Thin‐Film Ferroelectrics

Fernández, Abel; Acharya, Megha; Lee, Han-Gyeol; Schimpf, Jesse; Jiang, Yizhe; Lou, Djamila; Tian, Zishen; Martin, Lane W.

doi:10.1002/adma.202108841

Cited by 37 publications

(14 citation statements)

References 489 publications

(732 reference statements)

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“…This emerging ability to directly integrate a strongly hysteretic nonlinear dielectric is transformational for future logic, memory, high-power, acoustic, or electro-optic devices ( 6 – 8 ). These ferroelectrics, however, bring their own challenges, the most notable being that the margin between the coercive field and breakdown field is uncomfortably small at room temperature.…”

mentioning

confidence: 99%

Atomic-scale polarization switching in wurtzite ferroelectrics

Calderón

Hayden

Baksa

et al. 2023

Science

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Ferroelectric wurtzites have the potential to revolutionize modern microelectronics because they are easily integrated with multiple mainstream semiconductor platforms. However, the electric fields required to reverse their polarization direction and unlock electronic and optical functions need substantial reduction for operational compatibility with complementary metal-oxide semiconductor (CMOS) electronics. To understand this process, we observed and quantified real-time polarization switching of a representative ferroelectric wurtzite (Al 0.94 B 0.06 N) at the atomic scale with scanning transmission electron microscopy. The analysis revealed a polarization reversal model in which puckered aluminum/boron nitride rings in the wurtzite basal planes gradually flatten and adopt a transient nonpolar geometry. Independent first-principles simulations reveal the details and energetics of the reversal process through an antipolar phase. This model and local mechanistic understanding are a critical initial step for property engineering efforts in this emerging material class.

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confidence: 99%

Atomic-scale polarization switching in wurtzite ferroelectrics

Calderón

Hayden

Baksa

et al. 2023

Science

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“…Ferroelectric materials have drawn significant attention for non‐volatile memory (NVM) devices because they exhibit bistable electric polarization states that can be switched by an external electric field 1 . Although commercial ferroelectric NVM devices are based on a ferroelectric capacitor for information storage and a transistor connected in series, such device architecture is limited by the destructive readout process 2,3 .…”

Section: Introductionmentioning

confidence: 99%

“…Ferroelectric materials have drawn significant attention for non-volatile memory (NVM) devices because they exhibit bistable electric polarization states that can be switched by an external electric field. 1 Although commercial ferroelectric NVM devices are based on a ferroelectric capacitor for information storage and a transistor connected in series, such device architecture is limited by the destructive readout process. 2,3 Ferroelectric field effect transistors (FeFETs), where a ferroelectric film is directly integrated as the gate dielectric of the FET to modulate the channel conductance, can address this challenge and are also advantageous for device downscaling.…”

Section: Introductionmentioning

confidence: 99%

SnS/MoS₂ van der Waals heterojunction for in‐plane ferroelectric field‐effect transistors with multibit memory and logic characteristics

Singh

Rhee

Baek

et al. 2023

EcoMat

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Ferroelectric two dimensional (2D) materials hold great potential to develop modern miniaturized electronic and memory devices. 2D ferroelectrics exhibiting spontaneous polarization in the out-of-plane direction have been extensively investigated to date, but the loss of their polarization during device operation has been problematic. Although 2D materials with in-plane ferroelectric behavior are more stable against depolarization and thus promising for memory and logic applications, experimental realization of in-plane 2D ferroelectric devices is still scarce. Here, we demonstrate in-plane ferroelectric field effect transistors (FETs) based on a van der Waals heterojunction (vdWHJ), which can perform multibit memory and logic operations. Tin monosulfide (SnS), a 2D material with in-plane ferroelectricity, is partially stacked on top of a semiconducting molybdenum disulfide (MoS2) on a silicon dioxide (SiO2)coated silicon substrate to fabricate vdWHJ FETs in back-gate configuration. Switching of the in-plane polarization direction in the SnS channel modulates the contact barriers at the electrode/SnS and SnS/MoS2 interfaces, thereby creating high resistance states and low resistance states (LRS). The device exhibits a logic transfer characteristic with a high drain current on/off ratio (>106) in LRS and non-volatile memory performance with excellent retention characteristics (extrapolated retention time > 10 years). With exquisite tuning of the channel resistance by SnS polarization and gate bias, we realize multiple states with distinct current levels for multibit memory and logic operations suitable for programmable logic-in-memory applications.

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“…Innovation in energy storage technology is a key to tackling energy and environmental issues, such as the ever-increasing demands for electrical energy and achievement of sustainable development goals (SDGs). Dielectric capacitors have been regarded as attractive options in this regard; they exhibit distinctive features of ultrahigh power densities (fast charge–discharge rates) and good stability, and they do not utilize chemical reactions during cycling, unlike batteries. − Dielectric capacitors can thus become ideal, safe, all-solid-state energy storage devices. However, the energy densities of current dielectrics fall significantly short of meeting the increasing demands for electrical energy; their energy densities are 1–2 orders of magnitude lower than those of batteries , and supercapacitors. , To overcome this issue, tremendous efforts have been dedicated to developing new dielectric materials with enhanced energy densities.…”

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confidence: 99%

Ultrahigh Energy Storage in 2D High-κ Perovskites

et al. 2023

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Dielectric capacitors have greater power densities than batteries, and, unlike batteries, they do not utilize chemical reactions during cycling. Thus, they can become ideal, safe energy storage devices. However, dielectric capacitors yield rather low energy densities compared with other energy storage devices such as batteries and supercapacitors. Here, we present a rational approach for designing ultrahigh energy storage capacitors using two-dimensional (2D) high-κ dielectric perovskites (Ca2Na m–3Nb m O3m+1; m = 3–6). Individual Ca2Na m–3Nb m O3m+1 nanosheets exhibit an ultrahigh dielectric strength (638–1195 MV m–1) even in the monolayer form, which exceeds those of conventional dielectric materials. Multilayer stacked nanosheet capacitors exhibit ultrahigh energy densities (174–272 J cm–3), high efficiencies (>90%), excellent reliability (>107 cycles), and temperature stability (−50–300 °C); the maximum energy density is much higher than those of conventional dielectric materials and even comparable to those of lithium-ion batteries. Enhancing the energy density may make dielectric capacitors more competitive with batteries.

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Thin‐Film Ferroelectrics

Cited by 37 publications

References 489 publications

Atomic-scale polarization switching in wurtzite ferroelectrics

Atomic-scale polarization switching in wurtzite ferroelectrics

SnS/MoS₂ van der Waals heterojunction for in‐plane ferroelectric field‐effect transistors with multibit memory and logic characteristics

Ultrahigh Energy Storage in 2D High-κ Perovskites

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Thin‐Film Ferroelectrics

Cited by 37 publications

References 489 publications

Atomic-scale polarization switching in wurtzite ferroelectrics

Atomic-scale polarization switching in wurtzite ferroelectrics

SnS/MoS2 van der Waals heterojunction for in‐plane ferroelectric field‐effect transistors with multibit memory and logic characteristics

Ultrahigh Energy Storage in 2D High-κ Perovskites

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SnS/MoS₂ van der Waals heterojunction for in‐plane ferroelectric field‐effect transistors with multibit memory and logic characteristics