Effects of high pressure and temperature conditions on the chemical fate of flowback water related chemicals

Environmental risk assessment is generally based on atmospheric conditions for the modelling of chemical fate after entering the environment. However, during hydraulic fracturing, chemicals may be released deep underground. This study therefore focuses on the effects of high pressure and high temper...

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Bibliographic Details
Published in:The Science of the total environment 2023-08, Vol.888, p.163888-163888, Article 163888
Main Authors: Faber, Ann-Hélène, Brunner, Andrea M., Schimmel, Mariska, Schot, Paul P., de Voogt, Pim, van Wezel, Annemarie
Format: Article
Language:English
Subjects:
chemical composition
Downhole conditions
environment
environmental assessment
Environmental fate
Flowback water
Risk assessment
salinity
Shale
sorption
temperature
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Summary:Environmental risk assessment is generally based on atmospheric conditions for the modelling of chemical fate after entering the environment. However, during hydraulic fracturing, chemicals may be released deep underground. This study therefore focuses on the effects of high pressure and high temperature conditions on chemicals in flowback water to determine whether current environmental fate models need to be adapted in the context of downhole activities. Crushed shale and flowback water were mixed and exposed to different temperature (25–100 °C) and pressure (1–450 bar) conditions to investigate the effects they have on chemical fate. Samples were analysed using LC-HRMS based non-target screening. The results show that both high temperature and pressure conditions can impact the chemical fate of hydraulic fracturing related chemicals by increasing or decreasing concentrations via processes of transformation, sorption, degradation and/or dissolution. Furthermore, the degree and direction of change is chemical specific. The change is lower or equal to a factor of five, but for a few individual compounds the degree of change can exceed this factor of five. This suggests that environmental fate models based on surface conditions may be used for an approximation of chemical fate under downhole conditions by applying an additional factor of five to account for these uncertainties. More accurate insight into chemical fate under downhole conditions may be gained by studying a fluid of known chemical composition and an increased variability in temperature and pressure conditions including concentration, salinity and pH as variables. [Display omitted] •Are current environmental fate models suitable for downhole activities?•Chemical comparison of high pressure/temperature and atmospheric samples•Chemical composition analysed via non-target screening using LC-HRMS•Average change is equal or lower to a factor 5.•Use of environmental fate models possible using additional factor of 5
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2023.163888