Abstract
A practical quantum computer must be capable of performing high fidelity quantum gates on a set of quantum bits (qubits). In the presence of noise, the realization of such gates poses daunting challenges. Geometric phases, which possess intrinsic noise-tolerant features, hold the promise for performing robust quantum computation. In particular, quantum holonomies, i.e., non-Abelian geometric phases, naturally lead to universal quantum computation due to their non-commutativity. Although quantum gates based on adiabatic holonomies have already been proposed, the slow evolution eventually compromises qubit coherence and computational power. Here, we propose a general approach to speed up an implementation of adiabatic holonomic gates by using transitionless driving techniques and show how such a universal set of fast geometric quantum gates in a superconducting circuit architecture can be obtained in an all-geometric approach. Compared with standard non-adiabatic holonomic quantum computation, the holonomies obtained in our approach tends asymptotically to those of the adiabatic approach in the long run-time limit and thus might open up a new horizon for realizing a practical quantum computer.
Highlights
A practical quantum computer must be capable of performing high fidelity quantum gates on a set of quantum bits
We propose a general approach to speed up an implementation of adiabatic holonomic gates by using transitionless driving techniques and show how such a universal set of fast geometric quantum gates in a superconducting circuit architecture can be obtained in an all-geometric approach
We would like to put forward some remarks on the holonomic gates based on transitionless quantum driving algorithm (TQDA) proposed here and the nonadiabatic holonomic gates proposed in ref
Summary
A practical quantum computer must be capable of performing high fidelity quantum gates on a set of quantum bits (qubits). A possible approach towards robust quantum computation is to implement quantum gates by means of different types of geometric phases[1,2,3,4]; an approach known as holonomic quantum computation (HQC)[5,6,7,8,9,10]. The adiabatic evolution is associated with long run time, which increases the exposure to detrimental decoherence and noise This drawback can be eliminated by using non-adiabatic HQC schemes based on Abelian[8,9] or non-Abelian geometric phases[10].
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