High CO2 permeability in supported molten-salt membranes with highly dense and aligned pores produced by directional solidification

Composite molten salt-ceramic membranes are promising devices for high-temperature CO2 separation. Intensive material properties impact on separation performance as do membrane geometry (thickness) and microstructure (pore volume fraction, size, connectivity, and tortuosity factor). Although controlling pore size is considered somewhat routine, achieving pore alignment and connectivity is still challenging. Here we report the production of the first gas separation membrane using a porous ceramic matrix obtained from a directionally-solidified magnesium-stabilised zirconia (MgSZ) - MgO fibrilar eutectic as the membrane support. MgO was removed from the parent material by acid-etching to create a porous matrix with highly aligned pores with diameters of similar to 1 mu m. X-ray nano-computed tomography of a central portion (similar to 32, 000 mu m(3)) of the support identified similar to 21% porosity, with all pores aligned within 10 degrees and similar to 76% percolating along the longest sampled length. Employing the matrix as a support for a carbonate molten salt, a high CO2 permeability of 1.41x10(-10) mol m(-1).s(-1).Pa-1 at 815 degrees C was achieved, among the highest reported for supported molten-carbonate membranes (typically 10(-12) to 10(-10) mol m(-1).s(-1).Pa-1 at similar temperatures). We suggest that the high permeability is attributable to the excellent pore characteristics resulting from directional solidification, namely a dense array of parallel, micron-scale pores connecting the feed and permeate sides of the membrane

Dielectric Barrier Plasma Discharge Exsolution of Nanoparticles at Room Temperature and Atmospheric Pressure

Exsolution of metal nanoparticles (NPs) on perovskite oxides has beendemonstrated as a reliable strategy for producing catalyst-support systems.Conventional exsolution requires high temperatures for long periods of time,limiting the selection of support materials. Plasma direct exsolution isreported at room temperature and atmospheric pressure of Ni NPs from amodel A-site deficient perovskite oxide (La 0.43 Ca 0.37 Ni 0.06 Ti 0.94 O2.955 ). Plasmaexsolution is carried out within minutes (up to 15 min) using a dielectricbarrier discharge configuration both with He-only gas as well as with He/H2gas mixtures, yielding small NPs (<30 nm diameter). To prove the practicalutility of exsolved NPs, various experiments aimed at assessing their catalyticperformance for methanation from synthesis gas, CO, and CH4 oxidation arecarried out. Low-temperature and atmospheric pressure plasma exsolution aresuccessfully demonstrated and suggest that this approach could contribute tothe practical deployment of exsolution-based stable catalyst systems

Roadmap on exsolution for energy applications

Over the last decade, exsolution has emerged as a powerful new method for decorating oxide supports with uniformly dispersed nanoparticles for energy and catalytic applications. Due to their exceptional anchorage, resilience to various degradation mechanisms, as well as numerous ways in which they can be produced, transformed and applied, exsolved nanoparticles have set new standards for nanoparticles in terms of activity, durability and functionality. In conjunction with multifunctional supports such as perovskite oxides, exsolution becomes a powerful platform for the design of advanced energy materials. In the following sections, we review the current status of the exsolution approach, seeking to facilitate transfer of ideas between different fields of application. We also explore future directions of research, particularly noting the multi-scale development required to take the concept forward, from fundamentals through operando studies to pilot scale demonstrations

Dose-Dependent Onset of Regenerative Program in Neutron Irradiated Mouse Skin

Background: Tissue response to irradiation is not easily recapitulated by cell culture studies. The objective of this investigation was to characterize, the transcriptional response and the onset of regenerative processes in mouse skin irradiated with different doses of fast neutrons. Methodology/Principal Findings: To monitor general response to irradiation and individual animal to animal variation, we performed gene and protein expression analysis with both pooled and individual mouse samples. A high-throughput gene expression analysis, by DNA oligonucleotide microarray was done with three months old C57Bl/6 mice irradiated with 0.2 and 1 Gy of mono-energetic 14 MeV neutron compared to sham irradiated controls. The results on 440 irradiation modulated genes, partially validated by quantitative real time RT-PCR, showed a dose-dependent up-regulation of a subclass of keratin and keratin associated proteins, and members of the S100 family of Ca2+-binding proteins. Immunohistochemistry confirmed mRNA expression data enabled mapping of protein expression. Interestingly, proteins up-regulated in thickening epidermis: keratin 6 and S100A8 showed the most significant up-regulation and the least mouse-to-mouse variation following 0.2 Gy irradiation, in a concerted effort toward skin tissue regeneration. Conversely, mice irradiated at 1 Gy showed most evidence of apoptosis (Caspase-3 and TUNEL staining) and most 8-oxo-G accumulation at 24 h post-irradiation. Moreover, no cell proliferation accompanied 1 Gy exposure as shown by Ki67 immunohistochemistry. Conclusions/Significance: The dose-dependent differential gene expression at the tissue level following in vivo exposure to neutron radiation is reminiscent of the onset of re-epithelialization and wound healing and depends on the proportion of cells carrying multiple chromosomal lesions in the entire tissue. Thus, this study presents in vivo evidence of a skin regenerative program exerted independently from DNA repair-associated pathways

Development of mixed ionic and electronic conducting materials for gas separation membranes: A critical overview

\ua9 2024 Elsevier B.V. Coupling simultaneous mixed ionic (i.e. O2−) and electronic conductivity in a single inorganic membrane has been demonstrated as a very promising approach for gas separation applications. This paper discusses the state-of-the-art materials used on mixed ionic and electronic conducting (MIEC) oxides including cubic fluorite, perovskite, spinel, and multi-phase composites and the underlying interface chemistry for capturing and separating CO2, O2 and H2. The applications for MIEC materials for such separations have been reviewed with an emphasis on the corresponding permeation mechanism. Designing novel MIEC materials with an enhanced permeation performance is critical for reducing the operational costs in large-scale applications of membrane modules, while reduction of the associated energy penalties via renewable energy solutions is of great importance in the future for achieving the net zero targets for greenhouse-gas emissions