FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2569993485> ?p ?o ?g. }

• W2569993485 endingPage "20" @default.
• W2569993485 startingPage "11" @default.
• W2569993485 abstract "Dissolved CO2 in the subsurface resulting from geological CO2 storage may react with minerals in fractured rocks, confined aquifers, or faults, resulting in mineral precipitation and dissolution. The overall rate of reaction can be affected by coupled processes including hydrodynamics, transport, and reactions at the (sub) pore-scale. In this work pore-scale modeling of coupled fluid flow, reactive transport, and heterogeneous reactions at the mineral surface is applied to account for permeability alterations caused by precipitation-induced pore-blocking. This work is motivated by observations of CO2 seeps from a natural CO2 sequestration analog, Crystal Geyser, Utah. Observations along the surface exposure of the Little Grand Wash fault indicate the lateral migration of CO2 seep sites (i.e., alteration zones) of 10–50 m width with spacing on the order of ~100 m over time. Sandstone permeability in alteration zones is reduced by 3–4 orders of magnitude by carbonate cementation compared to unaltered zones. One granular porous medium and one fracture network systems are used to conceptually represent permeable porous media and locations of conduits controlled by fault-segment intersections and/or topography, respectively. Simulation cases accounted for a range of reaction regimes characterized by the Damköhler (Da) and Peclet (Pe) numbers. Pore-scale simulation results demonstrate that combinations of transport (Pe), geochemical conditions (Da), solution chemistry, and pore and fracture configurations contributed to match key patterns observed in the field of how calcite precipitation alters flow paths by pore plugging. This comparison of simulation results with field observations reveals mechanistic explanations of the lateral migration and enhances our understanding of subsurface processes associated with the CO2 injection. In addition, permeability and porosity relations are constructed from pore-scale simulations which account for a range of reaction regimes characterized by the Da and Pe numbers. The functional relationships obtained from pore-scale simulations can be used in a continuum scale model that may account for large-scale phenomena mimicking lateral migration of surface CO2 seeps." @default.
• W2569993485 created "2017-01-13" @default.
• W2569993485 creator A5021078344 @default.
• W2569993485 creator A5027828097 @default.
• W2569993485 creator A5088203471 @default.
• W2569993485 creator A5089401974 @default.
• W2569993485 date "2017-07-01" @default.
• W2569993485 modified "2023-10-14" @default.
• W2569993485 title "Application of a pore-scale reactive transport model to a natural analog for reaction-induced pore alterations" @default.
• W2569993485 cites W1526779240 @default.
• W2569993485 cites W1571636227 @default.
• W2569993485 cites W1589984731 @default.
• W2569993485 cites W1879273348 @default.
• W2569993485 cites W1978990551 @default.
• W2569993485 cites W1981214837 @default.
• W2569993485 cites W1990567095 @default.
• W2569993485 cites W1991639870 @default.
• W2569993485 cites W2002979969 @default.
• W2569993485 cites W2003469114 @default.
• W2569993485 cites W2013615178 @default.
• W2569993485 cites W2016954314 @default.
• W2569993485 cites W2017428450 @default.
• W2569993485 cites W2018379677 @default.
• W2569993485 cites W2019418345 @default.
• W2569993485 cites W2019480430 @default.
• W2569993485 cites W2020415537 @default.
• W2569993485 cites W2030843616 @default.
• W2569993485 cites W2034059473 @default.
• W2569993485 cites W2041044410 @default.
• W2569993485 cites W2045020781 @default.
• W2569993485 cites W2047476280 @default.
• W2569993485 cites W2048603894 @default.
• W2569993485 cites W2054041788 @default.
• W2569993485 cites W2061844629 @default.
• W2569993485 cites W2061892033 @default.
• W2569993485 cites W2074300450 @default.
• W2569993485 cites W2076561113 @default.
• W2569993485 cites W2083492120 @default.
• W2569993485 cites W2084433545 @default.
• W2569993485 cites W2085385901 @default.
• W2569993485 cites W2122950289 @default.
• W2569993485 cites W2124610955 @default.
• W2569993485 cites W2147318572 @default.
• W2569993485 cites W2158660715 @default.
• W2569993485 cites W2216191844 @default.
• W2569993485 cites W2309363047 @default.
• W2569993485 cites W2314553727 @default.
• W2569993485 cites W2318173295 @default.
• W2569993485 cites W2335387859 @default.
• W2569993485 cites W4302544546 @default.
• W2569993485 doi "https://doi.org/10.1016/j.petrol.2017.01.002" @default.
• W2569993485 hasPublicationYear "2017" @default.
• W2569993485 type Work @default.
• W2569993485 sameAs 2569993485 @default.
• W2569993485 citedByCount "6" @default.
• W2569993485 countsByYear W25699934852019 @default.
• W2569993485 countsByYear W25699934852021 @default.
• W2569993485 countsByYear W25699934852022 @default.
• W2569993485 crossrefType "journal-article" @default.
• W2569993485 hasAuthorship W2569993485A5021078344 @default.
• W2569993485 hasAuthorship W2569993485A5027828097 @default.
• W2569993485 hasAuthorship W2569993485A5088203471 @default.
• W2569993485 hasAuthorship W2569993485A5089401974 @default.
• W2569993485 hasBestOaLocation W25699934851 @default.
• W2569993485 hasConcept C102579867 @default.
• W2569993485 hasConcept C105569014 @default.
• W2569993485 hasConcept C120882062 @default.
• W2569993485 hasConcept C127313418 @default.
• W2569993485 hasConcept C127413603 @default.
• W2569993485 hasConcept C161790260 @default.
• W2569993485 hasConcept C175113610 @default.
• W2569993485 hasConcept C178790620 @default.
• W2569993485 hasConcept C185592680 @default.
• W2569993485 hasConcept C187320778 @default.
• W2569993485 hasConcept C191897082 @default.
• W2569993485 hasConcept C192562407 @default.
• W2569993485 hasConcept C199289684 @default.
• W2569993485 hasConcept C2780191791 @default.
• W2569993485 hasConcept C2780659211 @default.
• W2569993485 hasConcept C41625074 @default.
• W2569993485 hasConcept C42360764 @default.
• W2569993485 hasConcept C523993062 @default.
• W2569993485 hasConcept C55493867 @default.
• W2569993485 hasConcept C6648577 @default.
• W2569993485 hasConcept C75622301 @default.
• W2569993485 hasConcept C76177295 @default.
• W2569993485 hasConcept C88380143 @default.
• W2569993485 hasConcept C94556721 @default.
• W2569993485 hasConceptScore W2569993485C102579867 @default.
• W2569993485 hasConceptScore W2569993485C105569014 @default.
• W2569993485 hasConceptScore W2569993485C120882062 @default.
• W2569993485 hasConceptScore W2569993485C127313418 @default.
• W2569993485 hasConceptScore W2569993485C127413603 @default.
• W2569993485 hasConceptScore W2569993485C161790260 @default.
• W2569993485 hasConceptScore W2569993485C175113610 @default.
• W2569993485 hasConceptScore W2569993485C178790620 @default.
• W2569993485 hasConceptScore W2569993485C185592680 @default.
• W2569993485 hasConceptScore W2569993485C187320778 @default.

• next