Nb 9-Layer Fabrication Process for Superconducting Large-Scale SFQ Circuits and Its Process Evaluation

Nagasawa, Shuichi; Hinode, K.; Satoh, T.; Hidaka, Mutsuo; Akaike, Hiroyuki; Fujimaki, Akira; Yoshikawa, Nobuyuki; Takagi, Kazuyoshi; Takagi, Naofumi

doi:10.1587/transele.e97.c.132

Cited by 139 publications

(59 citation statements)

References 17 publications

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“…Also, by virtue of recent developments in fabrication technology with a multi-layered structure [13], [14] and some energy-efficient circuit technology [15]- [19], several research projects on SFQ microprocessors have been undertaken [20], [21], and an 8-bit microprocessor composed of more than 10,000 Josephson junctions successfully operates at 50 GHz [7]. In addition, inventions of several novel superconductor devices based on new physical phenomena have made the SFQ logic technology much more attractive, e.g., superconductor junctions with one or more ferromagnet layers show different electrical characteristics depending on the magnetic states, by which we can obtain high-density, low-power, cryogenic memory compatible with SFQ circuits [22], [23].…”

Section: Sfq Circuitsmentioning

confidence: 99%

Towards Ultra-High-Speed Cryogenic Single-Flux-Quantum Computing

Ishida

Tanaka

Ono

et al. 2018

IEICE Trans. Electron.

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SUMMARYCMOS microprocessors are limited in their capacity for clock speed improvement because of increasing computing power, i.e., they face a power-wall problem. Single-flux-quantum (SFQ) circuits offer a solution with their ultra-fast-speed and ultra-low-power natures. This paper introduces our contributions towards ultra-high-speed cryogenic SFQ computing. The first step is to design SFQ microprocessors. From qualitatively and quantitatively evaluating past-designed SFQ microprocessors, we have found that revisiting the architecture of SFQ microprocessors and on-chip caches is the first critical challenge. On the basis of cross-layer discussions and analysis, we came to the conclusion that a bit-parallel gate-level pipeline architecture is the best solution for SFQ designs. This paper summarizes our current research results targeting SFQ microprocessors and onchip cache architectures.

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Section: Sfq Circuitsmentioning

confidence: 99%

Towards Ultra-High-Speed Cryogenic Single-Flux-Quantum Computing

Ishida

Tanaka

Ono

et al. 2018

IEICE Trans. Electron.

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“…Our DC SQUID sensor consists of two JJs, which were designed to have a junction area of each JJ of 2.2 m x 2.2 m and the critical current Ic of 12.5 A. It was reported that the typical variation in JJ critical currents is better than 2% [20]. In each single sensor, the pick-up coil is connected to a SQUID washer directly, which was covered fully by superconducting Nb film.…”

Section: Design To Fabricate Squid Sensormentioning

confidence: 99%

Vector sensor for scanning SQUID microscopy

Takeuchi

Huy

Miyajima

et al. 2017

J. Phys.: Conf. Ser.

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“…InductEx remains the only simulator other than Lmeter [5] that can handle full-gate superconductive circuit extractions. We discuss the background to 3D inductance extraction, and show how extraction models are constructed and used to find inductances, coupling and current distribution for circuit layouts in the AIST advanced process (ADP2) [13], [14] and standard process (STP2). We also discuss developments and refinements that were necessary to model ADP2 and STP2 layouts.…”

Section: Introductionmentioning

confidence: 99%

Inductance and Current Distribution Extraction in Nb Multilayer Circuits with Superconductive and Resistive Components

Fourie

Takeuchi

Yoshikawa

2016

IEICE Trans. Electron.

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SUMMARYWe describe a calculation tool and modeling methods to find self and mutual inductance and current distribution in superconductive multilayer circuit layouts. Accuracy of the numerical solver is discussed and compared with experimental measurements. Effects of modeling parameter selection on calculation results are shown, and we make conclusions on the selection of modeling parameters for fast but sufficiently accurate calculations when calibration methods are used. Circuit theory for the calculation of branch impedances from the output of the numerical solver is discussed, and compensation for solution difficulties is shown through example. We elaborate on the construction of extraction models for superconductive integrated circuits, with and without resistive branches. We also propose a method to calculate current distribution in a multilayer circuit with multiple bias current feed points. Finally, detailed examples are shown where the effects of stacked vias, bias pillars, coupling, ground connection stacks and ground return currents in circuit layouts for the AIST advanced process (ADP2) and standard process (STP2) are analyzed. We show that multilayer inductance and current distribution extraction in such circuits provides much more information than merely branch inductance, and can be used to improve layouts; for example through reduced coupling between conductors.

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Nb 9-Layer Fabrication Process for Superconducting Large-Scale SFQ Circuits and Its Process Evaluation

Cited by 139 publications

References 17 publications

Towards Ultra-High-Speed Cryogenic Single-Flux-Quantum Computing

Towards Ultra-High-Speed Cryogenic Single-Flux-Quantum Computing

Vector sensor for scanning SQUID microscopy

Inductance and Current Distribution Extraction in Nb Multilayer Circuits with Superconductive and Resistive Components

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