Directional freeze-cast hybrid-backbone meso-macroporous bodies as micromonolith catalysts for gas-to-liquid processes

Kim, Jonglack; Nese, Valentina; Joos, Jochen; Jeske, Kai; Duyckaerts, Nicolas; Pfänder, Norbert; Prieto, Gonzalo

doi:10.1039/c8ta07512c

Cited by 14 publications

(9 citation statements)

References 41 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Devising processing routes to controllably generate pores at different length scales using, for example, novel manufacturing methods or in situ pore‐forming mechanisms is thus a timely and important research topic. [ 25–28 ]…”

Section: Introductionmentioning

confidence: 99%

Ultrastrong Hierarchical Porous Materials via Colloidal Assembly and Oxidation of Metal Particles

Huo

Zhang

Tervoort

et al. 2020

Adv Funct Materials

View full text Add to dashboard Cite

Porous materials are useful as lightweight structures, bone substitutes, and thermal insulators, but exhibit poor mechanical properties compared to their dense counterparts. Biological materials such as bone and bamboo are able to circumvent this trade‐off between porosity and mechanical performance by combining pores at multiple length scales. Inspired by these biological architectures, a manufacturing platform that allows for the fabrication of Al2O3 foams and Al2O3/Al composites with hierarchical porosity and enhanced mechanical properties is developed. Macroscale pores are formed through the assembly of aluminum particles around templating air bubbles in wet foams, whereas the thermal oxidation of the metal particles above 800 °C generates porosity at the micrometer scale. After elucidating the mechanism of pore formation under different sintering conditions at the microscale, the mechanical performance of the resulting hierarchical foams using compression experiments and finite element simulations is evaluated. Porous materials manufactured via this simple approach are found to reach unparalleled mechanical properties with near‐zero sintering shrinkage and minimum loss in mechanical strength. The ability to produce macroscopic objects with ultrahigh strength at porosities up to 95% makes this an attractive manufacturing technology for the fabrication of high‐performance lightweight structures or advanced thermal and acoustic insulators.

show abstract

Section: Introductionmentioning

confidence: 99%

Ultrastrong Hierarchical Porous Materials via Colloidal Assembly and Oxidation of Metal Particles

Huo

Zhang

Tervoort

et al. 2020

Adv Funct Materials

View full text Add to dashboard Cite

show abstract

“…In addition to the particles and solvents, various organic and inorganic additives, such as, glycerol, [ 161 ] gelatin, [ 162,163 ] PVA, [ 163 ] polyethyleneglycol, [ 164 ] sodium chloride, [ 101 ] sucrose, [ 165 ] silica clay, [ 166 ] dioxane, [ 167 ] zirconium acetate, H 4 SiW 12 O 40 (SiW 12 ) [ 168 ] trehalose, [ 101 ] ethanol, [ 169 ] poly(acrylic acid) (PAA), [ 170 ] polyethylene glycol, poly vinyl pyrrolidone, poly(methyl methacrylate), [ 125 ] dextran, [ 171 ] isopropanol, [ 172 ] and polystyrene, [ 173 ] can be incorporated to change the porous structure and morphology of scaffolds. The underlining mechanism becomes more complicated than in pure water without additives.…”

Section: Control In the Internal Porous Structure Via Ice Frozen Asse...mentioning

confidence: 99%

A New Era of Integrative Ice Frozen Assembly into Multiscale Architecturing of Energy Materials

Yeon

Gupta

Bhattacharya

et al. 2022

Adv Funct Materials

View full text Add to dashboard Cite

The ice templating assembly has been investigated to construct macroporous channels of functional nanomaterials with well‐defined homogeneous morphology. Recently, this templating method has been revisited integrating with other materials’ synthesis and processing methodologies (such as, spinning, spraying, filtration, hydrothermal, oxygenation, gelation, and 3D printing) for electrochemical energy conversion and storage applications. Herein, the recent progress on “integrative ice frozen assembly” focusing on the hierarchical structures and chemistries of functional nanomaterials such as, organic, inorganic, carbon, and composite materials for a rational design of energy application‐oriented materials is comprehensively reviewed. This integrative process allows functional nanomaterials to be assembled into various dimensions, such as, 0D, 1D, 2D, and 3D macrostructures, as well as, into larger bulk objects such as, fibers, films, monoliths, and powders. The fundamental understanding of the integrative ice frozen assembly is thermodynamically and kinetically discussed with the help of primitive freeze casting domain knowledge and the energy conversion and storage performances of the as‐designed electrodes with their hierarchical structures and chemistries are further correlated. The applications of the as‐assembled electrodes into batteries, supercapacitors, fuel cells, and electrocatalysis are also addressed. Finally, the perspective on the current impediments and future directions in this field is discussed.

show abstract

“…[7] Removal of hard templates often requires harsh procedures, such as dissolution, chemical etching, or combustion methods, resulting in costly, tedious, and suboptimal approaches for mass production. [3,8] Hüsing and coworkers [3] have already reviewed all the techniques developed for the fabrication of hierarchically organized porous materials. In this Review, we limit to those anisotropic (e.g., biomimetic) architectured porous materials that are exclusively processed through the so-called directional freeze-casting or ice templating approach.…”

Section: Introductionmentioning

confidence: 99%

“…In hard templating, the scarifying secondary phase, or porogen‐like colloidal crystals are loaded into the main sol of the colloidal particles or molecular precursors before gelation/solidification, and then removed after the gelation process to create microstructures with organized multimodal porosity in the final structure . Removal of hard templates often requires harsh procedures, such as dissolution, chemical etching, or combustion methods, resulting in costly, tedious, and suboptimal approaches for mass production . Hüsing and coworkers have already reviewed all the techniques developed for the fabrication of hierarchically organized porous materials.…”

Section: Introductionmentioning

confidence: 99%

Directional Freeze‐Casting: A Bioinspired Method to Assemble Multifunctional Aligned Porous Structures for Advanced Applications

2020

View full text Add to dashboard Cite

Mohammad-Ali Shahbazi received his Ph.D. in 2015 from University of Helsinki, Finland, where he worked on porous materials for drug delivery to cancer tissues. He is currently a postdoc scientist at Faculty of Pharmacy, University of Helsinki, working on therapeutic microdevices for autoimmune diseases. He is an expert in oral peptide delivery and fabrication of cell-mimicking carriers. His current research interest includes nano-based regenerative hydrogels for wound healing, bone repair, and long-term drug delivery.

show abstract

Directional freeze-cast hybrid-backbone meso-macroporous bodies as micromonolith catalysts for gas-to-liquid processes

Cited by 14 publications

References 41 publications

Ultrastrong Hierarchical Porous Materials via Colloidal Assembly and Oxidation of Metal Particles

Ultrastrong Hierarchical Porous Materials via Colloidal Assembly and Oxidation of Metal Particles

A New Era of Integrative Ice Frozen Assembly into Multiscale Architecturing of Energy Materials

Directional Freeze‐Casting: A Bioinspired Method to Assemble Multifunctional Aligned Porous Structures for Advanced Applications

Contact Info

Product

Resources

About