Synaptic learning behaviors achieved by metal ion migration in a Cu/PEDOT:PSS/Ta memristor

Luo, Wenqiang; Yuan, Fangyuan; Wu, Huaqiang; Pan, Liyang; Deng, Ning; Zeng, Fei; Wei, Rongshan; Cai, Xuanjing

doi:10.1109/nvmts.2015.7457490

Cited by 3 publications

(6 citation statements)

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“…One of the justifications provided for doing so is the chalcogenide-based memristor's ultra-fast switching speeds, which allow for processes like STDP to take place at nanosecond scale [97]. Polymer-based memristors have been used because of their inexpensive cost and adjustable performance [68,[103][104][105][106][107][108][109][110][111]. There have also been suggestions for organic memristors, which include organic polymers [69, [112-123].…”

Section: Materials and Devicesmentioning

confidence: 99%

Neuromorphic Computing between Reality and Future Needs

Ahmed¹,

Shereif²

2023

Artificial Intelligence

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Neuromorphic computing is a one of computer engineering methods that to model their elements as the human brain and nervous system. Many sciences as biology, mathematics, electronic engineering, computer science and physics have been integrated to construct artificial neural systems. In this chapter, the basics of Neuromorphic computing together with existing systems having the materials, devices, and circuits. The last part includes algorithms and applications in some fields.

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Section: Materials and Devicesmentioning

confidence: 99%

Neuromorphic Computing between Reality and Future Needs

Ahmed¹,

Shereif²

2023

Artificial Intelligence

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“…The memristor has been treated as a promising candidate for building bio-inspired neuromorphic systems since its properties are similar to the memory and learning functions in biological systems which have been observed and reported in the experimental studies of memristors fabricated by different materials. [1][2][3][4][5][6][7][8][9][10][11][12][13] Table 1 gives some commonly reported properties with their experimental details in those experimental studies. The forgetting behavior and the transition from short-term memory (STM) to long-term memory (LTM) are two typical properties of this kind of memristor.…”

Section: Introductionmentioning

confidence: 99%

“…[6] I = bt −m ∼ 13 mV Yes (II) 0.5 s/80 mV 12 4 s Yes No -No -Ag/PEDOT:PSS/Ta [7] EF 1.2 V Yes (I) -5-50 60 s No Yes 50/6 Yes Yes PVA [8] EF -Yes (I) 0.3 s/0.5 V 50-300 60 s -No -Yes No OTP [9] b) EF -0.75 V Yes (I) 0.2 s/−2 V 5-30 30 s No Yes c) -No -Ta/EV(ClO 4 ) 2 /BTP-F/Pt [10] EF 0.2 V Yes (I) 10 ms/1 V 10-60 60 s No Yes 40/9 Yes No Ta/EV(ClO 4 ) 2 /TPA-PI/Pt [11] -0.2 V Yes (II) 10 ms/0.5 V 6 800 ms -Yes 80/11 Yes No Cu/Cu 2 S/Pt [12] EF ∼ 10 mV Yes (II) 0. 5 s/0.1 V 4 10 s No No -No -Cu/PEDOT:PSS/Ta [13] EF -Yes (I) -10-70 60 s No No -Yes Yes…”

Section: Introductionmentioning

confidence: 99%

A phenomenological memristor model for synaptic memory and learning behaviors

2017

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Properties that are similar to the memory and learning functions in biological systems have been observed and reported in the experimental studies of memristors fabricated by different materials. These properties include the forgetting effect, the transition from short-term memory (STM) to long-term memory (LTM), learning-experience behavior, etc. The mathematical model of this kind of memristor would be very important for its theoretical analysis and application design. In our analysis of the existing memristor model with these properties, we find that some behaviors of the model are inconsistent with the reported experimental observations. A phenomenological memristor model is proposed for this kind of memristor. The model design is based on the forgetting effect and STM-to-LTM transition since these behaviors are two typical properties of these memristors. Further analyses of this model show that this model can also be used directly or modified to describe other experimentally observed behaviors. Simulations show that the proposed model can give a better description of the reported memory and learning behaviors of this kind of memristor than the existing model.

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“…The spike-timing dependent plasticity (STDP) synaptic learning rule, inspired from the behavior of the biological neural system (Dayan and Abbott, 2001) and dominant in the brain, has been proposed and experimentally demonstrated with memristors acting as synapses by several groups over the past few years in many material systems, such as oxides (Yu et al, 2011; Wang et al, 2012a,b, 2016; Wu et al, 2012; Pickett et al, 2013; Mandal et al, 2014; Kim et al, 2015), chalcogenides (Li et al, 2013b; Mahalanabis et al, 2014a,b, 2016; La Barbera et al, 2015), silicon (Jo et al, 2010; Subramaniam et al, 2013), organic materials (Alibart et al, 2012; Li et al, 2013a; Cabaret et al, 2014; Luo et al, 2015), and even magnetic tunnel junctions (Krzysteczko et al, 2012). Illustrations of memristor effectiveness have also been shown in simulation and with transistor and/or complementary metal oxide semiconductor (CMOS)-based memristors (Rachmuth et al, 2011; Rose et al, 2011a,b; Cruz-Albrecht et al, 2012; Noack et al, 2015) and graphics processing units (Snider et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

“…Some of the issues with previous experimental implementations of memristors in the synaptic role in the STDP application (Chang et al, 2011; Rose et al, 2011a,b; Li et al, 2013a; Subramaniam et al, 2013; Luo et al, 2015; Mahalanabis et al, 2016) include the lack of analog programmability of the memristor, high power requirements, and requirement of very specific programing spike shapes in order to effectively program the synaptic weights. Recent work, using a TaO x memristor as a synapse has demonstrated incremental switching in memristors, through the use of repetitive pulses and a pulse train with increasingly higher amplitudes.…”

Section: Introductionmentioning

confidence: 99%

Pulse Shape and Timing Dependence on the Spike-Timing Dependent Plasticity Response of Ion-Conducting Memristors as Synapses

Campbell

Drake

Smith

2016

Front. Bioeng. Biotechnol.

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Ion-conducting memristors comprised of the layered materials Ge2Se3/SnSe/Ag are promising candidates for neuromorphic computing applications. Here, the spike-timing dependent plasticity (STDP) application is demonstrated for the first time with a single memristor type operating as a synapse over a timescale of 10 orders of magnitude, from nanoseconds through seconds. This large dynamic range allows the memristors to be useful in applications that require slow biological times, as well as fast times such as needed in neuromorphic computing, thus allowing multiple functions in one design for one memristor type—a “one size fits all” approach. This work also investigated the effects of varying the spike pulse shapes on the STDP response of the memristors. These results showed that small changes in the pre- and postsynaptic pulse shape can have a significant impact on the STDP. These results may provide circuit designers with insights into how pulse shape affects the actual memristor STDP response and aid them in the design of neuromorphic circuits and systems that can take advantage of certain features in the memristor STDP response that are programmable via the pre- and postsynaptic pulse shapes. In addition, the energy requirement per memristor is approximated based on the pulse shape and timing responses. The energy requirement estimated per memristor operating on slower biological timescales (milliseconds to seconds) is larger (nanojoules range), as expected, than the faster (nanoseconds) operating times (~0.1 pJ in some cases). Lastly, the memristors responded in a similar manner under normal STDP conditions (pre- and post-spikes applied to opposite memristor terminals) as they did to the case where a waveform corresponding to the difference between pre- and post-spikes was applied to only one electrode, with the other electrode held at ground potential. By applying the difference signal to only one terminal, testing of the memristor in various applications can be achieved with a simplified test set-up, and thus be easier to accomplish in most laboratories.

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Synaptic learning behaviors achieved by metal ion migration in a Cu/PEDOT:PSS/Ta memristor

Cited by 3 publications

References 10 publications

Neuromorphic Computing between Reality and Future Needs

Neuromorphic Computing between Reality and Future Needs

A phenomenological memristor model for synaptic memory and learning behaviors

Pulse Shape and Timing Dependence on the Spike-Timing Dependent Plasticity Response of Ion-Conducting Memristors as Synapses

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