• Journal of the Korean Institute of Telematics and Electronics
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• v.25 no.2
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• pp.182-187
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• 1988

Hot carrier induced device degradation characteristics under DC bias stress have been investigated in n-MOSFETs with channel length of 1.2,1.8 um, and compared with those of LDD structure device with same channel length. Based on these results, the device lifetime in normal operating bias(Vgs=Vds=5V) is evaluated. The lifetimes of conventional and LDD n-MOSFET with channel length of 1.2 um are estimated about for 17 days and for 12 years, respectively. The degradation rate of LDD n-MOSFET under the same stress is the lowest at n-region implnatation dose of 2.5E15 cm-\ulcorner while the substrate current is the lowest at the dose of 1E13cm-\ulcorner Thses results show that the device degradation characteristics are basic measurement parameter to find optimum process conditions in LDD devices and evaluate a reliability of sub-micron device.

• Proceedings of the KIEE Conference
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• 1987.07a
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• pp.469-472
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• 1987

The hot-carrier induced degradation in very short-channel MOSFET was studied systematically. Under the traditional DC stress conditions, the threshold voltage shift (${\Delta}Vt$) and the transconductance degradation (${\Delta}Gm$/(Gmo-${\Delta}Gm$)) were confirmed to depend exponentially on the stress time and the dependency between the two parameters was proved to be linear. And the degradation due to the DC stress across gate and drain was studied. As the AC dynamic process is more realistic in actual device operation, the effects of dynamic stresses were studied.

• 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 Institute of Electronics Engineers of Korea SD
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• v.40 no.10
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• pp.32-38
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• 2003

This works reports the measurement and analysis results on the hot electron induced device degradation in Gate-All-Around SOI MOSFET's, which were fabricated using commercially available SIMOX material. It is observed that the worst-case condition of the device degradation in nMOSFETs is $V_{GS}$ = $V_{TH}$ due to the higher impact ionization rate when the parasitic bipolar transistor action is activated. It is confirmed that the device degradation is caused by the interface state generation from the extracted degradation rate and the dynamic transconductance measurement. The drain current degradation with the stress gate voltages shows that the device degradation of pMOSFETs is dominantly governed by the trapping of hot electrons, which are generated in drain avalanche hot carrier phenomena.r phenomena.

• Journal of the Korean Institute of Telematics and Electronics A
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• v.31A no.1
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• pp.93-102
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• 1994

This paper, presents SECRET(SEC REliability Tool), which predicts reliability problems related to the hot-carrier and electromigration effects on the submicron MOSFETs and interconnections. To simulate DC and AC lifetime for hot-carrier damaged devices, we have developed an accurate substrate current model with the geometric sensitivity, which has been verified over the wide ranges of transistor geometries. A guideline can be provided to design hot-carrier resistant circuits by the analysis of HOREL(HOT-carrier RFsistant Logic) effect, and circuit degradation with respect to physical parameter degradation such as the threshold voltage and the mobility can also be expected. In SECRET, DC and AC MTTF values of metal lines are calculated based on lossy transmission line analysis, and parasitic resistances, inductances and capacitances of metal lines are accurately considered when they operate in the condition of high speed. Also, circuit-level reliability simulation can be applied to the determination of metal line width and-that of optimal capacitor size in substrate bias generation circuit. Experimental results obtained from the several real circuits show that SECERT is very useful to estimate and analyze reliability problems.

• Journal of the Korea Institute of Information and Communication Engineering
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• v.21 no.1
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• pp.82-89
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• 2017

In this work, InGaZnO thin film transistors with Ni, Al and ITO source and drain electrode materials were fabricated to analyze a hot carrier induced device degradation according to the electrode materials. From the electrical measurement results with electrode materials, Ni device shows the best electrical performances in terms of mobility, subthreshold swing, and $I_{ON}/I_{OFF}$. From the measurement results on the device degradation with source and drain electrode materials, Al device shows the worst device degradation. The threshold voltage shifts with different channel widths and stress drain voltages were measured to analyze a hot carrier induced device degradation mechanism. Hot carrier induced device degradation became more significant with increase of channel widths and stress drain voltages. From the results, we found that a hot carrier induced device degradation in InGaZnO thin film transistors was occurred with a combination of large channel electric field and Joule heating effects.

• Journal of the Korean Institute of Telematics and Electronics D
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• v.35D no.11
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• pp.62-69
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• 1998

The general degradation model has been applied to analyze the hot carrier induced degradation of the DC and RF characteristics of RF-nMOSFET. The degradation of cut-off frequency has been severer than the degradation of bulk MOSFET drain current. The value of the degradation rate n and the degradation parameter m for RF-nMOSFET has been equal to those for bulk MOSFET. The decrease of device degradation with the increase of fingers could be explained by the large source/drain parasitic resistance and drain saturation voltage. It has been also found that the RF performance degradation could be explained by the decrease of $g_{m}$ and $C_{gd}$ and the increase of $g_{ds}$ after stress. The degradation of the DC and RF characteristics of RF-nMOSFET could be predicted by the measurement of the substrate current.t.

• Journal of the Korea Society for Simulation
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• v.17 no.2
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• pp.13-19
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• 2008

New Buffered deposition is proposed to decrease junction electric field in this paper. Buffered deposition process is fabricated after first gate etch, followed NM1 ion implantation and deposition & etch nitride layer. New Buffered deposition structure has buffer layer to decrease electric field. Also we compared the hot carrier characteristics of Buffered deposition and conventional. Also, we design a test pattern including NMOSFET, PMOSFET, LvtNMOS, High pressure N/PMOSFET, so that we can evaluate DC/AC hot carrier degradation on-chip. As a result, we obtained 10 years hot carrier life time satisfaction.

• Journal of the Korean Institute of Electrical and Electronic Material Engineers
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• v.11 no.9
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• pp.683-686
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• 1998

Hot carrier effects as a function of bias stress time and bias stress consitions were syste-matically investigated in p-channel poly-Si TFT s fabricated on the quartz substrate. The device degradation was observed for the negative bias stress, while improvement of electrical characteristic except for subthreshold slope was observed for the positive bias stress. It was found that these results were related to the hot-carrier injection into the gate oxide and interface states at the poly-Si/$SiO_2$interface rather than defects states generation within the poly-Si active layer under bias stress.

• 한국정보디스플레이학회:학술대회논문집
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• 2007.08b
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• pp.1065-1070
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• 2007

The effects of hot carriers and self-heating on the electrical stability of p-channel TFTs have been analysed combining experimental data and numerical simulations. While hot carrier effects were shown not to induce appreciable degradation, self-heating related instability was found to more seriously affect the device characteristics. New models have been developed to explain the reported results.