Study and design of resistive switching behaviors in PMMA-based conducting-bridge random-access memory (CBRAM) devices

IEEE Microw. Wireless Compon. Lett.

Meghit

et al. 2017

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This letter reports the design and development of a Conductive Bridging RF-Switch with simple fabrication steps without the use of any clean room technologies. The reported device is a fully passive shunt mode RF-Switch on a Co-Planar Waveguide (CPW) transmission line, which operates in the DC to 3GHz range. This particular topology is chosen in contemplation to limitations imposed by the chosen realization process. The device is based on a Metal-Insulator (electrolyte)-Metal (MIM) structure, with Copper-Nafion ®-Aluminum switching layers. S21 switching between-1dB (RF-On) and-16dB (RF-Off) is demonstrated till 3GHz by the device. DC pulses in the range 18V/0.5mA and-20V/0.1A are used respectively to SET and RESET the switch, and the instantaneous power consumed for SET and RESET is respectively 1.7µW and 3mW. The SET and RESET state DC resistance of the switch are observed as 2Ω and 2MΩ subsequently. The model is initially simulated using commercial FEM based Electromagnetic modeling tool and validated experimentally.

Section: Discussionmentioning

confidence: 73%

“…1 is the fundamental switching element of the CBRAM switching technology. The Insulator layer is a solid electrolyte, like common synthetic resin [7], [8] and one of the electrodes is an electrochemically active metal like copper or silver and the other is a relatively inert metal like aluminum or gold.…”

Section: Motivation and Overviewmentioning

confidence: 99%

Nafion-Based Fully Passive Solid-State Conductive Bridging RF Switch

IEEE Microw. Wireless Compon. Lett.

Meghit

et al. 2017

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“…In black and white, non-volatility gives a special contrast to this switching technology in comparison to classic RF switches like MEMS or semiconductor solutions like PIN and Varactors. The possible list of ion-conductors for MIM applications include materials like chalcogenide glass [7], Hafnium dioxide [8], mouldable polymers like PMMA [9], Nafion [10] and even an air gap with precisely controlled electrode spacing [6]. Recent literature on MIM switches using in house fabrication techniques, reports >2000 cycles of operation [9], which is quite an acceptable number at the budding stage of a technology.…”

Section: Introductionmentioning

confidence: 99%

“…The possible list of ion-conductors for MIM applications include materials like chalcogenide glass [7], Hafnium dioxide [8], mouldable polymers like PMMA [9], Nafion [10] and even an air gap with precisely controlled electrode spacing [6]. Recent literature on MIM switches using in house fabrication techniques, reports >2000 cycles of operation [9], which is quite an acceptable number at the budding stage of a technology. CBRAM or MIM switch is identified to have more versatility of application, and lesser complexities in terms of ease of fabrication in comparison to other members of the PMC family like the phase change memory (PCM) [11,12] devices.…”

Section: Introductionmentioning

confidence: 99%

Investigation of integrated solid state nano‐ionic metal–insulator–metal switches for electronically reconfigurable band‐stop filter applications

IET Microwaves, Antennas & Propagation

Sorli

et al. 2019

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A proof of concept of application of Nano-Ionic Conductive-Bridging Metal-Insulator-Metal (MIM) switches in electronically reconfigurable band stop filters, through design, and experimental results are presented in this article. Two similar designs of band stop filters with different mechanism of operation are proposed herewith. One is a microstrip, resonant open stub based band stop filter and the other is a microstrip tuned shorted stub based band stop filter. Electrical length of the stubs in both these devices are tuned by an integrated MIM switch forcing them to resonate at different frequencies and thus achieving electronically switchable band stop filtering characteristics. Working mechanism of the devices is validated with the help of developed electrical equivalent circuit models. Analysis on time stability of switch states for 1000 minutes with affirmative results is also presented herewith. These devices are fabricated without any soldered electrical components and without the use of any clean room technologies, using proven low cost method, and are promising to work at very-low power and have the potential to be directly printed on low cost flexible substrates like paper, for potential disposable applications.

“…The CBRAM RF switch is based on a Metal-Insulator-Metal structure as shown in Fig. 1 where the Insulator layer is a solid electrolyte like common synthetic resin [6,7]and one of the electrode is an electrochemically active metal like copper or silver and the other is a relatively inert metal like aluminum or gold. The switching action is obtained by applying electric field of sufficient voltage to establish a metallic link between the two electrodes through the electrolyte, and by dissolving this link using an electric field of opposite polarity, to establish the SET and RESET states respectively, as shown in the Fig.…”

Section: Introductionmentioning

confidence: 99%

Fully passive conductive-bridging solid state RF switch

2017 XXXIInd General Assembly and Scientific Symposium of the International Union of Radio Science (URSI GASS)

Sorli

et al. 2017

Self Cite

This study reports the design and experimental results of a fully-passive solid-state RF switch based on the Conductive Bridging Memory Technology, popularly known as CBRAM. The developed device is a shunt mode RF switch based on a Metal-Insulator-Metal (MIM) structure with Copper-Nafion-Aluminum switching layers on a Coplanar Waveguide (CPW) transmission line, operational in the DC to 3GHz range. DC pulses in the range +12V to-20V are used to operate the switch. The design is initially simulated using the FEM based CST microwave Studio and then realized and validated on a low cost FR4 substrate, and without using any sophisticated clean room technology.