Abstract
Based on a quantum interferometric circuit, we implement a NMR quantum thermometer, in which a probe qubit measures the temperature of a nuclear spin at thermal equilibrium with a bath. The whole procedure lasts 5.5 ms, a much shorter time than the probe’s spin-lattice relaxation time, which is (formula presented). The fidelity of the probe final quantum state, in respect to the ideal theoretical prediction, is above 99 %. We show that quantum coherence is essential for the high fidelity of temperature measurement. We discuss the source of errors on the temperature measurement and some possible applications of the thermometer.
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Raitz, C., Souza, A. M., Auccaise, R., Sarthour, R. S., & Oliveira, I. S. (2015). Experimental implementation of a nonthermalizing quantum thermometer. Quantum Information Processing, 14(1), 37–46. https://doi.org/10.1007/s11128-014-0858-z
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