Observation of Critical Phenomena in Parity-Time-Symmetric Quantum Dynamics

Liu, Xiao; Wang, Kunkun; Zhan, Xiang; Bian, Zhihao; Kawabata, Ken‐ichi; Ueda, Masahito; Wu, Yi; Xue, Peng

doi:10.1103/physrevlett.123.230401

Cited by 160 publications

(117 citation statements)

References 36 publications

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“…In the PT -symmetric phase, the eigenvalues are real and the intensities oscillate as a result of the nonorthogonality of eigenstates [17]; in the broken PTsymmetric phase, the intensities exponentially increase because of the complex eigenvalues [7]. Besides the coupled waveguide/resonator lattice, PT -symmetric systems are simulated by photonic quantum walks [18][19][20].…”

Section: Introductionmentioning

confidence: 99%

High-order exceptional points in supersymmetric arrays

Zhang

Jin

et al. 2020

Phys. Rev. A

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We employ the intertwining operator technique to synthesize a supersymmetric (SUSY) array of arbitrary size N . The synthesized SUSY system is equivalent to a spin-(N − 1)/2 under an effective magnetic field. By considering an additional imaginary magnetic field, we obtain a generalized parity-time-symmetric non-Hermitian Hamiltonian that describes a SUSY array of coupled resonators or waveguides under a gradient gain and loss; all the N energy levels coalesce at an exceptional point (EP), forming the isotropic high-order EP with N states coalescence (EPN). Near the EPN, the scaling exponent of phase rigidity for each eigenstate is (N − 1)/2; the eigen frequency response to the perturbation acting on the resonator or waveguide couplings is 1/N . Our findings reveal the importance of the intertwining operator technique for the spectral engineering and exemplify the practical application in non-Hermitian physics. arXiv:2003.07510v1 [quant-ph]

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Section: Introductionmentioning

confidence: 99%

High-order exceptional points in supersymmetric arrays

Zhang

Jin

et al. 2020

Phys. Rev. A

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“…we adopt a Naimark dilation approach [20,22,52] using an extended Hermitian system. The evolution of the total system (including the system s and the ancilla qubit a) |Ψ(t) = |0 a ⊗ |ψ(t) s + |1 a ⊗ |χ(t) s follows a dilated Hamiltonian H [58].…”

Section: Initializationmentioning

confidence: 99%

“…Analysis of sensing performance.-The experimental realization of a pseudo-Hermitian qubit sensor relies on the conditional evolution in a dilated Hermitian quantum system [20,22,52]. This approach results in a finite success probability γ(λ o , τ ) (7.4 − 10.4 √ ε)ε 2 [58], which equals to the probability of the ancilla qubit in the state |0 a , see Fig.1.…”

Section: Initializationmentioning

confidence: 99%

“…ηH = H † η with a Hermitian invertible linear operator η) [6][7][8][9] can have real spectrum. The discovery has opened a new avenue to intriguing non-Hermitian physics in both classical and quantum systems [10][11][12][13][14][15][16][17][18][19][20][21][22][23][24]. In particular, the concepts of exceptional point [25][26][27] and PT -phase transition [28,29] lead to important experimental observations such as single-mode lasers [30,31], non-reciprocal light transport [32,33], non-Hermitian topological light steering [34], asymmetric mode switching [35] and topological energy transfer [36] when encircling an exceptional point.…”

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confidence: 99%

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Quantum Sensing with a Single-Qubit Pseudo-Hermitian System

Chu

Liu

et al. 2020

Phys. Rev. Lett.

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Quantum sensing exploits fundamental features of quantum system to achieve highly efficient measurement of physical quantities. Here, we propose a strategy to realize a single-qubit pseudo-Hermitian sensor from a dilated two-qubit Hermitian system. The pseudo-Hermitian sensor exhibits divergent susceptibility in dynamical evolution that does not necessarily involve exceptional point. We demonstrate its potential advantages to overcome noises that cannot be averaged out by repetitive measurements. The proposal is feasible with the state-of-art experimental capability in a variety of qubit systems, and represents a step towards the application of non-Hermitian physics in quantum sensing.Introduction.-Non-Hermitian Hamiltonians usually have complex energy eigenvalues and do not conserve probabilities, thus presumably only serve as phenomenological descriptions of open quantum system [1,2]. Remarkably, a non-Hermitian Hamiltonian H with an exact PT -symmetry [3-5] and more general pseudo-Hermiticity (i.e. ηH = H † η with a Hermitian invertible linear operator η) [6-9] can have real spectrum. The discovery has opened a new avenue to intriguing non-Hermitian physics in both classical and quantum systems [10][11][12][13][14][15][16][17][18][19][20][21][22][23][24]. In particular, the concepts of exceptional point [25][26][27] and PT -phase transition [28,29] lead to important experimental observations such as single-mode lasers [30, 31], non-reciprocal light transport [32, 33], non-Hermitian topological light steering [34], asymmetric mode switching [35] and topological energy transfer [36] when encircling an exceptional point.Among a number of important applications, enhancing the sensitivity of energy splitting detection by using exceptional points attracts increasingly intensive theoretical interest [37][38][39][40][41][42]. The unique feature of exceptional point based sensing is the divergent eigenvalue susceptibility arising from the square-root frequency topology around exceptional points [27]. Exceptional point based sensing has been demonstrated in PT -symmetric linear coupled-mode optic systems, with potential applications for single-particle detection [43,44] and optical gyroscope [45]. Nevertheless, the singular behavior of the energy splitting is counteracted by the eigenstate coalescence [46][47][48]. Quantum sensing based on non-Hermitian qubit system without involving exceptional points and its potential advantages remain largely unexplored.In this work, we propose a novel strategy to harness a qubit probe with pseudo-Hermiticity as a resource for quantum sensing by introducing an additional qubit ancilla [49][50][51][52]. The dilated two-qubit Hermitian system, when exposed to a parameter-dependent weak field, reproduces an effective pseudo-Hermitian qubit sensor by postselection, inheriting the influence of the parameter. The eigenstate coalescence without involving exceptional point induces divergent susceptibility in the normalized

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“…2, our experimental setup consists of three modules: state preparation, Alice's measurement, and Bob's measurement. In the state preparation module, entangled photons are generated via type-I spontaneous parametric down-conversion (SPDC) [38][39][40][41][42][43][44][45][46][47][48]. By choosing the setting angle of the half-wave plate (HWP, H 0 ) to be cos 2χ = a, photon pairs are prepared into a family of entangled state |φ + = a |HH + √ 1 − a 2 |V V .…”

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confidence: 99%

Experimental demonstration of one-sided device-independent self-testing of any pure two-qubit entangled state

et al. 2020

Self Cite

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We demonstrate one-sided device-independent self-testing of any pure entangled two-qubit state based on a fine-grained steering inequality. The maximum violation of a fine-grained steering inequality can be used to witness certain steerable correlations, which certify all pure two-qubit entangled states. Our experimental results identify which particular pure two-qubit entangled state has been self-tested and which measurement operators are used on the untrusted side. Furthermore, we analytically derive the robustness bound of our protocol, enabling our subsequent experimental verification of robustness through state tomography. Finally, we ensure that the requisite no-signalling constraints are maintained in the experiment.

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Observation of Critical Phenomena in Parity-Time-Symmetric Quantum Dynamics

Cited by 160 publications

References 36 publications

High-order exceptional points in supersymmetric arrays

High-order exceptional points in supersymmetric arrays

Quantum Sensing with a Single-Qubit Pseudo-Hermitian System

Experimental demonstration of one-sided device-independent self-testing of any pure two-qubit entangled state

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