HX5 PROMISES SUPERIOR SPACE PERFORMANCE AFTER DEMONSTRATING RETENTION OF 96% MECHANICAL PERFORMANCE WITH EXPOSURE TO 5 MILLION RADS OF GAMMA RADIATION

DALLAS – HX5™, a lightweight military aviation grade thermoplastic nano composite offered by Alpine Advanced Materials, has demonstrated that it retains up to 96% of its original mechanical performance when subjected to 5 million rads of gamma radiation. Results from the mechanical and radiation testing performed by both the National Institute of Aviation Research (NIAR) and VPT Rad Radiation Lab suggest that the material presents a superior alternative to aluminum for satellite providers and private companies focused on space exploration.

NIAR used the ASTM D6272 four-point bend test to validate and assure HX5’s uniform performance and consistency.Gamma radiation resistant up to 5 million rads, HX5 meets the resistance requirements for satellites (around500,000 rads), and interstellar space travel and flight (ranging from 1 to 10 million rads). This means that traditionally aluminum parts and components used in space can now be made at half the weight.

“Reducing weight is one of the keys to making space flight both more possible and more affordable – every gram you save translates to less fuel you have to pay for and more distance you can travel.” said Roger Raley, president of Alpine Advanced Materials. “In the realm of space travel, making longer flights more achievable by reducing weight becomes a game changer.”

Developed by Lockheed Martin Skunk Works®over more than a decade of testing and validation with an R&D investment in excess of $50 million, HX5 was engineered to replace machined aerospace-grade aluminum at half the weight. In addition to its durability in highly radioactive environments, HX5 demonstrates extreme resistance to solvents, fuels, lubricants, and chemicals, giving it the ability to withstand the most demanding applications. Already certified for use in rockets and satellites, HX5 satisfies NASA spacecraft limits on outgassing and radiation resistance stability, is highly temperature capable, and has passed accelerated lifetime thermal cycling and high-temperature thermal stability.

“With its low thermal coefficient of expansion and low thermal conductivity, HX5 is an ideal material for use in space,” added Peter Shpik, director of technical service for Alpine Advanced Materials. “While one surface is exposed to hot sunlight, the opposite side is in cold darkness, yielding a structure with little to no twisting or bending, and without high dimensional changes. HX5 also has little to no outgassing in a vacuum like space, limiting the potential of material film developing on surfaces within a vehicle.”

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