Direct measurement of ferroelectric polarization in a tunable semimetal

Barrera, Sergio C. de la; Cao, Qingrui; Gao, Yang; Gao, Yuan; Bheemarasetty, Vineetha; Yan, Jiaqiang; Mandrus, David; Zhu, Wenguang; Hunt, Benjamin

doi:10.1038/s41467-021-25587-3

Cited by 49 publications

(40 citation statements)

References 33 publications

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“…[248] Microscopically, the polarization reversal can be attributed to re-distribution of electrons and holes and even interlayer sliding. [69,249] The switchable polarization states are further confirmed by PFM experiments carried out on the 1T′-WTe 2 thin films [250] (Figure 8f,g). Distinct from cycle-dependent activity decay in ordinary catalysts, [251] the HER performance of 1T′-MoTe 2 is dramatically improved as the electrode is held at a cathodic bias, [252] where its over-potential decreases from 320 to 178 mV at a current density of 10 mA cm −2 (Figure 8h).…”

Section: Ferroelectric Metal Wtementioning

confidence: 70%

Progress on Emerging Ferroelectric Materials for Energy Harvesting, Storage and Conversion

Wei

Domingo

Sun

et al. 2022

Advanced Energy Materials

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Since the discovery of Rochelle salt a century ago, ferroelectric materials have been investigated extensively due to their robust responses to electric, mechanical, thermal, magnetic, and optical fields. These features give rise to a series of ferroelectric‐based modern device applications such as piezoelectric transducers, memories, infrared detectors, nonlinear optical devices, etc. On the way to broaden the material systems, for example, from three to two dimensions, new phenomena of topological polarity, improper ferroelectricity, magnetoelectric effects, and domain wall nanoelectronics bear the hope for next‐generation electronic devices. In the meantime, ferroelectric research has been aggressively extended to more diverse applications such as solar cells, water splitting, and CO2 reduction. In this review, the most recent research progress on newly emerging ferroelectric states and phenomena in insulators, ionic conductors, and metals are summarized, which have been used for energy storage, energy harvesting, and electrochemical energy conversion. Along with the intricate coupling between polarization, coordination, defect, and spin state, the exploration of transient ferroelectric behavior, ionic migration, polarization switching dynamics, and topological ferroelectricity, sets up the physical foundation ferroelectric energy research. Accordingly, the progress in understanding of ferroelectric physics is expected to provide insightful guidance on the design of advanced energy materials.

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Section: Ferroelectric Metal Wtementioning

confidence: 70%

Progress on Emerging Ferroelectric Materials for Energy Harvesting, Storage and Conversion

Wei

Domingo

Sun

et al. 2022

Advanced Energy Materials

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“…In recent years, novel atomically thin ferroelectric semiconducting materials have been synthesized and are generically known as group-IV monochalcogenide monolayers, which exhibit stable ferroelectrics at the monolayer level. − However, these materials usually suffer from lack of chemical stability, making their potential applications in memory challenges. Unlike conventional epitaxial growth, van der Waals (vdW) integration offers an alternative strategy to tailor and engineer crystal symmetry by simply stacking and rotating different building blocks, − as exemplified by two-dimensional (2D) twist electronics. − Recently, artificial ferroelectrics created by tearing-and-stacking bipartite honeycomb 2D materials have been theoretically predicted and experimentally realized in the parallel hexagonal boron nitride (hBN) bilayer system − and very recently in semiconducting transition metal dichalcogenides (s-TMDs). , For these materials, the ferroelectric phase transitions have not yet been carefully studied, and the phase transition order has not been identified experimentally.…”

mentioning

confidence: 99%

Identifying the Transition Order in an Artificial Ferroelectric van der Waals Heterostructure

Liu

Yoo

et al. 2022

Nano Lett.

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Two-dimensional semiconducting ferroelectrics can enable new technology for low-energy electronic switching. However, conventional ferroelectric materials are usually electrically insulating and suffer from severe depolarization effects when downscaled to atomic thickness. Following recent work, we show that robust ferroelectricity can be obtained from nonferroelectric semiconducting 2H-WSe2 by creating R-stacked bilayers with broken inversion symmetry. Here, we identify that the phase transition order of this artificial ferroelectric heterostructure is first-order, with a discontinuous jump in the order parameter across the phase transition temperature. The Curie temperature has been experimentally determined as 353 K. Using the Landau-Devonshire theory, we further determine the Curie–Weiss temperatures to be 351.2 K. We additionally demonstrate the robustness of this artificial ferroelectric material using consecutive polarization measurements, where no appreciable deterioration was detected.

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“…Yasuda et al reported that parallel-stacked bilayer h-BN exhibits OOP ferroelectricity that reverses depending on the stacking order . Similar phenomenon was found in multilayer TMDs (d1T-MoTe 2 , 1T’-ReS 2 , WTe 2 , ), which exhibit OOP ferroelectricity arising from in-plane slipping. For example, in bilayer ReS 2 , two energy-degenerate ferroelectric structures can be obtained by moving the upper layer with a sliding distance from the high-symmetry nonpolar structure, and the nonequivalence of the top and bottom layers leads to an uncompensated charge transfer between them and results in the vertical polarization .…”

Section: Ferroelectric Materials In 2d Devicesmentioning

confidence: 67%

“…Although 2D ferroelectricity has been theoretically predicted for a wide range of 2D layered materials, only a few 2D vdW ferroelectrics have been experimentally achieved and explored, including bilayer h-BN, TMDs, ,,− group-IV metal chalcogenides, − ,, CIPS, ,,− and α- and β-In 2 Se 3 . − Owing to the different ferroelectricity between IP and OOP directions depending on the crystal structure, 2D ferroelectrics provide a promising platform to explore domain physics. In particular, IP ferroelectricity is confined within the 2D plane by the interlayer vdW gap, thus stabilizing it against OOP perturbation.…”

Section: Ferroelectric Materials In 2d Devicesmentioning

confidence: 99%

“…The discovery of 2D layered ferroelectric materials with weak interlayer vdW interaction promotes the development of 2D ferroelectricity for their basic properties such as the dangling-bond-free surface and excellent durability against strain. Intrinsic ferroelectricity in 2D materials, such as TMDs, − group IV metal chalcogenides, − CuInP 2 S 6 (CIPS), − and indium selenide (In 2 Se 3 ), − have been theoretically or experimentally demonstrated, while extrinsic ferroelectricity can be achieved through the defect, strain, or surface engineering of particular 2D materials with no ferroelectricity . In addition, 2D ferroelectrics have been reported to possess properties rarely found in the bulk counterpart, e.g., the interrelated coupling effect of out-of-plane (OOP) and in-plane (IP) ferroelectric polarizations in In 2 Se 3 . ,, As a result, 2D vdW ferroelectrics can be intuitively integrated with 2D semiconductors to form vdW heterostructures regardless of lattice mismatch, which probably leads to sharp band edges and minimal interfacial traps for realizing intriguing properties and versatile device functionalities.…”

mentioning

confidence: 99%

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

et al. 2022

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Ferroelectric materials play an important role in a wide spectrum of semiconductor technologies and device applications. Two-dimensional (2D) van der Waals (vdW) ferroelectrics with surface-insensitive ferroelectricity that is significantly different from their traditional bulk counterparts have further inspired intensive interest. Integration of ferroelectrics into 2D-layered-material-based devices is expected to offer intriguing working principles and add desired functionalities for next-generation electronics. Herein, fundamental properties of ferroelectric materials that are compatible with 2D devices are introduced, followed by a critical review of recent advances on the integration of ferroelectrics into 2D devices. Representative device architectures and corresponding working mechanisms are discussed, such as ferroelectrics/2D semiconductor heterostructures, 2D ferroelectric tunnel junctions, and 2D ferroelectric diodes. By leveraging the favorable properties of ferroelectrics, a variety of functional 2D devices including ferroelectric-gated negative capacitance field-effect transistors, programmable devices, nonvolatile memories, and neuromorphic devices are highlighted, where the application of 2D vdW ferroelectrics is particularly emphasized. This review provides a comprehensive understanding of ferroelectrics-integrated 2D devices and discusses the challenges of applying them into commercial electronic circuits.

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Direct measurement of ferroelectric polarization in a tunable semimetal

Cited by 49 publications

References 33 publications

Progress on Emerging Ferroelectric Materials for Energy Harvesting, Storage and Conversion

Progress on Emerging Ferroelectric Materials for Energy Harvesting, Storage and Conversion

Identifying the Transition Order in an Artificial Ferroelectric van der Waals Heterostructure

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

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