G. J. Hudak scite author profile

The original MOUDI (Micro-Orifice Uniform Deposit Impactor) cascade impactor, reported in the literature in 1991, used an external gear system to achieve a uniform deposit and was intended for industrial hygiene studies with sample times in the range of minutes to a few hours. To facilitate much longer run times, a second generation MOUDI, MOUDI-II, which uses internal electric motors to rotate the impaction plates, was developed. Three model 120 MOUDI-IIs were used in a 32-month program to sample ambient atmospheric aerosols at several industrial and urban locations in Minnesota. For these sampling locations, each 120 MOUDI-II operated continuously for a minimum of five, and optimally 7 days, to collect a sample at a site. During these community sampling events, the three 120 MOUDI-IIs logged 4007, 2637, and 3230 h of operating time, respectively. A laboratory side-by-side comparison of the three 120 MOUDI-IIs showed good agreement amongst the three 120 MOUDI-IIs and, thus, the particle size distributions were independent of the 120 MOUDI-II used. Application of the 120 MOUDI-IIs for long-term ambient sampling was demonstrated by comparing size distributions from the background locations: Minneapolis, Duluth and Ely, Minnesota, representing urban, light industrial, and pristine area type of aerosols, respectively. PM 2.5 averages from Minneapolis and Duluth compare well with three-year averages from state regulatory sampling.

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The early development of an Archean submarine caldera complex with emphasis on the Mattabi ash-flow tuff and its relationship to the Mattabi massive sulfide deposit

Morton¹,

Walker²,

Hudak³

et al. 1991

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The south Sturgeon Lake area of northwestern Ontario is underlain by an Archean submarine caldera complex which is host to six massive sulfide deposits. The complex is approximately 30 km in strike length and is partly filled by mesobreccias, subaqueous debris-flow deposits and other epiclastic rocks, as well as five major ash-flow tuff units. The most voluminous of these, the Mattabi ash-flow tuff, is up to 800 m in thickness and can be traced for more than 15 km across the caldera complex. Based on flow morphology and composition, the Mattabi ash-flow tuff is divisible into two distinct units: a bedded quartz crystal and pumice-rich unit (150-650 m thick), and a massive to poorly bedded ash unit (20-150 m thick). The bedded unit is host to the Mattabi massive sulfide deposit, as well as numerous other massive sulfide occurrences. In addition, this unit exhibits a pronounced stratigraphic and geochemical cyclicity. Individual beds (flow units) can be subdivided into basal quartz-and pumice-rich lower sections which are overlain by bedded ash tops; thicknesses of individual beds vary from 14 to 155 m. Each bed also exhibits a pronounced zonation of trace elements with high concentrations of Zr, Y, and Nb at and/ornear the base gradually decreasing upward into the ash tops. The overlying massive ash unit contains no known massive sulfide mineralization and lacks any pronounced geochemical zoning.The bedded nature and geochemical zonation of individual flow units can be explained by periodic eruptions from a zoned or layered, recharged siliceous magma chamber. The difference in flow morphology between the bedded unit and the overlying massive ash-flow tuff most likely reflects the deeper submarine nature of the eruptive vents associated with the bedded deposits. The periodic and subaqueous nature of the Mattabi eruptions is indicated by the presence of exhalites and massive sulfide lenses between flow units. The ore lenses, which comprise the Mattabi deposit, formed between eruptive events from high temperature fluids whose origin may be related to processes within the magma chamber.

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3 Standards: A Perspective and Some Future Directions for the Systems Engineering Community

Velman¹,

Widmann²,

Hudak

1999

INCOSE International Symp

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Morphology, distribution, and estimated eruption volumes for intracaldera tuffs associated with volcanic-hosted massive sulfide deposits in the Archean Sturgeon Lake Caldera Complex, Northwestern Ontario

Hudak

Morton

Franklin

et al. 2003

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G. J. Hudak

Submarine Volcanic Processes, Deposits, and Environments Favorable for the Location of Volcanic-Associated Massive Sulfide Deposits

Second Generation Micro-Orifice Uniform Deposit Impactor, 120 MOUDI-II: Design, Evaluation, and Application to Long-Term Ambient Sampling

The early development of an Archean submarine caldera complex with emphasis on the Mattabi ash-flow tuff and its relationship to the Mattabi massive sulfide deposit

3 Standards: A Perspective and Some Future Directions for the Systems Engineering Community

Morphology, distribution, and estimated eruption volumes for intracaldera tuffs associated with volcanic-hosted massive sulfide deposits in the Archean Sturgeon Lake Caldera Complex, Northwestern Ontario

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