• Journal of the Korean Institute of Telematics and Electronics A
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• v.30A no.12
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• pp.77-87
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• 1993

PMOSFETs were studied on the effect of Hot-Carrier induced drain leakage current (Gate-Induced-Drain-Leakage). The result turned out that change in Vgl(drain voltage where 1pA/$\mu$m of drain leadage current flows) was largest in the Channel-Hot-Hole(CHH) injection condition and next was in dynamic stress and was smallest in electron trapping (Igmax) condition under various stress conditions. It was analyzed that if electron trapping occurrs in the overlap region of gate and drain(G/D), it reduces GIDL current due to increment of flat-band voltage(Vfb) and if CHH is injected, interface states(Nit) were generated and it increases GIDL current due to band-to-defect-tunneling(BTDT). Especially, under dynamic stress it was confirmed that increase in GIDL current will be high when electron injection was small and CHH injection was large. Therefore as applying to real circuit, low drain voltage GIDL(BTDT) was enhaced as large as CHH Region under various operating voltage, and it will affect the reliablity of the circuit.

• Journal of the Institute of Electronics and Information Engineers
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• v.50 no.8
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• pp.285-291
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• 2013

In this paper, MOS-Capacitor and MOSFET devices with a Low Level Leakage Current of oxide thickness, channel width and length respectively were to investigate the reliability characterizations mechanism of ultra thin gate oxide films. These stress induced leakage current means leakage current caused by stress voltage. The low level leakage current in stress and transient current of thin silicon oxide films during and after low voltage has been studied from strss bias condition respectively. The stress channel currents through an oxide measured during application of constant gate voltage and the transient channel currents through the oxide measured after application of constant gate voltage. The study have been the determination of the physical processes taking place in the oxides during the low level leakage current in stress and transient current by stress bias and the use of the knowledge of the physical processes for driving operation reliability.

• Journal of the Institute of Electronics Engineers of Korea SD
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• v.37 no.4
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• pp.31-37
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• 2000

In the case of metal-induced lateral crystallization (MILC) for low temperature poly-Si TFT, offset length between Ni-thin film and the sides of gate could be modified to control the location of MILC boundary. Electrical characteristics were compared to analyze the effect of MILC boundary that was located either in or out of the channel region of the TFT. By removing the MILC boundary from channel region, on current, subthreshold slope and leakage current properties could be improved. When MILC boundary was located in the channel region, leakage current was reduced with electrical stress biasing. The amount of reduction increased as the channel width increased, but it was independent of the channel length.

• Journal of the Korean Crystal Growth and Crystal Technology
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• v.8 no.3
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• pp.411-418
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• 1998

The thickness dependence of stress electric filed oxide currents has been measured in oxides with thicknesses between 10 nm and 80 nm. The oxide currents were shown to be composed of stress current and transient current. The stress current was composed of stress induced leakage current and dc current. The stress current was caused by trap assisted tunneling through the oxide. The transient current was caused by the tunneling charging and discharging of the trap in the interfaces. The stress current was used to estimate to the limitations on oxide thicknesses. The transient current was used to the data retention in memory devices.

• The Journal of Korea Institute of Information, Electronics, and Communication Technology
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• v.16 no.4
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• pp.173-179
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• 2023

This paper analyzes the time-dependent dielectric breakdown(TDDB) degradation mechanism for each stress region of Peri devices manufactured by 4th generation VNAND process, and presents a complementary lifetime prediction model that improves speed and accuracy in a wider reliability evaluation region compared to the conventional model presented. SiON dielectric nMOSFETs were measured 10 times each under 5 constant voltage stress(CVS) conditions. The analysis of stress-induced leakage current(SILC) confirmed the significance of the field-based degradation mechanism in the low electric field region and the current-based degradation mechanism in the high field region. Time-to-failure(TF) was extracted from Weibull distribution to ascertain the lifetime prediction limitations of the conventional E-model and 1/E-model, and a parallel complementary model including both electric field and current based degradation mechanisms was proposed by extracting and combining the thermal bond breakage rate constant(k) of each model. Finally, when predicting the lifetime of the measured TDDB data, the proposed complementary model predicts lifetime faster and more accurately, even in the wider electric field region, compared to the conventional E-model and 1/E-model.

• The Journal of Korean Institute of Communications and Information Sciences
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• v.15 no.3
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• pp.252-259
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• 1990

This paper present new scheme for a Side Wall Masked Isolation(SWAMI) technology which take all the advatages provided by conventional LOCOS process. A new SWAMI process incorporates a sloped sidewall by reactive ion etch and a layer of thin nitride around the side walls such that both intrinsic nitride stress and volume expansion induced stress are greatly reduced. As a fabricate results, a defect-free fully recessed zero bird's beak local oxidation process can be realized by the sloped wall anisotropic oxide isolation. No additional masking step is required. The leakage current of PN diodes of this process were reduced than PN diode of conventional LOCOS process. On the other hand, the edge junction part was larger than the flat juction part in the density of leakage current.

• Proceedings of the Korean Vacuum Society Conference
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• 1998.02a
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• pp.71-72
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• 1998

반도체 집적 공정의 발달로 차세대 소자용으로 30 A 이하의 극 박막 Si02 절연막이 요구되고 있으며, 현재 제품으로 50-70 A 두께의 절연막을 사용한 것이 발표되고 있다. 절연막의 두께가 앓아질수록 많은 문제가 발생할 수 있는데 그 예로 절연막의 breakdo때둥에 의한 신뢰성 특성의 악화, 절연막올 통한 direct tunneling leakage current, boron풍의 dopant 침투로 인한 소자 특성 ( (Threshold Voltage)의 불안, 전기적 stress하에서의 leakage current증가와 c charge-trap 및 피terface s쩌.te의 생성으로 인한 소자 특성의 변화 둥으로 요약 된다. 절연막의 특성올 개선하기 위해 여러 가지 새로운 공정들이 제안되었다. 그 예로, Nitrogen올 Si/Si02 계면에 doping하여 절연막의 특성을 개선하는 방법 으로 고온 열처 리 를 NH3, N20, NO 분위 기 에서 실시 하거 나, polysilicon 또는 s silicon 기판에 nitrogen올 이온 주입하여 열처리 하는 방법, 그리고 Plasma분 위기에서 Nitrogen 함유 Gas를 이용하여 nitrogen을 doping시키는 방법 둥이 연구되고 있다. 또한 Oxide cleaning 후 상온에서 성장되는 oxide를 최소화 하여 절연막의 특성올 개선하기 위하여 LOAD-LOCK을 이용하는 방법, C뼈피ng 공정의 개선올 통한 contamination 감소와 silicon surface roughness 감소 로 oxide 신뢰성올 개선하는 방법 둥이 있다. 구조적 인 측면 에 서 는 Polysilicon 의 g없n size 를 최 적 화하여 OxideIPolysilicon 의 계면 특성올 개선하는 연구와 Isolation및 Gate ETCH공정이 절연막의 특성에 미 치 는 영 향도 많이 연구되 고 있다 .. Plasma damage 가 Oxide 에 미 치 는 효과 를 제어하는 방법과 Deuterium열처리 퉁올 이용하여 Hot electron Stress하에서 의 MOS 소자의 Si/Si02 계면의 신뢰성을 개선하고 있다. 또한 극 박막 전연막의 신뢰성 특성올 통계적 분석올 통하여 사용 가능한 수명 올 예 측 하는 방법 과 Direct Tunneling Leakage current 를 고려 한 허 용 가농 한 동작 전 압 예측 및 Stress Induced Leakage Current 둥에 관해서 도 최 근 활발 한 연구가 진행되고 있다.

• Journal of the Korean Institute of Telematics and Electronics D
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• v.34D no.11
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• pp.30-36
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• 1997

AlGaAs/GaAs HBTs are developed well enough to be commercialized as an active device in optical transmission system, but there remains the unanswered questions about reliability. In this paper we applied the reverse constant current stress at the high voltage in avalanche region for a long time to find out a new degradation mechanism of junctrion I-V. The unction off-set voltage at which the current vanishes to zero was shifted to the negative direction of applied bias due to the increment of leakage current as the stress time increases. It was identified that the degradation was induced by the hot carriers which were generated at space charge region and trapped at the interface between GaAs base and the passivation nitride enhancing the electric field across the nesa edge.

• Journal of the Korea Institute of Information and Communication Engineering
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• v.13 no.2
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• pp.348-354
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• 2009

It has analyzed that the device degradation by NBTI (Negative Bias Temperature Instability) stress induced the increase of gate-induced-drain-leakage(GIDL) current for p-MOSFETs. It is shown that the degradation magnitude, as well as its time, temperature, and field dependence, is govern by interface traps density at the silicon/oxide interface. from the relation between the variation of threshold voltage and subthreshold slope, it has been found that the dominant mechanism for device degradation is the interface state generation. From the GIDL measurement results, we confined that the EHP generation in interface state due to NBTI stress led to the increase of GIDL current. Therefore, one should take care of the increased GIDL current after NBTI stress in the ultra-thin gate oxide device. Also, the simultaneous consideration of reliability characteristics and dc device performance is highly necessary in the stress engineering of nanoscale CMOSFETs.

• The Journal of Korean Institute of Communications and Information Sciences
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• v.35 no.1A
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• pp.80-86
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• 2010

This work has been measured and analyzed the device degradation of NBTI (Negative Bias Temperature Instability) stress induced the increase of gate-induced-drain-leakage(GIDL) current for p-MOS transistors of gate channel length 0.13 [${\mu}m$]. From the relation between the variation of threshold voltage and subthreshold slop by NBTI stress, it has been found that the dominant mechanism for device degradation is the interface state generation. From the GIDL measurement results, we confined that the EHP generation in interface state due to NBTI stress led to the increase of GIDL current. As a results, one should take care of the increased GIDL current after NBTI stress in the ultra-thin gate oxide device. Also, the simultaneous consideration of reliability characteristics and dc device performance is highly necessary in the stress parameters of nanoscale CMOS communication circuit design.