Your search keyword '"Ren, Shuangpo"' showing total 8 results

1. Borehole Nuclear Magnetic Resonance Estimation of Specific Yield in a Fractured Granite Aquifer.

Author

Phillips, Stephanie N., Carr, Bradley, Zhang, Ye, Flinchum, Brady, and Ren, Shuangpo

Subjects

NUCLEAR magnetic resonance, GRANITE, AQUIFERS, WATER pumps, HYDROGEOLOGY

Abstract

In this study, we introduce a novel field‐based method to estimate specific yield (Sy) in fractured, low‐porosity granite aquifers using borehole nuclear magnetic resonance (bNMR). This method requires collecting a bNMR survey immediately following a pump test, which dewaters the near‐borehole fractures. The residual water content measured from bNMR is interpreted as "bound" and represents the specific retention (Sr) while the water drained by the pump is the Sy. The transverse relaxation cutoff time (T2C) is the length of time that partitions the total porosity measured by bNMR into Sr and Sy. When applying a calibrated T2C, Sy equals the bNMR total porosity minus Sr; thus, a calibrated T2C is required to determine Sy directly from NMR results. Based on laboratory experiments on sandstone cores, the default T2C is 33 ms; however, its applicability to fractured granite aquifers is uncertain. The optimal T2C based on our pumping test is 110 ± 25 ms. Applying this calibrated T2C on a saturated, A‐type granite at our field site, we estimate the Sy to be 0.012 ± 0.005 m3 m−3 which is significantly different from the Sy (0.021 ± 0.005 m3 m−3) estimate using the default T2C of 33 ms. This Sy estimate falls within a range determined using traditional hydraulic testing at the same site. Using the conventional T2C (33 ms) for fractured granite leads to an inaccurate Sy; therefore, it is essential to calibrate the bNMR T2C for the local site conditions prior to estimating Sy. Article impact statement: New method to determine specific yield in low, porosity fractured granite using borehole nuclear magnetic resonance. [ABSTRACT FROM AUTHOR]

Published

2024

2. High-resolution geostatistical modeling of an intensively drilled heavy oil reservoir, the BQ 10 block, Biyang Sag, Nanxiang Basin, China

Author

Ren, Shuangpo, Yao, Guangqing, and Zhang, Ye

Published

2019

3. Borehole Nuclear Magnetic Resonance Estimation of Specific Yield in a Fractured Granite Aquifer

Author

Phillips, Stephanie N., primary, Carr, Bradley, additional, Zhang, Ye, additional, Flinchum, Brady, additional, and Ren, Shuangpo, additional

Published

2023

4. Borehole characterization of hydraulic properties and groundwater flow in a crystalline fractured aquifer of a headwater mountain watershed, Laramie Range, Wyoming

Author

Ren, Shuangpo, Gragg, Samuel, Zhang, Ye, Carr, Bradley J., and Yao, Guangqing

Published

2018

5. 莺歌海盆地LD10区高含CO2天然气充注期次精细厘定与成藏模式

Author

Jiang, Ping, primary, He, Shenglin, additional, Yang, Zhaoqiang, additional, Yang, Kaile, additional, Wang, Meng, additional, Lan, Zhangjian, additional, Ren, Shuangpo, additional, Zhang, Ruixue, additional, Zhao, Xiaobo, additional, and Yao, Guangqing, additional

Published

2022

6. Multiscale Hydraulic Conductivity Characterization in a Fractured Granitic Aquifer: The Evaluation of Scale Effect

Author

Ren, Shuangpo, primary, Zhang, Ye, additional, Jim Yeh, Tian‐Chyi, additional, Wang, Yuli, additional, and Carr, Bradley J., additional

Published

2021

7. Hydraulic Conductivity Calibration of Logging NMR in a Granite Aquifer, Laramie Range, Wyoming

Author

Ren, Shuangpo, primary, Parsekian, Andrew D., additional, Zhang, Ye, additional, and Carr, Bradley J., additional

Published

2018

8. Hydraulic Conductivity Calibration of Logging NMR in a Granite Aquifer, Laramie Range, Wyoming.

Author

Ren, Shuangpo, Parsekian, Andrew D., Zhang, Ye, and Carr, Bradley J.

Subjects

*HYDRAULIC conductivity, *AQUIFERS, *GROUNDWATER, *NUCLEAR magnetic resonance, *BOREHOLES, *DIFFUSION, *GRANITE

Abstract

In granite aquifers, fractures can provide both storage volume and conduits for groundwater. Characterization of fracture hydraulic conductivity (K) in such aquifers is important for predicting flow rate and calibrating models. Nuclear magnetic resonance (NMR) well logging is a method to quickly obtain near‐borehole hydraulic conductivity (i.e., KNMR) at high‐vertical resolution. On the other hand, FLUTe flexible liner technology can produce a K profile at comparable resolution but requires a fluid driving force between borehole and formation. For three boreholes completed in a fractured granite, we jointly interpreted logging NMR data and FLUTe K estimates to calibrate an empirical equation for translating borehole NMR data to K estimates. For over 90% of the depth intervals investigated from these boreholes, the estimated KNMR are within one order of magnitude of KFLUTe. The empirical parameters obtained from calibrating the NMR data suggest that "intermediate diffusion" and/or "slow diffusion" during the NMR relaxation time may occur in the flowing fractures when hydraulic aperture are sufficiently large. For each borehole, "intermediate diffusion" dominates the relaxation time, therefore assuming "fast diffusion" in the interpretation of NMR data from fractured rock may lead to inaccurate KNMR estimates. We also compare calibrations using inexpensive slug tests that suggest reliable KNMR estimates for fractured rock may be achieved using limited calibration against borehole hydraulic measurements. Article Impact Statement: A joint interpretation of logging NMR data and FLUTe K estimates are used to calibrate the SDR equation in a fractured granite aquifer. [ABSTRACT FROM AUTHOR]

Published

2019