A vital requirement for a quantum computer is the ability to locally address, with high fidelity, any of its qubits without affecting their neighbors. We propose an addressing method using composite sequences of laser pulses, which reduces dramatically the addressing error in a lattice of closely spaced atoms or ions, and at the same time significantly enhances the robustness of qubit manipulations. To this end, we design novel high-fidelity composite pulses for the most important single-qubit operations. In principle, this method allows one to beat the diffraction limit, for only atoms situated in a small spatial region around the center of the laser beam are excited, well within the laser beam waist. c 2017 Optical Society of America Scalable quantum computers depend critically on the ability to perform local addressing of their individual qubits [1]. In a Paul ion trap, which is one of the most promising scalable platforms for the future quantum computer [2], local addressing is the ability to operate on a single ion by focused laser light while keeping the neighboring ions unaffected. When the number of ions increases, the distance between them diminishes and local addressing becomes one of the principal experimental challenges. For example, in a recent experimental demonstration of the Toffoli gate [3] most of the error was attributed to addressing error, as the neighboring ions were seeing 7% of the central Rabi frequency.In this Letter, we propose a method for high-fidelity local addressing applicable to various types of atomic qubits: trapped ions, atoms in optical lattices, quantum dots, etc. To this end, we present new narrowband (NB) and passband (PB) composite pulses 1 , which are specially designed for local addressing. The excitation profiles of such pulses allow one to manipulate only a single qubit, as the outer parts of the spatial laser beam profile practically do not excite its neighbors, although the latter may be subjected to significant laser intensity. Moreover, with a PB pulse one enhances the robustness of qubit manipulations, thereby eliminating errors due to imperfectly calibrated and fluctuating laser intensity and laser beam pointing instability.The technique of composite pulses was introduced in nuclear magnetic resonance (NMR) [4-6] as a powerful tool for manipulation of spins by magnetic fields. A composite pulse compensates the imperfections of a single pulse, which is the traditional tool used to drive a quantum transition, and it consists of a sequence of pulses, each with a well-defined phase. The composite phases are determined from the conditions imposed on the desired overall excitation profile. In particular, in a NB composite pulse only the qubits seeing pulse areas within a narrow range around some value A are subjected to trans-1 We follow the usual NMR terminology, which is related to the features of the excitation profile, rather than the radiation.formation, while qubits seeing areas outside this range remain unaffected in the end of the composite sequence.Most known...
