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Journal of Australian Energy Producers
 

Geoscience Poster G1: Origins of hydrogen sulfide (H2S) in gas reservoirs by isotopic analyses: the mitigation of operation risks

Gareth R. L. Chalmers A *
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A University of the Sunshine Coast, Sippy Downs, Qld, Australia.

* Correspondence to: gchalmers@usc.edu.au

The APPEA Journal 62 - https://doi.org/10.1071/AJ21397
Published: 3 June 2022

Abstract

Poster G1

The distribution and origin of hydrogen sulfide (H2S) within gas reservoirs is an important issue due to its toxicity and ability to corrode metal infrastructure, even at low concentrations (i.e. 50 ppm). H2S gas is regarded as a high priority for health and safety at drilling sites. The distribution of H2S, in some basins, can be inexplicable with a mix of sweet (no H2S) and sour (contains H2S) wells within one multi-well pad. Sour gas is a concern in some gas and coal fields in Australia which include Gippsland, Bowen and Cooper-Eromanga basins as well as in the North West Shelf with typical concentrations below 10 000 ppm. For example, the German Creek Formation (Bowen Basin) contains up to 77 ppm of H2S gas and coal seam gas producers will need to perform a risk assessment while exploring and developing this resource. There are multiple sources of H2S gas sulfur and this includes sulfate minerals, pyrite, organic sulfur or from frack water. This research utilises the isotopic variation in the sulfur and oxygen of potential sources, coupled with petrological analyses to determine H2S gas generation. Data is used to predict the gas distribution within the reservoirs to reduce exploration risks. One initial study on the Triassic Montney Formation in western Canada produces H2S gas at concentrations up to 220 000 ppm. Isotopic analyses suggest that the H2S is generated from either Triassic sulfates or a mixture of Triassic and Devonian sources and not solely from Devonian rocks as first expected.

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Keywords: environmental geology, hydrogen sulphide gas, isotopic analyses, Montney Formation, risking, sedimentology, sulfur​ isotopes, unconventional gas, well planning.

Gareth R. L. Chalmers is a Lecturer at the University of the Sunshine Coast and is researching Australian gas reservoirs. He has over 15 years’ experience in coal and shale geology. His MSc (Newcastle University, 2001) expanded sequence stratigraphy into non-marine coal-bearing strata by correlating significant surfaces identified through organic petrology of an amalgamated coal seam. Gareth then completed his PhD at the University of British Columbia, Canada (2007) where he used a multidisciplinary approach incorporating organic geochemistry, petrology, sedimentology and mineralogy to investigate the geology of shale gas resources. He continued research at UBC as Postdoctoral Fellow and evaluated four shale formations in North America. Gareth then joined Shell Canada (Calgary, 2013) to gain industry experience in developing the Duvernay gas shale play. Gareth is currently investigating the origin and distribution of toxic H2S gas within the Montney Formation in western Canada.