Yuesheng Cheng scite author profile

We present the first 13C magnetic resonance imaging study of CO2 transient adsorption/desorption processes in a zeolite 5A column. CO2 transient concentration profiles were measured with a centric scan spin-echo single point imaging technique. The adsorption wave profiles were determined under flow conditions, with the results analyzed by the Bohart-Adams model. The model adequately accounts for the spatial and the temporal behavior of CO2 in the column. CO2 adsorption rate constants were calculated from the fit. Desorption profiles were acquired by blowing a helium stream through a zeolite 5A column saturated with CO2. An asymmetry between the adsorption and desorption profiles is readily apparent. A linear relationship between the CO2 condensed phase concentration and square root of time was observed.

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Detection of intermolecular homonuclear dipolar coupling in organic rich shale by transverse relaxation exchange

Washburn¹,

Cheng

2017

Journal of Magnetic Resonance

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Improved Correlations for Heavy-Oil Viscosity Prediction with NMR

Sandor

Cheng

Chen

2016

Journal of Petroleum Science and Engineering

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Evaluation of sandstone surface relaxivity using laser-induced breakdown spectroscopy

Washburn¹,

Sandor

Cheng

2017

Journal of Magnetic Resonance

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Direct Detection of Hydrocarbon Displacement in a Model Porous Soil with Magnetic Resonance Imaging

et al. 2005

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The direct detection of hydrocarbon fluid and the discrimination of water through carbon-13 magnetic resonance imaging (MRI) would be a significant advance in many scientific fields including food, petrogeological, and environmental sciences. Carbon-13 MRI is a noninvasive analytical technique that has great potential for direct detection of hydrocarbons. However, the low natural abundance of carbon-13, low gyromagnetic ratio, and generically short transverse signal lifetimes in realistic porous media all conspire to hinder carbon-13 MRI. A multiple echo pure phase encode MRI technique introduced in this paper helps to overcome these limitations. As a pure phase encode technique, it is immune to artifacts arising from inhomogeneous B0 fields. It is also, by its nature, more quantitative than most MRI methods. Viscous hydrocarbon flow through a sand bed, a simple realistic porous medium, was used as our test system. Flow in this model system was driven by capillary suction. The detection limit, spatially resolved, was determined to be 26 mg.

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Yuesheng Cheng

CO₂ Dynamic Adsorption/Desorption on Zeolite 5A Studied by ¹³C Magnetic Resonance Imaging

Detection of intermolecular homonuclear dipolar coupling in organic rich shale by transverse relaxation exchange

Improved Correlations for Heavy-Oil Viscosity Prediction with NMR

Evaluation of sandstone surface relaxivity using laser-induced breakdown spectroscopy

Direct Detection of Hydrocarbon Displacement in a Model Porous Soil with Magnetic Resonance Imaging

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Yuesheng Cheng

CO2 Dynamic Adsorption/Desorption on Zeolite 5A Studied by 13C Magnetic Resonance Imaging

Detection of intermolecular homonuclear dipolar coupling in organic rich shale by transverse relaxation exchange

Improved Correlations for Heavy-Oil Viscosity Prediction with NMR

Evaluation of sandstone surface relaxivity using laser-induced breakdown spectroscopy

Direct Detection of Hydrocarbon Displacement in a Model Porous Soil with Magnetic Resonance Imaging

Contact Info

Product

Resources

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CO₂ Dynamic Adsorption/Desorption on Zeolite 5A Studied by ¹³C Magnetic Resonance Imaging