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    <title>UTas ePrints - Spatial distribution patterns of sulfur isotopes, nodular carbonate, and ore textures in the McArthur River (HYC) Zn-Pb-Ag deposit, Northern Territory, Australia</title>
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    <meta content="Ireland, T." name="eprints.creators_name" />
<meta content="Large, R.R." name="eprints.creators_name" />
<meta content="McGoldrick, P.J." name="eprints.creators_name" />
<meta content="Blake, M.D." name="eprints.creators_name" />
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<meta content="Spatial distribution patterns of sulfur isotopes, nodular carbonate, and ore textures
in the McArthur River (HYC) Zn-Pb-Ag deposit, Northern Territory, Australia" name="eprints.title" />
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<meta content="260100" name="eprints.subjects" />
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<meta content="SEDEX, Seafloor massive sulfide, sediment-hosted,zinc, lead, Mt Isa, McArthur Basin" name="eprints.keywords" />
<meta content="The HYC Zn-Pb-Ag deposit at McArthur River is the largest known and least deformed Australian sedimenthosted
stratiform base metal deposit. A study of mineralogical, geochemical, and isotopic zonation through the
deposit reveals concentric distribution patterns in (1) the occurrence of nodular carbonate, (2) the δ34S composition
of sphalerite, and (3) microscopic ore textures. The correlation of previously documented lateral metal
zonation with these other zonation patterns precludes exclusive postsedimentation mineralization and provides
some insight into the mechanisms and controls on synsedimentary to early diagenetic mineralization. This mineralization
timing is also supported by new carbon and oxygen isotope analyses, recognition of two stages of texturally
and isotopically distinct sphalerite, and reinterpretation of complex sulfide textures.
Dolomitic carbonate nodules occur in the south, southwest, northwest, and northern fringes of the deposit
and are interpreted to have surrounded the high-grade ore lenses prior to structural and erosive truncation.
The carbon and oxygen isotope composition of these carbonate nodules is similar to the sedimentary dolomite
within the ore lenses. There is no evidence for incorporation of light carbon derived from oxidation of organic
material under closed-system conditions and the nodular carbonate probably formed under open-system conditions
in communication with seawater. These nodules displace siltstone laminae and, therefore, likely formed
in the very shallow subsea-floor environment.
In ore lens 3, the δ34S of laminated early sphalerite (sp1) changes from a mean value of 5 per mil in the deposit
center to a mean of 1.7 per mil in the extreme fringes. We interpret this to be the result of sulfide precipitation
in a restricted marine basin. Later sphalerite (sp2) associated with nodular carbonate has a mean δ34S
value of 9.8 per mil, whereas laminated early sphalerite (sp1) has a mean δ34S value of 3.8 per mil. This isotopic
separation of the two paragenetic stages of sphalerite is found in immediately adjacent aggregates. Concentration
of 34S in late sphalerite (sp2) is likely the result of closed-system conditions in the sediment pore fluid.
Textures of laminated sphalerite change from strongly anastomosing in the central part of the deposit to
plane laminar and patchy in the deposit fringes. Mass-balance calculations preclude substantial carbonate dissolution
and a stylolitic origin for these textures. Instead we propose that rapidly precipitated sphalerite coagulated
and trapped pelagic silt and early pyrite (py1) as it was deposited on the sea floor. In contrast, paragenetically
late sphalerite (sp2) and pyrite (py2) must be diagenetic as they overprint and are pseudomorphous
after the carbonate nodules. We propose a repeating paragenetic sequence of galena/sphalerite (sp1) → pyrite
(py1) → nodular carbonate → sphalerite (sp2) → pyrite (py2), which accounts for all the textural complexity and
isotopic disequilibrium between sulfide phases.
The data presented in this paper suggest that base metal sulfides formed both in the water column and in
the uppermost sediment pile. Biological and thermochemical sulfate reduction probably occurred simultaneously
in different parts of a complex physicochemical system in which stratification of the marine environment
is seen as the primary control on the lateral distribution of the mineralized facies. We propose a stratified water
body in which sharp internal chemical gradients separate a surficial oxic layer, an anoxic layer, and a basal hypersaline
brine pool. Asymmetric metal zonation across the deposit reflects individual pulses of metalliferous
fluid that were introduced into the basin as a bottom-hugging dense current." name="eprints.abstract" />
<meta content="2004-12" name="eprints.date" />
<meta content="published" name="eprints.date_type" />
<meta content="Economic Geology" name="eprints.publication" />
<meta content="99" name="eprints.volume" />
<meta content="8" name="eprints.number" />
<meta content="1687-1709" name="eprints.pagerange" />
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<meta content="Arp, G., Reimer, A., and Reitner, J., 2003, Microbialite formation in seawater
of increased alkalinity, Satonda Crater Lake, Indonesia: Journal of Sedimentary
Research, v. 73, p. 105–127.
Atkins, P.W., 1999, Physical chemistry, 6th ed.: New York, Oxford University
Press, 874 p.
Badham, J.P.N., 1981, Shale hosted Pb-Zn deposits: Products of exhalation of
formation waters?: Institution of Mining and Metallurgy Transactions, v.
90, p. 370–376.
Barrett, T., and MacLean, W.H., 1994, Chemostratigraphy and hydrothermal
alteration in exploration for VHMS deposits in greenstones and younger
volcanic rocks, in Lentz, D.R., ed., Alteration and alteration processes associated
with ore forming systems: Geological Society of Canada Short
Course Notes, v. 11, p. 433–467.
Benning, L.G., Wilkin, R.T., and Barnes, H.L., 2000, Reaction pathways in
the Fe-S system below 100 degrees: Chemical Geology, v. 167, p. 25–51.
Bosbach, D., Hall, C., and Putnis, A., 1998, Mineral precipitation and dissolution
in aqueous solution: In situ microscopic observations on barite (001)
with atomic force microscopy: Chemical Geology, v. 151, p. 143–160.
Broadbent, G.C., Myers, R.E., and Wright, J.V., 1998, Geology and origin of
shale-hosted Zn-Pb-Ag mineralization at the Century deposit, Northwest
Queensland, Australia: ECONOMIC GEOLOGY, v. 93, p. 1264–1294.
Bull, S.W., 1998. Sedimentology of the Palaeoproterozoic Barney Creek Formation
in DDH BMR McArthur 2, southern McArthur basin, Northern
Territory: Australian Journal of Earth Sciences, v. 45, p. 21–31.
Canfield, D.E., and Thamdrup, B., 1994, The production of 34S-depleted sulphide
during bacterial disproprtionation of elemental sulphur: Science, v.
266, p. 1973–1975.
Chafetz, H.S., and Buczynski, C., 1992, Bacterially induced lithification of
microbial mats: Palaios, v. 7, no. 3, p. 277–293.
Chen, J., Walter, M.R., Logan, G.A., Hinman, M.C., and Summons, R.E.,
2003, The Paleoproterozoic McArthur River (HYC) Pb/Zn/Ag deposit of
northern Australia: Organic geochemistry and ore genesis: Earth and Planetary
Science Letters, v. 210, p. 467–479.
Cooke, D.R., Bodon, S.B., and Bull, S.W., 1998, Element associations and
depositional processes for McArthur-type and Selwyn-type sediment
hosted Pb-Zn deposits: Australian Mineral Industry Research Association
International Ltd. Unpublished Report P384A, v. 2, p. 145–182.
Cooke, D.R., Bull, S.W., Large, R.R., and McGoldrick, P.J., 2000, The importance
of oxidized brines for the formation of Australian Proterozoic
stratiform sediment-hosted Pb-Zn (SEDEX) deposits: ECONOMIC GEOLOGY,
v. 95, p. 1–17.
Cotton, R.E., 1965, HYC lead-zinc-silver deposit, McArthur River: Geology
of Australian Ore Deposits, Commonwealth Mining and Metallurgy Congress,
8th, Melbourne, Proceedings, v. 1, p. 197–200.
Craig, H., 1969, Geochemistry and origin of the Red Sea brines, in Degens,
E.T., ed., Hot brines and recent heavy metal deposits in the Red Sea: New
York, Springer-Verlag, p. 208–242.
Crick, I.H., 1992, Petrological and maturation characteristics of organic matter
from the Middle Proterozoic McArthur basin, Australia: Australian
Journal of Earth Sciences, v. 39, p. 501–519.
Croxford, N.J.W., 1968, A mineralogical examination of the McArthur leadzinc-
silver deposit: Australasian Institute of Mining and Metallurgy Proceedings,
v. 226, p. 97–108.
Croxford, N.J.W., and Jephcott, S., 1972, The McArthur lead-zinc-silver deposit,
Northern Territory, Australia: Australasian Institute of Mining and
Metallurgy Proceedings, v. 243, p. 1–26.
Degens, E.T., Herzen, R.P., Wong, H-K., Deuser, W.G., Jannasch, H.W., and
Hole, W., 1973, Lake Kivu: Structure, chemistry and biology of an East
African rift lake: Geologische Rundschau, v. 62, p. 245–277.
Druschel, G.K., Labrenz. M., Thomsen-Ebert, T., Fowle, D.A., and Banfield,
J.F., 2002, Biogenic precipitation of monomineralic nanocrystalline
sulfides: Implications of observed and modeled processes to ore deposition:
ECONOMIC GEOLOGY, v. 97, p. 1319–1329.
Eldridge, C.S., Williams, N., and Walshe, J.L., 1993, Sulfur isotope variability
in sediment-hosted massive sulfide deposits as determined using the ion
microprobe SHRIMP II: A study of the HYC deposit at McArthur River,
Northern Territory, Australia: ECONOMIC GEOLOGY, v. 88, p. 1–26.
Hinman, M.C., 1995, Base-metal mineralization at McArthur River: Structure
and kinematics of the HYC-Cooley zone at McArthur River [abs.]:
Australian Geological Survey Organisation Record 1995/5, p. 29.
——1996, Constraints, timing and processes of stratiform base metal mineralization
at the HYC Ag-Pb-Zn deposit, McArthur River [ext. abs.]. James
Cook University of North Queensland Economic Geology Research Unit
(Extended Abstracts) Contribution 55, p. 56–59.
——2001, Inhalation, thermochemical sulphate reduction, and processes of
ore formation at McArthur River, Northern Territory: “A Hydrothermal
Odyssey,” Ore Deposits Conference, James Cook University of North
Queensland, Townsville, Australia, Unpublished poster presentation.
Horodyski, R.J., and Donaldson, J.A., 1980, Microfossils from the Middle
Proterozoic Dismal Lakes Group, Arctic Canada: Precambrian Research, v.
11, p. 125–159.
Huston, D.L., Power, M., Gemmell, J.B., and Large, R.R., 1995, Design, calibration
and geological application of the first operational Australian laser
ablation sulphur isotope microprobe: Australian Journal of Earth Sciences,
v. 42, p. 549–555.
Ireland, T., 2001, Lateral variability of sedimentology, mineralogy and geochemistry
in the HYC Zn-Pb-Ag deposit, Northern Territory, Australia: Implications
for deposit genesis: Unpublished honours thesis, Hobart, University
of Tasmania, 138 p.
Ireland, T., Bull, S.R., and Large, R.R., 2004, Mass flow sedimentology
within the HYC Zn-Pb-Ag deposit, Northern Territory, Australia: Evidence
for syn-sedimentary ore genesis: Mineralium Deposita, v. 39, p. 143–158.
Jorgensen, B.B., 1990, A thiosulphate shunt in the sulphur cycle of marine
sediments: Science, v. 249, p. 152–154.
Kribek, B., 1975, The origin of framboidal pyrite as a surface effect of sulphur
grains: Mineralium Deposita, v. 10, p. 389–396.
Lambert, I.B., 1976, The McArthur lead-zinc-silver deposit: Features in metallogenesis
and comparisons with some other stratiform ores, in Wolfe,
K.H., ed., Handbook of stratabound and stratiform ore deposits: Amsterdam,
Elsevier, v. 6, p. 535–585.
Lambert, I.B., and Scott, K.M., 1973, Implications of geochemical investigations
of sedimentary rocks within and around the zinc-lead-silver deposit,
Northern Territory, Australia: Journal of Geochemical Exploration, v. 2, p.
307–330.
Large, D.E., 1983, Sediment-hosted massive sulphide lead-zinc deposits:
Mineralogical Association of Canada Short Course Handbook, v. 9, p. 1–29.
Large, R.R., Bull, S.W., Cooke, D.R., and McGoldrick, P.J, 1998, A genetic
model for the HYC deposit, Australia, based on regional sedimentology,
geochemistry, and sulfide-sediment relationships: ECONOMIC GEOLOGY, v.
93, p. 1345–1368.
Large, R.R., Bull, S.W., and McGoldrick, P.J., 2000, Lithogeochemical halos
and geochemical vectors to stratiform sediment hosted Zn-Pb-Ag deposits.
Part 2: HYC deposit, McArthur River, Northern Territory: Journal of Geochemical
Exploration, v. 68, p. 105–126.
Large, R.R., Bull, S.W., and Winefield, P.R., 2001, Carbon and oxygen isotope
halo in carbonate related to the McArthur River (HYC) Zn-Pb-Ag deposit:
Implications for sedimentation, ore genesis, and mineral exploration:
ECONOMIC GEOLOGY, v. 96, p. 1567–1593.
Logan, G.A., Hinman, M., Walter, M.R., and Summons, R.E., 2001, Biogeochemistry
of the 1640 Ma McArthur River (HYC) lead-zinc ore and host
sediments, Northern Territory, Australia: Geochimica et Cosmochimica
Acta, v. 65, p. 2317–2336.
Logan, R.G., 1979, The geology and mineralogical zoning of the HYC Ag-Pb-
Zn deposit, McArthur River, Northern Territory, Australia: Unpublished
M.Sc. thesis, Canberra, Australian National University, 277 p.
Longstaffe, F.J., 1989, Stable isotopes as tracers in clastic diagenesis: Mineralogical
Asociation of Canada Short Course Handbook, v. 15, p. 201–277.
Lydon, J.W., 1983, Chemical parameters controlling the origin and deposition
of sediment-hosted stratiform lead-zinc deposits: Mineralogical Association
of Canada Short Course Handbook, v. 9, p. 175–245.
Machel, H.G., Krouse, H.R., and Sassen, R., 1995, Products and distinguishing
criteria of bacterial and thermochemical sulphate reduction: Applied
Geochemistry, v. 10, p. 373–389.
McDougall, T.J., 1984, Convection processes caused by a dense hot saline
source flowing into a submarine depression from above: Deep Sea Research,
v. 31, p. 1287–1309.
Muir, M.D., Donnelly, T.H., Wilkins, R.W.T., and Armstrong, K.J., 1985, Stable
isotope, petrological and fluid inclusion studies of minor mineral deposits
from the McArthur basin: Implications for the genesis of some sediment-
hosted base metal mineralization from the Northern Territory:
Australian Journal of Earth Sciences, v. 32, p. 239–260.
Murray, W.J., 1975, McArthur River HYC lead-zinc-silver and related deposits,
in Knight, C.L., ed., Economic geology of Australia and Papua New
Guinea—metals: Melbourne, Australasian Institute of Mining and Metallurgy,
p. 329–338.
Oehler, J.H., and Logan, R.G, 1977, Microfossils, cherts and associated mineralization
in the Proterozoic McArthur (HYC) lead-zinc-silver deposit:
ECONOMIC GEOLOGY, v. 72, p. 1393–1409.
Ohmoto, H., and Goldhaber, M.B., 1997, Sulfur and carbon isotopes, in
Barnes, H.L., ed., Geochemistry of the hydrothermal ore deposits, 3rd ed.:
New York, Wiley and Sons, p. 517–612.
Page, R.W., and Sweet, I.P., 1998, Geochronology of basin phases in the
western Mt. Isa inlier, and correlation with the McArthur basin: Australian
Journal of Earth Sciences, v. 45, p. 219–232.
Peck, H.D.J., 1982, Physiological diversity of the sulfate-reducing bacteria, in
Strohl, W.R., and Tuovinen, O.H., eds., Microbial chemautotrophy: Columbus,
OH, Ohio State University Press, 351 p.
Perkins, W.G., and Bell, T.H., 1998, Stratiform replacement lead-zinc deposits:
A comparison between Mount Isa, Hilton, and McArthur River:
ECONOMIC GEOLOGY, v. 93, p. 1190–1212.
Plumb, K.A., and Brown, M.C., 1973, Revised correlations and stratigraphic
nomenclature in the Proterozoic carbonate complex of the McArthur
Group, Northern Territory: Australian Bureau of Mineral Resources, Geology
and Geophysics Bulletin, v. 139, p. 103–115.
Plumb, K.A., and Wellman, P., 1987, McArthur basin, Northern Territory:
Mapping of deep troughs using gravity and magnetic anomalies: Bureau of
Mineral Resources Journal of Australian Geology and Geophysics, v. 10, p.
243–251.
Plumb, K.A., Ahmad, M., and Wygralak, A.S., 1990, Mid-Proterozoic basins
of the North Australian craton—regional geology and mineralization, in
Hughes, E.H., ed., Geology of the mineral deposits of Australia and Papua
New Guinea: Melbourne, Australasian Institute of Mining and Metallurgy,
p. 881–902.
Raiswell, R., and Berner, R.A., 1985, Pyrite formation in euxinic and semieuxinic
sediments: American Journal of Science, v. 285, p. 710–724.
Ramsing, N.B., Fossing, H., Ferdelman, T.G., Andersen, F., and Thomdrup,
B., 1996, Distribution of bacterial populations in a stratified fjord
(Maragier Fjord, Denmark) quantified by in situ hybridisation and related
to chemical gradients in the water column: Applied and Environmental Microbiology,
v. 62, p. 1391–1404.
Rozanov, A.G., Volkov, I.I., and Yagodinskaya, T., 1974, Forms of iron in surface
layers of Black Sea sediments: American Association of Petroleum Geologists
Memoir, v. 20, p. 532–541.
Rye, D.M., and Williams, N., 1981, Studies of the base metal sulfide deposits
at McArthur River, Northern Territory, Australia: III. The stable isotope
geochemistry of the HYC, Ridge and Cooley deposits: ECONOMIC GEOLOGY,
v. 76, p. 1–26.
Sangster, D.F., 2001, The role of dense brines in the formation of vent-distal
sedimentary-exhalative (sedex) lead-zinc deposits: Field and laboratory evidence:
Mineralium Deposita, v. 37, p. 149–157.
Schidlowski, M., 2000, Carbon isotopes and microbial sediments, in Riding,
R., and Awramik, S., eds., Microbial sediments: Berlin Hiedelberg,
Springer-Verlag, 331 p.
Schieber, J., and Baird, G., 2001, On the origin and significance of pyrite
spheres in Devonian black shales of North America: Journal of Sedimentary
Research, v. 71, p. 155–166.
Sholkovitz, E.R., 1976, Flocculation of dissolved organic and inorganic matter
during mixing of river water and seawater: Geochimica et Cosmochimica
Acta, v. 40, p. 831–845.
Smith, J.W., and Croxford, N.F.J., 1973, Sulphur isotope ratios in the
McArthur Pb-Zn-Ag deposit: Nature, v. 245, p. 10–12.
Strauss, H., 1993, The sulphur isotopic record of Precambrian sulphates:
New data and a critical evaluation of the existing record: Precambrian Research,
v. 63, p. 225–246.
Walker, R.N., Logan, R.G., and Binnekamp, J.G., 1977, Recent geological
advances concerning the HYC and associated deposits, McArthur River,
Northern Territory: Journal of the Geological Society of Australia, v. 24, p.
365–380.
Williams, N., 1978, Studies of the base metal sulfide deposits at McArthur
River, Northern Territory, Australia: I. The Cooley and Ridge deposits:
ECONOMIC GEOLOGY, v. 73, p. 1005–1035.
Winefield, P., 1999. Late Palaeoproterozoic carbonates, southern McArthur
Basin, Northern Territory. Unpublished Ph.D. thesis, Hobart, University of
Tasmania, 252 p." name="eprints.referencetext" />
<meta content="Ireland, T. and Large, R.R. and McGoldrick, P.J. and Blake, M.D. (2004) Spatial distribution patterns of sulfur isotopes, nodular carbonate, and ore textures in the McArthur River (HYC) Zn-Pb-Ag deposit, Northern Territory, Australia. Economic Geology, 99 (8). pp. 1687-1709. ISSN 0361-0128" name="eprints.citation" />
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<meta content="Spatial distribution patterns of sulfur isotopes, nodular carbonate, and ore textures
in the McArthur River (HYC) Zn-Pb-Ag deposit, Northern Territory, Australia" name="DC.title" />
<meta content="Ireland, T." name="DC.creator" />
<meta content="Large, R.R." name="DC.creator" />
<meta content="McGoldrick, P.J." name="DC.creator" />
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<meta content="The HYC Zn-Pb-Ag deposit at McArthur River is the largest known and least deformed Australian sedimenthosted
stratiform base metal deposit. A study of mineralogical, geochemical, and isotopic zonation through the
deposit reveals concentric distribution patterns in (1) the occurrence of nodular carbonate, (2) the δ34S composition
of sphalerite, and (3) microscopic ore textures. The correlation of previously documented lateral metal
zonation with these other zonation patterns precludes exclusive postsedimentation mineralization and provides
some insight into the mechanisms and controls on synsedimentary to early diagenetic mineralization. This mineralization
timing is also supported by new carbon and oxygen isotope analyses, recognition of two stages of texturally
and isotopically distinct sphalerite, and reinterpretation of complex sulfide textures.
Dolomitic carbonate nodules occur in the south, southwest, northwest, and northern fringes of the deposit
and are interpreted to have surrounded the high-grade ore lenses prior to structural and erosive truncation.
The carbon and oxygen isotope composition of these carbonate nodules is similar to the sedimentary dolomite
within the ore lenses. There is no evidence for incorporation of light carbon derived from oxidation of organic
material under closed-system conditions and the nodular carbonate probably formed under open-system conditions
in communication with seawater. These nodules displace siltstone laminae and, therefore, likely formed
in the very shallow subsea-floor environment.
In ore lens 3, the δ34S of laminated early sphalerite (sp1) changes from a mean value of 5 per mil in the deposit
center to a mean of 1.7 per mil in the extreme fringes. We interpret this to be the result of sulfide precipitation
in a restricted marine basin. Later sphalerite (sp2) associated with nodular carbonate has a mean δ34S
value of 9.8 per mil, whereas laminated early sphalerite (sp1) has a mean δ34S value of 3.8 per mil. This isotopic
separation of the two paragenetic stages of sphalerite is found in immediately adjacent aggregates. Concentration
of 34S in late sphalerite (sp2) is likely the result of closed-system conditions in the sediment pore fluid.
Textures of laminated sphalerite change from strongly anastomosing in the central part of the deposit to
plane laminar and patchy in the deposit fringes. Mass-balance calculations preclude substantial carbonate dissolution
and a stylolitic origin for these textures. Instead we propose that rapidly precipitated sphalerite coagulated
and trapped pelagic silt and early pyrite (py1) as it was deposited on the sea floor. In contrast, paragenetically
late sphalerite (sp2) and pyrite (py2) must be diagenetic as they overprint and are pseudomorphous
after the carbonate nodules. We propose a repeating paragenetic sequence of galena/sphalerite (sp1) → pyrite
(py1) → nodular carbonate → sphalerite (sp2) → pyrite (py2), which accounts for all the textural complexity and
isotopic disequilibrium between sulfide phases.
The data presented in this paper suggest that base metal sulfides formed both in the water column and in
the uppermost sediment pile. Biological and thermochemical sulfate reduction probably occurred simultaneously
in different parts of a complex physicochemical system in which stratification of the marine environment
is seen as the primary control on the lateral distribution of the mineralized facies. We propose a stratified water
body in which sharp internal chemical gradients separate a surficial oxic layer, an anoxic layer, and a basal hypersaline
brine pool. Asymmetric metal zonation across the deposit reflects individual pulses of metalliferous
fluid that were introduced into the basin as a bottom-hugging dense current." name="DC.description" />
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    <h1 class="ep_tm_pagetitle">Spatial distribution patterns of sulfur isotopes, nodular carbonate, and ore textures in the McArthur River (HYC) Zn-Pb-Ag deposit, Northern Territory, Australia</h1>
    <p style="margin-bottom: 1em" class="not_ep_block"><span class="person_name">Ireland, T.</span> and <span class="person_name">Large, R.R.</span> and <span class="person_name">McGoldrick, P.J.</span> and <span class="person_name">Blake, M.D.</span> (2004) <xhtml:em>Spatial distribution patterns of sulfur isotopes, nodular carbonate, and ore textures in the McArthur River (HYC) Zn-Pb-Ag deposit, Northern Territory, Australia.</xhtml:em> Economic Geology, 99 (8). pp. 1687-1709. ISSN 0361-0128</p><p style="margin-bottom: 1em" class="not_ep_block"></p><table style="margin-bottom: 1em" class="not_ep_block"><tr><td valign="top" style="text-align:center"><a href="http://eprints.utas.edu.au/2048/1/Ireland.Large.McGoldrick.Blake.ECON.2004.pdf"><img alt="[img]" src="http://eprints.utas.edu.au/style/images/fileicons/application_pdf.png" class="ep_doc_icon" border="0" /></a></td><td valign="top"><a href="http://eprints.utas.edu.au/2048/1/Ireland.Large.McGoldrick.Blake.ECON.2004.pdf"><span class="ep_document_citation">PDF</span></a> - Full text restricted - Requires a PDF viewer<br />1417Kb</td><td><form method="get" accept-charset="utf-8" action="http://eprints.utas.edu.au/cgi/request_doc"><input accept-charset="utf-8" value="2584" name="docid" type="hidden" /><div class=""><input value="Request a copy" name="_action_null" class="ep_form_action_button" onclick="return EPJS_button_pushed( '_action_null' )" type="submit" /> </div></form></td></tr></table><p style="margin-bottom: 1em" class="not_ep_block">Official URL: <a href="http://dx.doi.org/10.2113/99.8.1687">http://dx.doi.org/10.2113/99.8.1687</a></p><div class="not_ep_block"><h2>Abstract</h2><p style="padding-bottom: 16px; text-align: left; margin: 1em auto 0em auto">The HYC Zn-Pb-Ag deposit at McArthur River is the largest known and least deformed Australian sedimenthosted&#13;
stratiform base metal deposit. A study of mineralogical, geochemical, and isotopic zonation through the&#13;
deposit reveals concentric distribution patterns in (1) the occurrence of nodular carbonate, (2) the δ34S composition&#13;
of sphalerite, and (3) microscopic ore textures. The correlation of previously documented lateral metal&#13;
zonation with these other zonation patterns precludes exclusive postsedimentation mineralization and provides&#13;
some insight into the mechanisms and controls on synsedimentary to early diagenetic mineralization. This mineralization&#13;
timing is also supported by new carbon and oxygen isotope analyses, recognition of two stages of texturally&#13;
and isotopically distinct sphalerite, and reinterpretation of complex sulfide textures.&#13;
Dolomitic carbonate nodules occur in the south, southwest, northwest, and northern fringes of the deposit&#13;
and are interpreted to have surrounded the high-grade ore lenses prior to structural and erosive truncation.&#13;
The carbon and oxygen isotope composition of these carbonate nodules is similar to the sedimentary dolomite&#13;
within the ore lenses. There is no evidence for incorporation of light carbon derived from oxidation of organic&#13;
material under closed-system conditions and the nodular carbonate probably formed under open-system conditions&#13;
in communication with seawater. These nodules displace siltstone laminae and, therefore, likely formed&#13;
in the very shallow subsea-floor environment.&#13;
In ore lens 3, the δ34S of laminated early sphalerite (sp1) changes from a mean value of 5 per mil in the deposit&#13;
center to a mean of 1.7 per mil in the extreme fringes. We interpret this to be the result of sulfide precipitation&#13;
in a restricted marine basin. Later sphalerite (sp2) associated with nodular carbonate has a mean δ34S&#13;
value of 9.8 per mil, whereas laminated early sphalerite (sp1) has a mean δ34S value of 3.8 per mil. This isotopic&#13;
separation of the two paragenetic stages of sphalerite is found in immediately adjacent aggregates. Concentration&#13;
of 34S in late sphalerite (sp2) is likely the result of closed-system conditions in the sediment pore fluid.&#13;
Textures of laminated sphalerite change from strongly anastomosing in the central part of the deposit to&#13;
plane laminar and patchy in the deposit fringes. Mass-balance calculations preclude substantial carbonate dissolution&#13;
and a stylolitic origin for these textures. Instead we propose that rapidly precipitated sphalerite coagulated&#13;
and trapped pelagic silt and early pyrite (py1) as it was deposited on the sea floor. In contrast, paragenetically&#13;
late sphalerite (sp2) and pyrite (py2) must be diagenetic as they overprint and are pseudomorphous&#13;
after the carbonate nodules. We propose a repeating paragenetic sequence of galena/sphalerite (sp1) → pyrite&#13;
(py1) → nodular carbonate → sphalerite (sp2) → pyrite (py2), which accounts for all the textural complexity and&#13;
isotopic disequilibrium between sulfide phases.&#13;
The data presented in this paper suggest that base metal sulfides formed both in the water column and in&#13;
the uppermost sediment pile. Biological and thermochemical sulfate reduction probably occurred simultaneously&#13;
in different parts of a complex physicochemical system in which stratification of the marine environment&#13;
is seen as the primary control on the lateral distribution of the mineralized facies. We propose a stratified water&#13;
body in which sharp internal chemical gradients separate a surficial oxic layer, an anoxic layer, and a basal hypersaline&#13;
brine pool. Asymmetric metal zonation across the deposit reflects individual pulses of metalliferous&#13;
fluid that were introduced into the basin as a bottom-hugging dense current.</p></div><table style="margin-bottom: 1em" cellpadding="3" class="not_ep_block" border="0"><tr><th valign="top" class="ep_row">Item Type:</th><td valign="top" class="ep_row">Article</td></tr><tr><th valign="top" class="ep_row">Keywords:</th><td valign="top" class="ep_row">SEDEX, Seafloor massive sulfide, sediment-hosted,zinc, lead, Mt Isa, McArthur Basin</td></tr><tr><th valign="top" class="ep_row">Subjects:</th><td valign="top" class="ep_row"><a href="http://eprints.utas.edu.au/view/subjects/260100.html">260000 Earth Sciences &gt; 260100 Geology</a></td></tr><tr><th valign="top" class="ep_row">ID Code:</th><td valign="top" class="ep_row">2048</td></tr><tr><th valign="top" class="ep_row">Deposited By:</th><td valign="top" class="ep_row"><span class="ep_name_citation"><span class="person_name">Mrs Katrina Keep</span></span></td></tr><tr><th valign="top" class="ep_row">Deposited On:</th><td valign="top" class="ep_row">11 Oct 2007 10:02</td></tr><tr><th valign="top" class="ep_row">Last Modified:</th><td valign="top" class="ep_row">09 Jan 2008 02:30</td></tr><tr><th valign="top" class="ep_row">ePrint Statistics:</th><td valign="top" class="ep_row"><a target="ePrintStats" href="/es/index.php?action=show_detail_eprint;id=2048;">View statistics for this ePrint</a></td></tr></table><p align="right">Repository Staff Only: <a href="http://eprints.utas.edu.au/cgi/users/home?screen=EPrint::View&amp;eprintid=2048">item control page</a></p>
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