Synthesis and memory performance of a conjugated polymer with an integrated fluorene, carbazole and oxadiazole backbone

Chen

2020

Polymer International

Self Cite

In the era of information explosion, silicon‐based storage can barely meet the burgeoning demand for data storage and making Moore's law no longer accurate. What is more, the traditional von Neumann architecture separates the computing module from the storage unit, which causes a slowing down of the overall computing efficiency. Conjugated polymer memristors, due to the advantages of simple fabrication, convenient operation and low cost, are considered as promising candidates for next‐generation memory and neuromorphic computing applications. This review summarizes the advances in conjugated polymer memristive materials and devices made during the first two decades of the 21st century, and their potential applications in information storage and neuromorphic computing. Focuses are on switching mechanisms and materials classifications, as well as memory, artificial synapse and bioinspired and in‐memory computing performance. © 2020 Society of Chemical Industry

Section: Operating Principle Of Conjugated Polymer Memristorsmentioning

confidence: 99%

Section: Conjugated Memristive Polymers For Data Storage Memoriesmentioning

confidence: 99%

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Conjugated polymers for information storage and neuromorphic computing

Chen

2020

Polymer International

Self Cite

“…In particular, the solution processing capability of organic materials allows them to be handled via dip coating, blade casting, spray coating, spin coating, rollercoating and even ink-jet printing, not only making the more elaborated processes of vacuum deposition of functional thin films eliminable, but allowing the fabrication of flexible memory chips. Extensive studies have been performed on the resistance switching in organic materials, wherein focus has been concentrated on the development of novel materials for memory performance [28][29][30][31][32][33][34][35] optimization.…”

Section: Resistive Switching Mechanisms In Organic Materialsmentioning

confidence: 99%

“…By incorporating both electron donating (D) and accepting (A) moieties into the chemical structure, a series of electroactive polymer materials exhibiting resistive switching behaviors have been [28][29][30][31][32][33] synthesized successfully.…”

Section: Resistive Switching Mechanisms In Organic Materialsmentioning

confidence: 99%

Recent Advances in Resistive Switching Materials and Devices: From Memories to Memristors

Liu¹,

Chen²,

Gao³

et al. 2018

Eng. Sci.

Self Cite

Resistive switching devices have not only been considered as an emerging candidate for the next generation information storage technology, but also demonstrated great potential for in-memory computing systems with greatly enhanced computation capability. This review focuses on the recent advances in resistive materials and devices. We first describe the electric field-induced filamentary conduction model that accounts for the resistive switching behavior observed in inorganic materials, as well as the novel electric field-engineering strategy that is used to optimize the device structure and the memory performance. The alternative ways of using organic and hybrid materials to construct resistive switching devices are then illustrated. By tuning the charge transfer interaction and solid state electrochemical redox properties in small molecules, polymer, metal-organic framework and organic-inorganic hybrid perovskite materials, bistable and multibit memories, as well as the biomimicking memristors have been fabricated. Finally, we discuss the future development of the resistive switching materials and devices, aiming to clarifying the key issues that hinders its practical applications.

Journal of Polymer Science

Realizing fast photoinduced recovery with polyfluorene‐block‐poly(vinylphenyl oxadiazole) block copolymers as electret in photonic transistor memory devices

Ercan

Lin

Chen

et al. 2021

Photonic field-effect transistor (FET) memory devices offer unique advantages owing to their solution processability, low cost production, and their lightweight and structural flexibility. Despite the plethora of research demonstrated the photon based programming process, limited reports are available for photoinduced recovery mechanism in such devices. To investigate the influence of polymer electret design on photonic memory performance, poly(9,9-dioctylfluorene) (PFO)block-poly (vinylphenyl oxadiazole) (POXD) conjugated block copolymers were employed to a photonic FET memory with n-type semiconducting channel. The studied device exhibited bistable ON/OFF current states after electrical programming and photoinduced recovery (erasing) processes. The device operating mechanism was elaborated by comparing the device performance with respective electrets of PFO-b-POXD and PFO-b-polystyrene (PS) and PFO homopolymer. We found that PFO-b-POXD can efficiently generate photoexciton under UV illumination to neutralize the trapped hole, and assuage the hole trapping propensity of PFO segment, simultaneously. By optimizing the POXD content in the block copolymer, a decent memory ratio (I ON /I OFF ) of ~10 5 was achieved after 10 4 s, indicating its superior long-term stability and data discernibility. This research shows the judicious strategy to design polymer electret for photonic memory, and it opens up the possibility of developing photonic memory, human perception and futuristic communication systems using simple, convenient and reliable optoelectronic technique.