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Simultaneous detection of multiple spin states in a single quantum dot
- Written by: Tyler O'Neal, Staff Editor
Osaka University-based researchers simultaneously detect multiple spin states in a quantum dot in real time, holding great promise for quantum supercomputing
Quantum dots are very small particles that exhibit luminescence and electronic properties different from those of their bulk materials. As a result, they are attractive for use in solar cells, optoelectronics, and quantum supercomputing. Quantum supercomputing involves applying a small voltage to quantum dots to regulate their electron spin state, thus encoding information. While traditional computing is based on a binary information system, electron spin states in quantum dots can display further degrees of freedom because of the possibility of superposition of both states at the same time. This feature could increase the density of encoded information.
Readout of the electron spin of quantum dots is necessary to realize quantum computing. Single-shot spin readout has been used to detect spin-dependent single-electron tunneling events in real time. The performance of quantum computing could be improved considerably by single-shot readout of multiple spin states.
A Japanese research collaboration based at Osaka University has now achieved the first successful detection of multiple spin states through single-shot readout of three two-electron spin states of a single quantum dot. They reported their findings in Physical Review Letters.
To read out multiple spin states simultaneously, the researchers used a quantum point contact charge sensor positioned near a gallium arsenide quantum dot. The change in current of the charge sensor depended on the spin state of the quantum dot and was used to distinguish between singlet and two types of triplet spin states.
"We obtained single-shot ternary readout of two-electron spin states using edge-state spin filtering and the orbital effect," study first author Haruki Kiyama says.
That is, the rate of tunneling between the quantum dot and electron reservoir depended on both the spin state of the electrons and the interaction between electron spin and the orbitals of the quantum dot. The team identified one ground state and two excited states in the quantum dot using their setup.
The researchers then used their ternary readout setup to investigate the spin relaxation behavior of the three detected spin states.
"To confirm the validity of our readout system, we measured the spin relaxation of two of the states," Kiyama explains. "Measurement of the dynamics between the spin states in a quantum dot is an important application of the ternary spin readout setup."
The spin relaxation times for the quantum dot measured using the ternary readout system agreed with those reported, providing evidence that the system yielded reliable measurements.
This ternary readout system can be extended to quantum dots composed of other materials, revealing a new approach to examine the spin dynamics of quantum dots and representing an advance in quantum information processing.