Molecular-Shape-Controlled Binary to Ternary Resistive Random-Access Memory Switching of N-Containing Heteroaromatic Semiconductors

Yang Li; Yelong Pan; Cheng Zhang; Zhiming Shi; Chunlan Ma; Songtao Ling; Min Teng; Qijian Zhang; Yucheng Jiang; Run Zhao; Qichun Zhang

doi:10.1021/acsami.2c11960

Molecular-Shape-Controlled Binary to Ternary Resistive Random-Access Memory Switching of N-Containing Heteroaromatic Semiconductors

Yang Li^*, Yelong Pan, Cheng Zhang^*, Zhiming Shi, Chunlan Ma, Songtao Ling, Min Teng, Qijian Zhang^*, Yucheng Jiang, Run Zhao, Qichun Zhang^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

13 Citations (Scopus)

Abstract

In organic resistive random-Access memory (ReRAM) devices, deeply understanding how to control the performance of π-conjugated semiconductors through molecular-shape-engineering is important and highly desirable. Herein, we design a family of N-containing heteroaromatic semiconductors with molecular shapes moving from mono-branched 1Q to di-branched 2Q and tri-branched 3Q. We find that this molecular-shape engineering can induce reliable binary to ternary ReRAM switching, affording a highly enhanced device yield that satisfies the practical requirement. The density functional theory calculation and experimental evidence suggest that the increased multiple paired electroactive nitrogen sites from mono-branched 1Q to tri-branched 3Q are responsible for the multilevel resistance switching, offering stable bidentate coordination with the active metal atoms. This study sheds light on the prospect of N-containing heteroaromatic semiconductors for promising ultrahigh-density data-storage ReRAM application.

Original language	English
Pages (from-to)	44676-44684
Journal	ACS Applied Materials and Interfaces
Volume	14
Issue number	39
Online published	21 Sept 2022
DOIs	https://doi.org/10.1021/acsami.2c11960
Publication status	Published - 5 Oct 2022

Research Keywords

Data storage
Heteroaromatic semiconductors
Molecular design
Multilevel resistive memory
Organic electronics
ReRAM

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10.1021/acsami.2c11960

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title = "Molecular-Shape-Controlled Binary to Ternary Resistive Random-Access Memory Switching of N-Containing Heteroaromatic Semiconductors",

abstract = "In organic resistive random-Access memory (ReRAM) devices, deeply understanding how to control the performance of π-conjugated semiconductors through molecular-shape-engineering is important and highly desirable. Herein, we design a family of N-containing heteroaromatic semiconductors with molecular shapes moving from mono-branched 1Q to di-branched 2Q and tri-branched 3Q. We find that this molecular-shape engineering can induce reliable binary to ternary ReRAM switching, affording a highly enhanced device yield that satisfies the practical requirement. The density functional theory calculation and experimental evidence suggest that the increased multiple paired electroactive nitrogen sites from mono-branched 1Q to tri-branched 3Q are responsible for the multilevel resistance switching, offering stable bidentate coordination with the active metal atoms. This study sheds light on the prospect of N-containing heteroaromatic semiconductors for promising ultrahigh-density data-storage ReRAM application.",

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author = "Yang Li and Yelong Pan and Cheng Zhang and Zhiming Shi and Chunlan Ma and Songtao Ling and Min Teng and Qijian Zhang and Yucheng Jiang and Run Zhao and Qichun Zhang",

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Molecular-Shape-Controlled Binary to Ternary Resistive Random-Access Memory Switching of N-Containing Heteroaromatic Semiconductors. / Li, Yang; Pan, Yelong; Zhang, Cheng et al.
In: ACS Applied Materials and Interfaces, Vol. 14, No. 39, 05.10.2022, p. 44676-44684.

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

TY - JOUR

T1 - Molecular-Shape-Controlled Binary to Ternary Resistive Random-Access Memory Switching of N-Containing Heteroaromatic Semiconductors

AU - Li, Yang

AU - Pan, Yelong

AU - Zhang, Cheng

AU - Shi, Zhiming

AU - Ma, Chunlan

AU - Ling, Songtao

AU - Teng, Min

AU - Zhang, Qijian

AU - Jiang, Yucheng

AU - Zhao, Run

AU - Zhang, Qichun

PY - 2022/10/5

Y1 - 2022/10/5

N2 - In organic resistive random-Access memory (ReRAM) devices, deeply understanding how to control the performance of π-conjugated semiconductors through molecular-shape-engineering is important and highly desirable. Herein, we design a family of N-containing heteroaromatic semiconductors with molecular shapes moving from mono-branched 1Q to di-branched 2Q and tri-branched 3Q. We find that this molecular-shape engineering can induce reliable binary to ternary ReRAM switching, affording a highly enhanced device yield that satisfies the practical requirement. The density functional theory calculation and experimental evidence suggest that the increased multiple paired electroactive nitrogen sites from mono-branched 1Q to tri-branched 3Q are responsible for the multilevel resistance switching, offering stable bidentate coordination with the active metal atoms. This study sheds light on the prospect of N-containing heteroaromatic semiconductors for promising ultrahigh-density data-storage ReRAM application.

AB - In organic resistive random-Access memory (ReRAM) devices, deeply understanding how to control the performance of π-conjugated semiconductors through molecular-shape-engineering is important and highly desirable. Herein, we design a family of N-containing heteroaromatic semiconductors with molecular shapes moving from mono-branched 1Q to di-branched 2Q and tri-branched 3Q. We find that this molecular-shape engineering can induce reliable binary to ternary ReRAM switching, affording a highly enhanced device yield that satisfies the practical requirement. The density functional theory calculation and experimental evidence suggest that the increased multiple paired electroactive nitrogen sites from mono-branched 1Q to tri-branched 3Q are responsible for the multilevel resistance switching, offering stable bidentate coordination with the active metal atoms. This study sheds light on the prospect of N-containing heteroaromatic semiconductors for promising ultrahigh-density data-storage ReRAM application.

KW - Data storage

KW - Heteroaromatic semiconductors

KW - Molecular design

KW - Multilevel resistive memory

KW - Organic electronics

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Molecular-Shape-Controlled Binary to Ternary Resistive Random-Access Memory Switching of N-Containing Heteroaromatic Semiconductors

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