Multiscale X-Ray Scattering for Probing Chemo-Morphological Coupling in Pore-to-Field and Process Scale Energy and Environmental Applications

Gadikota, Greeshma

doi:10.5772/intechopen.76266

Cited by 4 publications

(4 citation statements)

References 39 publications

(42 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Furthermore, in situ experimental techniques for determining the time-resolved abundances of solids (including intermediate phases), gases, fluids, and solutes are required to delineate and quantify carbonation and serpentinization reactions under elevated-pressure and -temperature conditions. These techniques are continuing to be developed, as researchers are investigating olivine reactivity under subsurface-relevant conditions with in situ optical, ,,, nuclear magnetic resonance (NMR), − and X-ray spectroscopies that complement X-ray scattering and diffraction investigations. ,,,,− Experimental advances need to be partnered with computational studies to help unravel key mechanistic information, such as those that provide insight into processes at olivine–H 2 O–CO 2 interfaces ,− and the thermodynamic stabilities of Mg carbonates. − Coupled reactivity and transport during olivine carbonation is also being evaluated with flow-through − and diffusion-limited experimental setups ,− that simulate a range of realistic fluid:rock ratios, flow rates, and pore network , regimes. These studies and others − are beginning to clarify physicochemical feedback between olivine carbonation and porosity–permeability development, including how localized flow rates and crystallographic orientation influence preferential carbonate precipitation.…”

Section: Knowledge Gaps and Research Frontiersmentioning

confidence: 99%

Quantitative Review of Olivine Carbonation Kinetics: Reactivity Trends, Mechanistic Insights, and Research Frontiers

Miller

Schaef

Kaszuba

et al. 2019

Environ. Sci. Technol. Lett.

Self Cite

View full text Add to dashboard Cite

Magnesium-dominant olivine (Mg2SiO4) has received considerable attention for geologic and ex situ carbon mineralization due to its reaction potential with CO2 and its abundance in mafic and ultramafic rocks. To enable better predictions and optimization of its carbonation rate, here we compile the results of 15 separate studies into an internally consistent kinetic framework. Time-dependent transformation curves were determined, analyzed, and used to calculate temperature-dependent carbonation rate constants between 50 and 300 °C. The unified results clearly show that olivine carbonation is optimized at 185–200 °C and indicate a change in the carbonation reaction mechanism above 90 °C. Additional outcomes include the identification of important knowledge gaps and research frontiers for carbon mineralization, including those related to unraveling competitive serpentinization reactions, H2O-saturated supercritical CO2 (wet scCO2) reactivity, and the formation and impacts of secondary surface coatings. In addition to supporting the deployment of carbon storage technologies in a climate-responding world, the findings may help improve understanding of how carbonation and serpentinization processes influence critical geochemical cycles.

show abstract

Section: Knowledge Gaps and Research Frontiersmentioning

confidence: 99%

Quantitative Review of Olivine Carbonation Kinetics: Reactivity Trends, Mechanistic Insights, and Research Frontiers

Miller

Schaef

Kaszuba

et al. 2019

Environ. Sci. Technol. Lett.

Self Cite

View full text Add to dashboard Cite

show abstract

“…In addition to providing insights into the changes in the basal spacing of Ca(OH) 2 , detailed insights into the changes in the pore–solid interface from the Porod slope were obtained using USAXS/SAXS data. − ,− The Porod slope provides information about the “fractal dimensions” of the scattering objects. In this work, the Porod slope was calculated for the q values in the range 0.02–0.2 Å –1 and the fractality of local structure was investigated.…”

Section: Results and Discussionmentioning

confidence: 99%

“…To address these questions, we utilized multiscale in operando X-ray scattering measurements to elucidate the changes in the reactant and product phases with the corresponding textural changes in the materials. The wide angle X-ray scattering (WAXS) measurements provide detailed insights into the evolution of the solid reactant and product phases, while the ultrasmall/small angle X-ray scattering (USAXS/SAXS) measurements show the evolution of textural changes with reaction progress − (Figure ). The cross-scale evolution in the structure and morphology of the solid products during bioenergy production integrated with carbon capture, utilization, and storage starting from cellulose and lignin reacted with Ca(OH) 2 can be effectively probed using in operando USAXS/SAXS/WAXS measurements.…”

Section: Introductionmentioning

confidence: 99%

Relating Structural and Microstructural Evolution to the Reactivity of Cellulose and Lignin during Alkaline Thermal Treatment with Ca(OH)₂ for Sustainable Energy Production Integrated with CO₂ Capture

Asgar

Mohammed

Kuzmenko

et al. 2019

ACS Sustainable Chem. Eng.

Self Cite

View full text Add to dashboard Cite

The transition toward a low carbon economy necessitates the implementation of a wide range of negative emissions technologies, including bioenergy integrated with CO2 capture and storage. Advancing large-scale or modular technologies for bioenergy with carbon capture and storage requires a fundamental understanding of chemo-morphological coupling in these material systems. In this context, integrated chemical pathways such as alkaline thermal treatment (ATT) of biomass which involves the production of bio-H2 while converting and storing CO2 as solid carbonates provides promising potential for integrating bioenergy with carbon capture and storage. In this study, we elucidate the structural and morphological changes when biomass feedstocks such as cellulose and lignin are reacted with calcium hydroxide to capture, convert, and store CO2 as calcium carbonate while producing energy carrier such as H2. These structural and morphological changes were monitored using synchrotron based in operando multiscale X-ray scattering measurements. Enhanced CO2 capture at temperatures above 375 °C was evident from the significant growth of the calcium carbonate phase at these conditions. Increase in the surface area and porosity of cellulose was noted compared to lignin due to the relatively fast decomposition of cellulose. Pore–solid interfaces in Ca(OH)2 + cellulose system became smoother in the temperature range of 500–700 °C compared to Ca(OH)2 + lignin system, where the interfaces became rougher. Enhanced roughness of the pore–solid interfaces in the presence of lignin is attributed to the simultaneous slow decomposition of lignin and formation of calcium carbonate.

show abstract

“…Various studies have shown that the properties and transport of confined fluids such as water (Bonnaud et al, 2010;Ho and Striolo, 2015;Hu et al, 2015;Chakraborty et al, 2017), gases such as CO 2 (Chialvo et al, 2012;Striolo and Cole, 2017;Simoes Santos et al, 2018), and hydrocarbons (Cole et al, 2013;Le et al, 2015a,b;Wu et al, 2015;Le T. T. B. et al, 2017;Herdes et al, 2018;Obliger et al, 2018;Simoes Santos et al, 2018) in nanoporous environments differs from bulk behaviors due to changes in the structure and affinity of confined liquids (Wang H. et al, 2016;Johnston, 2017) and gases (Yuan et al, 2015;Sun et al, 2016aSun et al, ,b, 2017Wang S. et al, 2016a,b) for the solid interfaces. With increasing interest in enhanced gas recovery coupled with subsurface CO 2 storage, a fundamental understanding of the changes in the structure of CO 2 and CH 4 and transport properties of these gases through water-bearing nanoporous environments provides a scientific basis for the observed fate and transport of these gases at the field scale (Glezakou and McGrail, 2013;Gadikota et al, 2017;Gadikota, 2018;Gadikota and Allen, 2018).…”

Section: Introductionmentioning

confidence: 99%

The Effect of Hydration on the Structure and Transport Properties of Confined Carbon Dioxide and Methane in Calcite Nanopores

Mohammed

Gadikota

2018

Front. Energy Res.

Self Cite

View full text Add to dashboard Cite

With increasing interest in using or displacing confined water for CH 4 recovery or CO 2 storage in nanoporous environments, understanding the organization and diffusion of gases is confined water environments is essential. In this study, the effect of hydration on the structure and diffusivity of confined carbon dioxide (CO 2) and methane (CH 4) in 2 nm slit-shaped calcite nanopore was studied using classical molecular dynamics simulations. The absence of confined water and the effect of different water concentrations including one layer of confined water composed of 150 water molecules, 500 water molecules, and 1,296 water molecules that correspond to the density of bulk water of 1 g/cm 3 on the structural arrangement and diffusivity of confined CO 2 and CH 4 were investigated. Water molecules were found to influence the anisotropic distribution and mobility of confined CO 2 and CH 4 significantly by altering the structures of the adsorbed gas layers onto the calcite surfaces. The preferential adsorption of water on calcite surface over CO 2 and CH 4 resulted in the displacement of the adsorbed gas molecules toward the center of the pore. This water-induced displacement impacts the diffusivity of the confined gases by enabling transport through the center of the pore where there are fewer intermolecular collisions and less steric hindrance for transporting the molecules. Therefore, the diffusivity of CO 2 and CH 4 is higher in the presence of a single water layer as opposed to in pores without water. Energetic calculations showed that van der Waals and electrostatic interactions contributed to the affinity of CO 2 for calcite surfaces, while van der Waals interactions dominate CH 4 interactions with calcite and the surrounding water molecules. The anisotropic variations in the diffusivities of confined fluids emerge from changes in the organization of confined fluids and potential differences in the free energy distributions as a function of the orientation of the calcite surface. These findings suggest that any efforts to potentially engineer the nano-scale pore environment in calcite for enhanced gas recovery or storage will require us to consider the organization and anisotropic transport behaviors of confined fluids.

show abstract

Multiscale X-Ray Scattering for Probing Chemo-Morphological Coupling in Pore-to-Field and Process Scale Energy and Environmental Applications

Cited by 4 publications

References 39 publications

Quantitative Review of Olivine Carbonation Kinetics: Reactivity Trends, Mechanistic Insights, and Research Frontiers

Quantitative Review of Olivine Carbonation Kinetics: Reactivity Trends, Mechanistic Insights, and Research Frontiers

Relating Structural and Microstructural Evolution to the Reactivity of Cellulose and Lignin during Alkaline Thermal Treatment with Ca(OH)₂ for Sustainable Energy Production Integrated with CO₂ Capture

The Effect of Hydration on the Structure and Transport Properties of Confined Carbon Dioxide and Methane in Calcite Nanopores

Contact Info

Product

Resources

About

Multiscale X-Ray Scattering for Probing Chemo-Morphological Coupling in Pore-to-Field and Process Scale Energy and Environmental Applications

Cited by 4 publications

References 39 publications

Quantitative Review of Olivine Carbonation Kinetics: Reactivity Trends, Mechanistic Insights, and Research Frontiers

Quantitative Review of Olivine Carbonation Kinetics: Reactivity Trends, Mechanistic Insights, and Research Frontiers

Relating Structural and Microstructural Evolution to the Reactivity of Cellulose and Lignin during Alkaline Thermal Treatment with Ca(OH)2 for Sustainable Energy Production Integrated with CO2 Capture

The Effect of Hydration on the Structure and Transport Properties of Confined Carbon Dioxide and Methane in Calcite Nanopores

Contact Info

Product

Resources

About

Relating Structural and Microstructural Evolution to the Reactivity of Cellulose and Lignin during Alkaline Thermal Treatment with Ca(OH)₂ for Sustainable Energy Production Integrated with CO₂ Capture