Abstract
The Um Rus tonalite-granodiorite intrusion (w6 km2) occurs at the eastern end of the Neoproterozoic,
ENE-trending Wadi Mubarak shear belt in the Central Eastern Desert of Egypt. Gold-bearing quartz veins
hosted by the Um Rus intrusion were mined intermittently, and initially by the ancient Egyptians and
until the early 1900s. The relationship between the gold mineralization, host intrusion, and regional
structures has always been unclear. We present new geochemical and geochronological data that help to
define the tectonic environment and age of the Um Rus intrusion. In addition, field studies are integrated
with EPMA and LA-ICP-MS data for gold-associated sulfides to better understand the formation and
distribution of gold mineralization.
The bulk-rock geochemical data of fresh host rocks indicate a calc-alkaline, metaluminous to mildly
peraluminous, I-type granite signature. Their trace element composition reflects a tectonic setting intermediate
between subduction-related and within-plate environments, presumably transitional between
syn- and post-collisional stages. The crystallization age of the Um Rus intrusion was determined
by in situ SHRIMP 206Pb/238U and 207Pb/235U measurements on accessory monazite grains. The resultant
monazite UePb weighted mean age (643 9 Ma; MSWD ¼ 1.8) roughly overlaps existing geochronological
data for similar granitic intrusions that are confined to major shear systems and are locally
associated with gold mineralization in the Central Eastern Desert (e.g., Fawakhir and Hangaliya). This age
is also consistent with magmatism recognized as concomitant to transpressional tectonics (D2:
w650 Ma) during the evolution of the Wadi Mubark belt. Formation of the gold-bearing quartz veins in
NNE-SSW and NeS striking fault segments was likely linked to the change from transpressional to
transtensional tectonics and terrane exhumation (D3: 620e580 Ma). The development of NeS throughgoing
fault arrays and dike swarms (w595 Ma) led to heterogeneous deformation and recrystallization of
the mineralized quartz veins.
Ore minerals in the auriferous quartz veins include ubiquitous pyrite and arsenopyrite, with less
abundant pyrrhotite, chalcopyrite, sphalerite, and galena. Uncommon pentlandite, gersdorffite, and
cobaltite inclusions hosted in quartz veins with meladiorite slivers are interpreted as pre-ore sulfide
phases. The gold-sulfide paragenesis encompasses an early pyrite-arsenopyrite loellingite assemblage,
a transitional pyrite-arsenopyrite assemblage, and a late pyrrhotite-chalcopyrite-sphalerite galena
assemblage. Free-milling gold/electrum grains (10s mm-long) are scattered in extensively deformed vein
quartz and in and adjacent to sulfide grains. Marcasite, malachite, and nodular goethite are authigenic
alteration phases after pyrrhotite, chalcopyrite, and pyrite and arsenopyrite, respectively.
A combined ore petrography, EPMA, and LA-ICP-MS study distinguishes morphological and compositional
differences in the early and transitional pyrites (Py I, Py II) and arsenopyrite (Apy I, Apy II). Py I
forms uncommon small euhedral inclusions in later Py II and Apy II. Py II forms large subhedral crystals with porous inner zones and massive outer zones, separated by narrow As-rich irregular mantles. The Fe
and As contents in Py II are variable, and the LA-ICP-MS analysis shows erratic concentrations of Au (<1
to 177 ppm) and other trace elements (e.g., Ag, Te, and Sb) in the porous inner zones, most likely related
to discrete sub-microscopic sulfide inclusions. The outer massive zones have a rather homogenous
composition, with consistently lower abundances of base metals and Au (mean 1.28 ppm). The early
arsenopyrite (Apy I) forms fine-grained euhedral crystals enriched in Au (mean 17.7 ppm) and many
other trace elements (i.e., Ni, Co, Se, Ag, Sb, Te, Hg, and Bi). On the other hand, Apy II occurs as coarsegrained
subhedral crystals with lower and less variable concentrations of Au (mean 4 ppm). Elevated
concentrations of Au (max. 327 ppm) and other trace elements are measured in fragmented and
aggregated pyrite and arsenopyrite grains, whereas the undeformed intact zones of the same grains are
poor in all trace elements. The occurrence of gold/electrum as secondary inclusions in deformed pyrite
and arsenopyrite crystals indicates that gold introduction was relatively late in the paragenesis. The LAICP-
MS results are consistent with gold redistribution by the NeS though-going faults/dikes overprinted
the earlier NNW-SSE quartz veins in the southeastern part of the intrusion, where the underground
mining is concentrated. Formation of the Um Rus intrusion and gold-bearing quartz veins can be related
to the evolution of the Wadi Mubarak shear belt, where the granitic intrusion formed during or just
subsequent to D2 and provided dilatation spaces for gold-quartz vein deposition when deformed by D3
structures.