Carbon quantum dots with tracer-like breakthrough ability for reservoir characterization

Predictions have shown that our demand for oil and gas will continue to grow in the next decade, and future supply will become more reliant on tertiary recovery and from nonconventional resources. However, current reservoir characterization methodologies, such as well logs, cross-well electromagneti...

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Bibliographic Details
Published in:The Science of the total environment 2019-06, Vol.669, p.579-589
Main Authors: Hu, Zhongliang, Gao, Hui, Ramisetti, Srinivasa B., Zhao, Jin, Nourafkan, Ehsan, Glover, Paul W.J., Wen, Dongsheng
Format: Article
Language:English
Subjects:
High salinity
Medicin och hälsovetenskap
Quantum dots
Scalable nanotracer
Subsurface reservoir characterization
Transport behaviour
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Summary:Predictions have shown that our demand for oil and gas will continue to grow in the next decade, and future supply will become more reliant on tertiary recovery and from nonconventional resources. However, current reservoir characterization methodologies, such as well logs, cross-well electromagnetic imaging and seismic methods, have their individual limitations on detection range and resolution. Here we propose a pioneering way to use carbon quantum dots (CQDs) as nanoparticle tracers, which can be transported through a reservoir functioning as conventional tracers, while acting as sensors to obtain useful information. These hydrothermally produced CQDs from Xylose possess excellent stability in high ionic strength solutions, durable absorbance and fluorescence ability due to multi high-polarity functional group on their surfaces. Consistency between our on-line ultraviolet–visible (UV–Vis) spectroscopy and off-line Confocal laser scanning microscopy (CLSM) measurements confirms that CQDs have the tracer-like migration capability in glass beads-packed columns and sandstone cores, regardless of particle concentration and ionic strength. However, their migration ability is undermined in the column packed with crushed calcite grains with positive charge. We also demonstrate that quantitative oil saturation detection in unknown sandstone core samples can be achieved by such CQDs based on its breakthrough properties influenced by the presence of oil phase. [Display omitted] •The CQDs produced form D-(+)-Xylose has a tracer-like breakthrough ability in glass beads column and Brea sandstone.•CQDs show a good stability against high salinity, and ions even improve their stability.•The concentration and deposition of CQDs can be determined by the fluorescence method.•CQDs can be used to detect the oil saturation in the Berea Sandstone.•CQD transport behaviour in rock saturated with oil is simulated by using the modified 1-D ADR equation.
ISSN:0048-9697
1879-1026
1879-1026
DOI:10.1016/j.scitotenv.2019.03.007