Markus Jech scite author profile

Nanoelectronic devices based on 2D materials are far from delivering their full theoretical performance potential due to the lack of scalable insulators. Amorphous oxides that work well in silicon technology have ill-defined interfaces with 2D materials and numerous defects, while 2D hexagonal boron nitride does not meet required dielectric specifications. The list of suitable alternative insulators is currently very limited. Thus, a radically different mindset with respect to suitable insulators for 2D technologies may be required. We review possible solution scenarios like the creation of clean interfaces, production of native oxides from 2D semiconductors and more intensive studies on crystalline insulators.

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Comphy — A compact-physics framework for unified modeling of BTI

Rzepa

Franco

O’Sullivan

et al. 2018

Microelectronics Reliability

165

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Identification of oxide defects in semiconductor devices: A systematic approach linking DFT to rate equations and experimental evidence

Goes

Wimmer

El-Sayed

et al. 2018

Microelectronics Reliability

120

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It is well-established that oxide defects adversely affect functionality and reliability of a wide range of microelectronic devices. In semiconductor-insulator systems, insulator defects can capture or emit charge carriers from/to the semiconductor. These defects feature several stable configurations, which may have profound implications for the rates of the charge capture and emission processes. Recently, these complex capture/emission events have been investigated experimentally in considerable detail in Si/SiO2 devices, but their theoretical understanding still remains vague. In this paper we discuss in detail how the capture/emission processes can be simulated using the theoretical methods developed for calculating rates of charge transfer reactions between molecules and in electro-chemistry. By employing this theoretical framework we link the atomistic defect configurations to known trapping model parameters (e.g. trap levels) as well as measured capture/emission times in Si/SiO2 devices. Using density functional theory (DFT) calculations, we investigate possible atomistic configurations for various defects in amorphous (a)-SiO2 implicated in being involved in the degradation of microelectronic devices. These include the oxygen vacancy and hydrogen bridge as well as the recently proposed hydroxyl E center. In order to capture the effects of statistical defect-to-defect variations that are inevitably present in amorphous insulators, we analyze a large ensemble of defects both experimentally and theoretically. This large-scale investigation allows us to prioritize the candidates from our defect list based on their trap parameter distributions. For example, we can rule out the E center as a possible candidate. In addition, we establish realistic ranges for the trap parameters, which are useful for model calibration and increase the credibility of simulation results by avoiding artificial solutions. Furthermore, we address the effect of nuclear tunneling, which is involved according to the theory of charge transfer reactions. Based on our DFT results, we demonstrate the impact of nuclear tunneling on the capture/emission process, including their temperature and field dependence, and also give estimates for this effect in Si/SiO2 devices.

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Understanding and Modeling the Temperature Behavior of Hot-Carrier Degradation in SiON nMOSFETs

Tyaginov

Jech

Franco

et al. 2016

IEEE Electron Device Lett.

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Ab initio investigations in amorphous silicon dioxide: Proposing a multi-state defect model for electron and hole capture

Wilhelmer

Waldhoer

Jech

et al. 2022

Microelectronics Reliability

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Markus Jech

Insulators for 2D nanoelectronics: the gap to bridge

Comphy — A compact-physics framework for unified modeling of BTI

Identification of oxide defects in semiconductor devices: A systematic approach linking DFT to rate equations and experimental evidence

Understanding and Modeling the Temperature Behavior of Hot-Carrier Degradation in SiON nMOSFETs

Ab initio investigations in amorphous silicon dioxide: Proposing a multi-state defect model for electron and hole capture

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