On the origin of bistable resistive switching in metal organic charge transfer complex memory cells

Kever, Thorsten; Böttger, U.; Schindler, Christina; Waser, Rainer

doi:10.1063/1.2772191

Cited by 77 publications

(48 citation statements)

References 16 publications

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“…55͒ or Cu:TCNQ. 56 Interestingly, in their OFF state, these memories exhibit a symmetric non-Ohmic current similar to the shunt in OPV cells. Note that PEDOT-:PSS is commonly used as an interfacial layer in organic BHJ solar cells, 26 and we suspect it, as well as substrate defects, may be involved in the formation of shunt paths.…”

Section: B Physical Originmentioning

confidence: 99%

Universality of non-Ohmic shunt leakage in thin-film solar cells

Dongaonkar

Servaites

Ford

et al. 2010

Journal of Applied Physics

191

135

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This document has been made available through Purdue e-Pubs, a service of the Purdue University Libraries. Please contact epubs@purdue.edu for additional information. We compare the dark current-voltage ͑IV͒ characteristics of three different thin-film solar cell types: hydrogenated amorphous silicon ͑a-Si:H͒ p-i-n cells, organic bulk heterojunction ͑BHJ͒ cells, and Cu͑In, Ga͒Se 2 ͑CIGS͒ cells. All three device types exhibit a significant shunt leakage current at low forward bias ͑V Ͻ ϳ 0.4͒ and reverse bias, which cannot be explained by the classical solar cell diode model. This parasitic shunt current exhibits non-Ohmic behavior, as opposed to the traditional constant shunt resistance model for photovoltaics. We show here that this shunt leakage ͑I sh ͒, across all three solar cell types considered, is characterized by the following common phenomenological features: ͑a͒ voltage symmetry about V =0, ͑b͒ nonlinear ͑power law͒ voltage dependence, and ͑c͒ extremely weak temperature dependence. Based on this analysis, we provide a simple method of subtracting this shunt current component from the measured data and discuss its implications on dark IV parameter extraction. We propose a space charge limited ͑SCL͒ current model for capturing all these features of the shunt leakage in a consistent framework and discuss possible physical origin of the parasitic paths responsible for this shunt current mechanism.

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Section: B Physical Originmentioning

confidence: 99%

Universality of non-Ohmic shunt leakage in thin-film solar cells

Dongaonkar

Servaites

Ford

et al. 2010

Journal of Applied Physics

191

135

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“…1,2 The ECM cell consists of an insulator layer sandwiched between two electrodes, in which one is made from an electrochemically active electrode (AE) metal, such as Ag or Cu, and the other is a counter electrode (CE), such as Pt, Ir, W, or Ag. 3,4 Till now, a large number of ECM cells have been reported, employing various insulating materials such as chalcogenides, [5][6][7][8][9][10][11][12][13] oxides, [14][15][16][17][18][19][20][21][22][23][24] amorphous Si (Refs. 25 and 26) and C, [27][28][29][30] and organic materials.…”

Section: Introductionmentioning

confidence: 99%

Mechanism for resistive switching in chalcogenide-based electrochemical metallization memory cells

Zhuge

et al. 2015

AIP Advances

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It has been reported that in chalcogenide-based electrochemical metallization (ECM) memory cells (e.g., As2S3:Ag, GeS:Cu, and Ag2S), the metal filament grows from the cathode (e.g., Pt and W) towards the anode (e.g., Cu and Ag), whereas filament growth along the opposite direction has been observed in oxide-based ECM cells (e.g., ZnO, ZrO2, and SiO2). The growth direction difference has been ascribed to a high ion diffusion coefficient in chalcogenides in comparison with oxides. In this paper, upon analysis of OFF state I–V characteristics of ZnS-based ECM cells, we find that the metal filament grows from the anode towards the cathode and the filament rupture and rejuvenation occur at the cathodic interface, similar to the case of oxide-based ECM cells. It is inferred that in ECM cells based on the chalcogenides such as As2S3:Ag, GeS:Cu, and Ag2S, the filament growth from the cathode towards the anode is due to the existence of an abundance of ready-made mobile metal ions in the chalcogenides rather than to the high ion diffusion coefficient.

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“…For these reasons the chemical reaction of TCNQ with a (patterned) Cu substrate seemed for us to be the best suited method, since the material is only formed at the interface of the (patterned) metal. To complement previous works on CuTCNQ nanowires [7,13,22] and dense films [10,23], we report in this paper two different routes to grow CuTCNQ complex in liquid phase within small via holes opened in SiO 2 /SiC stack. The basic common idea relies on the formation of CuTCNQ material from the partial and controlled corrosion of a Cu bottom electrode by a TCNQ-based solution.…”

Section: Introductionmentioning

confidence: 77%

“…The best experimental conditions -corresponding to a low solubility of the formed Cu + TCNQ -charge transfer complex and sufficient high solubility of TCNQ (1 mg/ml) -were obtained with acetonitrile/2-butanone mixture in 5:95 volume ratio. Several reaction times (10,20,30 or 40 s) were tested to optimize conditions for the CuTCNQ growth process and to apprehend via hole filling. Once again, the formation of CuTCNQ complex was checked by Raman spectroscopy: the measured spectrum was very similar to the one obtained on CuTCNQ nanocrystals [27] crystallizing in phase I [28].…”

Section: Solution Growth Of Cutcnq Complexmentioning

confidence: 99%