Prediction of dielectric reliability from I–V characteristics: Poole–Frenkel conduction mechanism leading to √E model for silicon nitride MIM capacitor

Allers, K.-H.

doi:10.1016/j.microrel.2003.12.007

Cited by 87 publications

(24 citation statements)

References 19 publications

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“…For area and perimeter extrapolations also a structure with the largest area should be integrated. Usually, areas range from a few lm 2 to nearly 1 cm 2 [42].…”

Section: Mim Capacitor Test Structuresmentioning

confidence: 99%

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Reliability of gate dielectrics and metal–insulator–metal capacitors

Martin¹

2005

Microelectronics Reliability

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“…For area and perimeter extrapolations also a structure with the largest area should be integrated. Usually, areas range from a few lm 2 to nearly 1 cm 2 [42].…”

Section: Mim Capacitor Test Structuresmentioning

confidence: 99%

“…A sqrt(E)-model has been reported for a nitride MIM-capacitor dielectric [33,42] and for tantalum pentoxide dielectric [34]. Fig.…”

Section: Model For Mim Capacitormentioning

confidence: 99%

Reliability of gate dielectrics and metal–insulator–metal capacitors

Martin¹

2005

Microelectronics Reliability

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“…where E f is the electric field like the previous two models, and Q BD is the critical charge or the breakdown charge, Φ B is the trap depth, q is the elementary charge, ε 0 is permeability in a vacuum, and ε∞ is permeability in the dielectric [9]. Again, the square root E dependence can be seen.…”

Section: Time Dependent Dielectric Breakdown: the E 1/e And The √E mentioning

confidence: 93%

“…There are at least five (5) oxide breakdown models currently used by reliability engineers: the Bandgap Ionization Model, the Classic Anode Hole Injection (1/E) Model, the Hydrogen Release Model, the Thermochemical (E) Model [8], and a combination of the Charge-to-Breakdown (QBD) Hypothesis and the Poole-Frenkel (PF) Conduction (√E) Mechanism [9]. The important models to consider are the Classic Anode Hole…”

Section: Figure 222: Various Quantum Tunneling Illustrations [8]mentioning

confidence: 99%

“…The charge to breakdown hypothesis states that once a critical charge has been forced through the dielectric, the dielectric will break down. Also, the Poole-Frenkel Leakage Mechanism predicts that leakage current interacts with the dielectric which leads to degradation [9]. The corresponding equation…”

Section: Time Dependent Dielectric Breakdown: the E 1/e And The √E mentioning

confidence: 99%

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Design techniques to improve time dependent dielectric breakdown based failure for CMOS circuits

Tarog¹

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ii Analysis of the data from the software infrastructure showed that transistor sizing played a role in the MTTF. To maximize the MTTF of a transistor in a CMOS inverter, the activity of the pull-up transistor should be balanced with the transistor in the pulldown chain, ensuring the electric fields are balanced across both transistors. While it is impossible to completely balance an arbitrary CMOS circuit's activity for an arbitrary set of input signals, circuits can be intelligently skewed to help maximize the MTTF without increasing power consumption and without sacrificing circuit performance.Consequently, attaining a maximum MTTF does not come at a cost as it is possible to design a circuit with a high MTTF that performs better and uses less power than a circuit with low MTTF.

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Reliability of PZT Capacitors

2011

Ferroelectric Dielectrics Integrated on Silicon

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Prediction of dielectric reliability from I–V characteristics: Poole–Frenkel conduction mechanism leading to √E model for silicon nitride MIM capacitor

Cited by 87 publications

References 19 publications

Reliability of gate dielectrics and metal–insulator–metal capacitors

Reliability of gate dielectrics and metal–insulator–metal capacitors

Design techniques to improve time dependent dielectric breakdown based failure for CMOS circuits

Reliability of PZT Capacitors

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