A group led by Australian of the Year, Michelle Simmons, has overcome another critical technical hurdle for building a silicon-based quantum computer.
Simmons' team at UNSW Sydney has demonstrated a compact sensor for accessing information stored in the electrons of individual atoms – a breakthrough that brings us one step closer to scalable quantum computing in silicon.
The research, conducted within the Simmons group at the Center of Excellence for Quantum Computing and Communication Technology (CQC2T) with PhD student Prasanna Pakkiam as lead author, was published on November 27 in the Physical Review X journal.
Quantum bits (or qubits) made of electrons hosted on single atoms in semiconductors is a promising platform for large-scale quantum computers thanks to their long-lasting stability.
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Creating qubits by precisely positioning and encapsulating individual phosphorus atoms within a silicon chip is a unique Australian approach that Simmons' team has been leading globally.
But the addition of all the connections and gates needed to scale the atomic architecture of phosphorus was going to be a challenge – until now.
"To monitor even one qubit, you have to build multiple connections and gates around individual atoms, where there is not a lot of room," said Simmons.
"What's more, you need high-quality qubits in close proximity so they can talk to each other – which is only achievable if you have as little gate infrastructure around them as possible."
In comparison with other approaches to making a quantum computer, Simmons' system already had a relatively low gate density. Yet conventional measurement still required at least 4 gates per qubit: 1 to control it and 3 to read it.
By integrating the read-out sensor into one of the control gates, the team at UNSW has been able to drop this to just two gates: 1 for control and 1 for reading.
Lead author Pakkiam said that the system is more compact but by integrating a superconducting circuit attached to the gate, the team now has the sensitivity to determine the quantum state of the qubit by measuring whether an electron moves between two adjacent atoms.
"And we've shown that we can do this real-time with just one measurement – without the need to repeat the experiment and average the results," said Pakkiam.
Simmons said this represents a major advance in how we read information embedded in our qubits.
"The result confirms that single-gate reading of qubits is now reaching the sensitivity required to perform the necessary quantum error correction for a scalable quantum computer," said Simmons.