**Physicist**: This isn’t a question anybody asked, just an interesting goings-on.

A few weeks ago QUESS (QUantum Experiments at Space Scale) began teleporting quantum information to and from the Micius satellite and between ground stations 1200 km apart. This is exciting, because it demonstrates the feasibility of easy (cheap), high-fidelity, long-distance quantum entanglement, which is the key to all quantum communication. Micius is the first shaky pillar of a global-scale quantum infrastructure.

Entanglement is basically a combination of correlation and superposition. The difference between a bit and a qubit is that a bit is either 1 or 0 while a qubit is simultaneously 1 and 0. There are a lot of different forms that a qubit can take (just like there are many forms a bit can take): in this case the polarization of light is used. There are two possible polarization states, which is perfect for encoding two possibilities, 0 and 1 (and incidentally perfect for making 3D movies; one movie for each polarization and each eye).

A photon can be in a superposition of both horizontal and vertical polarization. When measured they are always found to be in one state or the other (0 or 1), but there are a lot of clever things we can do with qubits before doing that measurement.

While it is impossible to be sure of the result, the probability that you see a “0” or “1” is described by the state (in the picture above, “0” is more likely, but not guaranteed). The spooky thing about entangled particles is that, as long as you measure them the same way, their random results will be correlated. For the simplest kind of entangled state, , the results are the same. If two photons are in the shared state and you find that one of them is vertically polarized, then the other will also be vertically polarized. Random, but the same as each other. Unfortunately, practically any interaction with either particle breaks the entanglement and leaves you with just a pair of regular, unrelated particles. This discussion on entanglement goes into a bit more detail.

What QUESS is doing, and what “quantum communication” is all about, is getting two entangled particles far apart without accidentally breaking the entanglement or losing the particles (which is difficult when they’re being fired at you from space).

Once two widely separated parties share a pair of entangled particles, they can start doing some rather remarkable things. One of those is the ability to send qubits from one particle to its entangled twin: “quantum teleportation”. Quantum teleportation requires both an entangled pair of particles and a “classical communication channel” (which includes, but is not limited to, shouting loudly). With those in hand, we can easily “teleport” a qubit, from one location to another.

Qubits (quantum states in general) are as delicate as delicate can be. Absolutely any interaction capable of allowing anything to determine their state “collapses” that state; a qubit goes from being *both* 0 and 1 to being *either* 0 or 1, and all of the advantages that may have gone with that superposition go out the window. So teleportation needs to be able to measure the to-be-sent qubit, A, without actually determining anything about it, which is tricky. The way to get around that is to do a measurement that compares A and B, without measuring either of them directly. If you learn that two coins have either the same or opposite side up, then you’ve learned something about the two of them *together*, but nothing specific about either of them *individually*.

The same idea applies in quantum teleportation. The central idea behind entanglement is that if B and C are entangled, then they react to measurements in the same way. So by comparing A and B and learning how they’re different, you’re also learning how A and C are different. Knowing that, you can figure out what needs to be done to C to make it have the same state as A. And all without actually learning what that state is. Even if C is, hypothetically, on the far side of China, you can just tell whoever has it what the results of the test were. For coins/regular bits you only need to send one bit of information; the result of the comparison is either “same” or “different”. For qubits you need to send two bits, because of how terrifyingly complex quantum mechanics is. Here’s a bit more detail on how quantum teleportation works.

Not a lot of physicists are too surprised that ground-to-space quantum teleportation works (nobody builds and launches spacecraft on a hunch). There’s never been any indication that distance is a factor for quantum entanglement, so this isn’t a matter of overcoming physical laws, just getting around (a lot of) engineering difficulties. Teleportation is easy to do with equipment on opposite sides of a room. The difference here is that the “opposite side of the room” is moving at about 8 km/s and is in *freaking* *space*.

Quantum states are delicate, so we need to be able to catch, manipulate, and accurately measure the states of individual photons with minimal interference. Assuming that you’re not having someone else read this out loud, you are presently noticing that photons carry information through air pretty well. *Pretty* well. Over a large enough distance, even clean air is effectively opaque. The present through-air record for this same procedure is 143 km, between a couple of Canary Islands. That’s 143 km through the densest region of our atmosphere (sea level). There’s about as much air between you and space as there is between you and anything 7 km away along the ground (it gets thin fast as you go up). So teleportation straight up should be easier than teleportation between ground stations.

Generally speaking, the big problem with conveying intact quantum information is all the stuff in the way, so space is kind of an obvious solution. The problem with space is the distances involved; the farther something is away, the smaller the target. Establishing entanglement between two locations comes down to creating a pair of entangled particles in one location and then sending one of the pair to the other location. QUESS manages to catch about 1 in every 6 million photon pairs and it doesn’t work during the day because the sunlight scatters off of the air (likely to be a non-issue between *two* quantum satellites). In all, the QUESS team claims to be able to establish 1 entangled pair per second. All things considered, that’s bragging-rights-impressive. This and this is what constitutes “bragging” (the QUESS team’s official papers on the subject).

Even with a noisy channel, with lots of photons lost and the states of many of the others perturbed by their journey, a reliable quantum channel is still possible. We can distill quantum entanglement, turning many weakly entangled pairs into fewer strongly entangled pairs. You can think of this like repeating a digital message to get it across a noisy channel; it takes more time to send the signal, but the result is a message clearer than any of the individual attempts. Once an entanglement has been established between two parties, a quantum state can be teleported between the two, including a state entangled with something else. In this way, two entangled pairs between A-B and B-C can be turned into one entangled pair between A-C. With “quantum repeaters” in place, we can establish quantum channels over huge distances by piecing together many short, possibly noisy, channels. Point is: despite quantum states being perfectly delicate, we don’t need perfect delicacy to work with them.

Quantum information technology is still in its infancy. Where we are now is analogous to the age of telegraphs and Morse code. We can send qubits, a few at a time, over long distances, but we don’t have computers at the ends capable of doing much with those qubits. Despite that massive shortcoming, there are some killer apps that are likely to drive this technology forward. In particular: quantum cryptography.

Skirting the details, quantum encryption boils down to:

1) distribute lots of pairs of entangled particles

2) measure each pair the same way

3) write down the results

No quantum computation involved! The defining characteristic of maximally entangled pairs is that measurements on the pair are perfectly correlated and fundamentally random. Anyone/thing that intercepts an entangled particle breaks (or at least weakens) the entanglement, so eavesdropping can be detected. For you cypherpunks out there, quantum cryptography is a method of creating a shared random secret that is perfectly robust to man-in-the-middle attacks (or at least detects such attempts). You and someone else create a random number that only the two of you can possibly know, which allows you to then encrypt any message and send it (by email for example) with security guaranteed by physical laws.

Shockingly, this is of interest to lots of space-capable governments, so Micius is unlikely to be the last quantum communication satellite.

Just as a quick aside, since it’s often not stated clearly: quantum teleportation does not involve actual teleportation in any sense. Nothing actually makes the journey from one quantum system to the other. There are a pair of theorems in the field of quantum information theory that say that if you and someone else share an entangled pair of particles (sometimes called an “ebit”), then at the cost of that entanglement and the application of some cute tricks you can:

1) send 2 bits to convey one qubit

2) send 1 qubit to convey two bits

The first procedure is called “teleportation” and the second is called “super-dense coding”. One of those is a terrible, misleading name and the other is “super-dense coding”.

The laser picture is from here, the telegraph picture is from here, and the spy picture is by Tomer Hanuka.