English

Breaking the rotating wave approximation for a strongly-driven, dressed, single electron spin

Mesoscale and Nanoscale Physics 2016-10-26 v2 Quantum Physics

Abstract

We investigate the dynamics of a strongly-driven, microwave-dressed, donor-bound electron spin qubit in silicon. A resonant oscillating magnetic field B1B_1 is used to dress the electron spin and create a new quantum system with a level splitting proportional to B1B_1. The dressed two-level system can then be driven by modulating the detuning Δν\Delta\nu between the microwave source frequency νMW\nu_{\rm MW} and the electron spin transition frequency νe\nu_e at the frequency of the level splitting. The resulting dressed qubit Rabi frequency ΩRρ\Omega_{R\rho} is defined by the modulation amplitude, which can be made comparable to the level splitting using frequency modulation on the microwave source. This allows us to investigate the regime where the rotating wave approximation breaks down, without requiring microwave power levels that would be incompatible with a cryogenic environment. We observe clear deviations from normal Rabi oscillations and can numerically simulate the time evolution of the states in excellent agreement with the experimental data.

Keywords

Cite

@article{arxiv.1606.02380,
  title  = {Breaking the rotating wave approximation for a strongly-driven, dressed, single electron spin},
  author = {Arne Laucht and Stephanie Simmons and Rachpon Kalra and Guilherme Tosi and Juan P. Dehollain and Juha T. Muhonen and Solomon Freer and Fay E. Hudson and Kohei M. Itoh and David N. Jamieson and Jeffrey C. McCallum and Andrew S. Dzurak and Andrea Morello},
  journal= {arXiv preprint arXiv:1606.02380},
  year   = {2016}
}
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