• Journal of the Korean Institute of Telematics and Electronics A
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• v.33A no.4
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• pp.129-135
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• 1996

In this paper, the hot carrier effect and device degradation of deep submicrometer SC-PMOSFETs have been measured and characterized. It has been shown that the substrate current of a 0.15$\mu$m PMOSFET increases with increasing of impact ionization rate, and the impact ionization rate is a function of the gate length and gate bias voltage. Correlation between gate current and substrate current is investigated within the general framework of the lucky-electron. It is found that the impact ionization rate increases, but the device degradation is not serious with decreasing effective channel length. SCIHE is suggested as the possible phusical mechanism for enhanced impact ionization rate and gate current reduction. Considering the hot carrier induced device degradation, it has been found that the maximum supply voltage is about -2.6V for 0.15$\mu$m PMOSFET.

• Proceedings of the Korean Institute of Information and Commucation Sciences Conference
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• 2014.10a
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• pp.769-772
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• 2014

The device reliability in amorphous InGaZnO under NBS(Negative Bias Stress) and hot carrier stress with different gate overlap has been characterized. Amorphous InGaZnO thin film transistor has been measured. and is channel $width=104{\mu}m$, $length=10{\mu}m$ with gate overlap $length=0,1,2,3{\mu}m$. The device reliability has been analyzed by I-V characteristics. From the experiment results, threshold voltage variation has been increased with increasing of the gate overlap length after hot carrier stress. Also, threshold voltage variation has been decreased and Hump Effect has been observed later with increasing of the gate overlap length after NBS.

• 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.

• Proceedings of the Korean Institute of Information and Commucation Sciences Conference
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• 2014.10a
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• pp.749-752
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• 2014

The device performance of n-channel MuGFET with different fin width, existence of spacer and channel length has been characterized. Tri-Gate structure(fin number=10) has been used. There are four kinds of Tri-Gate with fin width=55nm with spacer, fin width=70nm with spacer, fin width=55nm without spacer, fin width=70nm without spacer. DIBL, subthreshold swing, Vt roll-off, (above Short Channel Effect)and hot carrier stress degradation have been measured. From the experiment results, short Channel Effect with spacer was decreased, hot carrier degradation with spacer and narrow fin width was decreased. Therefore, layout of LDD structure with spacer and narrow fin width is desirable in short channel effect and hot carrier degradation.

• Proceedings of the KIEE Conference
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• 1998.11c
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• pp.735-736
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• 1998

Reduction of hot carrier degradation in MOS devices has been one of the most serious concerns for MOS-ULSIs. In this paper, three types of LDD structure for suppression of hot carrier degradation, such as spacer-induced degradation and decrease of performance due to increase of series resistance will be investigated. LDD-nMOSFETs used in this study had three different drain structure. (1) conventional ${\underline{S}}urface$ type ${\underline{L}}DD$(SL), (2) ${\underline{B}}uried$ type ${\underline{L}}DD$(BL), (3) ${\underline{S}}urface$urface ${\underline{I}}mplantation$ type LDD(SI). As a result, the surface implantation type LDD structure showed that improved hot carrier lifetime to comparison with conventional surface and buried type LDD structure.

• Journal of the Korean Institute of Telematics and Electronics A
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• v.33A no.10
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• pp.130-138
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• 1996

The size of a device needs to scale down to increase its integrity and speed. As the size of the device is reduced, the hot-carrier degradation that severely effects on device reliabilty is concerned. In this paper, sub-micron buried-channel P-MOSFETs were fabircated, and the hot-carrier effects were invetigated. Also the hot-carrier effect in the buired-channel P-MOSFETs and the surface-channel P-MOSFETs were compared with simulation programs using SUPREM-4 and MINIMOS-4. This paper showed that the electric characteristics of sub-micron P-MOSFET are different from those of N-MOSFET. Also it showed that the punchthrough voltage ( $V_{pt}$ ) was abruptly drop after applying the stress and became almost 0V when the channel lengths were shorter than 0.6.mu.m. The lower punchthrough voltage causes the device to operte poorly by the deterioration of cut-off characteries in the switching mode. We can conclude that the buried channel P-MOSFET for CMOS circuits has a limit of the channel length to be around 0.6.mu.m.

• Proceedings of the Korean Vacuum Society Conference
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• 2012.02a
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• pp.142-142
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• 2012

최근 반도체 산업의 발전과 동시에 소자의 집적화에 따른 단채널 효과가 문제되고 있다. 채널 영역에 대한 게이트 영역의 제어능력이 떨어지면서 누설전류의 증가, 문턱전압의 변화가 발생하며, 이를 개선하기 위해 이중게이트 혹은 다중게이트 구조의 트랜지스터가 제안되었다. 하지만 채널길이가 수십나노미터 영역으로 줄어듦에 따라 소스/드레인과 채널간의 접합형성이 어렵고, 고온에서 열처리 과정을 거칠 경우 채널의 유효길이를 제어하기 힘들어진다. 최근에 제안된 Junctionless 트랜지스터의 경우, 소스/드레인과 채널간의 접합이 없기 때문에 접합형성 시 발생하는 공정상의 문제뿐만 아니라 누설전류영역을 개선하며, 기존의 CMOS 공정과 호환되는 이점이 있다. 한편, 집적화되는 반도체 기술에 따라, 동작 시 발생하는 스트레스가 소자의 신뢰성에 중요한 요인으로 작용하게 되며, 현재 Junctionless 트랜지스터의 신뢰성 특성에 관한 연구가 부족한 상황이다. 따라서, 본 연구에서는 Junctionless 트랜지스터의 NBTI 특성과 hot carrier effect에 의한 신뢰성 특성을 분석하였다. Junctionless 트랜지스터의 경우, 축적모드로 동작하기 때문에 스트레스에 의해 유기되는 캐리어의 에너지가 낮다. 그 결과, 반전모드로 동작하는 Junction type의 트랜지스터에 비해 스트레스에 의한 subthreshold swing 기울기의 열화와 문턱전압의 이동이 감소하였다. 또한 소스/드레인과 채널간의 접합이 없기 때문에 hot carrier effect에 의한 게이트 절연막 및 계면에서의 열화가 개선되었다.

• Journal of the Korean Institute of Telematics and Electronics A
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• v.28A no.12
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• pp.53-58
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• 1991

Hot-carrier induced degradation has been studied for the BF$_2$ ion-implanted surface-channel LDD(P$^{+}$ polysilicon gate) PMOSFET in comparison to the buried-channel structure(N$^{+}$ polysilicon gate) PMOSFET. The conditions for maximum degradation better correlated to I$_{g}$ than I$_{sub}$ for both PMOSFET's. Due to the use of LDD structure on SC-PMOSFET, the substrate current for SC-PMOSFET was shown to be smaller than that of BC-PMOSFET. The gate current was smaller as well, due to the gate material work-function difference between p$^{+}$ and n$^{+}$ polysilicon gates. From the results, it was shown that the surface-channel LDD PMOSFET is more resistant to short channel effect than the buried-channel PMOSFET.

• 전자공학회논문지 IE
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• v.45 no.2
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• pp.1-5
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• 2008

In this work, RF performance degradation due to hot carrier effects in SOI MOSFET have been measured and analyzed. The LNA that designed at $V_{GS}=0.8V$, f=2.5GHz, gain is 16.51dB and noise figure is 1.195dB. After stress at SOI, the LNA's gain and noise figure change of 15.3dB and 1.44dB with before stress.

• Proceedings of the IEEK Conference
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• 1999.06a
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• pp.970-973
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• 1999

When the size of the device is decreased, the hot carrier degradation presents a severe problem for long-term device reliability. In this paper we fabricated & tested the 0.26${\mu}{\textrm}{m}$ NMOSFET with wet gate oxide and nitride oxide gate to compare that the characteristics of hot carrier effect, charge to breakdown, transistor Id_Vg curve and charge trapping using the Hp4145 device tester As a result we find that the characteristics of nitride oxide gate device better than wet gate oxide device, especially a hot carrier lifetime(nitride oxide gate device satisfied 30years, but the lifetime of wet gate oxide was only 0.1year), variation of Vg, charge to breakdown and charge trapping etc.