Temperature nanotracers for fractured reservoirs characterization

Alaskar, Mohammed; Ames, Morgan; Liu, Chong; Li, Kewen; Horne, Roland N.

doi:10.1016/j.petrol.2015.01.021

Cited by 18 publications

(8 citation statements)

References 26 publications

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“…Utilization of nanoparticles in reservoir characterization bears the promise of helping to overcome some of these issues, while offering many additional possibilities for the development of smart and versatile exploration tools. First and foremost, while being small enough to be able to flow through porous rock layers 15 , nanoparticles can still concentrate a substantial amount of molecules, making detection feasible while using much lower tracer amounts 16 . Moreover, multiple chemical markers can be incorporated into the same nanoparticles, enabling the addition of a stable background signal alongside a reporting signal 17 – 19 .…”

Section: Introductionmentioning

confidence: 99%

Development of thermo-reporting nanoparticles for accurate sensing of geothermal reservoir conditions

Rudolph

Berson

Nitschke

et al. 2020

Sci Rep

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The inaccessibility of geological reservoirs, both for oil and gas production or geothermal usage, makes detection of reservoir properties and conditions a key problem in the field of reservoir engineering, including for the development of geothermal power plants. Herein, an approach is presented for the development of messenger nanoparticles for the determination of reservoir conditions, with a proof of concept example of temperature detection under controlled laboratory conditions. Silica particles are synthesized with a two-layer architecture, an inner enclosed core and an outer porous shell, each doped with a different fluorescent dye to create a dual emission system. Temperature detection happens by a threshold temperature-triggered irreversible release of the outer dye, thus changing the fluorescence signal of the particles. The reported particle system consequently enables a direct, reliable and fast way to determine reservoir temperature. It also displays a sharp threshold for accurate sensing and allows detection at concentration ranges as low as few nanograms of nanoparticles per milliliter.

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Section: Introductionmentioning

confidence: 99%

Development of thermo-reporting nanoparticles for accurate sensing of geothermal reservoir conditions

Rudolph

Berson

Nitschke

et al. 2020

Sci Rep

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“…The latter study quantified the fate of particulate matter, but did not provide insights into the transport behavior of these DNA-based tracer particles, which is required when using them as groundwater flow tracers. Horne and co-workers utilized these DNA-based particles as well as pure silica particles in sand columns, , Berea rock, and fractured medium, but no breakthrough curves or extent of recovery was reported. The authors further reported tracer loss, likely caused by the silica dissolution at the applied operating temperatures …”

Section: Introductionmentioning

confidence: 99%

Silica-Encapsulated DNA-Based Tracers for Aquifer Characterization

Mikutis

Deuber

Schmid

et al. 2018

Environ. Sci. Technol.

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Environmental tracing is a direct way to characterize aquifers, evaluate the solute transfer parameter in underground reservoirs, and track contamination. By performing multitracer tests, and translating the tracer breakthrough times into tomographic maps, key parameters such as a reservoir's effective porosity and permeability field may be obtained. DNA, with its modular design, allows the generation of a virtually unlimited number of distinguishable tracers. To overcome the insufficient DNA stability due to microbial activity, heat, and chemical stress, we present a method to encapsulated DNA into silica with control over the particle size. The reliability of DNA quantification is improved by the sample preservation with NaN 3 and particle redispersion strategies. In both sand column and unconsolidated aquifer experiments, DNA-based particle tracers exhibited slightly earlier and sharper breakthrough than the traditional solute tracer uranine. The reason behind this observation is the size exclusion effect, whereby larger tracer particles are excluded from small pores, and are therefore transported with higher average velocity, which is pore size-dependent. Identical surface properties, and thus flow behavior, makes the new material an attractive tracer to characterize sandy groundwater reservoirs or to track multiple sources of contaminants with high spatial resolution.

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“…Nanomaterials, which are of a commensurate size with micro/nano-sized pores in shale, will be considered as an excellent pore marker to light up the targeted pores to improve the pore recognition. In fact, due to their excellent properties, nanomaterials are of wide influence in geoscience, and it was reported they can participate in geological studies as nanosensors, tracers, , in-site catalysts, and surfactants . However, the application of nanomaterials as pore markers for imaging analysis of pore structure in geological materials is rarely reported.…”

mentioning

confidence: 99%

Precise Identification and Analysis of Micro/Nano-Sized Pore Structure in Shale with Fe₃O₄/Au Hybrid Nanocomposite

Zhong

Liu

et al. 2018

Anal. Chem.

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Analysis and characterization of micro/nano-sized pore structure are critical issues in shale geology and engineering. Scanning electron microscopy (SEM) imaging is one of the most widespread methods for the analysis of the micro/nano-sized pores in shale, but precise identification of the ultrafine pore structure in shale is still a big challenge because shale is so complex that some components may have overlap with pores based on the simple discrimination of gray scale under SEM microscopy. Here, Fe 3 O 4 /Au nanocomposite with magnetic properties is synthesized, characterized, and introduced as a novel pore-marker to improve SEM identification and quantitation of micro/nano-sized pores in shale. Due to the superparamagnetic property, the nanomarker is conveniently controlled by an external magnetic field to fill into pores and offers a sharp contrast imaging between matrix of shale (various gray) and pores (bright), which makes the identification of micro/ nano-sized pores in shale much more straightforward and reliable. Furthermore, because gold, as a noble metal, is particularly rare in shale, energy-dispersive X-ray spectroscopy mapping of Au is delicately used to precisely calculate area porosity in shale. Combining with the aforementioned merits of the nanomarker, a precise and practical technique is proposed to promote characterization of micro/nano-sized pores in shale.

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Temperature nanotracers for fractured reservoirs characterization

Cited by 18 publications

References 26 publications

Development of thermo-reporting nanoparticles for accurate sensing of geothermal reservoir conditions

Development of thermo-reporting nanoparticles for accurate sensing of geothermal reservoir conditions

Silica-Encapsulated DNA-Based Tracers for Aquifer Characterization

Precise Identification and Analysis of Micro/Nano-Sized Pore Structure in Shale with Fe₃O₄/Au Hybrid Nanocomposite

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Temperature nanotracers for fractured reservoirs characterization

Cited by 18 publications

References 26 publications

Development of thermo-reporting nanoparticles for accurate sensing of geothermal reservoir conditions

Development of thermo-reporting nanoparticles for accurate sensing of geothermal reservoir conditions

Silica-Encapsulated DNA-Based Tracers for Aquifer Characterization

Precise Identification and Analysis of Micro/Nano-Sized Pore Structure in Shale with Fe3O4/Au Hybrid Nanocomposite

Contact Info

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Precise Identification and Analysis of Micro/Nano-Sized Pore Structure in Shale with Fe₃O₄/Au Hybrid Nanocomposite