Related papers: Variable bandwidth, high efficiency microwave resonator for control of spin-qubits in nitrogen-vacancy centers

Variable bandwidth, high efficiency microwave resonator for control of spin-qubits in nitrogen-vacancy centers

URL: http://arxiv.org/abs/2301.03911v1
Date: Tue, 10 Jan 2023 11:26:42 GMT
Title: Variable bandwidth, high efficiency microwave resonator for control of spin-qubits in nitrogen-vacancy centers
Authors: Anton Savitsky, Jingfu Zhang, Dieter Suter
Abstract summary: Nitrogen-Vacancy (NV) centers in diamond are attractive tools for sensing and quantum information. We present a planar microwave resonator optimized for microwave-optical double resonance experiments.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Nitrogen-Vacancy (NV) centers in diamond are attractive tools for sensing and quantum information. Realization of this potential requires effective tools for controlling the spin degree of freedom by microwave (mw) magnetic fields. In this work we present a planar microwave resonator optimized for microwave-optical double resonance experiments on single nitrogen-vacancy (NV) centers in diamond. It consists of a piece of wide microstrip line which is symmetrically connected to two 50 $\Omega$ microstrip feed lines. In the center of the resonator, an $\Omega$-shaped loop focuses the current and the mw magnetic field. It generates a relatively homogeneous magnetic field over a volume of 0.07mm$^2\times$0.1mm. It can be operated at 2.9 GHz in both transmission and reflection modes with bandwidths of 1000 MHz and 400 MHz, respectively. The high power-to-magnetic field conversion efficiency allows to produce $\pi$-pulses with a duration of 50 ns with only about 200 mW and 50 mW microwave power in transmission and reflection, respectively. The transmission mode also offers capability for efficient radio frequency excitation. The resonance frequency can be tuned between 1.3 GHz and 6 GHz by adjusting the length of the resonator. This will be useful for experiments on NV-centers at higher external magnetic fields and on different types of optically active spin centers.

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