Erik R. Smith scite author profile

Changes in pore (throat) size, surface roughness, and mineralogy induced by supercritical CO 2-water-rock reactions impact petrophysical properties such as porosity, permeability, and especially wettability. Herein, we show that these changes directly impact relative permeability and capillary pressure curves, a fact rarely studied in the literature. In this work, we show that CO 2 contact angle changes emerge after Madison Limestone samples were soaked for 400 hr in CO 2-enriched brine. Coreflooding results show that the water production rate and cumulative water production increased after the rock was exposed to carbonic acid. Moreover, the mercury capillary pressure decreased in mesopores and macropores, indicating the increase of size in these pores due to reactions. This compounded wettability and pore network alteration can directly affect CO 2 injectivity, migration, and storage capacity. This fundamental insight into CO 2 geological storage processes should aid practitioners to reduce uncertainties in forecasting CO 2 distribution via injection simulation. Plain Language Summary Emitting a large amount of greenhouse gases into the atmosphere has disrupted the global carbon cycle. CO 2 captured from various sources could be transported to a close-by site for injection into deep saline aquifers or oil/gas reservoirs for storage or/and enhanced oil recovery. Reactions between the rock and the carbonic acid can alter the rock fabric. These reactions can change rock properties, for example, pore structure, porosity, permeability, and wettability. These changes can affect capillary pressure and relative permeability. These rock alterations can significantly impact the fate of the injected CO 2. Despite efforts made to determine changes in pore architecture or petrophysical properties, a few studies have investigated the impact of rock alteration on multiphase flow properties, namely, capillary pressure and relative permeability. Even less is understood on this subject when diffusion dominates over convective transport. Here we focused on changes in pore (throat) size distribution and wettability, and dynamic properties, as induced by geochemical reactions. We observed pore enlargement among the larger pores (mesopores to macropores) due to mineral dissolution, which contrasts with a decreased size in smaller pores (micropores), resulting from mineral precipitation. These processes lead to a more CO 2 surface wetting and thereby capillary pressure and relative permeability.

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Determining Relative Airport Threats from News and Social Media

Khandpur

Ning

et al. 2017

AAAI

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Airports are a prime target for terrorist organizations, drug traffickers, smugglers, and other nefarious groups. Traditional forms of security assessment are not real-time and often do not exist for each airport and port of entry. Thus, homeland security professionals must rely on measures of attractiveness of an airport as a target for attacks. We present an open source indicators approach, using news and social media, to conduct relative threat assessment, i.e., estimating if one airport is under greater threat than another. The three ingredients of our approach are a dynamic query expansion algorithm for tracking emerging threat-related chatter, news-Twitter reciprocity modeling for capturing interactions between social and traditional media, and a ranking scheme to provide an ordered assessment of airport threats. Case studies based on actual aviation incidents are presented.

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Time-Domain Nuclear Magnetic Resonance Determination of Wettability Alteration: Analysis for Low-Salinity Water

et al. 2020

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Wettability has been shown to influence oil recovery. This property has become central to low-salinity (LSW) and smart (SWF) water flooding recovery mechanisms research. The challenge lies in the fact that oil recovery results from the combined effects of solid-liquid and liquid-liquid interactions. This demands methods that allow an independent interpretation of wettability alteration contributions. The primary objective of this work is to assess changes in wettability through the application of Time-Domain Nuclear Magnetic Resonance (TD-NMR) T 2 distribution and diffusion coefficient, starting with a well-controlled porous system, that is, glass beads, and then a model rock (Berea), in the presence of one phase, either oil or brine exclusively. Subsequently, two-phase fluid saturation was tested. For the glass beads, dimethyldichlorosilane was used to induce a hydrophobic response, as confirmed by contact angle experiments on slides of the same material. Sodium sulfate was used for its known positive influence on oil recovery during LSW and SWF. In cases where alteration of surface properties was expected, a leftward shift of the average T 2 distribution curve modes, accompanied by a reduction on the diffusion coefficient during the aging process was observed. The results of this work confirm that fluid-solid interactions during LSW and SWF, namely a shift in wettability, take place after the injection of low-salinity water.

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WETTABILITY ALTERATION BY SUPERCRITICAL CO₂-ENRICHED WATER AND ITS IMPACT ON MULTIPHASE FLOW RELATED TO CO₂ SEQUESTRATION

Wang¹,

Alvarado²,

Kaszuba³

et al. 2019

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Influence of interfacial responses of Berea Sandstone in low-salinity waterflooding environments

Smith

Medina-Rodriguez

Alvarado

2022

Fuel

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Erik R. Smith

Link Between CO₂‐Induced Wettability and Pore Architecture Alteration

Determining Relative Airport Threats from News and Social Media

Time-Domain Nuclear Magnetic Resonance Determination of Wettability Alteration: Analysis for Low-Salinity Water

WETTABILITY ALTERATION BY SUPERCRITICAL CO₂-ENRICHED WATER AND ITS IMPACT ON MULTIPHASE FLOW RELATED TO CO₂ SEQUESTRATION

Influence of interfacial responses of Berea Sandstone in low-salinity waterflooding environments

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Erik R. Smith

Link Between CO2‐Induced Wettability and Pore Architecture Alteration

Determining Relative Airport Threats from News and Social Media

Time-Domain Nuclear Magnetic Resonance Determination of Wettability Alteration: Analysis for Low-Salinity Water

WETTABILITY ALTERATION BY SUPERCRITICAL CO2-ENRICHED WATER AND ITS IMPACT ON MULTIPHASE FLOW RELATED TO CO2 SEQUESTRATION

Influence of interfacial responses of Berea Sandstone in low-salinity waterflooding environments

Contact Info

Product

Resources

About

Link Between CO₂‐Induced Wettability and Pore Architecture Alteration

WETTABILITY ALTERATION BY SUPERCRITICAL CO₂-ENRICHED WATER AND ITS IMPACT ON MULTIPHASE FLOW RELATED TO CO₂ SEQUESTRATION