Hongyue Jing scite author profile

MXenes, an emerging class of two-dimensional (2D) transition metal carbides and nitrides, have potential for application as high-performance, low-cost electrodes in organic field-effect transistors (OFETs) because of their water dispersibility, high conductivity, and work-function tunability. In this study, we successfully fabricated a large-scale, uniform Ti3C2T x MXene electrode array on a flexible plastic substrate for application in high-performance OFETs. The work function of the Ti3C2T x MXene electrodes was also effectively modulated via chemical doping with NH3. The fabricated OFETs with Ti3C2T x MXene electrodes exhibited excellent device performance, such as a maximum carrier mobility of ∼1 cm2·V–1·s–1 and an on–off current ratio of ∼107 for both p-type and n-type OFETs, even though all the electrode and dielectric layers were fabricated on the plastic substrate by solution processing. Furthermore, MXene-electrode-based complementary logic circuits, such as NOT, NAND, and NOR, were fabricated via integration of p-type and n-type OFETs. The proposed approach is expected to expand the application range of MXenes to other OFET-based electronic devices, such as organic light-emitting displays and electronic skins.

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2D MXene–TiO₂ Core–Shell Nanosheets as a Data‐Storage Medium in Memory Devices

Lyu

et al. 2020

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MXenes, an emerging class of 2D transition metal carbides and nitrides with the general formula Mn+1XnTx (n = 1–4), have potential for application as floating gates in memory devices because of their intrinsic properties of a 2D structure, high density‐of‐states, and high work function. In this study, a series of MXene–TiO2 core–shell nanosheets are synthesized by deterministic control of the surface oxidation of MXene. The floating gate (multilayer MXene) and tunneling layer (TiO2) in a nano‐floating‐gate transistor memory (NFGTM) device are prepared simultaneously by a facile, low‐cost, and water‐based process. The memory performance is optimized via adjustment of the thickness of the oxidation layer formed on the MXene surface. The fabricated MXene NFGTMs exhibit excellent nonvolatile memory characteristics, including a large memory window (>35.2 V), high programming/erasing current ratio (≈106), low off‐current (<1 pA), long retention (>104 s), and cyclic endurance (300 cycles). Furthermore, synaptic functions, including the excitatory postsynaptic current/inhibitory postsynaptic current, paired‐pulse facilitation, and synaptic plasticity (long‐term potentiation/depression), are successfully emulated using the MXene NFGTMs. The successful control of MXene oxidation and its application to NFGTMs are expected to inspire the application of MXene as a data‐storage medium in future memory devices.

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Modulation of the Electronic Properties of MXene (Ti₃C₂T_x) via Surface-Covalent Functionalization with Diazonium

et al. 2021

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The physical and chemical properties of MXenes are strongly dependent on surface terminations; thus, the tailoring of surface functional groups in two-dimensional transition-metal carbides (MXenes) may extend the applicability of these compelling materials to a wider set of fields. In this work, we demonstrate the chemical modification of Ti3C2T x MXene via diazonium covalent chemistry and the subsequent effects on the electrical properties of MXene. The 4-nitrophenyl group was grafted onto the surface of MXene through a solid–liquid reaction, which was confirmed by various characterization methods, including X-ray photoelectron spectroscopy, Fourier transform infrared spectroscopy, electron energy loss spectroscopy, atomic force microscopy, and transmission electron microscopy. The degree of modification of MXene is expediently tunable by adjusting the concentration of the diazonium salt solution. The work function of functionalized MXene is modifiable by regulating the quantity of grafted diazonium surface groups, with an adjustable range of around 0.6 eV. Further, in this study, the electrical properties of modified MXene are investigated through the fabrication of field-effect-transistor devices that utilize modified MXene as a channel material. It was demonstrated that with increasing concentration of 4-nitrophenyl groups grafted onto the surface the on/off current ratio of the modified MXene was improved to as much as 3.56, with a corresponding decrease in conductivity and mobility. The proposed approach of controlled modification of surface groups in Ti3C2T x may imbue Ti3C2T x with favorable electronic behaviors and demonstrate prospects for use in electronic field applications.

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Work Function Engineering of Electrohydrodynamic-Jet-Printed PEDOT:PSS Electrodes for High-Performance Printed Electronics

Lyu

Jing

et al. 2020

ACS Appl. Mater. Interfaces

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Poly(3,:poly(4-styrene sulfonate) (PEDOT:PSS) has demonstrated outstanding performance as a charge transport layer or an electrode in various electronic devices, including organic solar cells, organic lightemitting diodes, and organic field-effect transistors (OFETs). The electrical properties of these devices are affected by the contact properties at the PEDOT:PSS−semiconductor junction. In this research, we performed work function (WF) engineering of electrohydrodynamic (EHD)-jet-printed PEDOT:PSS and successfully used it as an electrode to fabricate high-performance OFETs and complementary logic circuits. Two types of PEDOT:PSS materials−one with a high WF (HWF, 5.28 eV) and the other with a low WF (LWF, 4.53 eV)−were synthesized and EHD-jet-printed. The WF of PEDOT:PSS was deterministically modulated by approximately 0.75 eV through simple mixing of the two synthesized PEDOT:PSS materials in various ratios. OFETs fabricated with HWF and LWF PEDOT:PSS electrodes showed excellent electrical properties, including the ON/OFF switching ratio higher than 10 7 and the highest carrier mobility greater than 1 cm 2 •V −1 •s −1 . Furthermore, the HWF and LWF PEDOT:PSS electrodes were integrated to fabricate complementary metal−oxide− semiconductor (CMOS) NOT, NOR, and NAND circuits.

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Non-metal catalytic synthesis of graphene from a polythiophene monolayer on silicon dioxide

Jing

Min

Seo

et al. 2015

Carbon

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Hongyue Jing

Large-Area MXene Electrode Array for Flexible Electronics

2D MXene–TiO₂ Core–Shell Nanosheets as a Data‐Storage Medium in Memory Devices

Modulation of the Electronic Properties of MXene (Ti₃C₂T_x) via Surface-Covalent Functionalization with Diazonium

Work Function Engineering of Electrohydrodynamic-Jet-Printed PEDOT:PSS Electrodes for High-Performance Printed Electronics

Non-metal catalytic synthesis of graphene from a polythiophene monolayer on silicon dioxide

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Hongyue Jing

Large-Area MXene Electrode Array for Flexible Electronics

2D MXene–TiO2 Core–Shell Nanosheets as a Data‐Storage Medium in Memory Devices

Modulation of the Electronic Properties of MXene (Ti3C2Tx) via Surface-Covalent Functionalization with Diazonium

Work Function Engineering of Electrohydrodynamic-Jet-Printed PEDOT:PSS Electrodes for High-Performance Printed Electronics

Non-metal catalytic synthesis of graphene from a polythiophene monolayer on silicon dioxide

Contact Info

Product

Resources

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2D MXene–TiO₂ Core–Shell Nanosheets as a Data‐Storage Medium in Memory Devices

Modulation of the Electronic Properties of MXene (Ti₃C₂T_x) via Surface-Covalent Functionalization with Diazonium