Force Fields for Spacecraft Coming to a Galaxy Near You

Illustration of a force field surrounding the U.S.S. EnterpriseHowStuffWorks

Astronauts face myriad dangers in space, and at least one is perfectly familiar to the earthbound: cancer. The risk is so escalated that it standsfirmly in the wayof deep-space exploration. A European Union-funded research group is working to fix that.

TheEuropean Space Radiation Superconducting Shield project, comprising scientists from seven European research organizations, is developing a force field.

Technically, it's a superconducting magnetic shield. Scientists want to surround a spacecraft with a magnetic field something like the magnetosphere that surrounds Earth, which helps protect the planet from the cosmic rays that bombard astronauts in space.

Cosmic rays, the ones that gave theFantastic Fourtheir superpowers, are highly energized, charged subatomic particles. They include solar energetic particles expelled by solar flares and galactic cosmic rays produced by events likesupernovas. Galactic cosmic rays are the most problematic in the radiation context.Speaking to Wired in 2014, Dr. Francis Cucinotta, a health physics professor with the University of Nevada, Las Vegas, said among radiation types, galactic cosmic radiation creates especially aggressive tumors.

To keep cancer risks down, NASA caps mission durations to大约五个月. A quick trip to Mars and back would takeat least 16 months.

Inset — Illustration of a force field surrounding the U.S.S. Enterprise
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Spacecraft currently have shielding, but it's the passive type, according to Dr. Amalia Ballarino, a project scientist from consortium member CERN, the European Organization for Nuclear Research.

"Spacecraft are built with specific materials that mitigate the effect of radiation," writes Ballarino in an email. However, passive shielding isn't effective against the most damaging radiation sources. Galactic cosmic rays, which originate beyond our solar system, move so fast these shieldscan't stop them.

空间辐射超导屏蔽,或者SR2S, is an active-shielding approach. It would use superconducting magnets to generate a magnetic field3,000 times strongerthan the one protecting Earth. Magnetic fieldsalter the pathsof charged particles. SR2S would create a30-foot(10-meter), cosmic-ray-deflecting force field around a spacecraft.

“The magnet system must be light and stable," says Ballarino. "Different magnets and coil configurations have been studied." Scientists developed a specific conductor for the application, titanium-clad MgB2. The resulting magnetic shieldwouldn't block everything, but it would reduce an astronaut's radiation dose to what Ballarino calls "acceptable levels," making deep-space travel ethically possible.

Closer to Home

The success of active shielding also has broader implications. NASAlimitsastronauts to a 3-percent increase in their risk of dying from cancer. Once they've absorbed enough cosmic radiation to meet that limit, they can't go back to space (on NASA's dime, at least). Ineffective shielding dramatically shrinks the pool of candidates who qualify for certain mission types.

It also promotes a gender bias in candidacy. Women have a lower radiation threshold than men due to the unique risks associated with breast, uterine and ovarian cancers. This means women meet the 3-percent mark faster than their male colleagues. Women are automatically out of the running forup to halfof all missions due to anatomy.

The SR2S project expects to demonstrate the viability of the superconducting magnetic shield by the end of 2015, says Ballarino, which is when the project ends. If successful,project literatureestimates real-world implementation within 20 years.

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