Ferroelectrics-Integrated Two-Dimensional Devices toward Next-Generation Electronics

Jin, Tengyu; Mao, Jing‐Yu; Gao, Jing; Han, Cheng; Loh, Kian Ping; Wee, Andrew T. S.; Chen, Wei

doi:10.1021/acsnano.2c07281

Cited by 63 publications

(47 citation statements)

References 144 publications

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“…Nonvolatile, high-speed, high-density, and low-power memory devices have long been pursued because they can substantially improve the performance of processing and storing information. , Thanks to their atomic thicknesses and diverse electronic properties, 2DLMs offer many possibilities for memory devices working on various mechanisms, including filament forming, charge trapping, and ferroelectric switching. − Dependent on the working mechanisms, a variety of corresponding device architectures have been adopted. Among them, ferroelectric field-effect transistors (FeFETs) are a promising platform to exploit the synergistic coupling between 2DLMs and ferroelectric perovskite oxides for memory devices. − , Compared with other ferroelectric materials, perovskite oxide based ferroelectric materials, such as PZT and PMN-PT, are praised for their large polarization strength, fast switching speed, and environmental stability . Specifically, the Curie temperatures of the perovskite-type ferroelectrics are mostly considerably higher than room temperature, which allows a wide temperature window for the device operation.…”

Section: Mosfetsmentioning

confidence: 99%

Two-Dimensional Layered Materials Meet Perovskite Oxides: A Combination for High-Performance Electronic Devices

Yang

Wang

et al. 2023

ACS Nano

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As the Si-based transistors scale down to atomic dimensions, the basic principle of current electronics, which heavily relies on the tunable charge degree of freedom, faces increasing challenges to meet the future requirements of speed, switching energy, heat dissipation, and packing density as well as functionalities. Heterogeneous integration, where dissimilar layers of materials and functionalities are unrestrictedly stacked at an atomic scale, is appealing for next-generation electronics, such as multifunctional, neuromorphic, spintronic, and ultralow-power devices, because it unlocks technologically useful interfaces of distinct functionalities. Recently, the combination of functional perovskite oxides and two-dimensional layered materials (2DLMs) led to unexpected functionalities and enhanced device performance. In this paper, we review the recent progress of the heterogeneous integration of perovskite oxides and 2DLMs from the perspectives of fabrication and interfacial properties, electronic applications, and challenges as well as outlooks. In particular, we focus on three types of attractive applications, namely field-effect transistors, memory, and neuromorphic electronics. The van der Waals integration approach is extendible to other oxides and 2DLMs, leading to almost unlimited combinations of oxides and 2DLMs and contributing to future high-performance electronic and spintronic devices.

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Section: Mosfetsmentioning

confidence: 99%

Two-Dimensional Layered Materials Meet Perovskite Oxides: A Combination for High-Performance Electronic Devices

Yang

Wang

et al. 2023

ACS Nano

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“…For instance, complex oxides ABO 3 ‐type perovskites and binary oxide HfO 2 with fluorite‐structure are also used in the integration of ferroelectrics into 2D material‐based devices. [ 44,45 ] Compared with traditional inorganic ferroelectric perovskite oxides and binary HfO 2 , ferroelectric polymers PVDF and P(VDF‐TrFE) display distinct features. For example, the inorganic ferroelectrics has some intrinsic drawbacks such as limited mechanical deformation.…”

Section: Fundamentals Of Ferroelectricitymentioning

confidence: 99%

Interface Engineering and Device Applications of 2D Ultrathin Film/Ferroelectric Copolymer P(VDF‐TrFE)

Dang

Guo

et al. 2022

Advanced Physics Research

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Ferroelectric materials with switchable electrical polarization have been widely used in tunnel junctions, non-volatile memories, and field-effect transistors. Large-area organic ferroelectric polymers compatible with silicon or flexible substrates have played a crucial role in nanoelectronics. Poly(vinylidene fluoride-trifluoroethylene) P(VDF-TrFE) as a representative, different from traditional bulk oxide ferroelectrics in terms of atom arrangements and fabrication methods, has frequently been used as the ferroelectric gate for high-performance electronic, optical, and synaptic transistors. Ferroelectric copolymers have gradually become a promising and versatile alternative for inorganic ferroelectrics. This review will focus on the interface engineering and device applications of 2D materials/ferroelectric P(VDF-TrFE) hybrid structures. The intrinsic ferroelectric properties and unique features of P(VDF-TrFE) are first elucidated. Next, typical device structures with ferroelectric gating effect followed by its physical working mechanisms will be discussed. In the next section, diverse nanoelectronics applications of ferroelectric field effect transistors based on P(VDF-TrFE), including optoelectronic devices, non-volatile memories, neuromorphic computing, and negative capacitance transistors, are clarified. Moreover, existing challenges and further development for ferroelectric polymer will be discussed. With an emphasis on the ferroelectric polymer gate and related issues, this review provides a timely summary of current physical understanding and progresses.

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“…Moreover, the versatility and ease of assembling of vdW materials open the door to exploring new ferroelectric heterostructures with unique properties arising from increased interfacial contributions. − Ferroelectric tunneling junctions based on CuInP 2 S 6 (CIPS)/graphene heterostructures have shown record electroresistance values . Mixed dimensional heterostructures, coupling a 2D semiconductor channel to a bulk ferroelectric film, opened the way toward 2D material-based ferroelectric synapses. ,,− Finally, the reduced electromagnetic screening of vdW 2D materials unlocks new means of electrical and optical control in device architectures. , This positions ferroelectric vdW heterostructures as interesting platforms for fundamental understanding as well as emerging photoferroelectric technologies. ,,,,− However, studies of FeFET based on a vdW ferroelectric layer coupled to a vdW semiconductor channel are still very scarce, − while optoelectronic neuromorphic devices based on this platform are mostly uncharted.…”

Section: Introductionmentioning

confidence: 99%

Photoferroelectric All-van-der-Waals Heterostructure for Multimode Neuromorphic Ferroelectric Transistors

Soliman

Maity

Gloppe

et al. 2023

ACS Appl. Mater. Interfaces

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Interface-driven effects in ferroelectric van der Waals (vdW) heterostructures provide fresh opportunities in the search for alternative device architectures toward overcoming the von Neumann bottleneck. However, their implementation is still in its infancy, mostly by electrical control. It is of utmost interest to develop strategies for additional optical and multistate control in the quest for novel neuromorphic architectures. Here, we demonstrate the electrical and optical control of the ferroelectric polarization states of ferroelectric field effect transistors (FeFET). The FeFETs, fully made of ReS 2 /hBN/CuInP 2 S 6 vdW materials, achieve an on/off ratio exceeding 10 7 , a hysteresis memory window up to 7 V wide, and multiple remanent states with a lifetime exceeding 10 3 s. Moreover, the ferroelectric polarization of the CuInP 2 S 6 (CIPS) layer can be controlled by photoexciting the vdW heterostructure. We perform wavelength-dependent studies, which allow for identifying two mechanisms at play in the optical control of the polarization: band-to-band photocarrier generation into the 2D semiconductor ReS 2 and photovoltaic voltage into the 2D ferroelectric CIPS. Finally, heterosynaptic plasticity is demonstrated by operating our FeFET in three different synaptic modes: electrically stimulated, optically stimulated, and optically assisted synapse. Key synaptic functionalities are emulated including electrical long-term plasticity, optoelectrical plasticity, optical potentiation, and spike rate-dependent plasticity. The simulated artificial neural networks demonstrate an excellent accuracy level of 91% close to ideal-model synapses. These results provide a fresh background for future research on photoferroelectric vdW systems and put ferroelectric vdW heterostructures on the roadmap for the next neuromorphic computing architectures.

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Ferroelectrics-Integrated Two-Dimensional Devices toward Next-Generation Electronics

Cited by 63 publications

References 144 publications

Two-Dimensional Layered Materials Meet Perovskite Oxides: A Combination for High-Performance Electronic Devices

Two-Dimensional Layered Materials Meet Perovskite Oxides: A Combination for High-Performance Electronic Devices

Interface Engineering and Device Applications of 2D Ultrathin Film/Ferroelectric Copolymer P(VDF‐TrFE)

Photoferroelectric All-van-der-Waals Heterostructure for Multimode Neuromorphic Ferroelectric Transistors

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