In a quantum computation scheme, such as recycling a qubit, the initialization of the qubit is always required. At present, the initialization of the qubit is one of the bottlenecks in such computation, and high fidelity and fast initialization still remain important research subjects. In this study, by coupling a SINIS (superconductor–insulator–normal metal–insulator–superconductor) junction to a coupled system consisting of a qubit and a resonator, a photon is removed from the resonator by single-photon-assisted tunneling, and the effective relaxation rate of the resonator is increased. In addition, by applying an | e , 0 | f , 0 drive pulse and an | f , 0 | g , 1 drive pulse to the qubit, the energy of the qubit is rapidly transferred to the resonator to realize high-speed initialization. The present simulation shows that the qubit can be initialized with 99% fidelity in 80 ns and 99.9% in 137 ns when the electron temperature of the normal metal of the SINIS junction is 10 mK. The simulation also shows that the relaxation time of the qubit is about 13% longer when the resonator is interposed between the SINIS junction and the qubit than when the SINIS junction is directly coupled to the qubit.

1.
C.-C.
Chen
,
S.-Y.
Shiau
,
M.-F.
Wu
, and
Y.-R.
Wu
, “
Hybrid classical-quantum linear solver using noisy intermediate-scale quantum machines
,”
Sci. Rep.
9
,
16251
(
2019
).
2.
R.
Raussendorf
,
J.
Harrington
, and
K.
Goyal
, “
Topological fault-tolerance in cluster state quantum computation
,”
New J. Phys.
9
,
199
199
(
2007
).
3.
A. G.
Fowler
,
M.
Mariantoni
,
J. M.
Martinis
, and
A. N.
Cleland
, “
Surface codes: Towards practical large-scale quantum computation
,”
Phys. Rev. A
86
,
032324
(
2012
).
4.
R.
Barends
,
J.
Kelly
,
A.
Megrant
,
A.
Veitia
,
D.
Sank
,
E.
Jeffrey
,
T. C.
White
,
J.
Mutus
,
A. G.
Fowler
,
B.
Campbell
et al, “
Superconducting quantum circuits at the surface code threshold for fault tolerance
,”
Nature
508
,
500
503
(
2014
).
5.
T.
Walter
,
P.
Kurpiers
,
S.
Gasparinetti
,
P.
Magnard
,
A.
Potočnik
,
Y.
Salathé
,
M.
Pechal
,
M.
Mondal
,
M.
Oppliger
,
C.
Eichler
et al, “
Rapid high-fidelity single-shot dispersive readout of superconducting qubits
,”
Phys. Rev. Appl.
7
,
054020
(
2017
).
6.
P.
Magnard
,
P.
Kurpiers
,
B.
Royer
,
T.
Walter
,
J.-C.
Besse
,
S.
Gasparinetti
,
M.
Pechal
,
J.
Heinsoo
,
S.
Storz
,
A.
Blais
, and
A.
Wallraff
, “
Fast and unconditional all-microwave reset of a superconducting qubit
,”
Phys. Rev. Lett.
121
,
060502
(
2018
).
7.
K. Y.
Tan
,
M.
Partanen
,
R. E.
Lake
,
J.
Govenius
,
S.
Masuda
, and
M.
Möttönen
, “
Quantum-circuit refrigerator
,”
Nat. Commun.
8
,
15819
(
2017
).
8.
V.
Sevriuk
,
K. Y.
Tan
,
E.
Hyyppä
,
M.
Silveri
,
M.
Partanen
,
M.
Jenei
,
S.
Masuda
,
J.
Goetz
,
V.
Vesterinen
,
L.
Grönberg
et al, “
Fast control of dissipation in a superconducting resonator
,”
Appl. Phys. Lett.
115
,
082601
(
2019
).
9.
M.
Silveri
,
S.
Masuda
,
V.
Sevriuk
,
K. Y.
Tan
,
M.
Jenei
,
E.
Hyyppä
,
F.
Hassler
,
M.
Partanen
,
J.
Goetz
,
R. E.
Lake
et al, “
Broadband lamb shift in an engineered quantum system
,”
Nat. Phys.
15
,
533
537
(
2019
).
10.
A.
Viitanen
,
M.
Silveri
,
M.
Jenei
,
V.
Sevriuk
,
K. Y.
Tan
,
M.
Partanen
,
J.
Goetz
,
L.
Grönberg
,
V.
Lahtinen
, and
M.
Möttönen
, “
Photon-number-dependent lamb shift
,” preprint arXiv:2008.08268 (
2020
).
11.
S.
Zeytinoğlu
,
M.
Pechal
,
S.
Berger
,
A. A.
Abdumalikov
,
A.
Wallraff
, and
S.
Filipp
, “
Microwave-induced amplitude- and phase-tunable qubit-resonator coupling in circuit quantum electrodynamics
,”
Phys. Rev. A
91
,
043846
(
2015
).
12.
A.
Ronzani
,
B.
Karimi
,
J.
Senior
,
Y.-C.
Chang
,
J. T.
Peltonen
,
C.
Chen
, and
J. P.
Pekola
, “
Tunable photonic heat transport in a quantum heat valve
,”
Nat. Phys.
14
,
991
995
(
2018
).
13.
M.
Partanen
,
J.
Goetz
,
K. Y.
Tan
,
K.
Kohvakka
,
V.
Sevriuk
,
R. E.
Lake
,
R.
Kokkoniemi
,
J.
Ikonen
,
D.
Hazra
,
A.
Mäkinen
,
E.
Hyyppä
,
L.
Grönberg
,
V.
Vesterinen
,
M.
Silveri
, and
M.
Möttönen
, “
Exceptional points in tunable superconducting resonators
,”
Phys. Rev. B
100
,
134505
(
2019
).
14.
M.
Silveri
,
H.
Grabert
,
S.
Masuda
,
K.
Tan
, and
M.
Möttönen
, “
Theory of quantum-circuit refrigeration by photon-assisted electron tunneling
,”
Phys. Rev. B
96
,
094524
(
2017
).
15.
H.
Hsu
,
M.
Silveri
,
A.
Gunyhó
,
J.
Goetz
,
G.
Catelani
, and
M.
Möttönen
, “
Tunable refrigerator for nonlinear quantum electric circuits
,”
Phys. Rev. B
101
,
235422
(
2020
).
You do not currently have access to this content.