Silver Migration in Electrical Insulation

Kohman, G. T.; Hermance, H. W.; Downes, G. H.

doi:10.1002/j.1538-7305.1955.tb03793.x

Cited by 165 publications

(66 citation statements)

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“…Under otherwise identical conditions, a higher current led to a filament with larger diameter and hence lower resistance; however, this may also increase the energy required for programming. The filament formation initiates from the silver side, consistent with the electrochemical reaction mechanism [30][31][32] . However, previously reported devices with a similar structure but a larger gap size had considerably higher resistance because, rather than a continuous metal filament, isolated metal islands were formed between the electrodes 28,31 .…”

Section: Resultssupporting

confidence: 71%

Nanoscale memristive radiofrequency switches

et al. 2015

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Radiofrequency switches are critical components in wireless communication systems and consumer electronics. Emerging devices include switches based on microelectromechanical systems and phase-change materials. However, these devices suffer from disadvantages such as large physical dimensions and high actuation voltages. Here we propose and demonstrate a nanoscale radiofrequency switch based on a memristive device. The device can be programmed with a voltage as low as 0.4 V and has an ON/OFF conductance ratio up to 10 12 with long state retention. We measure the radiofrequency performance of the switch up to 110 GHz and demonstrate low insertion loss (0.3 dB at 40 GHz), high isolation (30 dB at 40 GHz), an average cutoff frequency of 35 THz and competitive linearity and power-handling capability. Our results suggest that, in addition to their application in memory and computing, memristive devices are also a leading contender for radiofrequency switch applications.

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Section: Resultssupporting

confidence: 71%

Nanoscale memristive radiofrequency switches

et al. 2015

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“…In metals, ECM involves the movement and precipitation of metallic atoms of electrodes in contact with an insulating material, inside and at the surface of the insulating material (Kohman et al, 1955 andFujishiro et al, 2007). The existence of water between the electrodes is a key factor.…”

Section: Theoretical Backgroundmentioning

confidence: 99%

Enhanced fabrication of hybrid Cu-Cu<sub>2</sub>O nanostructures on electrodes using electrochemical migration

Fukaya

Aoki

Kimura

et al. 2018

Mechanical Engineering Letters

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Cu, Cu2O and CuO nanostructures have characteristic physical properties, and are used in a variety of fields such as lithium ion batteries, solar batteries and gas sensors. Recently, various techniques for the nanostructures fabrication have been studied for these applications. It has been reported that electrochemical migration (ECM) causes insulation deterioration on the printed circuit boards in high-humidity and high-temperature conditions. Previous investigations of the suppression of ECM revealed that eluted Cu ions grew as dendrites. A considerable number of studies have investigated the suppression of ECM, but the beneficial use of ECM has not been studied extensively. The use of ECM has become the subject of increasing interest because ECM is a low-cost and green fabrication technique, and the reaction requires only DC voltage and water without any metal salts and hydroxides. Some attempts have been made to fabricate hybrid Cu-Cu2O nanostructures using ECM. However, it has been reported that the growth of dendrites between electrodes ceases because the dendrites create a shortcircuit. Thus, proper fabrication has not yet been achieved. This study aimed to enhance the fabrication of hybrid Cu-Cu2O nanostructures using ECM. In this study, we changed the path length of the dendrites' growth, and improved the fabrication process through evaluation of the results.

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“…CFF is an electrochemical process that involves the transport (usually ionically) of a metal through or across a non-metallic medium under the influence of an applied electric field [69][70][71]. CFF is a potential reliability problem, in that it can cause current leakage, dielectric breakdown and electrical shorts between conductors.…”

Section: Conductive Filament Formationmentioning

confidence: 99%

Power Modulation Investigation for High Temperature (175-200 degrees Celcius) Automotive Application

McCluskey¹

2007

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Silver Migration in Electrical Insulation

Cited by 165 publications

References 0 publications

Nanoscale memristive radiofrequency switches

Nanoscale memristive radiofrequency switches

Enhanced fabrication of hybrid Cu-Cu<sub>2</sub>O nanostructures on electrodes using electrochemical migration

Power Modulation Investigation for High Temperature (175-200 degrees Celcius) Automotive Application

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