Almost every product we use has a shelf life. From milk and meat to laundry detergent and batteries, it's important to know when it's safe to use a product, and when it's time to replace it. But what about materials used for spacecraft?

It is vital for scientists to know exactly how long a material will last in outer space; which is why Kim de Groh, a senior materials research engineer at NASA's Glenn Research Center in Cleveland, is gathering data from the Materials International Space Station Experiment (MISSE) missions.

In April, de Groh will send 138 different material samples to the International Space Station as part of MISSE-9, which will be launched on SpaceX CRS-14 aboard a Dragon spacecraft. These samples will be part of the first MISSE mission to use the space station's new external materials testing platform, the MISSE-Flight Facility (MISSE-FF).

De Groh wants to know how long these materials will last in outer space and will learn this by analyzing the affects atomic oxygen and radiation have on exposed polymers, composites and coatings. The flight data is needed to predict spacecraft performance and durability.

On Earth, the oxygen we breathe is made of two atoms of oxygen (O2), but in space the sun's rays break down (O2) into single oxygen atoms, creating atomic oxygen.

When spacecraft, such as the space station and resupply vehicles, travel in low-Earth orbit, atomic oxygen can react with its surfaces, causing materials, such as polymers, to erode. In addition, radiation can cause spacecraft materials to become brittle and crack.

De Groh has been involved with the MISSE missions since they began in 2001, and through this research, de Groh and her colleague Bruce Banks, have developed a model to predict the erosion of materials in space.

MISSE-9 will expose materials in each flight orientation on the space station. This includes forward facing known as "ram," rear-facing known as "wake," space-facing known as "zenith," and Earth-facing, known as "nadir." Flying samples in each orientation will show how the varying atomic oxygen and solar exposures in each position affect material.

"We will fly some of the same materials in different orientations as the same material can react differently in each flight direction," said de Groh.

The researchers expect the highest exposure to atomic oxygen for the ram samples and the least exposure to atomic oxygen for the wake samples. The highest solar exposure is likely for the zenith samples and the lowest solar exposure for the nadir samples. Monthly photos will be taken of the samples while in space showing color changes or sample cracking.

After a year in space, the MISSE-9 samples will be returned to Earth for post-flight analyses.

The data obtained from this mission will enable de Groh to make more accurate predictions of materials and component lifetimes in space, allowing engineers to build longer-lasting vehicles for spaceflight.

Related Links
Space Station Research and Technology
Space Technology News - Applications and Research

Tweet

Thanks for being here; We need your help. The Space Media Network continues to grow but revenues have never been harder to maintain. With the rise of Ad Blockers, and Facebook - our traditional revenue sources via quality network advertising continues to decline. And unlike so many other news sites, we don't have a paywall - with those annoying usernames and passwords. Our news coverage takes time and effort to publish 365 days a year. If you find our news sites informative and useful then please consider becoming a regular supporter or for now make a one off contribution.
SpaceMediaNetwork Contributor $5 Billed Once credit card or paypal		SpaceMediaNetwork Monthly Supporter $5 Billed Monthly paypal only

A new way to combine soft materials
Boston MA (SPX) Mar 20, 2018
Every complex human tool, from the first spear to latest smartphone, has contained multiple materials wedged, tied, screwed, glued or soldered together. But the next generation of tools, from autonomous squishy robots to flexible wearables, will be soft. Combining multiple soft materials into a complex machine requires an entirely new toolbox - after all, there's no such thing as a soft screw. Current methods to combine soft materials are limited, relying on glues or surface treatments that can re ... read more