Synthetic calcium carbonate improves the effectiveness of treatments with nanolime to contrast decay in highly porous limestone

Ševčík, Radek; Viani, Alberto; Machová, Dita; Lanzafame, Gabriele; Mancini, Lucia; Appavou, Marie-Sousai

doi:10.1038/s41598-019-51836-z

Cited by 21 publications

(9 citation statements)

References 65 publications

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“…Figure 2b shows an SEM image of SrCO 3 , which demonstrates a flower‐like microstructure where the elongated needle like structures show a highly textured surface, which is consistent with previous observations on the morphology of this material, [29] whereas EDS analysis confirmed that Sr, C, and O are present (Figure 2e). In the case of CaCO 3 , coalesced cubic crystals with a smooth texture was observed (Figure 2c), which is highly indicative of calcite formation, [30] whereas EDS analysis confirmed the presence of Ca, C, and O (Figure 2f). MnCO 3 was found to crystallize in a spherical shape of different sizes, which exhibited a highly textured surface (Figure 2d), consistent with a previous report, [31] and EDS analysis confirmed the presence of Mn, C, and O.…”

Section: Resultsmentioning

confidence: 98%

Electrochemical Capture and Storage of CO₂ as Calcium Carbonate

Oloye

O’Mullane

2021

ChemSusChem

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A carbon dioxide capture, conversion, and utilization technology has been developed that can be powered by renewable energy with the potential to mitigate CO2 emissions. This relies on an electrochemical process whereby the dissolution of carbon dioxide into carbonate ions is accelerated by a locally induced pH change at the cathode. The carbonate ions can then complex with metal cations, such as Ca2+, Sr2+, or Mn2+, present in solution to form their respective metal carbonates, which precipitate out of solution. To ensure the cathode is not fouled by deposition of the insulating metal carbonate, the process is operated under hydrogen evolution conditions, thereby alleviating any significant attachment of the solid to the electrode. This process is demonstrated in CO2‐saturated solutions while the possibility of direct air capture is also shown, where the precipitation of CaCO3 from atmospherically dissolved CO2 during electrolysis is observed. The latter process can be significantly enhanced by using 5 vol.% of monoethanolamine (MEA) in the electrochemical cell. Finally, the process is investigated using seawater, which is also successful after the initial precipitation of metal sulfates from solution. In particular, the use of renewable energy to capture CO2 and create CaCO3 while also generating hydrogen may be of particular interest to the cement industry, which has a significant CO2 footprint.

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Section: Resultsmentioning

confidence: 98%

Electrochemical Capture and Storage of CO₂ as Calcium Carbonate

Oloye

O’Mullane

2021

ChemSusChem

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“…A definitive assessment of the morphology of CaCO 3 crystals was performed using SEM, infrared spectroscopy, and PXRD analysis. Figure a–c shows representative SEM images of CaCO 3 extracted from [CA–MA–PLs]; a combination of different crystal structures of various shapes including pseudocubical, rod-like, and spherical structures were seen, much in resemblance to CaCO 3 crystals reported in the literature. − Figure a shows that cubic calcite crystals of sizes 2.5 × 2.7 μm were observed, while in another area within the same sample, different sizes of aragonite rod-like crystals with an average size of 7.6 × 2.2 μm were seen (Figure b); vaterite was also observed in certain regions with an average size of 11 ± 3 μm (Figure c) (average sizes have been provided in the Supporting Information, Figure S19). XRD analysis (Figure d) showed peaks of calcite crystals at 2θ = 23, 29, 31,39, 44, 46, 48, 56, 60, and 65° corresponding to (012), (104), (110), (113), (202), (024), (211), and (214) planes, respectively (PDF#05–0586) .…”

Section: Resultsmentioning

confidence: 99%

Efficient Carbon Capture and Mineralization Using Porous Liquids Comprising Hollow Nanoparticles and Enzymes Dispersed in Fatty Acid-Based Ionic Liquids

Kulshrestha,

Kumar,

Sharma

2024

ACS Sustainable Chem. Eng.

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Deploying permanent porosity in the liquid phase provides significant opportunities for innovative industrial usage. Liquid-like novel porous materials can thus be employed in continuous flow processes related to toxic gas capture and conversion. Porous liquids (PLs) are a new class of materials that have been used for the capture, sequestration, and separation of various gases. Although, in the past few years, research in this field has garnered a lot of interest, materials that not only combine high fluidity with permanent porosity but also exhibit catalytic activity are still scarce. Here, we show a simple and facile strategy to develop another class of highly stable PLs obtained by the dispersion of surface-engineered hollow silica nanorods in sterically hindered fatty acid (laurate or myristate) and phosphonium-based ionic liquids at room temperature. The PLs show high thermal stability (up to 340 °C) with a rheological behavior suggesting high fluidity (viscosity ∼1.8 Pa•s at 25 °C). Furthermore, the PLs can adsorb gaseous carbon dioxide up to 7.4 folds higher than the pure ionic liquids at low pressure and 25 °C. In a significant advancement, we show that carbonic anhydrase enzyme can be incorporated and stabilized in the PLs to allow in situ biomineralization of carbon dioxide into bicarbonate ions and further conversion to CaCO3. Polarized light and scanning electron microscopy along with PXRD and FTIR studies confirm the coexistence of the calcite, aragonite, and vaterite polymorphs of CaCO3. These findings provide new insights into making fluid-like materials with permanent porosity for low-pressure carbon dioxide uptake and enzyme-based carbon mineralization for the ultimate utility-based materials approach.

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“…This technique, when complemented with the elemental information of micro-X-ray fluorescence (μXRF) mapping, becomes particularly well-suited for the micro-analysis of highly heterogeneous systems, especially when the new phases are present in minor fractions if compared to the substrate’s minerals or are poorly crystalline. These techniques, although well-known and already used in many fields over the years 31 – 35 , in CH materials are mainly used in the examination of oil paintings 22 – 39 and wall paintings 40 , 41 , ceramics 42 , 44 , paper 45 , and metals 46 , 47 , but, to the best of our knowledge, have not been employed to study the reaction products of inorganic consolidation solutions on porous carbonate stones in CH.…”

Section: Introductionmentioning

confidence: 99%

Advanced mapping of inorganic treatments on porous carbonate stones by combined synchrotron radiation high lateral μXRPD and μXRF

Massinelli,

Marinoni,

Colombo

et al. 2024

Sci Rep

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Understanding the effects of consolidating inorganic mineral treatments on carbonate stones of cultural heritage, and on the nature and distribution of newly formed products within the matrix, poses a significant challenge in Heritage Science and Conservation Science. Existing analytical methods often fail to deliver spatial and compositional insights into the newly formed crystalline phases with the appropriate high lateral resolution. In this study, we explore the capabilities and limitations of synchrotron radiation (SR) micro-X-ray powder diffraction (μXRPD) mapping combined with micro-X-ray fluorescence (μXRF) to give insight into compounds formed following the application of ammonium oxalate (AmOx) and diammonium phosphate-based (DAP) solutions on porous carbonate stone. Ultimately, the integration of μXRPD mapping and μXRF analysis proved itself a powerful asset in providing precise qualitative and quantitative data on the newly formed phases, in the case of both calcium oxalates (CaOxs) and calcium phosphates (CaPs), and their complex stratigraphic distribution, thus opening a new route for applications to a more comprehensive study of inorganic treatments applied to carbonate substrates.

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Synthetic calcium carbonate improves the effectiveness of treatments with nanolime to contrast decay in highly porous limestone

Cited by 21 publications

References 65 publications

Electrochemical Capture and Storage of CO₂ as Calcium Carbonate

Electrochemical Capture and Storage of CO₂ as Calcium Carbonate

Efficient Carbon Capture and Mineralization Using Porous Liquids Comprising Hollow Nanoparticles and Enzymes Dispersed in Fatty Acid-Based Ionic Liquids

Advanced mapping of inorganic treatments on porous carbonate stones by combined synchrotron radiation high lateral μXRPD and μXRF

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Synthetic calcium carbonate improves the effectiveness of treatments with nanolime to contrast decay in highly porous limestone

Cited by 21 publications

References 65 publications

Electrochemical Capture and Storage of CO2 as Calcium Carbonate

Electrochemical Capture and Storage of CO2 as Calcium Carbonate

Efficient Carbon Capture and Mineralization Using Porous Liquids Comprising Hollow Nanoparticles and Enzymes Dispersed in Fatty Acid-Based Ionic Liquids

Advanced mapping of inorganic treatments on porous carbonate stones by combined synchrotron radiation high lateral μXRPD and μXRF

Contact Info

Product

Resources

About

Electrochemical Capture and Storage of CO₂ as Calcium Carbonate

Electrochemical Capture and Storage of CO₂ as Calcium Carbonate