Coherent oscillations in superconducting flux qubit without microwave pulse

About This Presentation

Title:

Coherent oscillations in superconducting flux qubit without microwave pulse

Description:

1 Physikalisches Institut III, Universit t Erlangen-N rnberg - Germany ... The system is fully gradiometric, realized in Nb, designed by IFN-CNR, ... – PowerPoint PPT presentation

Number of Views:34

Avg rating:3.0/5.0

Slides: 17

Provided by: stefano55

Category:

more less

Transcript and Presenter's Notes

Title: Coherent oscillations in superconducting flux qubit without microwave pulse

1
Coherent oscillations insuperconducting flux
qubit without microwave pulse

S. Poletto1, J. Lisenfeld1, A. Lukashenko1
M.G. Castellano2, F. Chiarello2,
C. Cosmelli3, P. Carelli4, A.V. Ustinov1

1 Physikalisches Institut III, Universität
Erlangen-Nürnberg - Germany 2 Istituto di
Fotonica e Nanotecnologie del CNR Italy 3 INFN
and Università di Roma la Sapienza - Italy 4
Università degli Studi dellAquila - Italy
2
Outline
Outline

Circuit description
Observation of coherent oscillations without
microwaves
Theoretical interpretation
Summary and conclusions

3
Circuit description
4
Circuit description
For Fx F0/2 the potential is a symmetric double
well
Qubit parameters
Fully controllable system
5
Circuit description
The system is fully gradiometric, realized in Nb,
designed by IFN-CNR, fabricated by Hypres (100
A/cm2)
Flux bias Fc
1/100 coupling
Readout SQUID
flux bias Fx
junctions
100mm
6
Coherent oscillations without microwaves
7
Coherent oscillations without microwaves
Main idea (energy potential view)
E2
E1
E0
system preparation
evolution
readout
Population of the ground and exited states is
determined by the potential symmetry and barrier
modulation rate
8
Coherent oscillations without microwaves
Main idea (fluxes view)
?x
?c
Readout
9
Coherent oscillations without microwaves
Experimental results

Oscillations for preparation of the left L? and
right R? states

Frequency changes depending on pulse amplitude

?c
10
Theoretical interpretation
11
Theoretical interpretation
Symmetric double-well potential (Fx F0/2 ) ?
description in the base L?, R?
L?
R?
It is possible to describe the system in the
energy base 0?, 1? as well
1?
0?
12
Theoretical interpretation
?
expected oscillation frequency of up to 35 GHz
13
Theoretical interpretation
Frequency dependence on pulse amplitude (?Fc)
Green dots experimental data Blue line
theoretical curve
14
Theoretical interpretation
Note In the case of asymmetric potential one
should take into account a non-adiabatic
population of the states 0?, 1?
15
Conclusions
16
Summary and conclusions
Advantages of the demonstrated approach

Oscillations are obtained without using
microwave pulses
Due to large energy level spacing the system
can evolve at high temperature (up to h?/kB ?
1.1K)
High frequency of coherent oscillations (up to
35 GHz) allow for high speed quantum gates
A qubit coherence time of 500 ns should be
sufficient to implement an error correction
algorithm
(required 104 operations during the
coherence time.
See e.g. arXivquant-ph/0110143)