for VMS deposit formation

□ Black smoker fluids usually vent through tube-like structures, called chimneys

□ Chimneys are built out of a mixture of anhydrite, barite, and sulfide minerals such
as pyrite, pyrrhotite, chalcopyrite, and sphalerite, as well as gangue opaline silica.

□ Metal-charged fluids venting on the ocean floor point to the hydrothermal
exhalative processes by which most, if not all, VMS deposits can be
explained

□ Drop in Temperature (seawater T few degrees) at the exit of the chimneys
causes an instantaneous drop of the sulphide minerals
Modelled hydrothermal fluids cell
responsible for the formation of black
smokers and VMS deposits close to mid-
oceanic ridges

1
7
 Exhalative vent site showing the
construction of anhydrite–
sulfide chimneys on top of a
mound of massive sulfide
mineralization.

Fluid characteristics and circulation
patterns in mid-ocean ridge environments
that give rise to the formation of “black
smokers” on the sea floor.
1
9
 Formation of ophiolite-hosted VMS deposits

Ocean water flows through fractures and at divergent plate
normal faults in mafic oceanic crust and boundaries
percolates deep into the oceanic crust via
faults

Seawater is progressively heated by
the underlying mafic magma
chamber, and becomes a
hydrothermal fluid.

A seawater convection cell reacts with
basalts, alters them, and leaches metals.
 Formation of ophiolite-hosted VMS deposits

Dissolved metals are transported back up at divergent boundaries
to the ocean floor.

When hot hydrothermal fluid mixes with
the cold bottom ocean waters, there is a
sudden decrease in temperature causes
metals to precipitate from the solution
 Source of hydrothermal fluids and paths

Seawater

Percolate deep into the oceanic crust
via normal faults
 Source of metals

ore metals are derived and
scavenged/leached from the mafic
volcanic rocks that form the oceanic
crust
Cu and Zn are derived from alteration
of pyroxenes
 Formation of ophiolite-hosted VMS deposits

 metals precipitated are sulphides and sulphates
 they form sulphide-rich mounds and chimneys
around plumes of smoke
 Chimneys may be finger size of several metres
high – chimneys
 may be active for periods of a few years to
decades

 Black smokers - fine-grained pyrrhotite with
minor sphalerite and pyrite
 White smokers -silica, barite and pyrite
Major VMS deposits in the world
 VMS can be found in ophiolite (e.g. Cyprus and Oman)
 Ophiolite is a remnant of oceanic crust
preserved in continental collision zones

Ophiolitic sequences 
 Simplified
VMS ores associated with the basalts and
pillow lavas; ophiolitic
sequence
massive ores dominated by pyrite
together with variable amounts of
chalcopyrite, sphalerite and
pyrrhotite

massive sulphide overlie stringer
zones (stockwork mineralisation)
Section through a typical
ophiolite- hosted, Cyprus-
type VMS deposit.
Footwall rocks may consist
of a sheeted dyke complex
and the associated volcanics
are often pillowed and have
a tholeiitic composition.
Ore deposits associated
with ophiolites
 GEOL3051A
L17 Hydrothermal deposits -
Linda Iaccheri IOCG
School of Geosciences
[email protected]
3 Types of hydrothermal ore deposits:

1. Deposits that have a close spatial and temporal association to
magmatic activity

2. Deposits that form during periods of regional magmatism
and tectonism, but are not clustered close to or around
magmatic centres

3. Deposits that lack widespread or temporally related
magmatic activity
 What are IOCGs?

Hydrothermal ore deposits characterized by large amounts of
hydrothermally precipitated iron oxide (magnetite and/or
haematite)

 hematitic alteration

with associated copper-iron sulfides and gold.

As we will see, it is a very broad group of ore deposits.
 IOCG Deposits
did not exist as a deposit-type before the discovery of Olympic Dam in 1975-
1976.

The first academic paper defining them is:
Hitzman et al., (1992) Geological characteristics and tectonic setting of Proterozoic
iron oxide (Cu-U-Au-REE) deposits.

Once Olympic Dam was discovered, evaluated, and found to be the world’s:
5th largest copper deposit,
3rd largest gold deposit and
the world’s largest uranium deposit –
Everybody wants one!!!

 Now there are IOCG’s all over the world.
The Gawler Craton & Olympic Dam

The Olympic Dam IOCG deposit is
located in the north of the Gawler
craton (South Australia), fairly
close to the craton margin.
The Gawler Craton and the discovery of Olympic Dam

Olympic Dam has been discovered by geophysics: it is buried
and not exposed, in an area of very flat topography:
Before Olympic Dam discovery

Olympic Dam today 7
Olympic Dam: Discovery in 1975

Western Mining
Tim O’Driscoll  lifelong interest in regional and continental linear structures
 Olympic Dam: Discovery in 1975
1974 selected targets for
drilling campaign based on
regional linear discontinuities
and magnetic anomalies

Beginning of modern
geological exploration.
World map of IOCG deposits and significant Na(-Ca) and K alterations
from Barton (2014)
Diversity is indeed a hallmark of the IOCG deposit class:

 diversity within the IOCG deposits in terms of the mineralogy of the iron oxide
phase, with the terms ‘hematite-group’ and ‘magnetite-group’

 The sources of fluids associated with IOCG deposits can vary from magmatic
to sedimentary

 A large spectrum of alteration minerals associated with IOCG deposits

 IOCG deposits are complex ore deposits

 economic elements like uranium, iron, lead, zinc, silver, bismuth and rare
earth elements, in addition to the main ore forming elements copper and
gold
Copper in IOCGs,
Olympic Dam has more Cu
than two of the largest
porphyry copper deposits
(Bingham Canyon and
Grasberg)

Groves et al., 2010

Gold in IOCGs,
Olympic Dam is a more
important gold deposit than
any VMS, and any porphyry
Au system
 Table with resource data for IOCG deposits from Australia and
South America
Mt Cu (%) U3O8 (ppm) Au (ppm) Other

Gawler Craton (South Australia)
Olympic Dam 8,330 0.8 280 0.76 3.95 g/t Ag
Prominent Hill 152.8 1.18 0.48
Hillside 170 0.7 0.2
Wilcherry Hill 60 31% Fe
Carapateena 203 1.13 0.56
South America
Punta del Cobre (Chile)
La Candelaria (Chile) 600 0.95 0.2 3 g/t Ag
Mantoverde (Chile) 580 ~0.5
Mantos Blanco (Chile) >500 1.0
Cloncurry District (Queensland, Australia)
Ernest Henry 122 1.18 0.55
Mt Elliot 475 0.5 0.3
South America
Cristalino (Brazil) 500 1.0 0.2-0.3
Sossego (Brazil) 355 1.1 0.28
Igarape Bahia (Brazil) >30 2
Salobo (Salobo) 986 0.82 0.49
It has been difficult obtaining a consensus on what constitutes or
characterises a “typical” IOCG, because there is diversity within the
deposits.

 critical features of the IOCG sensu stricto deposits
 IOCG Sensu Stricto (strictly speaking):

 hydrothermal deposits that contain economic Cu + Au grades
(generally 0.7-1.5% Cu; 0.8 – 1 g/t Au);

 Structurally controlled and commonly containing significant
volumes of breccia;

 Commonly associated with pre-sulfide sodic or sodic-calcic
alteration on a large, often regional scale relative to economic
mineralization;
 IOCG Sensu Stricto (strictly speaking, cont.):

 Contains abundant low-Ti iron oxides (hematite or magnetite)
associated with, but generally earlier than, Fe-Cu sulfides;

 They have low-S sulfides (= lack abundant pyrite);

 They generally have elevated (anomalous) Ce and La (REE);
 IOCG Sensu Stricto (strictly speaking, cont.):

 Lack abundant quartz veins or silicification;

 Show a clear temporal, but often not close spatial, relationship to
major magmatic intrusions;

 Form from highly oxidized, saline fluids.
 Characteristics of IOCG's

 Age:

Late Archean to Pliocene (basically most of Earth’s geological history).

However, most of them formed in the Archean to mid Proterozoic.
 Characteristics of IOCG's

 Tectonic setting:

- extremely variable
- Associated to major crustal structure and shear zones
- Most major districts appear to be “anorogenic.”

Mesozoic Andean (and Mexican) deposits in subduction-related settings –
probably fundamentally different from Precambrian examples.
 Characteristics of IOCG's

 Association with igneous activity:

the vast majority are spatially related to magmatic event, but this does NOT
mean genetically related
No specific magma composition is related to the deposits.

Extremes:
Raul, Peru, South America – direct spatial, temporal, and genetic
relationship to dacite dome field

Wernecke, Yukon, Canada – no evidence of spatial, temporal, or genetic
relationship to any igneous rocks (driven by circulating basinal brines in
evaporite basin?)
 Characteristics of IOCG's

 Structural control:

Localised along high-angle (most common) or low-angle faults which
are commonly splays off crustal-scale structures.

Very commonly in zones of ductile-brittle transition with sulphides
precipitated during transition(s) between ductile and brittle
deformation or in the brittle phase.

Commonly with large volumes of breccia formed in different regimes
(in- situ replacement breccias and brittle structural breccias).
 Characteristics of IOCG's

 Mineralogy:

- Iron oxide minerals (magnetite, hematite) dominant,
- minor sulfides (generally chalcopyrite, lesser pyrite),
- gangue: feldspar, mica, calc-silicate minerals, carbonates, barite, (quartz)

 Large alteration footprint

Alteration minerals change with protolith and depth and/or
distance from the hydrothermal fluid conduit.
 Characteristics of IOCG's
 IOCGs – Elemental Variation
A hallmark of these deposits is that each district (if not deposit) has a
slightly different trace element signature:

–Olympic Dam, Gawler Craton, Australia (U, Ag, F)
–Salobo, Carajas district, Brazil (F, anomalous As, Co, Mo, Ni)
–Cloncurry, Australia – Mt. Dore (Zn, Pb); Mt. Cobalt (Co);
–Candelaria, Chile (Zn, Co, Ag)
–Great Bear, NWT Canada – Nico (Co, Bi); Port Radium (U)
–Guelb Moghrein, Mauritania (anomalous Bi, Te)

This reflects the geochemistry of the crust through which the
hydrothermal fluids moved.
24
 Characteristics of IOCG's

 Alteration:

There is a variety of alteration types, generally with regular time-
space pattern

Characteristic alteration type of IOCGs is sodic or sodic- calcic

Most IOCG sulfides ore with potassic, calcic, or hydrolytic
alteration assemblages.
 Vertical Variation in IOCG
System Alteration Patterns

5 km
1 km
Hydrolytic alteration

Potassic/calcic alteration
Sodic/sodic-calcic alteration

IOCG deposits
Mgt-apatite (IOA) deposits
(“Kiruna-type”)
 Vertical Variation in IOCG
System Alteration
Pb, Zn?
Patterns
Ag, Co,
U, S
5 km
1 km
Fe, Cu,
S, Au
Hydrolytic alteration

Potassic/calcic alteration
Fe Sodic/sodic-calcic
alteration
IOCG deposits
Fe Mgt-apatite (IOA) deposits
(“Kiruna-type”)
 IOCGs Alteration

Sodic and Sodic-calcic:

typical of this deposit type
Alteration mineralogy is wallrock controlled:
» Albite (scapolite) in more felsic host rocks
» Albite-actinolite-diopside (scapolite) in more mafic host rocks
 Sodic Alteration
(NB albite is not always a white colour – it
“White Rock”
can also be red)
Rhyodacite ash flow altered to
albite with disseminated hematite
(“red
“
rock”), footwall of Kiruna
magnetite orebody, Sweden.
Massively albitized diorite
with minor chlorite-
magnetite. El Espino, Chile

Felsic volcanic rocks altered to
albite (red with hematite“dust”)
and actinolite.
Archer Prospect, Cloncurry district,
Australia.
 IOCGs Alteration

Potassic alteration:

Potassium-bearing minerals include both biotite and orthoclase.
» Orthoclase in more felsic rocks
» Biotite in more mafic rocks
Potassic zones with variably abundant magnetite - generally >10%.
High level systems may have hematite at expense of magnetite.
 IOCGs Alteration

Potassic alteration:

Potassic alteration primarily as wall-rock replacement, not vein stockwork
at scale of hand specimen.
Quartz veinlets are rare.

 Ore bearing portion of many systems.
 Potassic alteration – Rhyolite ash flow altered to
Potassic Feldspar: orthoclase (Ksp) in the upper Hauki
hematite ores of the Kiruna system,
Sweden

NB: it is sometimes difficult to distinguish albitic
alteration from potassic alteration in hand
specimen.

Outcrop
Potassic alteration –
Biotite:
Andesite altered to massive Bio
Mgt

biotite-magnetite rock.
Candelaria deposit, Chile

Thin section
 IOCGs Alteration
Calcic:
Calcic

Not recognized at time of early papers (early 1990’s). Now
seen to be major component of many IOCG systems.

Calc-silicate minerals (actinolite, diopside, hornblende,
grunerite, garnet)

Calcic zones with variably abundant magnetite - generally
>10%.
 Grunerite-garnet clasts (Calcic
Calcic Alteration alteration) in a biotite- grunerite matrix
(Potassic-calcic alteration).
Salobo deposit, Carajas district, Brazil

Coarse-grained pyroxene
(diopside) with later vug filling
calcite. (“skarn”).
Mt. Elliot, Cloncurry
district, Australia
Calcareous siltstone altered to
diopside- magnetite and cut by
later sulfides.
Mt. Elliot
 Calcic Alteration

Calcareous siltstone altered
to magnetite- epidote-garnet.
Siltstone replaced by albite-epidote- El Espino, Chile
garnet-magnetite. Transitional with sodic-
calcic alteration.
El Espino, Chile
 IOCGs Alteration
Hydrolytic or
HSCC (Haematite-Sericite-Carbonate-Chlorite) alteration:

Generally developed at
high levels in the systems.

 Footprint generally small relative to other alteration types.

 May be difficult to distinguish from “epithermal” alteration
types.
 IOCGs Alteration
Hydrolytic or
HSCC (Haematite-Sericite-Carbonate-Chlorite) alteration:

Mineral assemblage of chlorite-sericite-carbonate-(quartz)

Haematite is the dominant iron oxide

May contain ore (HSCC alteration encases all major deposits
on Gawler Craton, but few other economic systems
recognized elsewhere in the world).
 Hydrolytic Alteration

Edge of Olympic Dam (Austalia) breccia body
with wallrock granite altered to sericite-
carbonate-hematite-(chlorite).

Volcanic rock altered to sericite-
carbonate in hematite matrix.
Prominent Hill, Australia
 Hydrolytic Alteration

Biotitized clasts of volcanic rocks (potassic
alteration) in a matrix of sericite-
carbonate-(haematite) with chalcopyrite.
Sossego deposit, Carajas district, Brazil

Dacites altered to sericite – siderite - haematite - (fluorite)
with late calcite veins.
San Xavier deposit, Sonora, Mexico
 IOCG Ore System Alteration

 Variable by district
 Variability partially depends on local host rock types.
 Variability probably depends on:

1. total hydrothermal fluid volumes (water/rock ratio),
2. permeability of rock mass,
3. magmatic/host rock brine ratio of fluids,
4. regional wallrock composition, and
5. depth of erosion.
Energy: Driven by Lower Crustal Processes

Heat + H2O

Very large hydrothermal systems – driven by intrusions at base of crust which
provide high heat flux. This may cause higher level intrusions which may be
temporally (and overall genetically) related to deposits.
Source of Metal Content of IOCGs

Need overall oxidized rock package (magnetite-bearing granite or granitic gneiss, subaerial
volcanic rocks, siiciclastic dominant sediments – not black shales, reduced carbonates) to
buffer hydrothermal fluids to oxidized state.

Each IOCG displays a different metal “fingerprint” (U, Ag, Zn, Mo, Co, Bi, LREE, etc.). This is
expected as the enormous hydrothermal systems which forms as these fluids “see” different
crust along their flow path.
Fluids & Transport in the IOCG Ore System

 Large volumes of fluids (huge alteration areas) – much more fluid than
available from cooling of individual plutons or even batholiths.

 Structural pathways guide fluids.
IOCG Ore System Traps
…Still very poorly known!

Fluid inclusion work + IOCG mineral assemblage (sulphide, particularly pyrite,
poor) suggests need to mix dominant hydrothermal fluid with another fluid
containing reduced sulphur at the level of the deposits.

Lack of significant quartz in most systems suggests that temperature drop alone is
not important (fluids must have been silica saturated after moving through crust).

Redox trap potential has probably been under appreciated.

44
 Vertical Variation in IOCG
System Alteration
Pb, Zn?
Patterns
Ag, Co,
U, S
5 km
1 km
Fe, Cu,
S, Au
Hydrolytic alteration

Potassic/calcic alteration
Fe Sodic/sodic-calcic
alteration
IOCG deposit
Fe Mgt-apatite deposit
(“Kiruna-type”)
Linda Iaccheri
School of Geosciences
[email protected]
DRIVERS of hydrothermal fluids to create hydrothermal ore deposits
(a)Gravity-driven fluid
flow in response to the
creation of a
hydrostatic head in an
area of uplift.

(b)Orogeny-driven fluid
flow in response to
rock compaction in a
fold and thrust belt.
H2O Vapour
CO2 globule

(c)Thermally driven fluid
flow in the ocean crust
in response to high
heat flow at mid-
Various tectonic scenarios illustrating the mechanisms by which major fluid movements in the Earth’s crust take place (Robb 2005, modified after ocean ridges
Garven and Raffensperger, 1997) & Microphotograph showing the typical appearance of a H2O–CO2bearing fluid inclusion (Robb, 2005)
DRIVERS of hydrothermal fluids to create hydrothermal ore deposits
(d) Thermally driven fluid
flow in a permeable unit
within a basin or rift.

(e)Dilatancy- or fault-
driven fluid flow along
major, seismically active
structural features by
seismic pumping and
H2O
CO2
Vapour
globule fault valve mechanisms

Various tectonic scenarios illustrating the mechanisms by which major fluid movements in the Earth’s crust take place (Robb 2005, modified after
Garven and Raffensperger, 1997) & Microphotograph showing the typical appearance of a H2O–CO2bearing fluid inclusion (Robb, 2005)
 Relevant for
strata-
bound Cu
deposits

Relevant for
orogenic Au
deposits

H2O Vapour
CO2 globule

Various tectonic scenarios illustrating the mechanisms by which major fluid movements in the Earth’s crust take place (Robb 2005, modified after
Garven and Raffensperger, 1997) & Microphotograph showing the typical appearance of a H2O–CO2bearing fluid inclusion (Robb, 2005)
Summary Hydrothermal ore deposits: enrichment by selective dissolution, transport and
precipitation of different hydrothermal fluids
Types of hydrothermal ore deposits:

1. Deposits that have a close spatial and temporal association to
magmatic activity

2. Deposits which form during periods of regional magmatism
and tectonism, but are not clustered close to or around
magmatic centres

3. Deposits that lack widespread or temporally related
magmatic activity
Examples of a deposit that lacks widespread or temporally related
magmatic activity are:

1. Sediment-hosted strata-bound copper deposits

2. Orogenic Au deposits
Sediment-hosted stratabound copper deposits

are some of the world’s important sources of copper – second
after porphyry copper
are widely distributed in space and time
they may have consistent grades and extensive lateral continuity
hydrothermal ore deposits
Represent most important global source of Co as well as many
other metals – Pb, Zn, Ag, U, Au, PGE.
 Global distribution of sediment-hosted copper districts:

 Neoproterozoic Katangan basin
of the Central African
Copperbelt

 Permian Zechstein basin of
Europe (the Kupferschiefer)

 Devonian to Carboniferous
Chu-Saryasu basin of
Kazakhstan

 Paleoproterozoic Kodaro - (Hitzman et al., 2010)

Udokan basin of Siberia
 Stratabound copper deposits – general model

Typically hosted within an intra-continental
rift and within related sedimentary sequence

Early deposition of oxidised (red-bed) aeolian
assemblage rapidly oxidised during burial and
diagenesis during Graben formation

A shallow marine transgression deposited a
more reduced assemblage of shales,
carbonates and evaporites in the rift basin
 Stratabound copper deposits – general model

Basin-derived fluids circulation was
promoted by high heat flow associated with
rifting along active faults

Fluids moved through porous clastic
sediments

Circulating water was saline, relatively
oxidised and pH neutral.

Metals, in particular Cu, derived from
alteration of detrital magnetite, biotite,
hornblende, and pyroxene
 Stratabound copper deposits – general model

Many deposits of this type but are dominated by the huge
resources of two regions:

1. Kupferschiefer (copper-shale) of central Europe

2. Central African Copperbelt
 The Central African Copper Belt (CACB)
It extends in a broad arc
~600 x 100 km, from
Luanshya in Zambia, to the
Kolwezi area of Katanga
Province in DRC into eastern
Angola.

The CAC is one of the great
metallogenic provinces of
Africa.

It contains some of the largest and richest copper, cobalt and uranium deposits
in the world at Nchanga, Konkola and Tenke Fungurumi
It has ~10% of world’s copper, and 34% of the world’s cobalt reserves.
The geological context of the Central African Copper Belt (CACB)

The
mineralisation
is related to
the opening
and closing of
the LUFILIAN
ARC
CACB occurs within the Lufilian Arc
Lufilian Arc is part of the system of Pan-African Orogenic Belts formed
during the amalgamation of Gondwana (~550 Ma):

The Lufilian Arc formed
as a result of the Pan-
African collision
between the Kalahari
and Congo cratons
 Pan-African orogeny

The Pan-African orogeny was a
major tectono- thermal event,
occurring at around 500Ma

During this event a number of
mobile belts formed, surrounding
older cratons

This brought together old continental
cratons, such as West African, Congo,
Kalahari andTanzania, forming the
supercontinent Gondwana

Map of Supercontinent Gondwana at the end of Neoproterozoic time
(-540 Ma) after Kusky et al, 2003
Tectonic evolution of the Lufilian Arc

Regional rifting associated with the dispersal of the supercontinent
Rodinia (~900Ma), responsible for regional rifting

Formation of the Lufilian basin and deposition of the copper-bearing
Katanga succession which contains volcanic rocks dated between 765
and 735 Ma.

Amalgamation of Gondwana (~530Ma), causing regional compression

Folding during extensional basin collapse or basin inversion
CENTRAL AFRICAN COPPERBELT (CACB) – STRATIGRAPHY of the KATANGA SUPERGROUP

 Katangan supergroup ~5 – 7km thick

 Deposited in an intracratonic basin

 Exact age of sediments are poorly
constrained

 thin sequence of rocks for long period of
time (~30Ma)

 Correlation from marker units, glacial
diamictites (Sturtian and Marinoan
glaciation)

 Goes from an initial stage of rifting,
renewed extension, glacial events as well
as salt diapirism
(after Hitzman, 2012)
KATANGAN
SUPERGROUP

Deposited in a
rifted basin
between 765 and
735 Ma.

Immature fluvial
sandstones and arkoses
The hydrothermal system and ore formation

20
 Cross-sectional models of basin-scale fluid flow in
sediment-hosted stratiform copper systems
(Hitzman, 2005)

A)Compaction driven fluid escape.
B)Topographically driven gravity recharge and escape.
C)Basinal fluid convection with impermeable basin
margins.
D)Topographic gravity-driven recharge and bittern
brine entering the basin from overlying evaporites.
E)Red-beds charged with brines from overlying
evaporites.
F)Red-bed aquifer charged with brine from dissolution
of evaporite during episodic diapir growth.

Evaporites – SEAL
Reducing strata – TRAP
Red Beds – SOURCE
Evaporites as a source of sulfur
23
 CENTRAL AFRICAN COPPERBELT (CACB) – CRUST ARCHITECTURE

CH4

CH4
CH4
CH4 CH4
CH4
CH4
CH4
CH4 CH4 CH4
SO42- SO2-
CH4 4

Proposed model showing north directed thrusting
circulation and chemical reactions forming ore deposits
 OPEN
Convection below evaporites
Movement along faults (paths)
Basinal fluid circulation
Oxidised Basement
Redox reactions are key!

Red Beds – SOURCE

CLOSED Evaporites – SEAL

Reducing strata – TRAP

 Closed systems are more
favourable as they are more likely
to host larger deposits
Schematic cross sections of sedimentary basins (Hitzman et al., 2010)
Source of metals
Basement
erosion resulted in Cu-rich red beds in basin

Source of fluids
basin dewatering during diagenesis transported Cu.
Evaporites within the succession provided Cl- and SO4.
Cu was leached from red beds.

Lack of evaporites reduces the chance of getting ore deposits
because they may be the source of sulphur.
 Brown, A.C. 2014

 Low-temperature aqueous brines leached metals from the oxidised red-beds
and basement rocks,
 transport them as cuprous-chloride complexes
 deposited them at the redox barrier, possibly as a result of fluid mixing.
 Reduced

Oxidised

the boundary between magnetite and haematite stability
reflection a REDOX transition/boundary, possibly as a result
of fluid mixing.
Central African Copper Belt summary

 Although the CACB deposits occur in a variety of stratigraphic positions
most are hosted by reduced rocks that overlie oxidised rocks.
 Precipitation of sulphides at multiple REDOX interfaces throughout the basin
where oxidised metal-charged basinal brines met reduced sediments/fluids with
a high organic content beneath an evaporite seal.

 Reductants may be in situ (carbonaceous material, diagenetic pyrite) or may have
been mobile (H2S, CH4, petroleum).
 Ores are generally zoned at a district scale:
barren/haematite – native copper – chalcocite – bornite – chalcopyrite –
Pb/Zn/Co sulphides- pyrite
33
Central African Copper Belt summary

 Most deposits formed close to syn-sedimentary faults, particularly the
early basin- margin normal faults and there is also a structural control on the
deposits (access for hydrothermal fluids)
 Fluids show
little or no
evidence of
temperatures
in excess of
120ºC

 The deposits are primarily the product of low-temperature aqueous brines which
flowed through large volumes of sedimentary rocks where they leached,
transported and ultimately deposited the metals.

 The source of the metals is thought to be the underlying red- beds.
Linda Iaccheri
School of Geosciences
Agnes Au Mine
[email protected] Barberton Greenstone Belt
Types of hydrothermal ore deposits:

1. Deposits that have a close spatial and temporal association
to magmatic activity

2. Deposits which form during periods of regional magmatism
and tectonism, but are not clustered close to or around
magmatic centres

3. Deposits that lack widespread or temporally related
magmatic activity
Orogenic Gold deposits
a type of hydrothermal mineral deposit.
More than 75% of the gold recovered by humans through history belongs
to the class of orogenic gold deposits.

V.G.
Orogenic Gold deposits are also known as

- Lode Gold deposits
- Quartz-vein Gold deposits
- Gold-only deposits
- Mesothermal Gold deposits
- Payable Gold deposits

 Mostly mined for Au only
 Rarely by-products As and Sb
 Most deposits are small
 few large world-class deposits
Orogenic Gold fundamentals:

 Deposits form in actively evolving orogenic belts

 They form at high pressure (4 to 15 km in the crust)

 Temperature around 300 to 450 degrees (Mesothermal)

 Many orogenic gold deposits are in Archean terranes (on cratons)

 Mineralisation hosted in regionally high-grade metamorphic rocks

 Dominantly along fault/shear zones and tectonically active regions
Orogenic gold deposits form in response to elevated heat and fluid fluxes during
compressional to transpressional deformation in metamorphic belts of accretionary
and collisional orogens.
Orogenic Gold deposits characteristics – CRUSTAL ARCHITECTURE
 localization of deposits in orogenic belts, along/near boundaries of
terranes/tectonic units.
Orogenic Gold deposits characteristics – GEOCHRONOLOGY
 The timing of ore formation is syn- to post-peak metamorphism and
late deformation events
Orogenic Gold deposits characteristics – CONDUITS
 structures controlling fluid flow are crustal-scale shear zones.
Orogenic gold deposits
are located at shallow
to mid-crustal levels,
most typically in
greenschist and
amphibolite facies
metamorphic rocks, in
brittle/ductile and
brittle deformation
zones with fault-
controlled pressure
fluctuation.
 The distribution of
lode gold deposits is
strongly controlled by
faults and shear
zones

 Huge volumes of fluid
needed to transport
the metals contained
in the multitude of
deposits
Orogenic Gold deposits characteristics – FLUIDS COMPOSITIONS
What type of fluid is responsible for orogenic Au-deposits and what was its source?
Two common ways to answer this:
analyses of fluid inclusions in minerals
isotopic signatures of minerals

Fluid inclusions – bubbles of fluid + gas trapped in minerals
Their composition help establishing conditions under which they existed
 Orogenic Gold - FLUIDS COMPOSITIONS

H 2 O-CO 2 (±CH4, N2, H2S) inclusions
indicate:
low to moderate salinity (mainly 3-7 wt
% equivalent NaCl)
P-T conditions: 200° to 350°C and 1 to 3
kbar
pH near neutral slightly alkaline (5.2
to 6.8), typical of fluid in equilibrium
with many common silicate rock
types.

Pettke et al., 2000
Orogenic Gold deposits characteristics – FLUIDS SOURCES

 fluids are not primary magmatic

 metamorphic fluids liberated
during prograde, regional
metamorphism (CO2, low salinity
diagnostic)

 Deeply convecting meteoric
fluids in tectonically active region
Orogenic Gold deposits characteristics - FLUIDS

 Devolization of volcanic and sedimentary rocks during metamorphism
or the sediment laden oceanic slab during subduction supports
generation of large volume fluids of crustal/sub-crustal origin.

 Migration of these fluids along crustal-scale fault systems mobilize and
transport the ore forming elements.

 Addition of fluids from other local sources along the pathways of the
regional scale fluid flow is not excluded.

 Local admixing of fluids of different origins to the regional scale fluid
flow system may explain the observed variation in metal associations
and stable/radiogenic isotope properties among deposits occurring in
the same orogenic belt and province.
Orogenic Gold deposits characteristics – FLUID TRANSPORT and FOCUSING

The unifying characteristic of orogenic Au-
deposits is the structural control on fluid
flow, and directly/indirectly on Au
precipitation

Deformation enables the large scale, high
flux, fluid flow responsible for these
deposits by increasing permeability
o at ~grain scale (inter- and intra-
crystalline strain) – DUCTILE
o fracture permeability - BRITTLE

 enables focusing of the fluid flow
Orogenic Gold deposits characteristics – GOLD TRANSPORT
How is gold transported in fluids? -

Mainly as a bisulfide complex i.e. Au(HS)2 in mesozonal environments

At low fluid/rock ratios
-
and high T Au is soluble enough to be scavenged
from range of hosts during alteration

 AuCl2 rarely occurs (oxidixing, saline, acidic conditions) and is not a good
gold complex under fluid conditions present
 Base metals usually complexed with chloride (Cl), and low chloride
abundance (low NaCl) explains why they are rare in the orogenic Au setting
Orogenic Gold deposits characteristics – GOLD EXSOLUTION FROM FLUIDS

To exsolve the dissolved and transported gold from the fluid:
 need to lower Au solubility and/or
 destabilize bisulfide (Au(HS) - ) complex

Under fluid and crustal depth conditions that characterize orogenic gold deposits,
gold precipitation is most often caused by:

1. fluid – wall rock reactions  Au replacing minerals in altered
wall rock (structurally and/or lithologically controlled)

2. pressure fluctuations  crystallization of Au in veins/fractures
Orogenic gold Trap – pressure fluctuations in veins Dube & Gosselin, 2007 after
Robert, 1990

At the deposit scale – veins are very common

Vein splay structure at the
Wonga mine, Australia

Vein geometry at Sigma gold
mine, Quebec

Miller and Wilson, 2004
 Orogenic gold Trap – pressure fluctuations in veins

In veins – sudden decreases in pressure can cause
“boiling” of fluids (really phase separation –
volatiles separate)
e.g., H2S and CO2 preferentially partitions
into volatile phase

1 cm

 Pf decrease occurs as part of the earthquake Bulyanhulu, Tanzania (C. Chamberlain)

cycle
 Orogenic gold Trap – pressure fluctuations in veins
Cyclic pressure fluctuations: Faults as valve behavior

Each incremental seismic event results in short episodes of reduced pressure
leading to Au exsolution from the fluid (via direct drops in solubility and
through phase separation)

Sibson, 2001
Formation of crack-seal growth of veins

Where the vein filling is made up by a series of small increments of microcracks
each followed by a period of precipitation – typically forming complex veins.
This typically occurs in the brittle-ductile transition or in the ductile regime.
 greater complexity than the relatively simple open-space filling.

Typically found in
orogenic/lode-gold systems.

Complex quartz vein formed by
repeated crack-seal events from
a thrust sheet a about 10 km
depth (Fisher & Byrne, 1990) 22
Photographs of complex, crack-seal
veins, including a vein breccia from
an orogenic / lode gold deposit in
the Abitibi Belt, Canada. (Chi &
The diagram on the right is an overall
Guha, 2011 Geosci Front) interpretation of the sequence of
opening and closing in this deposit.
23
Brittle fracture permeability

Kenworthy & Hagemann (2007)
 Orogenic Gold deposits characteristics – LOCALISATION OF DEPOSITS

Orogenic gold deposits are typically located along faults irregularities and jogs

 Faults grow by linking individual
fault segments linkage zones =
Jogs

 High fracture density, aperture,
and connectivity along jogs favors
high fluid flux along the jog axis.
Structural controls at deposit scale
gold is spatially related to:
low displacement faults and brittle-ductile shear zones
Competency contrast between lithologies

Modified from Hagemann & Cassidy (2000)

Distribution of gold deposits and prospects around the Boulder-Lefroy fault system in
the St. Ives goldfield, Western Australia. A major contractional jog occurs in the
Boulder-Lefroy fault system at the Victory complex. Main-shock rupture is modeled
to occur southeast of the jog.
 Saddle Reef mineralization, Bendigo, Australia

Sibson and Scott, 1998
Orogenic Gold deposits characteristics - TRAPS, FOOTPRINTS,
VECTORS

 The precipitation of gold is commonly triggered by phase
separation processes in the parent fluids along the fault networks
between rocks with contrasting competencies due to transient
change in the tectonic stress field and
sulphidation/carbonatization of host rocks during fluid-rock
interaction.

 The ore-forming fluids have a wide range of temperatures (250-
700°C), aqueous carbonic composition with low to moderate
salinities, and reduced, near-neutral chemistry.
SUMMARY: Source – Transport - Trap

Source of fluids
Metamorphic
Deeply convecting meteoric fluids

Transport, (i) medium(s); (ii) scale of transport; (iii) process of transport
H2O rich fluids
Laterally 100s km; vertically ~5-15 km
Structurally controlled and structurally facilitated FOCUSED fluid flow

Trap (process controlling Au precipitation and veining)
structurally enhanced fluid:rock interaction
structurally induced pressure drops and Au exsolution from the fluid (phase
separation mainly)
 Shape of the mineralisation
 Deposits are Lode-shape= they are tabular
or planar bodies (example a single
continuous quartz vein)

 Dimension of the lode from 2 meters to
hundreds of meters along the strike

 Larger deposits are found in networks of
veins or mineralized shear zones

 Lodes and veins are steeply dipping and
plunging.
Wiluna Gold Camp, Yilgarn Craton

East Lode deposit
 Many orogenic gold deposits are in Archean terranes (on cratons)
Orogenic Gold deposits in the West African Craton
Orogenic Gold deposits in the Yilgarn Craton, Western Australia
Orogenic Gold deposits in the Superior Craton, Canada
Abitibi greenstone belt –
principal breaks and
significant gold deposits

At the camp scale – gold is
Porcupine-Destor Fault
spatially related to:
First-order
(transcrustal) fault
zones (10 -100’s km in
length)
Larder Lake-Cadillac Fault
Large-scale structural
irregularities, such as
bends along major
faults/shear zones,
anticlines, synclines
Dube and Gosselin, 2007
Orogenic Gold deposits
in the Kaapvaal Craton,
South Africa

The Barberton
Greenstone Belt
 Orogenic Gold deposits
in the Kaapvaal Craton,
South Africa
Lily
Consort The Barberton
Sheba Greenstone Belt
Fairview
Agnes/Galaxy
Clusters of mines along main
faults and shear-zones

Large-scale structural
irregularities such as bends
along major faults/shear
zones, anticlines, synclines
 Main Archaean greenstone belts
of the Kaapvaal Craton

Barberton Greenstone Belt (BGB)
□ The Barberton Greenstone Belt (BGB) is recognized as one of the World's
oldest and best preserved, mineralized greenstone belts.

□ The belt forms a folded and highly faulted keel of volcanic and sedimentary
rocks, enveloped and intruded by a variety of younger granitic rocks, the
oldest of which were emplaced as a series of diapiric plutons.

□ The oldest successions, which now form the periphery of the belt, are
komatiite-dominated volcanic rocks with related subvolcanic layered
ultramafic complexes, the latter bodies occurring mainly along the northern
flank.

□ These, together with overlying mafic to felsic volcanic rocks and interlayered
chert horizons, form the Onverwacht Group and date back to 3500 Ma (De
Ronde and De Wit, 1994).
The Barberton Greenstone
Belt consists of a sedimentary
sequence of the Barberton
Supergroup:

Overwacht Group (oldest)
around 3.5 Ga
Fig Tree Group
Moodies Group (youngest)
around 3.2 Ga

And associated intrusions,
called TTG (plutons)
Generalized stratigraphy of the Barberton Supergroup

Group Age: oldest to youngest Composition and Formation
(Ma = Million Years)

Moodies 3225 – 3215 Ma Mudrocks, sandstones and conglomerates in alluvial,
fluvial, deltaic, shoreline and tidal environment

Fig Tree 3255 – 3225 Ma Sandstones, shales and conglomerates, mostly
Group deposited in deep water; chemical sediments,
including chert, BIF, baryte; some volcanic strata

Onverwacht 3550 – 3260 Ma Komatiites and basalts; occur as fine-grained tuffs,
pillow lavas, lava flows, breccias, some chert
□ Large-scale fold structures
associated with major strike
faults, sub-parallel to the
northeast- trending greenstone
lithologies are a feature of the
belt.

□ Gold mineralisation is closely
associated with these fault
systems, especially the Sheba Fault

□ Most important mines in the
Barberton belt: the Sheba,
Fairview, and New Consort mines
which together have contributed
~76% of the gold produced from
the Barberton goldfield.
Geological setting of the Sheba-Fairview Complex (SFC) illustrating the main mineralized structures in carbonate-
altered komatiites and argillaceous rocks to the south and in quartzitic rocks of the Eureka Syncline to the north
of the Sheba Fault (modified after Wagener and Wiegand, 1986)
North-south geological
section (A and B) through the
Sheba mine showing tight
anticlines defined by rocks of
the Zwartkoppie Formation
within argillite of the Fig Tree
Group.

5 different styles of
mineralization are depicted:
(i) Zwartkoppie section type
(ii) Main Reef Complex type
(iii) Golden Quarry type
(iv) fractures in quartzite
(v) Royal Sheba type.
Modified after Wagener and
Wiegand (1986).
□ Gold mineralisation at the Sheba-Fairview Complex occurs in a variety of
lithological and structural settings each with its own seemingly unique
characteristics.

□ Although belonging to a single large, compositionally uniform, hydrothermal
mineralising system, there is little evidence of ore types merging and changing
with depth or along strike.

□ The distinctive alteration assemblages and textures which formed are
largely a function of the composition of the host rocks at the various sites of
mineralisation.

□ Five main styles of mineralisation can be distinguished.
Green fuchsitic quartz-magnesite schist from the Zwartkoppie Formation, Sheba Mine.
Visible gold in quartz veining in highly fractured
and brecciated black Zwartkoppie chert.
Consort Contact reef, a sporadically mineralised and folded chert “Bar” containing black
chert and arsenopyrite-rich layers at the contact of the hornfelsic Fig Tree Group shales
and underlying altered ultramafic schist of the Onverwacht Group.
Linda Iaccheri
School of Geosciences
[email protected]
 Sedimentary Ore-Forming Processes

Processes that are syngenetic with respect to the host sediments
and where the ores are themselves sediments or part of the
sedimentary sequence.

2
 Sedimentary Ore-Forming Processes

Most major syn-sedimentary ore deposits tend to occur in a limited
range of basin types:

Shoreline and fluvial placer deposits

(example: heavy minerals such as gold, cassiterite, diamonds, and
zircon–ilmenite– rutile black sands)

Passive continental margin chemical sedimentary ores

(for example, banded iron formations and ironstones, bedded Mn
deposits, and phosphate ores)
Types of Sedimentary Ore-Forming Processes:

1. the accumulation of heavy, detrital minerals and the formation
of placer deposits;

2. the precipitation mechanisms that give rise to Fe and Mn
concentrations in chemical sediments;

3. the origins of oil and gas deposits, as well as of coalification
processes.
1. Accumulation of clastic sediments and heavy mineral
concentration  formation of Placer deposits

□ The formation of placer deposits is a process of sorting light
from heavy minerals during sedimentation.

□ A placer deposit is one in which dense (or “heavy”) detrital
minerals are concentrated during sediment deposition
 Placer deposits

Placer deposits can contain a wide variety of minerals and metals,
including:

 gold,
 uraninite
 diamond
 cassiterite,
 ilmenite,
 rutile, and
zircon.
Placer deposits examples in South Africa
 Placer deposits examples in South Africa

A well known example of an ancient placer deposit is the late Archean
Witwatersrand Basin.

Geologically more recent occurrences include:

 the diamond placers of the Orange River system and the western
coastline of southern Africa, and
 the heavy mineral sands mined at Richards Bay.
Hydraulic sorting mechanisms relevant to syn-sedimentary placer
formation
1. Entrainment Sorting
2. Shear Sorting
3. Suspension Sorting
4. Transport Sorting

(Carling and Breakspear, 2006)
Entrainment Sorting *mainly applicable to low turbulence scenarios

The ability of a fluid in contact with bed load particles to
dislocate certain grains from that bed and move them further
downstream.

The entrainment threshold of a particle sitting on the bed is determined
by:
the critical shear stress required to initiate movement of any given
particle,
influence of bed roughness (sediment transport rates decrease as
bed roughness increases)
Large grains move faster than smaller ones – smaller grains progress
less easily over a rough bed because of trapping and shielding.
for any given shear velocity and bed roughness, the largest grains
have the fastest transport rates
The critical boundary shear stress for entrainment increases as a
function of grain density.
Shear Sorting
The tendency for grains to accumulate in horizons of similar size/density
distributions within a “concentrated granular dispersion” (Slingerland,
1984), either due to grain collisions or kinematic sieving (Bagnold, 1954;
Middleton, 1965a, 1970)

□ Shear sorting of grains is a process that only applies to the
concentrated flow of suspended particles in a fluidized bed.

□ During the movement of suspended particles in a dense granular
dispersion, grain collisions create a net force that is perpendicular
to the plane of shearing and disperses the granules toward the free
surface (i.e. upwards).

□ Counter-intuitively, the dispersive pressure is greater on large
and/or dense grains within the same horizon of flow so that these
grains migrate upwards relative to smaller and lighter particles.

□ e.g. the effect produced by kinetic sieving, where smaller grains simply
Suspension sorting

The fractionation of grains with different settling velocities into different
levels above the bed in a turbulent channel flow system.

□ Suspension sorting involves the tendency for lighter, larger grains to
stay in suspension for longer (turbulent motion can keep particles
suspended for longer).

□ As heavy grains can be suspended for shorter distances, this differential
causes more proximal deposition, which can then result in the
concentration of a placer deposit consisting of the heaviest grains.

□ Subsequent to its deposition downstream, sediment sorted in
this fashion can result in substantial heavy mineral enrichments.
Transport sorting *Most important sorting process for
formation of placer deposits

□ Differential transport rates exist during movement of
particles in a flowing fluid medium.

□ Transport sorting corresponds to differences in the unit
transport rates for different fractions of the grains present.

□ Transport sorting incorporates both entrainment sorting
and suspension settling/sorting
i.e.
Varying rates of movement of grains in suspension
(determined by suspension settling).
Varying rates of movement of grains both in the bed
load (determined by entrainment)
Modes of heavy and light mineral sorting over a dune (Carling and Breakspear, 2006)

14
Crossbedding
Crossbedding in quartzite
 Application of sorting principles to placer deposits: small scale
Example:
heavy minerals along laminae associated with dunes and ripples
forming along a stream bed
 The dune crest is characterized by high shear velocities and non-turbulent flow promotes
entrainment of larger, lighter grains and residual concentration of the heavier particles.
The dune foreset, on the other hand, is likely to receive heavy mineral concentrations by
shear sorting of high concentration grain avalanches down the slope of the advancing
dune.
The trough or scour forming ahead of the dune is likely to receive heavy grain
concentrations by settling sorting in a locally turbulent microenvironment.
Rounded Gold grains lying on small-scale cross bed foresets and regarded as evidence of a primary placer origin.
Basal Reef, Free State Geduld Mine (W.E.L. Minter, 1990).
Source: Tucker et al. 2016
 Palaeocurrent direction

Rounded Gold grains lying on small-scale cross bed foresets and regarded as evidence of a primary placer origin.
Basal Reef, Free State Geduld Mine (W.E.L. Minter, 1990). Source: Tucker et al. 2016
15
 Application of sorting principles to placer deposits:
intermediate scale

Example: in an
aggrading point bar
forming along the
convex bank of a
meander channel

Deposition in an aggrading point bar forming along the
convex bank of a meander channel
 Dense, heavier minerals, may
concentrate where point bars
are developed along the
convex bank of a
meandering river channel.

Such sites are viable dredging
sites for accumulations of
HEAVY MINERALS, such as
cassiterite or gold

Heavy mineral
concentrations actually
form in degraded scours
along the bottom of the
channel itself.
Placer processes: Alluvial diamond deposits of the Orange River

Map showing the Orange River
drainage system in relation to
the distribution of deeply
eroded kimberlites on the
Kalahari Craton.

The distribution of alluvial
diamond deposits along major
river channels and paleo-
channels, as well as the beach
placers along the west coast of
southern Africa (after Lynn et al.,
1998).
Placer processes: Alluvial diamond
deposits of the Orange River

Diamonds are trapped in gravel terraces
that represent preserved sections of river
sediment, abandoned by the present river
as it migrates laterally or incises downwards

This is a secondary diamond ore deposit.
The primary ore deposit is represented
by the kimberlite
 Sediment sorting in beach and eolian environments: heavy
mineral sand deposits

□ Many important placer deposits are associated with sediments deposited in
shoreline environments where sediment sorting is largely controlled by the
dynamics of waves and by tidal fluctuations.

□ Source fertility is self-evident and dictates whether a placer deposit is likely to
contain ilmenite–zircon or diamond concentrations, or none at all.

□ Heavy mineral concentrations in some of the enormous beach-related
“black sand” (Ti–Zr) placer deposits of the world, such as Richard’s Bay in
South Africa, are a likely product of both beach and wind-related sorting
processes.
Map of Africa, showing
the producing heavy
minerals deposits

heavy minerals mines

heavy minerals
marginal deposits

Rozendaal et al. 2017
 Beach Placer Deposits

Heavy mineral layers
(“black sand”) within
quartz beach sand:

a) beach and aeolian facies
Trivandrum, India
Zircon (ZrSiO4), Rutile (TiO2) and Ilmenite (FeTiO3)

Zircon (ZrSiO4) Rutile (TiO2)
 Linda Iaccheri
School of Geosciences
[email protected]

GEOL3051A
L21-The Witwatersrand Basin -
The World’s Greatest Goldfield
The Witwatersrand Basin is the largest goldfield in the world having yielded
over 52,000 tonnes of gold (~1,672 Moz.) to the present time, representing
more than one third (30%) of all gold ever produced on Earth.

□ It is estimated that an inferred resource of about 30,000 tonnes (~965
Moz.) remain in the basin.

□ It is also an important source of uranium.

□ The Witwatersrand Supergroup is a 2.9 Ga old, Archaean, intracratonic,
sedimentary succession, occupying a central position on the Kaapvaal Craton
of South Africa.
Geological setting of the
Witwatersrand Basin in the
central portion of the
Kaapvaal Craton.
□ The Witwatersrand basin covers
an elliptical area - 300 km long
major axis from the NE to the SW,
and is 150 km wide from the SE-
NW.

□ Seven major goldfields which
extend for over 400 km “The
Golden Arc”.

□ The arc is centred on the
conspicuous Vredefort
Dome, a major meteorite
impact site (2 Ga ago)
Seven major goldfields of the “The
Golden Arc”:

1. Evander
2. East Rand
2a South Rand
3. Central Rand
4. West Rand
4a West Rand South
5. West Wits
5a. Eastern Section
5b. Carletonville
6. Klerksdorp
7. Welkom
Gold Production

□ The Witwatersrand was, for over a century, (late 1800s to 2006) the largest
producer of gold in the World.

□ The Witwatersrand still contains the largest resource of gold in the World,
estimated to be in the order of some 30,000 tonnes.

□ Gold has been mined down to 4,000 m and the resource has still not
bottomed out.

□ Major capital is however required to mine at these great depths.
A conservative estimate of gold produced from the principal gold fields, on the major reef
horizons (Handley, 2004 and Robb & Robb, 1998).
History of gold mining in the Wits Basin

In 1884, Henry Lewis an Australian digger found gold in the Blaaubank area
(Magaliesberg).

In 1885, the Nil Desperandum company was formed – the 1st gold-mining Co. in
the Wits region

Little gold produced – closed end 1887
History of gold mining in the Wits Basin

Between 1880 and 1885, Fred and Harry Struben found gold-bearing quartz
veins in the Roodepoort area (Kloofendal Nature Reserve) and they mined these
veins.

In Sept. 1884 Fred discovered the Confidence Reef, very high grades localised in a
shear zone, but low recoveries

Fred Struben

The Strubens’ plant
at Wilgespruit, 1883
History of gold In Dec. 1885 George Walker and George
Harrison, who had been in the goldfields
of Australia, sailed into Durban, and
made their way to Barberton.

Harrison went to work on farm
Langlaate and at weekends panned
streams for gold. He identified a
conglomerate and panned it

Discovered substantial gold, was
awarded a discovery claim, which was
bought by diamond magnates from
Kimberley.
Rissik Street Johannesburg around
1890 Ferreira’s camp
 Been mined for gold since 1886 from
conglomerate beds which are generally
poorly exposed in outcrop but well
documented from over 100 years of mining.

 90% of the gold is hosted in conglomerate
layers, called ‘reefs’.
1964-1974 was the
heydey of production
 The Witwatersrand Supergroup
deposited on top the >3.12 Ga
granite-greenstones basement
and bimodal rift-related
Dominion Group volcanics
3086- 3074 Ma

Sedimentation of the
Witwatersrand Supergroup
occurred in a foreland basin
(Wits Basin) during the collision
between the Zimbabwe and
Kaapvaal cratons ~3.07- 2.71 Ga
ago
 Sedimentary sequence of the Witwatersrand Basin

The Witwatersrand
Supergroup
deposited in the
Witwatersrand Basin
between 3.0 Ga and
2.7 Ga on an Archean
basement of
granitoids and Greenstone

greenstone belts remnant
 The Witwatersrand Supergroup of the Witwatersrand Basin

The sedimentary
sequence is
subdivided in:

Central Rand
Group (2900 m)

West Rand Group
(4000 m)
Greenstone
remnant
Model showing the main architectural elements of the multistage development
of Witwatersrand palaeoplacers (R.F. Tucker, 1980).

Eroded Archean Basement
Witwatersrand Supergroup - The West Rand Group

The West Rand Group consists of
shales, quartzites and minor
conglomerates

Deposited in an epicontinental
environment that evolved to a shallow
marine shelf

Then, compressional tectonics
fragmented the basement into a series
of discrete blocks resulting in a series
of sub-basins within the original basin,
into which the Central Rand Group was
deposited.
Witwatersrand Supergroup - The Central Rand Group
The Central Rand Group consists
mainly of quartzites and
conglomerates.
Arenaceous rocks dominate,
coarsening upwards

 important for mineralisation

The Central Rand Group comprises
several formations which, although
varying in thickness, can be traced and
correlated, with a few exceptions, in all
the goldfields
Stratigraphy of the Central Rand Group
The gold-bearing
conglomerate reefs can be
correlated in the seven major
goldfields.
Regional geological map and
section of the Central Rand
Group showing the outcrops of
the major conglomerate groups
(M.J. Viljoen - after E.T. Mellor, 1915).
Sedimentology
A clear relationship between gold mineralisation and sedimentation has been
observed in the Witwatersrand.
The most likely source of this
detrital gold is detritus derived
from the erosion of older,
Archaean, lode gold deposits
which are present in all the
greenstone belts of the
Kaapvaal Craton

water-cut reef channel containing gold-
bearing conglomerate and cross-bedded
quartzite in the Middle Elsburg Composite
Reef at Randfontein estates gold mine.
Quartz pebble conglomerate
with white to dark grey
quartz pebbles in a pyritic
matrix.

The dark-rimmed dreikanter
pebble near top right attests
to aeolian processes on the
braid plain (Kimberley Reef)
(Photo by C. Pais, Angloval Ltd.).
Rounded Gold grains
lying on small-scale
cross bed foresets and
regarded as evidence
of a primary placer
origin.
Basal Reef, Free State
Geduld Mine
(W.E.L. Minter, 1990)
Sedimentology & Pay (Ore) Shoots

Sedimentological studies have
played an important role in the
understanding of gold
distribution patterns and the
economic evaluation of various
reef horizons.

Identification of braided fluvial
patterns and paleocurrents for
locating the accumulation of
heavy minerals during
sedimentary processes.
Conceptual landscape at the time of formation of the
Carbon Leader Reef
The Pay (ore) shoots consist of
the richest part of the ore
deposit (reef)

 Paleo channels where gold
and heavy minerals were
deposited
 Pay (Ore) Shoots

MRL=Main Reef Leader

Main Reef Leader sedimentary channels and related ore shoots largely controlled by NW-SE
trending folds and highlighted by a reef isopach plan. Central Rand Goldfield
Plan and Section showing
the distribution of
sedimentological facies in
the Carbon Leader Reef,
Carletonville Goldfield.
(M.J. Viljoen)
The determination of palaeocurrent
trends and pay shoots patterns has
been an important factor in the
evaluation and understanding of
Witwatersrand reefs.

Palaeocurrent trends and pay shoots in the
Nigel and Kimberley Reefs of the East Rand
Goldfield
(After Minter and Loen, 1991)
A well-defined west-east
pay shoot pattern for the
Elsburg Composite Reef on
Cooke Section corresponds
with fluvial entry points in
the vicinity of the
Panvlakte fault to the west.

Well mineralised highly pyritic composite conglomerate containing buckshot pyrite and
large quartz pebbles with individual grades exceeding 100g/t, occurs in the proximal areas
of these ore shoots (M.J. Viljoen).
Main Reef Group
The Main Reef Group (MRG) of conglomerate reefs lies at the base of the
Johannesburg Subgroup of the Central Rand Group.

□ The Main Reef, Main Reef Leader and South Reef and their equivalents in
other goldfields are the most important reefs in this cluster and have been
extensively mined along the northern edge of the basin in the East Rand,
Central Rand and West Wits Goldfields.

□ In the East Rand Goldfield they are collectively reduced to the Nigel Reef
while they are not present in the Evander Goldfield.

The Main Reef and overlying Main Reef Leader (MRL) were the first reefs to be
mined.
Outcrop of the
Main Reef and
Main Reef Leader
conglomerates at
the Langlaagte
Discovery Site on
the Central Rand
Goldfield
(M.J. Viljoen)
 Main Reef

□ The Main Reef is the lowermost of the economically exploitable reefs.

□ It is generally a poorly sorted conglomerate with relatively large pebbles (typically up to 5 cm
in diameter) and occasional boulder filled channels.

□ It is usually composed of a number of pebble bands which coalesce as the reef package thins
from over 4 m to less than 2 m as seen on the western and eastern faces, respectively, at the
Discovery site on Langlaagte.

□ The reef has been sporadically mined along strike, particularly where it is thinner and has
higher grades. A substantial resource averaging just less than 4 g/t (using a 3 g/t cut- off) is
still present in the Main Reef on the Central Rand.

□ The Carbon Leader Reef is the correlative of the Main Reef in the Carletonville Goldfield. It is
characterised by an abundance of carbon with visible gold and very high gold grades.
 Pyrite
□ Pyrite is common in the Witwatersrand gold-bearing conglomerates and
in certain quartzites and is often enriched in gold.
□ Several forms of pyrite are present and attest to a range of formation
processes.
□ Some of the best gold values in Witwatersrand reefs occur when dull,
porous, “buckshot” pyrite is present.
Coarse, dull rounded,
porous pyrite
("buckshot") on
foresets, interpreted
as being syngenetic in
origin.

The gold grade is circa
200 g/t, E9G/d Reef
(top of Kimberley
Formation) on Cooke
Section, Randfontein
Estates Gold Mine
(Tucker, 1980).
 Uranium

□ Uranium occurs in the conglomerate
reefs mainly as the mineral uraninite
(UO2) which, due to oxidation,
contains a certain proportion of U3O8.
□ Uranium is also frequently associated
with carbonaceous matter in the reefs
(as for example in the Carbon Leader
Reef) A water-worn Pyritic pebble with inclusions of
uraninite (1), radiogenic galena (2), chromite
(3), allogenic pyrite (4), interstitial secondary
pyrite (5), chlorite (6) and pyrrhotite
(7). The pebble edge is indicated by (8) (R.F.
Tucker, 1980).
Carbon

□ Carbonaceous material is common in the gold bearing Witwatersrand
conglomerates.

□ It occurs mainly as thin black seams varying from a few millimetres to a few
centimetres in width.

□ It is particularly common in the Carbon Leader of the Carletonville Goldfield
and the Vaal, Basal and Elsburg Reefs.
□ As with gold and uranium, there has been considerable debate concerning
the origin of the carbon and reasons for its close association with gold in
particular
Carbon Seam on
basal scour of
Carbon Leader Reef
with columnar
carbon structure and
abundant visible
gold – West Wits
Goldfield (Photograph by
B. Cairncross).
 The early Earth atmosphere and the Great Oxidation Event (GOE)
The placer origin of the rounded pyrite indicates that before GOE pyrite and
uraninite were a stable heavy mineral during erosion and transport (sedimentary
processes) in an early Earth, oxygen-poor atmosphere.

GREAT OXIDATION EVENT
Change in
atmosphere’s
composition
through time

Today
 Is all the gold of the
Wits due to
sedimentary processes?

Gold vein with carbon nodules (black) in a buckshot pyrite matrix.
VCR, Carletonville Goldfield (A.A. Lanham)
We look now intoTHAT
MECHANISMS theHAVE
mechanisms that
CONTRIBUTED may have
TOWARDS contributed
THE GOLD
towards the goldOF
ENRICHMENT enrichment of the Witwatersrand
THE WITWATERSRAND BASIN Basin
Controversy: how was the Wits gold concentrated?

 Placer model (syngenetic
model)
 Epigenetic model hydrothermal
fluids percolating through the
sediments formed an epigenetic
gold deposit.
 Modified placer model
 Other newer models
Placer model gold, pyrite, and other heavy
minerals were washed into the
Basin as placer heavy minerals,
eroded from a fertile source and
concentrated by sedimentary
processes;

Evidence from water-cut channels
filled with gold-bearing
conglomerate
 evidence for placer origin

Basal Reef gold and pyrite along foresets –
Lawrie Minter

gold concentrated along fore-sets in coarse sands and conglomerates
micro-nuggets of gold, which are typical of detrital deposition.
also flattened and rolled gold grains
Rh-Os age of gold is older than the sediments and has a mantle signature – 3.01 Ga in
Vaal Reef
rounded pyrites that are also older than the sediments
 evidence for placer origin

The placer model has
dominated the exploration
models for predicting the
location of gold in the
The Vaal Reef, Klerksdorp
Wits Basin for the first
hundred years of mining.
Epigenetic model
or hydrothermal model

hydrothermal fluids percolating
through the sediments
preferentially moved through the
coarse gravels to form an
epigenetic gold deposit.

These fluids may have been
derived from basin dewatering
and/or metamorphism.
Schematic representation of the genesis of Witwatersrand gold through metamorphic
devolatilization and hydrothermal replacement. In this model, the mafic sequence is shown
undergoing regional metamorphism and generating an auriferous fluid (Phillips and Powell,
2014).
 octahedral gold crystal in
Evidence for epigenetic model Quartz vein
Skeletal gold can only
have formed after the
deposition of the
Epigenetic (secondary) pyrite sediments from
hydrothermal fluids.

 late appearance of gold in the
Skeletal gold paragenetic sequence as microfracture
fills and inclusions in sedimentary
hydrothermal mineral grains

 The presence of extensive alteration of
host rocks and an overprint of the gold-
uraninite mineralization has also been
related to the hydrothermal model
(Mathur et al, 2013; Phillips and Powell,
Woods, 2016
2014).
Linda Iaccheri
School of Geosciences
[email protected]
Types of Sedimentary Ore-Forming Processes

1. the accumulation of heavy, detrital minerals and the
formation of placer deposits;

2. the precipitation mechanisms that give rise to Fe and Mn
concentrations in chemical sediments;

3. the origins of oil and gas deposits, as well as of coalification
processes
 Chemical concentration of metals

A chemical sedimentary ore in which concentrations of ore minerals
accumul