America may be a melting pot, but the result is generally more stew than fondue; for many of us, where we came from—whether by boat or ice bridge—constitutes a significant part of our identity. Beyond whatever social implications it may have, our heritage slumbers within us in ways we don’t fully understand, yet are fascinated by.
It’s no wonder commercial genetic ancestry tests are so appealing. Still, a little caveat emptor is in order: According to an article in the journal Science, consumers who plop down their Benjamins for genetic answers may not be getting what they bargained for.
For some time now, conventional computer memory has been heading toward a crunch—a physical limit of how much storage can be crammed into a space before it is overwhelmed by heat and power problems. Generally, researchers have tried to avert this heat death in two ways: leapfrogging to the next generation of memory or refining current memory.
Researchers at Arizona State University’s Center for Applied Nanoionics (CANi) have combined the two approaches to create new memory that amps up performance while remaining compatible with today’s devices. CANi also used nanoionics (a technique for moving tiny bits of matter around on a chip) to overcome the limitations of conventional electronics: Instead of moving electrons among ions, nanoionics moves the ions themselves.