Testing the limits of quantum mechanical superpositions

Arndt, Markus; Hornberger, Klaus

doi:10.1038/nphys2863

Cited by 363 publications

(391 citation statements)

References 105 publications

(116 reference statements)

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“…The experimental predictions of this nonlinear theory are very close to the standard theory in the micro world, but differ from the standard theory in the meso and the macro world. A decisive experiment which chooses between standard quantum theory and stochastic nonlinear theories has not yet been performed, although an extraordinary worldwide effort in this direction is currently in progress [48]. The main reason is that, even if for meso and macro systems the nonlinear effects may be relevant, in this regime the interaction with the environment plays also an important role, which masks the nonlinear effects.…”

Section: Introductionmentioning

confidence: 99%

A Comparison Between Models of Gravity Induced Decoherence

et al. 2015

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It has been suggested in the literature that spatial coherence of the wave function can be dynamically suppressed by fluctuations in the spacetime geometry. These fluctuations represent the minimal uncertainty that is present when one probes spacetime geometry with a quantum probe. on the mass and size of the quantum object. In the present article we compare and contrast the two models from three aspects: (i) comparison of the spacetime bounds, (ii) method of calculating decoherence time, (iii) comparison of noise correlation. We show that under certain conditions the minimal spacetime bounds in the two models can be derived one from the other. We argue that the methods of calculating the decoherence time are equivalent. We re-derive the two-point correlation for the fluctuation potential in the K-model, and confirm the earlier result of Diósi and Lukács that it is non-white noise, unlike in the D-model, where the corresponding correlation is white noise in time. This seems to be the origin of the different results in the two models. We derive the non-Markovian master equation for the K-model. We argue that the minimal spacetime bound cannot predict the noise correlation uniquely, and additional criteria are necessary to accurately determine the effects of gravitationally induced decoherence.

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Section: Introductionmentioning

confidence: 99%

A Comparison Between Models of Gravity Induced Decoherence

et al. 2015

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“…It is a current experimental trend to push the tests of quantum mechanics towards the macroscopic domain, see for example Refs. [3][4][5][6]. In all these experiments, the superposition indeed involves large number of particles or excitations, nevertheless the states produced are somewhat "simple": some involve the superposition of a single degree of freedom, the center of mass; others target the GHZ state, or the Dicke state with few excitations, as ideal macroscopic states.…”

Section: Introductionmentioning

confidence: 99%

State complexity and quantum computation

Cai

Scarani

2015

Annalen der Physik

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The complexity of a quantum state may be closely related to the usefulness of the state for quantum computation. We discuss this link using the tree size of a multiqubit state, a complexity measure that has two noticeable (and, so far, unique) features: it is in principle computable, and non-trivial lower bounds can be obtained, hence identifying truly complex states. In this paper, we first review the definition of tree size, together with known results on the most complex three and four qubits states. Moving to the multiqubit case, we revisit a mathematical theorem for proving a lower bound on tree size that scales superpolynomially in the number of qubits. Next, states with superpolynomial tree size, the Immanant states, the Deutsch-Jozsa states, the Shor's states and the subgroup states, are described. We show that the universal resource state for measurement based quantum computation, the 2D-cluster state, has superpolynomial tree size. Moreover, we show how the complexity of subgroup states and the 2D cluster state can be verified efficiently. The question of how tree size is related to the speed up achieved in quantum computation is also addressed. We show that superpolynomial tree size of the resource state is essential for measurement based quantum computation. The necessary role of large tree size in the circuit model of quantum computation is still a conjecture; and we prove a weaker version of the conjecture.

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“…In molecular interference experiments, the diffraction grating is typically an etched membrane; however, van der Waals interactions with the slits make this hard to extend to large particles [1]. More advanced implementations use optically defined gratings; the pitch, which sets the momentum separation of the diffracted beams, is then limited by the optical wavelength [31]. In our scheme, the pitch is limited neither by an optical wavelength nor by the size of the resonator, but by the qubit-resonator coupling strength.…”

Section: Introductionmentioning

confidence: 99%

Displacemon Electromechanics: How to Detect Quantum Interference in a Nanomechanical Resonator

et al. 2018

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We introduce the "displacemon" electromechanical architecture that comprises a vibrating nanobeam, e.g., a carbon nanotube, flux coupled to a superconducting qubit. This platform can achieve strong and even ultrastrong coupling, enabling a variety of quantum protocols. We use this system to describe a protocol for generating and measuring quantum interference between trajectories of a nanomechanical resonator. The scheme uses a sequence of qubit manipulations and measurements to cool the resonator, to apply two effective diffraction gratings, and then to measure the resulting interference pattern. We demonstrate the feasibility of generating a spatially distinct quantum superposition state of motion containing more than 10 6 nucleons using a vibrating nanotube acting as a junction in this new superconducting qubit configuration.

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Testing the limits of quantum mechanical superpositions

Cited by 363 publications

References 105 publications

A Comparison Between Models of Gravity Induced Decoherence

A Comparison Between Models of Gravity Induced Decoherence

State complexity and quantum computation

Displacemon Electromechanics: How to Detect Quantum Interference in a Nanomechanical Resonator

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