Planar superconducting resonators with internal quality factors above one million

Megrant, A.; Neill, C.; Barends, R.; Chiaro, B.; Chen, Yu; Feigl, Ludwig; Kelly, J.; Lucero, Erik; Mariantoni, M.; O’Malley, P.; Sank, D.; Vainsencher, A.; Wenner, J.; White, Theodore C.; Yin, Yi; Jie, Zhao; Palmstrøm, C. J.; Martinis, John M.; Cleland, A. N.

doi:10.1063/1.3693409

Cited by 430 publications

(399 citation statements)

References 15 publications

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“…We fabricated the resonators from an aluminum film deposited on a highresistivity silicon subtrate and etched with a BCl 3 /Cl 2 inductively coupled plasma. 19 We have also used the process on a sapphire substrate with comparable results. We designed the resonators with 10 µm center traces and 5 µm gaps to match the dimensions of our typical feedlines, and designed the resonant frequencies to range from 5 to 6 GHz.…”

Section: Internal Quality Factormentioning

confidence: 98%

“…We determined Q i by measuring the transmission through a feedline that was capacitively coupled to each resonator (see Ref. 19 for measurement details). We varied the drive power such that the photon population n p in the resonator ranged from single photon levels up to 10 7 photons, at which point the resonators became non-linear.…”

Section: Internal Quality Factormentioning

confidence: 99%

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Fabrication and characterization of aluminum airbridges for superconducting microwave circuits

Chen

Megrant

Kelly

et al. 2014

Applied Physics Letters

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123

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Superconducting microwave circuits based on coplanar waveguides (CPW) are susceptible to parasitic slotline modes which can lead to loss and decoherence. We motivate the use of superconducting airbridges as a reliable method for preventing the propagation of these modes. We describe the fabrication of these airbridges on superconducting resonators, which we use to measure the loss due to placing airbridges over CPW lines. We find that the additional loss at single photon levels is small, and decreases at higher drive powers.Superconducting coplanar waveguide (CPW) transmission lines and resonators are integral components of cryogenic detectors for submillimeter electromagnetic radiation, 1,2 quantum memory elements, 3 and solid state quantum computing architectures. [4][5][6] The desired mode profile of a CPW is symmetric, 7 with the two ground planes on either side of the center trace held to the same voltage. However, asymmetries and discontinuities in the microwave circuitry can lead to the excitation of parasitic slotline modes. 8 These modes can couple to elements of the circuit such as qubits, and they represent a source of radiation loss and decoherence. 9,10 In order to suppress these spurious modes, crossover connections need to be made between the ground planes that are interrupted by the CPW structure. Free standing crossovers, known as airbridges, have been a staple of conventional microwave CPW technology, 11,12 and fabrication processes have recently been developed for building airbridges on superconducting microwave circuits. 13,14 However, the fabrication of airbridges adds additional processing that may degrade the quality of the circuit, and the airbridges themselves may present a source of loss. In addition, care must be taken in order to avoid accidentally creating tunnel junctions with small critical currents at the interfaces of such structures. In this Letter, we present the first characterizations of the loss due to fabricating airbridge crossovers on superconducting microwave resonators. We find that the loss due to airbridge crossovers is small but not negligible, and should be taken into account when engineering crossovers for low loss circuit elements.To motivate our use of airbirdges, we observe that in past work with superconducting circuits, connections between the different ground planes have been typically been made using wirebonds. However, with a wire diameter of 1 mil and a typical length of 1 mm, wirebonds have an inductance of order 1 nH 15 and an impedance 40 Ω at 6 GHz, making them an ineffective shunt. In comparison, airbridges have 100 times less inductance due to their small size. In order to understand the effect of the crossover impedance on slotline attenuation, we studied a simple transmission line model 16 for the slotline with evenly spaced inductive shunts to ground as shown in Fig. 1(a). We simulated in SPICE 1 mm of a transmission line with with a terminated load, and varied the number of inductive shunts. As seen in Fig. 1, the attenuation per millimeter of t...

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Section: Internal Quality Factormentioning

confidence: 98%

Section: Internal Quality Factormentioning

confidence: 99%

Fabrication and characterization of aluminum airbridges for superconducting microwave circuits

Chen

Megrant

Kelly

et al. 2014

Applied Physics Letters

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123

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“…The device is made in a fivestep deposition process, (I) Al deposition and control wiring etch, (II) crossover dielectric deposition, (III) crossover Al deposition, (IV) Qubit capacitor and resonator etch, (V) Josephson junction deposition. The qubit capacitor, ground plane, readout resonators, and control wiring are made using molecular beam epitaxy (MBE)-grown Al on sapphire [3]. The control wiring is patterned using lithography and etching with a BCl 3 /Cl 2 reactive ion etch.…”

Section: Supplementary Information Device Fundamentals Fabricationmentioning

confidence: 99%

“…A quantum computer can solve hard problems -such as prime factoring 1,2 , database searching 3,4 , and quantum simulation 5 -at the cost of needing to protect fragile quantum states from error. Quantum error correction 6 provides this protection, by distributing a logical state among many physical qubits via quantum entanglement.…”

mentioning

confidence: 99%

“…The CZ gate fidelity is limited by three error mechanisms: Decoherence (55% of the total error), control error (24%), and state leakage (21%), see Supplementary Information. Decoherence can be suppressed with enhanced materials and optimised fabrication 24,25 . Imperfections in control arise primarily from reflections and stray inductances in wiring, and can be improved using conventional microwave techniques.…”

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confidence: 99%

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Superconducting quantum circuits at the surface code threshold for fault tolerance

Barends

Kelly

Megrant

et al. 2014

Nature

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A quantum computer can solve hard problems -such as prime factoring 1,2 , database searching 3,4 , and quantum simulation 5 -at the cost of needing to protect fragile quantum states from error. Quantum error correction 6 provides this protection, by distributing a logical state among many physical qubits via quantum entanglement. Superconductivity is an appealing platform, as it allows for constructing large quantum circuits, and is compatible with microfabrication. For superconducting qubits the surface code 7 is a natural choice for error correction, as it uses only nearest-neighbour coupling and rapidly-cycled entangling gates. The gate fidelity requirements are modest: The per-step fidelity threshold is only about 99%. Here, we demonstrate a universal set of logic gates in a superconducting multi-qubit processor, achieving an average single-qubit gate fidelity of 99.92% and a two-qubit gate fidelity up to 99.4%. This places Josephson quantum computing at the fault-tolerant threshold for surface code error correction. Our quantum processor is a first step towards the surface code, using five qubits arranged in a linear array with nearest-neighbour coupling. As a further demonstration, we construct a five-qubit GreenbergerHorne-Zeilinger (GHZ) state 8,9 using the complete circuit and full set of gates. The results demonstrate that Josephson quantum computing is a high-fidelity technology, with a clear path to scaling up to large-scale, fault-tolerant quantum circuits.The high fidelity performance we demonstrate here is achieved through a combination of highly coherent qubits, a straightforward interconnection architecture, and a novel implementation of the two-qubit controlled-phase (CZ) entangling gate. The CZ gate uses a fast but adiabatic frequency tuning of the qubits 10 , which is easily adjusted yet minimises decoherence and leakage from the computational basis [Martinis, J., et al., in preparation]. We note that previous demonstrations of two-qubit gates achieving better than 99% fidelity used fixed-frequency qubits: Systems based on nuclear magnetic resonance and ion traps have shown two-qubit gates with fidelities of 99.5% 11 and 99.3% 12 . Here, the tuneable nature of the qubits and their entangling gates provides, remarkably, both high fidelity and fast control.Superconducting integrated circuits give flexibility in building quantum systems due to the macroscopic nature of the electron condensate. As shown in Fig. 1, we have designed a processor consisting of five Xmon qubits with nearestneighbour coupling, arranged in a linear array. The crossshaped qubit 14 offers a nodal approach to connectivity while maintaining a high level of coherence (see Supplementary Information for decoherence times). Here, the four legs of the cross allow for a natural segmentation of the design into coupling, control and readout. We chose a modest inter-qubit capacitive coupling strength of g/2π = 30 MHz and use alternating qubit idle frequencies of 5.5 and 4.7 GHz, enabling a CZ gate in 40 ns when two qubits are brough...

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Advanced Superconducting Circuits and Devices

Weides

Rotzinger

2016

Digital Encyclopedia of Applied Physics

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The article contains sections titled: Introduction Field‐Effect Devices Quantum Information Circuits Metamaterials at Microwave Frequencies Quantum Phase Slip Novel Quantum Circuits Quantum‐Limited Measurements: Microwave Parametric Amplifiers

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Planar superconducting resonators with internal quality factors above one million

Cited by 430 publications

References 15 publications

Fabrication and characterization of aluminum airbridges for superconducting microwave circuits

Fabrication and characterization of aluminum airbridges for superconducting microwave circuits

Superconducting quantum circuits at the surface code threshold for fault tolerance

Advanced Superconducting Circuits and Devices

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