Capacitively Coupled Charge Qubits

For a single charge qubit, the Hamiltonian is

${\displaystyle H_{i}=\left({\begin{matrix}\epsilon _{i}/2&\Delta _{i}\\\Delta _{i}&-\epsilon _{i}/2\end{matrix}}\right)}$ 

We will refer to ${\displaystyle \epsilon _{i}}$  and ${\displaystyle \Delta _{i}}$  as the detuning and tunnel coupling of qubit ${\displaystyle i}$ , respectively.

We can further write down the full Hamiltonian explicitly:

${\displaystyle H=\left({\begin{matrix}{\frac {1}{2}}(\epsilon _{1}+\epsilon _{2})+g&\Delta _{2}&\Delta _{1}&0\\\Delta _{2}&{\frac {1}{2}}(\epsilon _{1}-\epsilon _{2})-g&0&\Delta _{1}\\\Delta _{1}&0&{\frac {1}{2}}(-\epsilon _{1}+\epsilon _{2})-g&\Delta _{2}\\0&\Delta _{1}&\Delta _{2}&{\frac {1}{2}}(-\epsilon _{1}-\epsilon _{2})+g\end{matrix}}\right)}$ 

where ${\displaystyle g}$  is the capacitive coupling between the qubits.

A major issue with charge qubits is that they are very susceptible to charge noise, which occurs when charge fluctuations outside the system induce undesired shifts in the parameters of the Hamiltonian. The goal of a sweet spot is to find a point in the parameter space where the energy levels are as invariant to the shifts as possible.

First Order Detuning Noise

The most dominant noise source is due to the shifts in the detuning. It is believed that the only point at which the first order dependence on the detunings disappears is at ${\displaystyle \epsilon _{1}=\epsilon _{2}=0}$ . This has been confirmed analytically in the limit of small ${\displaystyle g}$ , and no exceptions have been observed numerically.

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  Gap between 01 and 10 states

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  Gap between 00 and 11 states

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  Gap between 00 and 01 states

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  Gap between 00 and 10 states

Second Order Detuning Noise

For ${\displaystyle \epsilon _{2}=0}$ , we have the following energy levels:

${\displaystyle \lambda _{1}=-{\sqrt {\Delta _{1}^{2}+\Delta _{2}^{2}+{\frac {\epsilon _{1}^{2}}{4}}+g^{2}+{\sqrt {4\Delta _{1}^{2}\Delta _{2}^{2}+\epsilon _{1}^{2}(\Delta _{2}+g^{2})}}}}}$ 

${\displaystyle \lambda _{2}=-{\sqrt {\Delta _{1}^{2}+\Delta _{2}^{2}+{\frac {\epsilon _{1}^{2}}{4}}+g^{2}-{\sqrt {4\Delta _{1}^{2}\Delta _{2}^{2}+\epsilon _{1}^{2}(\Delta _{2}+g^{2})}}}}}$ 

${\displaystyle \lambda _{3}={\sqrt {\Delta _{1}^{2}+\Delta _{2}^{2}+{\frac {\epsilon _{1}^{2}}{4}}+g^{2}-{\sqrt {4\Delta _{1}^{2}\Delta _{2}^{2}+\epsilon _{1}^{2}(\Delta _{2}+g^{2})}}}}}$ 

${\displaystyle \lambda _{4}={\sqrt {\Delta _{1}^{2}+\Delta _{2}^{2}+{\frac {\epsilon _{1}^{2}}{4}}+g^{2}+{\sqrt {4\Delta _{1}^{2}\Delta _{2}^{2}+\epsilon _{1}^{2}(\Delta _{2}+g^{2})}}}}}$ 

which to second order in ${\displaystyle \epsilon _{1}}$  are:

${\displaystyle \lambda _{1}\approx \lambda _{1}^{0}+{\frac {\Delta _{2}(\Delta _{1}+\Delta _{2})+g^{2}}{8\Delta _{1}\Delta _{2}\lambda _{1}^{0}}}\epsilon _{1}^{2}}$ 

${\displaystyle \lambda _{2}\approx \lambda _{2}^{0}+{\frac {\Delta _{2}(\Delta _{1}+\Delta _{2})-g^{2}}{8\Delta _{1}\Delta _{2}\lambda _{2}^{0}}}\epsilon _{1}^{2}}$ 

${\displaystyle \lambda _{3}\approx \lambda _{3}^{0}+{\frac {\Delta _{2}(\Delta _{1}+\Delta _{2})-g^{2}}{8\Delta _{1}\Delta _{2}\lambda _{3}^{0}}}\epsilon _{1}^{2}}$ 

${\displaystyle \lambda _{4}\approx \lambda _{4}^{0}+{\frac {\Delta _{2}(\Delta _{1}+\Delta _{2})+g^{2}}{8\Delta _{1}\Delta _{2}\lambda _{4}^{0}}}\epsilon _{1}^{2}}$ 

The second order terms cannot be tuned such that all gaps are invariant to second order noise. However, ${\displaystyle g}$  can be tuned such that some of the transitions become invariant to some of the second order detuning shifts. To make the transition between ${\displaystyle |01\rangle }$  and ${\displaystyle |10\rangle }$  flat with respect to second order fluctuations in ${\displaystyle \epsilon _{1}}$ , we can set

${\displaystyle g^{2}=\Delta _{2}(\Delta _{1}+\Delta _{2})}$ 

Similarly, to make the transitions between ${\displaystyle |00\rangle }$  and ${\displaystyle |01\rangle }$  and between ${\displaystyle |10\rangle }$  and ${\displaystyle |11\rangle }$  flat to second order in ${\displaystyle \epsilon _{1}}$ , we can set

${\displaystyle g^{2}={\frac {1}{2\Delta _{2}}}(\Delta _{1}+\Delta _{2}){\sqrt {(\Delta _{1}+\Delta _{2})(\Delta _{1}^{3}-\Delta _{1}^{2}\Delta _{2}+3\Delta _{1}\Delta _{2}^{2}+\Delta _{2}^{3})}}-\Delta _{1}^{3}-\Delta _{1}^{2}\Delta _{2}-\Delta _{1}\Delta _{2}^{2}-\Delta _{2}^{3}}$ 

Tunnel Coupling and Capacitive Coupling Noise

Assuming that we sit at the sweet spot ${\displaystyle \epsilon _{1}=\epsilon _{2}=0}$ , the energies are relatively simple, so we can easily see the effect of noise on the other parameters.

Note that if we want any of the transitions to be invariant to first-order fluctuations in tunnel coupling, we would need to set ${\displaystyle \Delta _{1}=\Delta _{2}}$  or set either ${\displaystyle \Delta _{1}}$  or ${\displaystyle \Delta _{2}}$  to zero. Any of these changes however would make the energy levels degenerate, which must be avoided. The conclusion therefore is that we cannot make the transitions invariant to first-order fluctuations in tunnel coupling.

Similarly, there is nothing we can do short of making the energy levels degenerate to make the transitions invariant with respect to first-order fluctuations in capacitive coupling. We could, however, make the coupling itself as stable as possible through manipulating the geometry of the system.

SECTION IN PROGRESS

After bringing the system adiabatically to the sweet spot ${\displaystyle \epsilon _{1}=\epsilon _{2}=0}$ , we can apply an AC pulse to some of our parameters to induce a rotation within the system.