On the validity and applicability of models of negative capacitance and implications for MOS applications

Kittl, J. A.; Obradovic, B.; Reddy, D. Amaranatha; Rakshit, Titash; Hatcher, Ryan; Rödder, M.

doi:10.1063/1.5036984

Cited by 36 publications

(24 citation statements)

References 28 publications

(78 reference statements)

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“…However, physical understanding of NC effects is still under intensive debate [25][26][27][28][29][30][31][32][33][34][35][36] . Experimentally observed NC effects are different from each other, and also from the concepts initially proposed.…”

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confidence: 99%

“…Alternative explanations for the capacitance enhancement and transient NC effects in FE/PE stacks have been also proposed [25][26][27][28][29][30][31] . For example, a feasibility of capacitance enhancement is explainable from a strong coupling between FE and PE layers [25][26][27] , while the transient NC is understandable from the viewpoints of overshoot in voltage supply or slower speed of charge compensation relative to polarization switching in FE-CAP [28][29][30][31] . In fact, it has been argued that NC region of FE material is intrinsically unstable or even impossible 32,33 .…”

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confidence: 99%

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Stepwise internal potential jumps caused by multiple-domain polarization flips in metal/ferroelectric/metal/paraelectric/metal stack

Toriumi

2020

Nat Commun

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Negative capacitance (NC) effects in ferroelectric/paraelectric (FE/PE) stacks have been recently discussed intensively in terms of the steep subthreshold swing (SS) in field-effect transistors (FETs). It is, however, still disputable to stabilize quasi-static-NC effects. In this work, stepwise internal potential jumps in a metal/FE/metal/PE/metal system observed near the coercive voltage of the FE layer are reported through carefully designed DC measurements. The relationship of the internal potential jumps with the steep SS in FETs is also experimentally confirmed by connecting a FE capacitor to a simple metal-oxidesemiconductor FET. On the basis of the experimental results, the observed internal potential jumps are analytically modelled from the viewpoint of bound charge emission associated with each domain flip in a multiple-domain FE layer in a FE/PE stack. This view is different from the original NC concept and should be employed for characterizing FE/PE gate stack FETs.

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confidence: 99%

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confidence: 99%

Stepwise internal potential jumps caused by multiple-domain polarization flips in metal/ferroelectric/metal/paraelectric/metal stack

Toriumi

2020

Nat Commun

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“…Besides improving the sub-threshold slope significantly, the inclusion of a Ferroelectric layer of thickness of 4 nm in the gate stack will also eliminate the tunneling current through the gate oxide [6]. The Ferroelectric material has been deposited on the existing High-k gate stack, with the Ferroelectric material parameters reported by Agarwal et al [26] used for the simulation of the electrostatics of the Metal-Ferroelectric-Insulator-Semiconductor (MFIS) FET structure, which is found to be more practical compared to the Metal-Ferroelectric-Metal-Insulator-Semiconductor (MFMIS) structure [27]. The use of a Ferroelectric material in the gate stack of a short channel MOSFET has been reported to result in Drain induced barrier raise (DIBR) [28].…”

Section: Incorporation Of a Ferroelectric Materials Based Gate Stack ...mentioning

confidence: 99%

A Negative Capacitance Partially Junction-less Bulk MOSFET with Hysteresis Free Behavior and Improved Performance

Kansal¹,

Medury²

2022

Preprint

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<div>Despite the use of High-k gate stacks, poor channel electrostatics at short channel lengths has limited the applicability of conventional Bulk MOSFETs. With the use of Ferroelectric materials in the gate stack, enhanced transverse (gate) electric field has the potential to enable greater scalability, which needs to be further explored in the context of planar Bulk MOSFETs. In this paper, we firstly present the design of an optimized N-channel Partially Junction-less Bulk MOSFET with a view to suppressing various leakage mechanisms, while also taking channel quantization effects into account. Through detailed process simulations, the process steps required to achieve this device design are determined, thus providing a more practical appraisal of the feasibility of the device. We then identify the thickness of the Ferroelectric layer over the existing gate stack with a view to achieve steep sub-threshold slope (SS) while simultaneously ensuring hysteresis-free characteristics, including enhanced Analog as well as Digital performance of the device.</div><div><br></div>

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“…A second strategy exploits a positive feedback mechanism that amplifies the electrostatic control of the gate over the channel surface potential, such as in the nanoelectromechanical FET [11][12][13] and the steep-slope ferroelectric FET (SS-FeFET) [14][15][16][17] . In a SS-FeFET, the internal voltage amplification is realized either by means of abrupt (non-stabilized SS-FeFET) [18][19][20][21][22][23] , or gradual polarization switching (stabilized SS-FeFET) [24][25][26][27][28][29][30][31] of the ferroelectric.…”

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confidence: 99%

“…The importance of analyzing the appropriate thermodynamic potential cannot be understated: a thermodynamic equilibrium analysis based on an inappropriate potential is at risk of producing unphysical results. In the vast majority of works published today, the Gibbs free energy 21,[38][39][40][41][42][43][44] or (though less frequently) the Helmholtz free energy 27,45,46 is used. However, a formal justification has never been provided.…”

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confidence: 99%

Thermodynamic equilibrium theory revealing increased hysteresis in ferroelectric field-effect transistors with free charge accumulation

et al. 2021

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At the core of the theoretical framework of the ferroelectric field-effect transistor (FeFET) is the thermodynamic principle that one can determine the equilibrium behavior of ferroelectric (FERRO) systems using the appropriate thermodynamic potential. In literature, it is often implicitly assumed, without formal justification, that the Gibbs free energy is the appropriate potential and that the impact of free charge accumulation can be neglected. In this Article, we first formally demonstrate that the Grand Potential is the appropriate thermodynamic potential to analyze the equilibrium behavior of perfectly coherent and uniform FERRO-systems. We demonstrate that the Grand Potential only reduces to the Gibbs free energy for perfectly non-conductive FERRO-systems. Consequently, the Grand Potential is always required for free charge-conducting FERRO-systems. We demonstrate that free charge accumulation at the FERRO interface increases the hysteretic device characteristics. Lastly, a theoretical best-case upper limit for the interface defect density DFI is identified.

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On the validity and applicability of models of negative capacitance and implications for MOS applications

Cited by 36 publications

References 28 publications

Stepwise internal potential jumps caused by multiple-domain polarization flips in metal/ferroelectric/metal/paraelectric/metal stack

Stepwise internal potential jumps caused by multiple-domain polarization flips in metal/ferroelectric/metal/paraelectric/metal stack

A Negative Capacitance Partially Junction-less Bulk MOSFET with Hysteresis Free Behavior and Improved Performance

Thermodynamic equilibrium theory revealing increased hysteresis in ferroelectric field-effect transistors with free charge accumulation

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