Quantum interference device for controlled two-qubit operations
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Quantum interference device for controlled two-qubit operations. / Loft, Niels Jakob Soe; Kjaergaard, Morten; Kristensen, Lasse Bjorn; Andersen, Christian Kraglund; Larsen, Thorvald W.; Gustavsson, Simon; Oliver, William D.; Zinner, Nikolaj T.
I: npj Quantum Information, Bind 6, Nr. 1, 47, 29.05.2020.Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › fagfællebedømt
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TY - JOUR
T1 - Quantum interference device for controlled two-qubit operations
AU - Loft, Niels Jakob Soe
AU - Kjaergaard, Morten
AU - Kristensen, Lasse Bjorn
AU - Andersen, Christian Kraglund
AU - Larsen, Thorvald W.
AU - Gustavsson, Simon
AU - Oliver, William D.
AU - Zinner, Nikolaj T.
PY - 2020/5/29
Y1 - 2020/5/29
N2 - Universal quantum computing relies on high-fidelity entangling operations. Here, we demonstrate that four coupled qubits can operate as a quantum gate, where two qubits control the operation on two target qubits (a four-qubit gate). This configuration can implement four different controlled two-qubit gates: two different entangling swap and phase operations, a phase operation distinguishing states of different parity, and the identity operation (idle quantum gate), where the choice of gate is set by the state of the control qubits. The device exploits quantum interference to control the operation on the target qubits by coupling them to each other via the control qubits. By connecting several four-qubit devices in a two-dimensional lattice, one can achieve a highly connected quantum computer. We consider an implementation of the four-qubit gate with superconducting qubits, using capacitively coupled qubits arranged in a diamond-shaped architecture.
AB - Universal quantum computing relies on high-fidelity entangling operations. Here, we demonstrate that four coupled qubits can operate as a quantum gate, where two qubits control the operation on two target qubits (a four-qubit gate). This configuration can implement four different controlled two-qubit gates: two different entangling swap and phase operations, a phase operation distinguishing states of different parity, and the identity operation (idle quantum gate), where the choice of gate is set by the state of the control qubits. The device exploits quantum interference to control the operation on the target qubits by coupling them to each other via the control qubits. By connecting several four-qubit devices in a two-dimensional lattice, one can achieve a highly connected quantum computer. We consider an implementation of the four-qubit gate with superconducting qubits, using capacitively coupled qubits arranged in a diamond-shaped architecture.
KW - UNIVERSAL
U2 - 10.1038/s41534-020-0275-3
DO - 10.1038/s41534-020-0275-3
M3 - Journal article
VL - 6
JO - npj Quantum Information
JF - npj Quantum Information
SN - 2056-6387
IS - 1
M1 - 47
ER -
ID: 247333666