Quantum computers have the potential to solve certain interesting problems
significantly faster than classical computers. To exploit the power of a
quantum computation it is necessary to perform inter-qubit operations and
generate entangled states. Spin qubits are a promising candidate for
implementing a quantum processor due to their potential for scalability and
miniaturization. However, their weak interactions with the environment, which
leads to their long coherence times, makes inter-qubit operations challenging.
We perform a controlled two-qubit operation between singlet-triplet qubits
using a dynamically decoupled sequence that maintains the two-qubit coupling
while decoupling each qubit from its fluctuating environment. Using state
tomography we measure the full density matrix of the system and determine the
concurrence and the fidelity of the generated state, providing proof of
entanglement

A. Yacoby

Ansmann

Barthel

Bennett

Bluhm

Churchill

H. Bluhm

Koppens

Leibfried

Levy

M. D. Shulman

Nadj-Perge

O. E. Dial

S. P. Harvey

Sackett

V. Umansky

Science

English

arXiv

Quantum computers have the potential to solve certain problems faster than classical computers. To exploit their power, it is necessary to perform interqubit operations and generate entangled states. Spin qubits are a promising candidate for implementing a quantum processor because of their potential for scalability and miniaturization. However, their weak interactions with the environment, which lead to their long coherence times, make interqubit operations challenging. We performed a controlled two-qubit operation between singlet-triplet qubits using a dynamically decoupled sequence that maintains the two-qubit coupling while decoupling each qubit from its fluctuating environment. Using state tomography, we measured the full density matrix of the system and determined the concurrence and the fidelity of the generated state, providing proof of entanglement.Physic

Shulman, Michael Dean

Dial, O

Harvey, Shannon Pasca

Bluhm, H.

Umansky, V.

Yacoby, Amir

Harvard University - DASH 

Demonstration of Entanglement of Electrostatically Coupled Singlet-Triplet Qubits

Entangling Qubits
          
            The basic building block of a quantum computer, a qubit, has been realized in many physical settings, each of which has its advantages and drawbacks. Solid-state spin qubits interact weakly with their environment and each other, leading not only to long coherence times but also to difficulties in performing multiqubit operations.
            
              Shulman
              et al.
            
            (p.
            202
            ) used a double quantum dot to produce a singlet-triplet qubit, where the two quantum states available are a singlet and a triplet formed by two spin-1/2 electrons. Two such qubits are then entangled by electrical gating, which affects the charge configuration of one qubit and that, in turn, influences the electric field experienced by the other. This type of two-qubit entanglement is essential for further development of quantum computing in these systems.
          </jats:p

Crossref

Demonstration of Entanglement of Electrostatically Coupled
  Singlet-Triplet Qubits

Demonstration of Entanglement of Electrostatically Coupled Singlet-Triplet Qubits

Abstract

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