Noble‐Metal‐Free Memristive Devices Based on IGZO for Neuromorphic Applications

Pereira, Maria; Deuermeier, Jonas; Nogueira, R.P.; Carvalho, Patrícia Almeida; Martins, Rodrigo; Fortunato, Elvira

doi:10.1002/aelm.202000242

Cited by 36 publications

(44 citation statements)

References 59 publications

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“…An alternative is area-scaling devices with built-in rectification, which operate through barrier modulation. In the area-scaling mode, the set operation typically happens in the forward direction of the diode and allows the rectification to be maintained [26][27][28]. The saturation current is most effectively suppressed in the case of high barriers [29][30][31][32].…”

Section: Introductionmentioning

confidence: 99%

Reversible Barrier Switching of ZnO/RuO2 Schottky Diodes

et al. 2021

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Section: Introductionmentioning

confidence: 99%

Reversible Barrier Switching of ZnO/RuO2 Schottky Diodes

et al. 2021

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“…As an example, retention loss that mimics the dynamics of biological memory is beneficial for artificial neural network applications. [ 345 ] Furthermore, a large on/off ratio is not a main concern for some neuromorphic applications. [ 339 ] However, low endurance is a limitation for computation and in memory logics, which require frequent alteration of the resistance states.…”

Section: Figures Of Merit and Current Challenges Of S‐rrammentioning

confidence: 99%

Recent Progress in Solution‐Based Metal Oxide Resistive Switching Devices

et al. 2020

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Metal oxide resistive switching memories have been a crucial component for the requirements of the Internet of Things, which demands ultra‐low power and high‐density devices with new computing principles, exploiting low cost green products and technologies. Most of the reported resistive switching devices use conventional methods (physical and chemical vapor deposition), which are quite expensive due to their up‐scale production. Solution‐processing methods have been improved, being now a reliable technology that offers many advantages for resistive random‐access memory (RRAM) such as high versatility, large area uniformity, transparency, low‐cost and a simple fabrication of two‐terminal structures. Solution‐based metal oxide RRAM devices are emergent and promising non‐volatile memories for future electronics. In this review, a brief history of non‐volatile memories is highlighted as well as the present status of solution‐based metal oxide resistive random‐access memory (S‐RRAM). Then, a focus on describing the solution synthesis parameters of S‐RRAMs which induce a massive influence in the overall performance of these devices is discussed. Next, a precise analysis is performed on the metal oxide thin film and electrode interface and the recent advances on S‐RRAM that will allow their large‐area manufacturing. Finally, the figures of merit and the main challenges in S‐RRAMs are discussed and future trends are proposed.

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“…When taking neuromorphic applications such as pattern recognition into account, it was shown that a better accuracy is achieved due to a lower random telegraphic noise of area-dependent memristors, compared to filamentary systems [11]. Besides that, by applying AOS-based material as the resistive switching material, flexible and transparent substrates such as plastic or paper can be used due to low processing temperatures and conventional patterning methods [12], which are great advantages for applications such as IoT. The most prominent AOS material in recent literature has been indium-galliumzinc oxide (IGZO) [12][13][14].…”

Section: Introductionmentioning

confidence: 99%

“…Besides that, by applying AOS-based material as the resistive switching material, flexible and transparent substrates such as plastic or paper can be used due to low processing temperatures and conventional patterning methods [12], which are great advantages for applications such as IoT. The most prominent AOS material in recent literature has been indium-galliumzinc oxide (IGZO) [12][13][14]. This material has shown synaptic operations which can be applied for both computing paradigms of deep neural networks (DNNs) and spiking neural networks (SNNs).…”

Section: Introductionmentioning

confidence: 99%

Towards Sustainable Crossbar Artificial Synapses with Zinc-Tin Oxide

Silva

Martins

Deuermeier

et al. 2021

Electronic Materials

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In this article, characterization of fully patterned zinc-tin oxide (ZTO)-based memristive devices with feature sizes as small as 25 µm2 is presented. The devices are patterned via lift-off with a platinum bottom contact and a gold-titanium top contact. An on/off ratio of more than two orders of magnitude is obtained without the need for electroforming processes. Set operation is a current controlled process, whereas the reset is voltage dependent. The temperature dependency of the electrical characteristics reveals a bulk-dominated conduction mechanism for high resistance states. However, the charge transport at low resistance state is consistent with Schottky emission. Synaptic properties such as potentiation and depression cycles, with progressive increases and decreases in the conductance value under 50 successive pulses, are shown. This validates the potential use of ZTO memristive devices for a sustainable and energy-efficient brain-inspired deep neural network computation.

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Noble‐Metal‐Free Memristive Devices Based on IGZO for Neuromorphic Applications

Cited by 36 publications

References 59 publications

Reversible Barrier Switching of ZnO/RuO2 Schottky Diodes

Reversible Barrier Switching of ZnO/RuO2 Schottky Diodes

Recent Progress in Solution‐Based Metal Oxide Resistive Switching Devices

Towards Sustainable Crossbar Artificial Synapses with Zinc-Tin Oxide

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