Implementation of superconductive passive phase shifters in high-speed integrated RSFQ digital circuits

Dimov, B.; Balashov, D; Khabipov, M.; Ortlepp, T.; Buchholz, F.-I.; Zorin, A. B.; Niemeyer, J.; Uhlmann, Friedrich

doi:10.1088/0953-2048/21/4/045007

Cited by 10 publications

(13 citation statements)

References 11 publications

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“…It is anticipated that unconventional junctions either with a fixed phase shift ϕ 0 (ϕ-junctions), or with an in-built spatial phase variation along the junction ∆ϕ (0 − ϕ junctions) may provide additional functionality in Josephson electronics [1][2][3][4]. For example, they can operate as autonomous and persistent phase batteries -one of key elements of quantum [1,[5][6][7][8][9][10][11][12][13][14] and digital Josephson electronics [2,3,15,16]. Such junctions can be also used for development of novel types of cryogenic memory [17][18][19][20][21][22].…”

Section: Introductionmentioning

confidence: 99%

“…Such junctions can be also used for development of novel types of cryogenic memory [17][18][19][20][21][22]. The π-phase shift is most commonly needed, e.g., for bringing the flux-qubit to the degeneracy point [1,[5][6][7], for realization of complementary digital Josephson electronics [2,3,15,16] and for maximum distinction between 0 and 1 state in a memory cell [17].…”

Section: Introductionmentioning

confidence: 99%

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Two mechanisms of Josephson phase shift generation by an Abrikosov vortex

2019

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Abrikosov vortex contains magnetic field and circulating currents that decay at a short range λ ∼ 100 nm. However, the vortex can induce a long range Josephson phase shift at distances r ∼ µm λ. The mechanism of this puzzling phenomenon is not clearly understood. Here we present a systematic study of vortex-induced phase shift in planar Josephson junctions. We make two key observations: (i) The cutoff effect: although vortexinduce phase shift is a long-range phenomenon, it is terminated by the junction and does not persists beyond it. (ii) A crossover from linear to superlinear dependence of the phase shift on the vortex polar angle occurs upon approaching of the vortex to the junction. The crossover occurs at a distance comparable with the penetration depth. This, together with theoretical and numerical analysis of the problem, allows unambiguous identification of two distinct and independent mechanisms. The short range mechanism is due to circulating vortex currents inside superconducting electrodes without involvement of magnetic field. The long range mechanism is due to stray magnetic fields outside electrodes without circulating vortex currents. We argue that understanding of controlling parameters of vortex-induced Josephson phase shift can be used for development of compact and fast electronic devices with low dissipation power.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Two mechanisms of Josephson phase shift generation by an Abrikosov vortex

2019

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“…Josephson junctions [45][46][47][48][49]. Even for conventional RSFQ circuits, the improved operational margins, bit-error rates, and gate memory non-volatility were reported [50][51][52][53].…”

Section: Magnetically Biased Esfq Shift Register (Mesr)mentioning

confidence: 99%

Implementation of energy efficient single flux quantum digital circuits with sub-aJ/bit operation

Volkmann

Sahu

Fourie

et al. 2012

Supercond. Sci. Technol.

137

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We report the first experimental demonstration of recently proposed energy-efficient single flux quantum logic, eSFQ. This logic can represent the next generation of RSFQ logic eliminating dominant static power dissipation associated with a dc bias current distribution and providing over two orders of magnitude efficiency improvement over conventional RSFQ logic. We further demonstrate that the introduction of passive phase shifters allows the reduction of dynamic power dissipation by about 20%, reaching ~0.8 aJ per bit operation. Two types of demonstration eSFQ circuits, shift registers and demultiplexers (deserializers), were implemented using the standard HYPRES 4.5 kA/cm 2 fabrication process. In this paper, we present eSFQ circuit design and demonstrate the viability and performance metrics of eSFQ circuits through simulations and experimental testing.

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“…Similar phase shifters have been used for digital RSFQ electronics. 14 , 15 Recently it was shown that an Abrikosov vortex can induce a JPS in nearby JJs in the full [−2π, + 2π] range. 23 , 43 , 44 Since vortices can be easily manipulated (displaced, introduced, or removed) by magnetic field, H , 23 , 45 − 47 current, I , 20 , 48 , 49 and light, 50 , 51 they can be used for creation of memory cells 20 and tunable phase shifters.…”

Section: Introductionmentioning

confidence: 99%

Reconfigurable Josephson Phase Shifter

et al. 2021

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Phase shifter is one of the key elements of quantum electronics. In order to facilitate operation and avoid decoherence, it has to be reconfigurable, persistent, and nondissipative. In this work, we demonstrate prototypes of such devices in which a Josephson phase shift is generated by coreless superconducting vortices. The smallness of the vortex allows a broad-range tunability by nanoscale manipulation of vortices in a micron-size array of vortex traps. We show that a phase shift in a device containing just a few vortex traps can be reconfigured between a large number of quantized states in a broad [−3π, +3π] range.

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Implementation of superconductive passive phase shifters in high-speed integrated RSFQ digital circuits

Cited by 10 publications

References 11 publications

Two mechanisms of Josephson phase shift generation by an Abrikosov vortex

Two mechanisms of Josephson phase shift generation by an Abrikosov vortex

Implementation of energy efficient single flux quantum digital circuits with sub-aJ/bit operation

Reconfigurable Josephson Phase Shifter

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