Imagine seeing the light from a torch reflected inside of a diamond. Now, imagine you’ve moved the diamond to another room, leaving the torch behind, yet it continues to reflect the light – that’s basically what the researchers did, just on a much smaller scale. How did they do this? The usual: they played something nice on the radio for the diamond, wooed it with some microwave cooking, and created a magnetic atmosphere for magic to happen. Or, as EurekAlert put it: Either way, the “vacancy” that researchers, Kazuya Tsurumoto, Ryota Kuroiwa, Hiroki Kano, Yuhei Sekiguchi and Hideo Kosaka were dealing with was the aforementioned flaw in the diamond. Irregularities inside of diamonds are caused by what scientists call a nitrogen-vacancy center – where there should be carbon, there is not. Thanks to the diamond’s flaws, the researchers had room to squeeze a photon in. Credit: Yokohama National University Photons are basic units of light that can be used to exploit a funky phenomenon called quantum entanglement in order to facilitate a type of communication called quantum teleportation. Much like the science fiction version of teleportation, where physical matter is transported through space without traversing it, quantum teleportation involves sending information to one atom in an entangled pair, where it automatically ends up reflected in the other. It’s an amazing accomplishment. Especially in the Yokohama University study, where sending a photon into an inaccessible space using quantum teleportation represents the bedrock for what could eventually become a completely secure, distributed quantum computing network.
