Bülent Demirel scite author profile

Information-theoretic definitions for noise and disturbance in quantum measurements were given in [Phys. Rev. Lett. 112, 050401 (2014)] and a state-independent noise-disturbance uncertainty relation was obtained. Here, we derive a tight noise-disturbance uncertainty relation for complementary qubit observables and carry out an experimental test. Successive projective measurements on the neutron's spin-1/2 system, together with a correction procedure which reduces the disturbance, are performed. Our experimental results saturate the tight noise-disturbance uncertainty relation for qubits when an optimal correction procedure is applied.

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Experimental Test of Residual Error-Disturbance Uncertainty Relations for Mixed Spin-½States

Demirel

Sponar

Sulyok

et al. 2016

Phys. Rev. Lett.

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The indeterminacy inherent in quantum measurements is an outstanding character of quantum theory, which manifests itself typically in the uncertainty principle. In the last decade, several universally valid forms of error-disturbance uncertainty relations were derived for completely general quantum measurements for arbitrary states. Subsequently, Branciard established a form that is optimal for spin measurements for some pure states. However, the bound in his inequality is not stringent for mixed states. One of the present authors recently derived a new bound tight in the corresponding mixed state case. Here, a neutron-optical experiment is carried out to investigate this new relation: it is tested whether error and disturbance of quantum measurements disappear or persist in mixing up the measured ensemble. The attainability of the new bound is experimentally observed, falsifying the tightness of Branciard's bound for mixed spin states.

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Erratum: Experimental Test of Entropic Noise-Disturbance Uncertainty Relations for Spin-1/2Measurements [Phys. Rev. Lett.115, 030401 (2015)]

Sulyok¹,

Demirel²,

Sponar³

et al. 2016

Phys. Rev. Lett.

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Experimental test of an entropic measurement uncertainty relation for arbitrary qubit observables

et al. 2019

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The uncertainty principle is an important tenet and active field of research in quantum physics. Information-theoretic uncertainty relations, formulated using entropies, provide one approach to quantifying the extent to which two non-commuting observables can be jointly measured. Recent theoretical analysis predicts that general quantum measurements are necessary to saturate some such uncertainty relations and thereby overcome certain limitations of projective measurements. Here, we experimentally test a tight information-theoretic measurement uncertainty relation with neutron spin-1 2 qubits. The noise associated to the measurement of an observable is defined via conditional Shannon entropies and a tradeoff relation between the noises for two arbitrary spin observables is demonstrated. The optimal bound of this tradeoff is experimentally obtained for various noncommuting spin observables. For some of these observables this lower bound can be reached with projective measurements, but we observe that, in other cases, the tradeoff is only saturated by general quantum measurements (i.e. positive-operator valued measures) as predicted theoretically. These results showcase experimentally the advantage obtainable by general quantum measurements over projective measurements when probing certain uncertainty relations. i 1 2, for arbitrary observables A and B and any state yñ | [10]. Entropic uncertainty relations have subsequently proven useful in quantum cryptography [11,12], entanglement witnessing [13], complementarity [14] and other topics in quantum information theory [15], where entropy is a natural quantity of interest.In recent years measurement uncertainty relations, in the spirit of Heisenberg's original proposal, have received renewed attention. Such uncertainty relations can be subdivided into two classes: noise-disturbance relations, which quantify the idea that the more accurately a measurement determines the value of an observable,

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Measurement of the spin–rotation coupling in neutron polarimetry

2015

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The effect of spin-rotation coupling is measured for the first time with neutrons. The coupling of spin with the angular velocity of a rotating spin turner can be observed as a phase shift in a neutron polarimeter set-up. After the neutron's spin is rotated by 2π through a rotating magnetic field, different phase shifts are induced for 'up' and 'down' spin eigenstates. This phase difference results in the rotation of the neutron's spin-vector, which turns out to depend solely on the frequency of the rotation of the magnetic field. The experimental results agree well with the solutions acquired by the Pauli-Schrödinger equation.

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Bülent Demirel

Experimental Test of Entropic Noise-Disturbance Uncertainty Relations for Spin-1/2Measurements

Experimental Test of Residual Error-Disturbance Uncertainty Relations for Mixed Spin-½States

Erratum: Experimental Test of Entropic Noise-Disturbance Uncertainty Relations for Spin-1/2Measurements [Phys. Rev. Lett.115, 030401 (2015)]

Experimental test of an entropic measurement uncertainty relation for arbitrary qubit observables

Measurement of the spin–rotation coupling in neutron polarimetry

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