Loss–DiVincenzo quantum computer

The Loss–DiVincenzo quantum computer (or spin-qubit quantum computer) is a scalable semiconductor-based quantum computer proposed by Daniel Loss and David P. DiVincenzo in 1997.^[1] The proposal was to use as qubits the intrinsic spin-1/2 degree of freedom of individual electrons confined to quantum dots. This was done in a way that fulfilled DiVincenzo Criteria for a scalable quantum computer,^[2] namely:

• identification of well-defined qubits;
• reliable state preparation;
• low decoherence;
• accurate quantum gate operations and
• strong quantum measurements.

A candidate for such a quantum computer is a lateral quantum dot system.

The Loss–DiVincenzo quantum computer operates, basically, using inter-dot gate voltage for implementing Swap (computer science) operations and local magnetic fields (or any other local spin manipulation) for implementing the Controlled NOT gate (CNOT gate).

The Swap operation is achieved by applying a pulsed inter-dot gate voltage, so the exchange constant in the Heisenberg Hamiltonian becomes time-dependent:

${\displaystyle H_s(t)=J(t){\overrightarrow{S}}_L\cdot {\overrightarrow{S}}_R.}$

This description is only valid if:

• the level spacing in the quantum-dot ${\displaystyle \mathrm{\Delta }E}$ is much greater than ${\displaystyle kT}$;
• the pulse time scale ${\displaystyle {\tau }_s}$ is greater than ${\displaystyle \hslash /\mathrm{\Delta }E}$, so there is no time for transitions to higher orbital levels to happen and
• the decoherence time ${\displaystyle {\mathrm{\Gamma }}^{-1}}$ is longer than ${\displaystyle {\tau }_s}$.

From the pulsed Hamiltonian follows the time evolution operator

${\displaystyle U_s(t)=\mathbf{𝐓}\exp \{-i{\displaystyle \underset{0}{\overset{t}{\int }}}d{t}^{\prime }{H}_s(t^{\prime })\}.}$

We can choose a specific duration of the pulse such that the integral in time over ${\displaystyle J(t)}$ gives ${\displaystyle J_0{\tau }_s=\pi (\text{mod}2\pi ),}$ and ${\displaystyle U_s}$ becomes the Swap operator ${\displaystyle U_s(J_0{\tau }_s=\pi )\equiv U_{sw}}$.

The XOR gate may be achieved by combining ${\displaystyle \sqrt{\text{swap}}}$ (square root of Swap) operations with individual spin operations:

${\displaystyle U_{XOR}=e^{i\frac{\pi }{2}{S}_L^z}{e}^{-i\frac{\pi }{2}{S}_R^z}{U}_{sw}^{1/2}{e}^{i\pi S_L^z}{U}_{sw}^{1/2}.}$

This operator gives a conditional phase for the state in the basis of ${\displaystyle {\overrightarrow{S}}_L+{\overrightarrow{S}}_R}$.

• Condensed Matter Theory at the University of Basel

0.00 (0 votes)