Entanglement Generation on the Double Quantum Transition of NV Ground State Via Globally Addressing Microwave Pulse
- URL: http://arxiv.org/abs/2501.18244v1
- Date: Thu, 30 Jan 2025 10:23:20 GMT
- Title: Entanglement Generation on the Double Quantum Transition of NV Ground State Via Globally Addressing Microwave Pulse
- Authors: Marcel Morillas-Rozas, Alberto López-García, Javier Cerrillo,
- Abstract summary: Entanglement is a key quantum feature that enables quantum sensors to improve their sensitivity up to the Heisenberg limit.<n>In the NV-center platform, the Heisenberg limit can only be achieved when the axes of the NV centers are parallel.<n>We propose for the first time a mechanism to prepare entangled states in the double quantum transition of two dipolarly coupled NV centers.
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- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Entanglement is a key quantum feature that enables quantum sensors to improve their sensitivity up to the Heisenberg limit. In the NV-center platform, the Heisenberg limit can only be achieved when the axes of the NV centers are parallel. Nevertheless, parallel NV centers are spectrally indistinguishable and no mechanisms to prepare entanglement in such configurations are known to date. In this work we propose for the first time a mechanism to prepare entangled states in the double quantum transition of two dipolarly coupled NV centers whose axes are parallel. Our approach is based on the NV effective Raman coupling (NV-ERC) protocol and makes use of global addressing of both NV centers with a single monochromatic microwave pulse. Supported by an adiabatic elimination analysis, several mechanisms for the preparation of different entangled states are identified which avoid participation of intermediate states in all cases, thus limiting the impact of additional unwanted noise sources. We consider the generation of different entangled states belonging to the double quantum transition, sensitive to either transverse electric fields or longitudinal magnetic fields, all with a fourfold improved sensitivity compared to conventional single NV settings.
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