Voltage-tunable superconducting resonators: a platform for random access
quantum memory
- URL: http://arxiv.org/abs/2006.08683v1
- Date: Mon, 15 Jun 2020 18:34:42 GMT
- Title: Voltage-tunable superconducting resonators: a platform for random access
quantum memory
- Authors: Kasra Sardashti, Matthieu C. Dartiailh, Joseph Yuan, Sean Hart, Patryk
Gumann, Javad Shabani
- Abstract summary: We propose a scalable voltage-tunable quantum memory (QuMem) design concept compatible with superconducting qubit platforms.
The proposed design would facilitate the implementation of random access memory for storage of quantum information in between computational gate operations.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: In quantum computing architectures, one important factor is the trade-off
between the need to couple qubits to each other and to an external drive and
the need to isolate them well enough in order to protect the information for an
extended period of time. In the case of superconducting circuits, one approach
is to utilize fixed frequency qubits coupled to coplanar waveguide resonators
such that the system can be kept in a configuration that is relatively
insensitive to noise. Here, we propose a scalable voltage-tunable quantum
memory (QuMem) design concept compatible with superconducting qubit platforms.
Our design builds on the recent progress in fabrication of Josephson field
effect transistors (JJ-FETs) which use InAs quantum wells. The JJ-FET is
incorporated into a tunable coupler between a transmission line and a
high-quality resonator in order to control the overall inductance of the
coupler. A full isolation of the high-quality resonator can be achieved by
turning off the JJ-FET. This could allow for long coherence times and
protection of the quantum information inside the storage cavity. The proposed
design would facilitate the implementation of random access memory for storage
of quantum information in between computational gate operations.
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