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Fabrication And Capillary Flow In Microporous Wick For Non-Thermal Solar Desilanation
Brief description not available
Sinter-Free Low-Temperature 3D-Printing Of Nanoscale Optical Grade Fused Silica Glass
Researchers at UC Irvine have developed a new method to 3D-print free-form silica glass materials which produces products with unparalleled purity, optical clarity, and mechanical strength under far milder conditions than currently available techniques. The novel processing method has potential to radically transform microsystem technology by enabling development of silica-based microsystems.
Bicontinuous Composite Nano-Mm Sized Particles, 1D, 2D And 3D Structures For Impact Resistance And Energy Dissipation
Multimodal Coatings For Heat And Fire Resistance
Ultrafast Welding of Ceramics
Strategy To Deliver Objects Suspended In Liquid To Hidden Targets
Vapor-Mediated Synthesis of Silicon Carbide Matrices for Ceramic Matrix Composites
Thermally Insulating Transparent Barrier (THINNER) coatings with high transmission, thermal and radiative resistance
Double-Negative-Index Ceramic Aerogels For Thermal Superinsulation
UCLA researchers in the Departments of Chemistry and Biochemistry and Materials Science and Engineering have developed a novel ceramic aerogel material that has robust mechanical and thermal stability under extreme conditions.
Ceramic And Metallic Cellular Structures Wtih Interconnected Microchannels
UCLA researchers in the Department of Mechanical Engineering have developed cellular porous metallic and ceramic structures that can be used to increase the production and recovery of tritium for fusion power reactors or as a support for electrode materials.
Super Ceramics With Self-Dispersed Nanoparticles Via Casting
UCLA researchers in the Departments of Mechanical and Aerospace Engineering and Materials Science and Engineering have developed a novel casting method to fabricate high performance bulk ceramic materials containing dispersed nanoparticles.
Powder bed additive manufacturing method of fabricating a porous matrix
An addictive manufacturing method used to create lightweight materials with tunable physical properties.
Innovative Ceramic Etching Technique
Liquid-Repellent Surfaces Made of Any Materials
UCLA researchers in the Department of Mechanical and Aerospace Engineering have developed a structured surface that can be made of any material (but demonstrated with glass) that repels all liquids (even fluorinated solvents) without using any repellant coating.
Mechanochemical Synthesis of Mg2Si and Related Compounds and Alloys
Professor Kaner and colleagues have developed methods to synthesize substantially phase pure compounds of magnesium silicide and related alloys. The phase purity achieved by this method is unprecedented, and the yielded products are suitable to be used as thermoelectric materials in the mid- to high-temperature range (400 K to 800 K).
Magnetically Controlled Casting Process
Impact Resistant Composites and Tough Materials
Manufacturers have been looking for a next-generation of composite materials that can absorb the shock and impact of intense collisions and accidents. Some plastic composites and metal alloys have offered the advantage of being light weight, but they are still limited in their ability to have comparable shock resistance to their heavier metal counterparts. Further, their high costs have made them cost prohibitive for their limited benefits.
CeramicAsh: Material and Method
Researchers at UCLA have developed a method for reducing the manufacturing costs associated with chemically bonded ceramics.
Efficient And Accurate Undercut Detection System
Molding and casting of parts can be done more simply and economically for parts that are free from undercut features, primarily because a more expensive multi-piece mold must be used for parts with such undercut features. Therefore immediate feedback to the designer about the presence of costly undercuts allows for their early removal in the design process. Without immediate and accurate feedback designers can wind up with high part costs, waste, and a complicated manufacturing process. UC Berkeley researchers have developed a design system, based on a sophisticated new algorithm that allows for very efficient and rapid identification of undercuts in 3D geometric models. The Berkeley system uses graphics acceleration to allow a user to rotate an object, examine the undercuts in real time and accurately identify undercuts on a pixel by pixel basis. The system also highlights the portions of faces, including curved faces, which have undercuts. Early detection and removal of undercuts ensures rapid development of the lowest cost design. The system can also be used as a subroutine in finding whether any under-cut free parting directions exist and for evaluating which is optimal if there are multiple choices. The ability to find the optimal direction along with pixel level accuracy makes the system highly desirable for designers.