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The Present

Quantum computing is on the way

Ready your Schrödinger’s Cat Jokes.
Quantum entanglement. Conceptual artwork of a pair of entangled quantum particles or events (left and right) interacting at a distance. Quantum entanglement is one of the consequences of quantum theory. Two particles will appear to be linked across space and time, with changes to one of the particles (such as an observation or measurement) affecting the other one. This instantaneous effect appears to be independent of both space and time, meaning that, in the quantum realm, effect may precede cause.
Key Takeaways
  • For a time, quantum computing was more theory than fact.
  • That’s starting to change.
  • New quantum computer designs look like they might be scalable.
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Quantum computing has existed in theory since the 1980’s. It’s slowly making its way into fact, the latest of which can be seen in a paper published in Nature called, “Deterministic teleportation of a quantum gate between two logical qubits.”

To ensure that we’re all familiar with a few basic terms: in electronics, a ‘logic gate’ is something that takes in one or more than one binary inputs and produces a single binary output. To put it in reductive terms: if you produce information that goes into a chip in your computer as a ‘0,’ the logic gate is what sends it out the other side as a ‘1.’

A quantum gate means that the ‘1’ in question here can — roughly speaking — go back through the gate and become a ‘0’ once again. But that’s not quite the whole of it.

A qubit is a single unit of quantum information. To continue with our simple analogy: you don’t have to think about computers producing a string of information that is either a zero or a one. A quantum computer can do both, simultaneously. But that can only happen if you build a functional quantum gate.

That’s why the results of the study from the folks at The Yale Quantum Institute saying that they were able to create a quantum gate with a “process fidelity” of 79% is so striking. It could very well spell the beginning of the pathway towards realistic quantum computing.

The team went about doing this through using a superconducting microwave cavity to create a data qubit — that is, they used a device that operates a bit like a organ pipe or a music box but for microwave frequencies. They paired that data qubit with a transmon — that is, a superconducting qubit that isn’t as sensitive to quantum noise as it otherwise could be, which is a good thing, because noise can destroy information stored in a quantum state. The two are then connected through a process called a ‘quantum bus.’

That process translates into a quantum property being able to be sent from one location to the other without any interaction between the two through something called a teleported CNOT gate, which is the ‘official’ name for a quantum gate. Single qubits made the leap from one side of the gate to the other with a high degree of accuracy.

Above: encoded qubits and ‘CNOT Truth table,’ i.e., the read-out.

The team then entangled these bits of information as a way of further proving that they were literally transporting the qubit from one place to somewhere else. They then analyzed the space between the quantum points to determine that something that doesn’t follow the classical definition of physics occurred.

They conclude by noting that “… the teleported gate … uses relatively modest elements, all of which are part of the standard toolbox for quantum computation in general. Therefore … progress to improve any of the elements will directly increase gate performance.”

In other words: they did something simple and did it well. And that the only forward here is up. And down. At the same time.

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