Dielectric Breakdown in Chemical Vapor Deposited Hexagonal Boron Nitride

Insulating films are essential in multiple electronic devices because they can provide essential functionalities, such as capacitance effects and electrical fields. Two-dimensional (2D) layered materials have superb electronic, physical, chemical, thermal, and optical properties, and they can be effectively used to provide additional performances, such as flexibility and transparency. 2D layered insulators are called to be essential in future electronic devices, but their reliability, degradation kinetics, and dielectric breakdown (BD) process are still not understood. In this work, the dielectric breakdown process of multilayer hexagonal boron nitride (h-BN) is analyzed on the nanoscale and on the device level, and the experimental results are studied via theoretical models. It is found that under electrical stress, local charge accumulation and charge trapping/detrapping are the onset mechanisms for dielectric BD formation. By means of conductive atomic force microscopy, the BD event was triggered at several locations on the surface of different dielectrics (SiO2, HfO2, Al2O3, multilayer h-BN, and monolayer h-BN); BD-induced hillocks rapidly appeared on the surface of all of them when the BD was reached, except in monolayer h-BN. The high thermal conductivity of h-BN combined with the one-atom-thick nature are genuine factors contributing to heat dissipation at the BD spot, which avoids self-accelerated and thermally driven catastrophic BD. These results point to monolayer h-BN as a sublime dielectric in terms of reliability, which may have important implications in future digital electronic devices.Fil: Jiang, Lanlan. Soochow University; ChinaFil: Shi, Yuanyuan. Soochow University; China. University of Stanford; Estados UnidosFil: Hui, Fei. Soochow University; China. Massachusetts Institute of Technology; Estados UnidosFil: Tang, Kechao. University of Stanford; Estados UnidosFil: Wu, Qian. Soochow University; ChinaFil: Pan, Chengbin. Soochow University; ChinaFil: Jing, Xu. Soochow University; China. University of Texas at Austin; Estados UnidosFil: Uppal, Hasan. University of Manchester; Reino UnidoFil: Palumbo, Félix Roberto Mario. Comisión Nacional de Energía Atómica; Argentina. Universidad Tecnológica Nacional; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas; ArgentinaFil: Lu, Guangyuan. Chinese Academy of Sciences; República de ChinaFil: Wu, Tianru. Chinese Academy of Sciences; República de ChinaFil: Wang, Haomin. Chinese Academy of Sciences; República de ChinaFil: Villena, Marco A.. Soochow University; ChinaFil: Xie, Xiaoming. Chinese Academy of Sciences; República de China. ShanghaiTech University; ChinaFil: McIntyre, Paul C.. University of Stanford; Estados UnidosFil: Lanza, Mario. Soochow University; Chin

Total dose evaluation of deep submicron CMOS imaging technology through elementary device and pixel array behavior analysis

Ionizing radiation effects on CMOS image sensors (CIS) manufactured using a 0.18 µm imaging technology are presented through the behavior analysis of elementary structures, such as field oxide FET, gated diodes, photodiodes and MOSFETs. Oxide characterizations appear necessary to understand ionizing dose effects on devices and then on image sensors. The main degradations observed are photodiode dark current increases (caused by a generation current enhancement), minimum size NMOSFET off-state current rises and minimum size PMOSFET radiation induced narrow channel effects. All these effects are attributed to the shallow trench isolation degradation which appears much more sensitive to ionizing radiation than inter layer dielectrics. Unusual post annealing effects are reported in these thick oxides. Finally, the consequences on sensor design are discussed thanks to an irradiated pixel array and a comparison with previous work is discussed

Reliability Studies of TiN/Hf-Silicate Based Gate Stacks

Hafnium-silicate based oxides are among the leading candidates to be included into the first generation of high-Κ gate stacks in nano-scale CMOS technology because of their distinct advantages as far as thermal stability, leakage characteristics, threshold stability and low mobility degradation are concerned. Their reliability, which is limited by trapping at pre-existing and stress induced defects, remains to be a major concern. Energy levels of electrically active ionic defects within the thick high-Κ have been experimentally observed in the context of MOS band diagram for the first time in Hf-silicate gate stacks from low temperature and leakage measurements. Excellent match between experimental and calculated defect levels shows that bulk O vacancies are probably responsible for electron trapping at both shallow and deep levels. Their role in trapping and transport under different gate polarity and band bending conditions has been determined. For gate injection, electron transport through mid-gap states dominates, which leads to slow transient trapping at deep levels. Under substrate injection field and temperature dependent transport through conduction-edge shallow levels or trap-assisted tunneling due to negative- U transition occurs depending on bias condition. The former gives rise to fast transient trapping, whereas the latter is responsible for slow transient trapping. Mixed degradation, due to trapping of both electrons and holes in the trap levels within the bulk high-K, was observed under constant voltage stress (CVS) applied on n-channel MOS capacitors with negative bias condition. Mixed degradation resulted in turn-around effect in flat-band voltage shift (ΔFB) with respect to stress time. Under CVS with positive bias, applied on nMOSFETs, lateral distribution of trapped charges in the deep levels causes turn-around effect in threshold voltage shift (ΔVT) with respect to stress levels. For the incident carrier energies above the calculated 0 vacancy formation threshold and thick high-Κ layer, both flatband voltage shift, due to electron trapping at the deep levels, and increase in leakage current during stress follow tn(n ≈ 0.4) power-law dependence under substrate hot electron injection. Negative-U transitions to deep levels are shown to be responsible for the strong correlation between slow transient trapping and trap assisted tunneling. As far as negative bias temperature instability, NBTI effects on pMOSFETs is concerned, ΔVT is due to the mixed degradation within the bulk high-Κ for low bias conditions. For moderately high bias, ΔVT shows an excellent match with that of SiO, based devices, which is explained by reaction-diffusion (R-D) model of NBTL. Under high bias condition at elevated temperatures, due to high Si-H bond-annealing/bond-breaking ratio, the experimentally observed absence of the impact ionization induced hot holes at the interfacial layer (IL)/Si interface probably limits the interface state generation and ΔVT as they quickly reach saturation. Time-zero dielectric breakdown (TZBD) characteristics of TiN/HfO2 based gate stacks show that thickness and growth conditions significantly affect the BD field of IL. For the thin high-w layers, BD of IL triggers BD of the gate stack. Otherwise, BD of high-w layer initiates it. During time dependent dielectric breakdown, TDDB, four regimes of degradation are observed under CVS with high gate bias conditions: (i) charge trapping/defect generation, (ii) soft breakdown (SBD), (iii) progressive breakdown and (iv) hard breakdown (HBD). Activation energy of bond-breakage, found from Arrhenius plots of 63% failure value of TBD, shows that IL degradation triggers gate stacks BD, and the wear-out during TDDB

Development of plasma enhanced chemical vapor deposition (PECVD) gate dielectrics for TFT applications

This study investigated a variety of electrically insulating materials for potential use as a gate dielectric in thin-film transistor applications. The materials that were investigated include silicon dioxide and oxynitride films deposited using PECVD and LPCVD techniques. Silicon source materials included tetraethylorthosilicate (TEOS) and silane (SiH4). Oxygen sources included diatomic oxygen (O2) and nitrous oxide (N2O). The optical, electrical, and material properties of the dielectrics were analyzed using Variable Angle Spectroscopic Ellipsometry (VASE), Fourier Transform Infrared Spectroscopy (FTIR), Capacitance-Voltage (C-V) analysis and current-voltage (I-V) analysis. Transistors were also fabricated at low temperatures with different gate dielectrics to investigate the impact on device performance. While a deposited gate dielectric is intrinsically inferior to a thermally grown SiO2 layer, an objective of this study was to create a high quality gate dielectric with low levels of bulk and interface charge (Qit & Qot~1x1010 cm2); this was achieved

TiN/HfO2/SiO2/Si gate stacks reliability : Contribution of HfO2 and interfacial SiO2 layer

Hafnium Oxide based gate stacks are considered to be the potential candidates to replace SiO2 in complementary metal-oxide-semiconductor (CMOS), as they reduce the gate leakage by over 100 times while keeping the device performance intact. Even though considerable performance improvement has been achieved, reliability of high-κ devices for the next generation of transistors (45nm and beyond) which has an interfacial layer (IL: typically SiO2) between high-κ and the substrate, needs to be investigated. To understand the breakdown mechanism of high-κ/SiO2 gate stack completely, it is important to study this multi-layer structure extensively. For example, (i) the role of SiO2 interfacial layers and bulk high-κ gate dielectrics without any interfacial layer can be investigated separately while maintaining same growth conditions; (ii) the evolution of breakdown process can be studied through stress induced leakage current (SILC); (iii) relationship of various degradation mechanisms such as negative bias temperature instability (NBTI) with that of the dielectric breakdown; and (iv) a fast evaluation process to estimate statistical breakdown distribution. In this dissertation a comparative study was conducted to investigate individual breakdown characteristics of high-κ/IL (ISSG SiO2)/metal gate stacks, in-situ steam generated (ISSG)-SiO2 MOS structures and HfO2-only metal-insulator-metal (MIM) capacitors. Experimental results indicate that after constant voltage stress (CVS) identical degradation for progressive breakdown and SILC were observed in high-κ/IL and SiO2-only MOS devices, but HfO2-only MIM capacitors showed insignificant SILC and progressive breakdown until it went into hard breakdown. Based on the observed SILC behavior and charge-to-breakdown (QBD), it was inferred that interfacial layer initiates progressive breakdown of metal gate/high-κ gate stacks at room temperature. From normalized SILC (ΔJg/Jg0) at accelerated temperature and activation energy of the timeto- breakdown (TBD), it was observed that IL initiates the gate stack breakdown at higher temperatures as well. A quantitative agreement was observed for key parameters of NBTI and time dependent dielectric breakdown (TDDB) such as the activation energies of threshold voltage change and SILC. The quality and thickness variation of the IL causes similar degradation on both NBTI and TDDB indicating that mechanism of these two reliability issues are related due to creation of identical defect types in the IL. CVS was used to investigate the statistical distribution of TBD, defined as soft or first breakdown where small sample size was considered. As TBD followed Weibull distribution, large sample size was not required. Since the failure process in static random access memory (SRAM) is typically predicted by the realistic TDDB model based on gate leakage current (IFAIL) rather than the conventional first breakdown criterion, the relevant failure distributions at IFAIL are non-Weibull including the progressive breakdown (PBD) phase for high-κ/metal gate dielectrics. A new methodology using hybrid two-stage stresses has been developed to study progressive breakdown phase further for high-κ and SiO2. It is demonstrated that VRS can be used effectively for quantitative reliability studies of progressive breakdown phase and final breakdown of high-κ and other dielectric materials; thus it can replace the time-consuming CVS measurements as an efficient methodology and reduce the resources manufacturing cost

Study of the effects of deuterium implantation upon the performance of thin-oxide CMOS devices

The use of ultra thin oxide films in modem semiconductor devices makes them increasingly susceptible to damage due to the hot carrier damage. Deuterium in place of hydrogen was introduced by ion implantation at the silicon oxide-silicon interface during fabrication to satisfy the dangling bonds. Deuterium was implanted at energies of 15, 25 and 35 keV and at a dose of 1x1014/cm2. Some of the wafers were subjected to N2O annealing following gate oxide growth. It was demonstrated that ion implantation is an effective means of introduction of deuterium. Deuterium implantation brings about a clear enhancement in gate oxide quality by improving the interface characteristics. N2O annealing further improves device performance. A reduction of electron traps with deutenum was also observed. A combination of deuterium implantation at 25 keV and a dose of 1x1015/cm2, followed by annealing in N2O was observed to have the most positive influence on device behavior. Concurrently, MEMS microheaters being fabricated for an integrated VOC sensor were also tested for their temperature response to an applied voltage. Different channel configurations and materials for the conducting film were compared and the best pattern for rapid heating was identified. Temperature rises of upto 390° C were obtained. The temperature responses after coating spin-on glass in the microchannels were also measured

Polycrystallization effects on the nanoscale electrical properties of high-k dielectrics

In this study, atomic force microscopy-related techniques have been used to investigate, at the nanoscale, how the polycrystallization of an Al2O3-based gate stack, after a thermal annealing process, affects the variability of its electrical properties. The impact of an electrical stress on the electrical conduction and the charge trapping of amorphous and polycrystalline Al2O3 layers have been also analyzed

Radiation damage studies in gate oxides

Detailed investigation of the effects of Gamma-ray irradiation on the electrical properties such as current-voltage arid capacitance-voltage characteristics in thermally grown SiO2 films in the thickness range of 15 to 120 nm on silicon substrates is presented in this thesis. The structures used in this study are Al/Poly/SiO2/Si/Al and Al/SiO2/Si/Al MOS capacitors. Based on the electrical characterization studies, we observe that irradiation causes generation of positive charges in the oxide leading to a shift of the high frequency Capacitance-Voltage (C-V) curves. An increase in surface state density at the SiO2-Si interface with increase in radiation dose is also observed. Static current-voltage (I-V) characteristics lead to a further insight in the formation of radiation induced oxide traps. Fowler-Nordheim tunneling in irradiated MOS structures is investigated