Fabrication of ZnO periodic structures by 3D printing

Tubío, Carmen R.; Guitián, Francisco; Gil, Álvaro

doi:10.1016/j.jeurceramsoc.2016.05.025

Cited by 59 publications

(27 citation statements)

References 25 publications

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“…Researchers 3D-printed many structures from materials which, once sintered, developed properties potentially significant to catalyst applications, like cellular structures built by bioplotting with metallic or oxide forms of Fe and Ni [ 102 ] or periodic structures based on ZnO and built by Robocasting [ 103 ].…”

Section: 3d Printing Applications In Heterogeneous Catalysismentioning

confidence: 99%

3D Printing in Heterogeneous Catalysis—The State of the Art

Богдан

Michorczyk

2020

Materials

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This paper describes the process of additive manufacturing and a selection of three-dimensional (3D) printing methods which have applications in chemical synthesis, specifically for the production of monolithic catalysts. A review was conducted on reference literature for 3D printing applications in the field of catalysis. It was proven that 3D printing is a promising production method for catalysts.

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Section: 3d Printing Applications In Heterogeneous Catalysismentioning

confidence: 99%

3D Printing in Heterogeneous Catalysis—The State of the Art

Богдан

Michorczyk

2020

Materials

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“…This can be enabled by certain AM technologies, particularly DIW. For instance, Tubio et al prepared ZnO (48 vol%) inks to fabricate 3D periodic structures consisting of alternating tetragonal symmetries with well‐defined interconnected layers with rod diameters of 200 µm, as depicted in Figure a–d . DIW was also used to construct spiral, woodpile, lattice (Figure h), cylindrical and half‐conical TiO 2 structures with micrometer scale dimensions .…”

Section: Am For Energy the Applicationsmentioning

confidence: 99%

Additive Manufacturing: Unlocking the Evolution of Energy Materials

et al. 2017

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The global energy infrastructure is undergoing a drastic transformation towards renewable energy, posing huge challenges on the energy materials research, development and manufacturing. Additive manufacturing has shown its promise to change the way how future energy system can be designed and delivered. It offers capability in manufacturing complex 3D structures, with near‐complete design freedom and high sustainability due to minimal use of materials and toxic chemicals. Recent literatures have reported that additive manufacturing could unlock the evolution of energy materials and chemistries with unprecedented performance in the way that could never be achieved by conventional manufacturing techniques. This comprehensive review will fill the gap in communicating on recent breakthroughs in additive manufacturing for energy material and device applications. It will underpin the discoveries on what 3D functional energy structures can be created without design constraints, which bespoke energy materials could be additively manufactured with customised solutions, and how the additively manufactured devices could be integrated into energy systems. This review will also highlight emerging and important applications in energy additive manufacturing, including fuel cells, batteries, hydrogen, solar cell as well as carbon capture and storage.

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“…The ability to fabricate a variety of structures requires good control over the formulation and rheologic behavior of the inks and printing parameters (velocity printing, pressure extrusion). 17 The fundamental requirement for any lattice structure is that it is self-supporting (to bear on itself) without the need for inside supports. Another key aspect for the use of porous structures is pore interconnectivity.…”

Section: Fabrication Of Personalized 3d Structuresmentioning

confidence: 99%

3D Bioprinting of Hybrid Materials for Regenerative Medicine: Implementation in Innovative Small and Medium-Sized Enterprises (SMEs)

Piticescu

Cursaru

Ciobota

et al. 2018

JOM

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Three-dimensional printing has significant potential as a fabrication method for synthetic scaffolds for regenerative medicine. The advantages of fabricating scaffolds using 3D printing are numerous, including the ability to create complex geometries and porosities that mimic the anatomical structures of organs and tissues. Three-dimensional printing can be used to create orbital implants, which replace the bony cavity surrounding the eye after eye removal. In the present article, an original 3D printing method is developed for the production of three-dimensional structures based on hydroxyapatite and polyurethane diol, which can be further used for the fabrication of orbital implants with interconnected porosity. For this purpose, hybrid nanostructured powders were prepared by hydrothermal synthesis and further used as raw materials for 3D printing of porous structures. Innovative porous 3D structures were tested in vitro and in vivo. The test results showed the vascularization capacity of the 3D implant and remodeling of the tissue.

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Fabrication of ZnO periodic structures by 3D printing

Cited by 59 publications

References 25 publications

3D Printing in Heterogeneous Catalysis—The State of the Art

3D Printing in Heterogeneous Catalysis—The State of the Art

Additive Manufacturing: Unlocking the Evolution of Energy Materials

3D Bioprinting of Hybrid Materials for Regenerative Medicine: Implementation in Innovative Small and Medium-Sized Enterprises (SMEs)

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