Geology of uranium deposits
This EOE article is adapted from an information paper published by the World Nuclear Association (WNA). WNA information papers are frequently updated, so for greater detail or more up to date numbers, please see the latest version on WNA website (link at end of article).
Uranium deposits world-wide can be grouped into 14 major categories of deposit types based on the geological setting of the deposits. Australian uranium deposits can be grouped into 6 of these categories, with some mineralization in two further ones:
Unconformity-related deposits arise from geological changes occurring close to major unconformities. Below the unconformity, the metasedimentary rocks which host the mineralization are usually faulted and brecciated. The overlying younger Proterozoic sandstones are usually undeformed.
Unconformity-related deposits constitute approximately 33% of the World Outside Centrally Planned Economies Area's (WOCA) uranium resources and they include some of the largest and richest deposits. Minerals are uraninite and pitchblende. The main deposits occur in Canada (the Athabasca Basin, Saskatchewan and Thelon Basin, Northwest Territories); and Australia (the Alligator Rivers region in the Pine Creek Geosyncline, Northern Territory and Rudall River area, Western Australia).
Unconformity-related deposits constitute a major proportion of Australia's total uranium resources, and much of Australia's total production since 1980 has been mined from two of these deposits - Nabarlek (now mined out) and Ranger 1 & 3. Other major deposits in the Alligator Rivers region are Jabiluka, Koongarra and Ranger 68.
Today, all of Canada's uranium production is from unconformity-related deposits—Key Lake, Cluff Lake, Rabbit Lake (all now depleted), and McClean Lake and McArthur River deposits. Other large, exceptionally high-grade unconformity-related deposits currently being developed include Cigar Lake (averaging almost 20% U3O8, some zones over 50% U3O8).
The deposits in the Athabasca Basin occur below, across and immediately above the unconformity, with the highest-grade deposits situated at or just above the unconformity (e.g., Cigar Lake and McArthur River). In the Alligator Rivers region, the known deposits are below the unconformity and like their Canadian counterparts, are generally much lower-grade.
Uranium exploration in the Alligator Rivers region and Arnhem Land has been restricted since the late 1970s because of political and environmental factors. Much of the Alligator Rivers region and Arnhem Land have only been subjected to first pass exploration designed to detect outcropping deposits and extensions of known deposits, e.g., Jabiluka 2 was found by drilling along strike from Jabiluka 1.
There has been very little exploration to locate deeply concealed deposits lying above the unconformity similar to those in Canada. It is possible that very high-grade deposits occur in the sandstones above the unconformity in the Alligator Rivers/Arnhem Land area.
The Kintyre deposit in the Rudall River area is similar to the deposits in the Alligator Rivers region. Metallurgical tests have shown that Kintyre ore can be radiometrically sorted and upgraded prior to milling and processing.
Breccia complex deposits
The Olympic Dam, South Australia deposit is one of the world's largest deposits of uranium, and accounts for the major portion of Australia's uranium resources. The deposit occurs in a hematite-rich granite breccia complex in the Gawler Craton. It is overlain by approximately 300 meters of flat-lying sedimentary rocks of the Stuart Shelf geological province.
The central core of the complex is barren hematite-quartz breccia, with several localized diatreme structures, flanked to the east and west by zones of intermingled hematite-rich breccias and granitic breccias. These zones are approximately one kilometer wide and extend almost 5 km in a northwest-southeast direction. Virtually all the economic copper-uranium mineralization is hosted by these hematite-rich breccias. This broad zone is surrounded by granitic breccias extending up to 3 km beyond the outer limits of the hematite-rich breccias.
The deposit contains iron, copper, uranium, gold, silver, rare earth elements (mainly lanthanum and cerium) and fluorine. Only copper, uranium, gold, and silver are recovered. Uranium grades average from 0.08 to 0.04% U3O8, the higher-grade mineralization being pitchblende. Copper grades average 2.7% for proved reserves, 2.0% for probable reserves, and 1.1% for indicated resources. Gold grades vary between 0.3-1.0 g/t.
Details of the origin of the deposit are still uncertain. However, the principal mechanisms which formed the breccia complex are considered to have been hydraulic fracturing, tectonic faulting, chemical corrosion, and gravity collapse. Much of the brecciation occurred in near surface eruptive environment of a crater complex during eruptions caused by boiling and explosive interaction of water (from lake, sea or groundwater) with magma.
Sandstone uranium deposits occur in medium to coarse-grained sandstones deposited in a continental fluvial or marginal marine sedimentary environment. Impermeable shale/mudstone units are interbedded in the sedimentary sequence and often occur immediately above and below the mineralized sandstone. Uranium precipitated under reducing conditions is caused by a variety of reducing agents within the sandstone including: carbonaceous material (detrital plant debris, amorphous humate, marine algae); sulphides (pyrite, H2S), hydrocarbons (petroleum), and interbedded basic volcanics with abundant ferro-magnesian minerals (e.g., chlorite).
There are three main types of sandstone deposits:
- rollfront deposits - arcuate bodies of mineralization that crosscut sandstone bedding;
- tabular deposits - irregular, elongate lenticular bodies parallel to the depositional trend, deposits commonly occur in palaeochannels incised into underlying basement rocks;
- tectonic/lithologic deposits - occur in sandstones adjacent to a permeable fault zone.
Sandstone deposits constitute about 18% of world uranium resources. Orebodies of this type are commonly low to medium grade (0.05 - 0.4% U3O8) and individual orebodies are small to medium in size (ranging up to a maximum of 50,000 t U3O8). The main primary uranium minerals are uraninite and coffinite. Conventional mining/milling operations of sandstone deposits have been progressively undercut by cheaper in situ leach mining methods.
The United States has large resources in sandstone deposits in the Western Cordillera region, and most of its uranium production has been from these deposits, recently by in situ leach (ISL) mining. The Powder River Basin in Wyoming, the Colorado Plateau and the Gulf Coast Plain in south Texas are major sandstone uranium provinces. Other large sandstone deposits occur in Niger, Kazakhstan, Uzbekistan, Gabon (Franceville Basin), and South Africa (Karoo Basin). Kazakhstan has reported substantial reserves in sandstone deposits with average grades ranging from 0.02 to 0.07% U.
Large uranium resources within sandstone deposits also occur in Niger, Kazakstan, Uzbekistan, Gabon (Franceville Basin), and South Africa (Karoo Basin). Kazakstan has reported substantial reserves in sandstone deposits with average grades ranging from 0.02 to 0.07% U.
Sandstone deposits represent only about 7% of Australia's total resources of uranium. Within the Frome Embayment, six uranium deposits are known, the largest being Beverley, Honeymoon, East Kalkaroo and Billaroo West-Gould Dam, all amenable to ISL mining methods. Other deposits are Manyingee, Oobagooma, and Mulga Rock in Western Australia (WA) and Angela, Northern Territory (NT). At Mulga Rock, uranium mineralization is in peat layers interbedded with sand and clay within a buried palaeochannel.
Surficial uranium deposits are broadly defined as young (Tertiary to Recent) near-surface uranium concentrations in sediments or soils. These deposits usually have secondary cementing minerals including calcite, gypsum, dolomite, ferric oxide, and halite. Uranium deposits in calcrete are the largest of the surficial deposits. Uranium mineralization is in fine-grained surficial sand and clay, cemented by calcium and magnesium carbonates.
Surficial deposits comprise about 4% of world uranium resources. Calcrete deposits represent 5% of Australia¹s total reserves and resources of uranium. They formed where uranium-rich granites were deeply weathered in a semi-arid to arid climate. The Yeelirrie deposit in WA is by far the world's largest surficial deposit. Other significant deposits in WA include Lake Way, Centipede, Thatcher Soak, and Lake Maitland.
In WA, the calcrete uranium deposits occur in valley-fill sediments along Tertiary drainage channels, and in playa lake sediments. These deposits overlie Archaean granite and greenstone basement of the northern portion of the Yilgarn Craton. The uranium mineralization is carnotite (hydrated potassium uranium vanadium oxide).
Calcrete uranium deposits also occur in the Central Namib Desert of Namibia, the largest being the Langer Heinrich deposit, also Trekkopje.
Uranium deposits of this type occur in acid to intermediate volcanic rocks and are related to faults and shear zones within the volcanics. Uranium occurs in veins or disseminated and is commonly associated with molybdenum and fluorine.
These deposits make up only a small proportion of the world¹s uranium resources. Significant resources of this type occur in China, Kazakhstan, Russian Federation and Mexico. In Australia, volcanic deposits are quantitatively very Minor—Ben Lomond and Maureen in Queensland are the most significant deposits. In Canada, the Michelin deposit is of this kind.
Deposits in this category make up a large proportion of the world’s uranium resources. Included in this type of uranium deposit are those associated with intrusive rocks including alaskite, granite, pegmatite, and monzonites. Major world deposits include Rossing (Namibia), Ilimaussaq (Greenland) and Palabora (South Africa). In Australia, the main ones are Radium Hill (SA) which was mined from 1954-62 (mineralization was mostly davidite) and the large bodies of low-grade mineralization at Crocker Well and Mount Victoria in the Olary Province, South Australia.
Metasomatite deposits consist of unevenly disseminated uranium in structurally deformed rocks that were affected by sodium metasomatism.- the introduction of sodium (or potassium or calcium) into these rocks. Major examples of this type include Espinharas deposit (Brazil) and the Zheltye Vody deposit (Ukraine). Valhalla and Skal near Mount Isa are Australian examples.
Metamorphic-type uranium deposits occur in metasediments and/or metavolcanics. Examples include the deposits at Forstau, Austria. In Australia the largest of this type was Mary Kathleen uranium/rare earth deposit, 60km east of Mount Isa, Qld, which was mined 1958-63 and 1976-82. The orebody occurs in a zone of calcium-rich alteration within Proterozoic metamorphic rocks.
Quartz-pebble conglomerate deposits
Detrital uranium occurs in some Archaean-early Palaeoproterozoic quartz-pebble conglomerates that unconformably overlie granitic and metamorphic basement. Quartz-pebble conglomerate uranium deposits occur in conglomerates deposited in the range 3070-2200 million years ago. Fluvial transport of detrital uraninite was possible at the time because of the prevailing anoxic atmosphere.
These deposits make up approximately 13% of the world's uranium resources. Where uranium is recovered as a by-product of gold mining, the grade may be as low as 0.01% U3O8. In deposits mined exclusively for uranium, average grades range as high as 0.15% U3O8. Individual deposits range in size from 6000-170,000 t contained U3O8. Major examples are the Elliot Lake deposits in Canada and the Witwatersrand gold-uranium deposits in South Africa. The mining operations in the Elliot Lake area have closed in recent years because these deposits are uneconomic under current uranium market conditions.
No such economic deposits are known in Australia, although quartz-pebble conglomerate containing low-grade uraninite and gold mineralization exists in several Archaean-Palaeoproterozoic basins in Western Australia. These are similar in lithology and age to the Witwatersrand conglomerates, being formed before there was any oxygen in the atmosphere.
Vein deposits of uranium are those in which uranium minerals fill cavities such as cracks, veins, fissures, pore spaces, breccias and stockworks. The dimensions of the openings have a wide range, from the massive veins of pitchblende at Jachymov deposit (Czech Republic), Schinkolobwe deposit (Democratic Republic of the Congo) and Port Radium deposit (Canada) to the narrow pitchblende-filled cracks, faults and fissures in some of the ore bodies in Europe, Canada and Australia.
Collapse breccia pipe deposits
These occur in circular, vertical collapse structures filled with coarse fragments and a fine matrix of the penetrated sediments. The collapse pipes are 30-200 m in diameter and up to 1000 m deep. Uranium mineralisation is mostly within permeable sandstone breccias within the pipe. The principal uranium mineral is pitchblende. The best known examples of this type are deposits in the Arizona Strip in Arizona, USA. Several of these have been mined.
Sedimentary phosphorites contain low concentrations of uranium in fine-grained apatite. Uranium concentrations are 0.01ñ0.015% U3O8. Very large phosphorite deposits occur in the USA (Florida and Idaho), Morocco and Middle Eastern countries and these are mined for phosphate. Where phosphoric acid is produced, uranium is, in some instances, extracted as a by-product; for example, in Florida.
Uranium mineralisation occurs in lignite and in clay and sandstone immediately adjacent to the lignite, in the Serres Basin, Greeceand in North and South Dakota, USA. Uranium has been adsorbed on to carbonaceous matter and consequently no discrete uranium minerals have formed.
Black shale deposits
Black shale-related uranium mineralisation consists of marine organic-rich shale or coal-rich pyritic shale, containing synsedimentary disseminated uranium adsorbed onto organic material. Examples include the uraniferous alum shale in Sweden, the Rudnoye and Zapadno-Kokpatasskaya deposits in Uzbekistan, the Chatanooga shale in the USA, deposits in the Guangxi Autonomous Region, China, and the Gera-Ronneburg deposit, Germany. None are known to be economic, though Japanese interests are working on the Uzbek deposits.
The major primary ore mineral is uraninite (basically UO2) or pitchblende (U2O5.UO3, better known as U3O8), though a range of other uranium minerals is found in particular deposits. These include carnotite (uranium potassium vanadate), the davidite-brannerite-absite type uranium titanates, and the euxenite-fergusonite-samarskite group (niobates of uranium and rare earths).
A large variety of secondary uranium minerals is known, many are brilliantly colored and fluorescent. The most common are gummite (a general term like limonite for mixtures of various secondary hydrated uranium oxides with impurities); hydrated uranium phosphates of the phosphuranylite type, including autunite (with calcium), saleeite (magnesian) and torbernite (with copper); and hydrated uranium silicates such as coffinite, uranophane (with calcium) and sklodowskite (magnesian).
WNA paper on Geology of uranium deposits
This paper was largely condensed from the following:
Lambert,I., McKay, A., and Miezitis, Y. (1996) Australia's uranium resources: trends, global comparisons and new developments, Bureau of Resource Sciences, Canberra, with their later paper: Australia's Uranium Resources and Production in a World Context, ANA Conference October 2001.
McKay, A., and Miezitis, Y. (2001) Australia’s Uranium Resources, Geology And Development Of Deposits, Geoscience Austrlai, ISBN 0 642 46716 1
Aust IMM, Field Geologist's Manual, 1989.
Recent Uranium Industry Developments, Exploration, Mining and Environmental Programs in the U.S. and Overseas, The Uranium Committee, Energy Minerals Division, AAPG, March 25, 2005