Mode Structure in Superconducting Metamaterial Transmission-Line Resonators

Wang, H.; Zhuravel, A. P.; Indrajeet, Sagar; Taketani, Bruno G.; Hutchings, Matthew; Yu, Hui; Rouxinol, Francisco; Wilhelm, Frank K.; LaHaye, Matthew; Ustinov, A. V.; Plourde, B. L. T.

doi:10.1103/physrevapplied.11.054062

Cited by 26 publications

(36 citation statements)

References 53 publications

(69 reference statements)

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“…Form the optomechanical damping rate, the unnormalized participation ratio η k i is experimentally obtained by Eq. (22). Using the relation described in Eq.…”

Section: A Samples Parametersmentioning

confidence: 99%

“…Using the on-site optomechanical interactions, we are able to perform a direct measurement of the collective microwave mode shapes, reconstruct the full Hamiltonian of such multimode system beyond the tightbinding approximation, and demonstrate exceptionally low disorder in our devices. Such optomechanical mode shape measurements equally addresses an experimental challenge in large-scale multimode superconducting circuits as a platform for quantum simulation [55][56][57] and many-body physics studies [12,13,58], where only indirect approaches were performed by near field scanning probes [19], laser scanning microscopy [22,23], or dispersive coupling to qubits [54].…”

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confidence: 99%

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Superconducting circuit optomechanics in topological lattices

Youssefi¹,

Kono²,

Bancora³

et al. 2021

Preprint

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“…Form the optomechanical damping rate, the unnormalized participation ratio η k i is experimentally obtained by Eq. (22). Using the relation described in Eq.…”

Section: A Samples Parametersmentioning

confidence: 99%

mentioning

confidence: 99%

Superconducting circuit optomechanics in topological lattices

Youssefi¹,

Kono²,

Bancora³

et al. 2021

Preprint

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“…We demonstrate non-trivial topological microwave modes in 1-D optomechanical chains as well as 2-D honeycomb lattices, realizing the canonical Su-Schrieffer-Heeger (SSH) model [16][17][18]. Exploiting the embedded optomechanical interaction, we show that it is possible to directly measure the mode functions of the bulk band modes, as well as the topologically protected edge states, without using any local probe [19][20][21] or inducing perturbation [22,23]. This enables us to reconstruct the full underlying lattice Hamiltonian beyond tight-binding approximations, and directly measure the existing residual disorder.…”

mentioning

confidence: 99%

“…Using the on-site optomechanical interactions, we are able to perform a direct measurement of the collective microwave mode shapes, reconstruct the full Hamiltonian of such multimode system beyond the tight-binding approximation, and demonstrate exceptionally low disorder in our devices. Such optomechanical mode shape measurements equally addresses an experimental challenge in large-scale multimode superconducting circuits as a platform for quantum simulation [55][56][57] and many-body physics studies [12,13,58], where only indirect approaches were performed by near field scanning probes [19], laser scanning microscopy [22,23], or dispersive coupling to qubits [54].…”

mentioning

confidence: 99%

Superconducting circuit optomechanics in topological lattices

Kippenberg

Youssefi

Bancora

et al. 2022

Preprint

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Cavity optomechanics enables controlling mechanical motion via radiation pressure interaction [1–3], and has contributed to the quantum control of engineered mechanical systems ranging from kg scale LIGO mirrors to nano-mechanical systems, enabling entanglement [4, 5], squeezing of mechanical objects [6], to position measurements at the standard quantum limit [7], non-reciprocal [8] and quantum transduction [9]. Yet, nearly all prior schemes have employed single- or few-mode optomechanical systems. In contrast, novel dynamics and applications are expected when utilizing optomechanical arrays and lattices [10], which enable to synthesize non-trivial band structures, and have been actively studied in the field of circuit QED [11–14]. Superconducting microwave optomechanical circuits are a promising platform to implement such lattices [15], but have been compounded by strict scaling limitations. Here we overcome this challenge and realize superconducting circuit optomechanical lattices. We demonstrate non-trivial topological microwave modes in 1-D optomechanical chains as well as 2-D honeycomb lattices, realizing the canonical SuSchrieffer-Heeger (SSH) model [16–18]. Exploiting the embedded optomechanical interaction, we show that it is possible to directly measure the mode functions of the bulk band modes, as well as the topologically protected edge states, without using any local probe [19–21] or inducing perturbation [22, 23]. This enables us to reconstruct the full underlying lattice Hamiltonian beyond tight-binding approximations, and directly measure the existing residual disorder. The latter is found to be sufficiently small to observe fully hybridized topological edge modes. Such optomechanical lattices, accompanied by the measurement techniques introduced, of-fers an avenue to explore out of equilibrium physics in optomechanical lattices such as quan-tum [24] and quench [25] dynamics, topological properties [10, 26, 27] and more broadly, emergent nonlinear dynamics in complex optomechanical systems with a large number of degrees of freedoms [28–31].

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“…In this manuscript, we use a laser scanning imaging technique in order to map the spatial distribution of the resonant modes across the lattice. This technique is similar to the laser scanning microscopy developed to observe the current density in superconductor films [14] and has already been used to characterize single a superconducting resonator [15,16] or coupled resonators [17]. It is an alternative to the scanning technique developed in [9].…”

mentioning

confidence: 99%

Observation of topological valley Hall edge states in honeycomb lattices of superconducting microwave resonators

Morvan

Féchant

Aiello

et al. 2021

Opt. Mater. Express

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We have realized different honeycomb lattices for microwave photons in the 4 to 8 GHz band using superconducting spiral resonators. Each lattice comprises a few hundred sites. Two designs have been studied, one leading to two bands touching at the Dirac points and one where a gap opens at the Dirac points. Using a scanning laser technique to image the eigenmodes of this new type of photonic lattices, we are able to reconstruct their band structure. The measured bands are in excellent agreement with ab initio models that combine numerical simulations of the electromagnetic properties of the spiral resonator and analytical calculations.

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Mode Structure in Superconducting Metamaterial Transmission-Line Resonators

Cited by 26 publications

References 53 publications

Superconducting circuit optomechanics in topological lattices

Superconducting circuit optomechanics in topological lattices

Superconducting circuit optomechanics in topological lattices

Observation of topological valley Hall edge states in honeycomb lattices of superconducting microwave resonators

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