Integrated interpretation of 3D seismic data to enhance the detection of the gold‐bearing reef: Mponeng Gold mine, Witwatersrand Basin (South Africa)

Manzi, M.; Cooper, G.R.J.; Malehmir, Alireza; Durrheim, Raymond; Nkosi, Zamaswazi

doi:10.1111/1365-2478.12273

Cited by 28 publications

(14 citation statements)

References 51 publications

(110 reference statements)

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“…Previous publications and recorded exploration drilled cores show the thickness of the Witwatersrand Supergroup to be approximately 5 km (Manzi et al, 2015). The thickness of the layers associated with the Witwatersrand Supergroup package on the reprocessed 2021 pre‐stack depth migration (PreSDM) data has a thickness of ∼4.5 km, which corresponds to the expected thickness of the supergroup.…”

Section: Discussionmentioning

confidence: 93%

“…The PreSDM was applied with velocity ranges of 4000–6900 m/s, choosing the velocity model with the most coherent reflections. The velocities used were derived from the physical properties studies conducted in the Witwatersrand Basin (Manzi et al, 2015). The effectiveness of PreSDM in complex hard rock environment is well documented by various authors (e.g., Bradford et al, 2006; Buske et al, 2009; Hu and Stoffa, 2009; Manzi et al, 2012b; Storch et al, 2021).…”

Section: Legacy 2d Seismic Data and 2d Seismic Modellingmentioning

confidence: 99%

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Seismic delineation of the gold‐bearing structures in the South Rand goldfield (South Africa): A comparison of pre‐stack time and depth migration approaches on legacy seismic data

Sihoyiya

Manzi

James

et al. 2022

Near Surface Geophysics

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To better image complex geological structures and explore for the gold-bearing quartz pebble conglomerate (locally termed Kimberley Reef) near Burnstone mine in the South Rand goldfield (South Africa), we reprocessed legacy 2D reflection seismic data using up-to-date seismic processing algorithms. The mining region is dominated by steeply dipping normal and reverse faults, as well as dolerite intrusions that crosscut the tabular gold mineralization and complicate the extraction of the ore. The legacy seismic data were acquired in 1993 in the South Rand goldfield as part of the gold exploration programme by the Gold Division of Anglo-American Corporation. The pre-stack data quality was improved by cautiously removing noise and applying static corrections to enhance the continuity of the reflection events. Improved structural imaging was then achieved using pre-stack time migration and pre-stack depth migration through careful velocity analysis. In particular, pre-stack depth migration provided better imaging of near-surface stratigraphic units and deep-seated complex structures, relative to older post-stack migrated images produced in 1993. Other reprocessing improvements included accurate imaging of key seismic reflective interfaces that can be used as proxies to 2D map the gold deposit, its dip variations, and geological structures (faults/dykes) crosscutting it. Synthetic shot gathers data computed using a 2D finite-difference algorithm provided some insight into the source of seismic reflectivity observed on the reprocessed seismic data. The new structural information from reprocessing is essential for enhancing ore resource evaluation and guiding future exploration projects in the region.

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Section: Discussionmentioning

confidence: 93%

Section: Legacy 2d Seismic Data and 2d Seismic Modellingmentioning

confidence: 99%

Seismic delineation of the gold‐bearing structures in the South Rand goldfield (South Africa): A comparison of pre‐stack time and depth migration approaches on legacy seismic data

Sihoyiya

Manzi

James

et al. 2022

Near Surface Geophysics

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“…In addition to the underground mapping, we carefully applied a series of 3D seismic attributes (Manzi et al 2013(Manzi et al , 2015 to the 3D reflection seismic data to enhance detection of faults (or fractures) and dikes affecting the BRF, with vertical displacements below the traditional resolution criteria (fig. 4a).…”

Section: Resultsmentioning

confidence: 99%

Recycling of Paleoplacer Gold through Mechanical and Postdepositional Mobilization in the Neoarchean Black Reef Formation, South Africa

Nwaila

Manzi

Kirk

et al. 2019

The Journal of Geology

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A B S T R A C TThe source of gold in the ca. 2.66 Ga Black Reef Formation (BRF) has been investigated and constrained through petrographic, mineralogical, geochemical, and high-resolution three-dimensional reflection seismic data combined with drill core and underground geological mapping. The BRF is a strong seismic marker and consists of carbonaceous shale, quartz arenite, and conglomerate. Gold grade in the BRF is primarily controlled by the nature of the host conglomerates. Most of the gold in the BRF conglomerate occurs in native form, and its morphology is highly heterogeneous. Gold was initially introduced through mechanical recycling of underlying Witwatersrand reefs, followed by short-range (millimeter-to centimeter-scale) postdepositional alteration/remobilization associated with the Bushveld Complex and the Vredefort meteorite impact. Although the BRF was subjected to high postdepositional fluid circulation facilitated by high fracture density, the volume of dissolved gold was probably too small to form a large gold deposit, except in areas around the Black Reef/Witwatersrand reefs subcrop positions. Findings from this study demonstrate the importance of both sedimentological controls and impact-related structures in the formation of paleoplacer gold deposits during Neoarchean times.

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“…Seismic methods have recently opened up new possibilities in the mineral exploration industry with promising examples reported worldwide, especially during the past 10 years (e.g. Koivisto et al ., 2012; Manzi et al ., 2012, 2015; Buske et al ., 2015 and references therein; Malehmir et al ., 2017, 2018; Balestrini et al ., 2020; Malehmir et al ., 2020 and references therein; Papadopoulou et al ., 2020, Polychronopoulou et al ., 2020). Given the commonly complex nature and small target size of deposits hosted within hardrock environments, seismic exploration in such settings may benefit from high‐resolution imaging provided by broadband data acquisition and processing workflows (ten Kroode et al ., 2013; Cordery, 2020).…”

Section: Introductionmentioning

confidence: 99%

Broadband seismic source data acquisition and processing to delineate iron oxide deposits in the Blötberget mine‐central Sweden

Pertuz

Malehmir

Bos³

et al. 2021

Geophysical Prospecting

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A prototype electromagnetic vibrator, referred to here as E‐Vib, was upgraded and developed for broadband hardrock and mineral exploration seismic surveys. We selected the iron oxide mine in Blötberget, central Sweden, for a test site in 2019 for the newly developed E‐Vib because of the availability of earlier seismic datasets (from 2015 to 2016) for verification of its performance for hardrock imaging purposes. The two‐dimensional data acquisition consisted of a fixed geometry with 550 receiver locations spaced at every 5 m, employing both cabled and wireless seismic recorders, along an approximately 2.7 km long profile. The E‐Vib operated at every second receiver station (i.e. 10 m spacing) with a linear sweep of 2–180 Hz and with a peak force of 7 kN. The processing workflow took advantage of the broadband signal generated by the E‐Vib in this challenging hardrock environment with varying ground conditions. The processed seismic section shows a set of reflections associated with the known iron oxide mineralization and a major crosscutting reflection interpreted to be from a fault system likely to be crosscutting the mineralization. The broadband source data acquisition and subsequent processing helped to improve signal quality and resolution in comparison with the earlier workflows and data where a drophammer seismic source was used as the seismic source. These results suggest new possibilities for the E‐Vib source for improved targeting in hardrock geological settings.

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Integrated interpretation of 3D seismic data to enhance the detection of the gold‐bearing reef: Mponeng Gold mine, Witwatersrand Basin (South Africa)

Cited by 28 publications

References 51 publications

Seismic delineation of the gold‐bearing structures in the South Rand goldfield (South Africa): A comparison of pre‐stack time and depth migration approaches on legacy seismic data

Seismic delineation of the gold‐bearing structures in the South Rand goldfield (South Africa): A comparison of pre‐stack time and depth migration approaches on legacy seismic data

Recycling of Paleoplacer Gold through Mechanical and Postdepositional Mobilization in the Neoarchean Black Reef Formation, South Africa

Broadband seismic source data acquisition and processing to delineate iron oxide deposits in the Blötberget mine‐central Sweden

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