Materials & Coatings

Building Better Bonds

Until recently, there was little up-to-date research about adhesives that could be used with Eastman Tritan™ copolyester. By collaborating with Henkel Corporation, whose LOCTITE® adhesive continues to be tested at the industry’s most comprehensive ISO 10993 biocompatibility standards, Eastman was able to determine which combination of resins and adhesives could help optimize a manufacturer’s assembly process. Results proved that Tritan, together with LOCTITE® adhesives, provides improved process efficiency for a wide range of medical devices.

Posted in: White Papers, White Papers, Manufacturing & Prototyping, Coatings & Adhesives, Medical

Engineering Plastics Development for New Market Demands

In Conjunction with SAE

This 30-minute Webinar on engineering plastics examines new measurable sustainable solutions, including polyamide-based products, that are meeting customer and market demands. The program focuses on automotive design and the implementation of value-added solutions for weight and cost savings relative to metal replacement, high temperature and chemically resistant nylon applications.

Posted in: On-Demand Webinars, Materials, Plastics

A New Material for Mars Habitats? Mars Itself

Researchers from the University of California, San Diego demonstrated a compaction technique that may someday be used to turn Mars soil into building blocks for the Red Planet. The scientists' new method of applying pressure offers construction possibilities as NASA plans manned Mars missions in the upcoming decades.

Posted in: News, Rapid Prototyping & Tooling, Materials

Enhanced Tailpipe, Material Emission, and Leak Analysis with SIFT-MS

In Conjunction with SAE

Regulators and consumers demand increasingly lower levels of gaseous emissions from diverse automotive and aerospace sources, such as combustion exhaust, component emissions, and leakage. Emission compositions vary widely between sources but frequently consist of both volatile organic compounds (VOCs) and inorganic gases.

Posted in: On-Demand Webinars, Automotive, Materials

The Lubricant Test Drive: How Lube Selection Can Improve Auto Performance in Extreme Underhood and Interior Applications

Faced with harsher environments and a wide range of automotive lubrication options, finding a lasting lubricant solution has become increasingly difficult. But solutions do exist.

Posted in: White Papers, Automotive, Materials

Driving Auto Performance Through Lubricant Selection: How Lubricants Can Reduce Component Failures and Extend Vehicle Life

Lubricant selection may be the answer. As automotive environemnts become increasingly extreme, finding a lubricant that can withstand the rising temperatures and harsh conditions over an extended period is critical to optimal vehicle performance.

Posted in: White Papers, Automotive, Materials

Highly Porous and Mechanically Strong Ceramic Oxide Aerogels

These materials provide improved environmental durability and elasticity for aerospace and terrestrial applications.

NASA's Glenn Research Center (GRC) has developed and produced ultra-lightweight polymer cross-linked aerogels (X-Aerogels). These mechanically robust, highly porous, low-density materials are three times denser than native aerogels, but more than 100 times stronger. Aerogels are ultra-lightweight glass foams with extremely small pores (on the order of 10 to 50 nanometers). These materials are extremely good thermal insulators, with R values ranging from 2 to 10 times higher than polymer foams. Unlike multilayer insulation, aerogels do not require a high vacuum to maintain their low thermal conductivity, and can function as good thermal insulators at ambient pressure. In addition, they are good electrical insulators and have low refractive indices, both approaching values close to air. Aerogels are also excellent vibration-damping materials. Traditional aerogels, however, suffer fragility and poor environmental durability.

Posted in: Briefs, Materials, Ceramics, Conductivity, Foams, Lightweight materials, Materials properties, Polymers

Asymmetric Dielectric Elastomer Composite Material

This material has applications in artificial muscle and hearts, physical therapy/rehab devices, morphing aircraft, robotics, and sensors.

This electronic active material converts a voltage input to a mechanical force and mechanical displacement output. As compared to prior dielectric elastomer (DE) systems, the material has reduced electrode spacing, which lowers significantly the required operating voltage. In addition, the inclusion of a combination of conducting and/or non-conducting reinforcing fibers greatly enhances the strength of the material, without weight penalty.

Posted in: Briefs, Materials, Voltage regulators, Voltage regulators, Composite materials, Elastomers, Fibers

Method of Creating Micro-Scale Silver Telluride Grains Covered with Bismuth Nanoparticles

Potential applications include power generation and waste heat recovery, and refrigeration and cooling.

NASA Langley Research Center has developed a novel thermoelectric (TE) material utilizing micro-scale silver telluride grains covered with bismuth nanoparticles. These materials have unique advantages in directly converting any level of thermal energy into electrical power and solid-state cooling by a reverse mode. Although thermoelectric devices are regarded advantageously with their high reliability, their lack of moving parts, and their ability to scale to any sizes, the devices’ energy conversion efficiency remains generally poor.

Posted in: Briefs, Materials, Electric power, Thermodynamics, Thermodynamics, Materials properties, Nanomaterials

Polyimides Derived from Novel Asymmetric Benzophenone Dianhydrides

NASA's Glenn Research Center invites companies to license or establish partnerships to develop its patented high-temperature, low-melt imide resins for fabrication of automotive components. Produced by a solvent-free melt process, these resins exhibit high glass transition temperatures (Tg = 370 to 400 °C), low melt viscosities (10 to 30 poise), long pot-life (1 to 2 hours), and can be easily processed by low-cost RTM and vacuum-assisted resin transfer molding (VARTM). These RTM resins melt at 260 to 280 °C, and can be cured at 340 to 370 °C in 2 hours without releasing any harmful volatile compounds.

Posted in: Briefs, Materials, Heat resistant materials, Materials properties, Resins

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