2017
DOI: 10.1088/1361-6641/aa92ff
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Extraction of mobility and Degradation coefficients in double gate junctionless transistors

Abstract: In this work, we use the modified McLarty function to understand and extract accumulation (μ acc ) and bulk (μ bulk ) mobility in Double Gate (DG) Junctionless (JL) MOSFETs over a wide range of doping concentration (N d ) and temperature range (250 K to 520 K). The approach enables the estimation of mobility and its attenuation factors (θ 1 and θ 2 ) by a single method. The extracted results indicate that μ acc can reach higher values than μ bulk due to the screening effect. Results also show that θ 2 extracte… Show more

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Cited by 10 publications
(13 citation statements)
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“…Due to the high source/drain series resistance R sd of the investigated devices, the second derivative of the drain current method for extracting the threshold voltage V t cannot be used [13], since the transconductance g m and, therefore, in JL transistors the measured V t would be underestimated [14], [15]. The series resistance R sd has been extracted following a simple extraction technique based on the measured total resistance R tot = V d /I d,tot as a function of the gate voltage, where I d,tot is the measured drain current and R tot is the sum of the source/drain series resistance and the channel resistance [15]. After determining the constant value of the total resistance R tot in the voltage range of V g  2 V for different channel lengths, the R sd value can be estimated from the intercept of the linear extrapolation of the R tot versus gate length L plot [15].…”
Section: Resultsmentioning
confidence: 99%
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“…Due to the high source/drain series resistance R sd of the investigated devices, the second derivative of the drain current method for extracting the threshold voltage V t cannot be used [13], since the transconductance g m and, therefore, in JL transistors the measured V t would be underestimated [14], [15]. The series resistance R sd has been extracted following a simple extraction technique based on the measured total resistance R tot = V d /I d,tot as a function of the gate voltage, where I d,tot is the measured drain current and R tot is the sum of the source/drain series resistance and the channel resistance [15]. After determining the constant value of the total resistance R tot in the voltage range of V g  2 V for different channel lengths, the R sd value can be estimated from the intercept of the linear extrapolation of the R tot versus gate length L plot [15].…”
Section: Resultsmentioning
confidence: 99%
“…The series resistance R sd has been extracted following a simple extraction technique based on the measured total resistance R tot = V d /I d,tot as a function of the gate voltage, where I d,tot is the measured drain current and R tot is the sum of the source/drain series resistance and the channel resistance [15]. After determining the constant value of the total resistance R tot in the voltage range of V g  2 V for different channel lengths, the R sd value can be estimated from the intercept of the linear extrapolation of the R tot versus gate length L plot [15]. Fig.…”
Section: Resultsmentioning
confidence: 99%
“…The accumulation mobility can be extracted by taking the second derivative of the 1/I acc curve. The bulk mobility can be computed by knowing the flat band voltage [64]. The mobility values can be degraded in case high voltages are applied [60].…”
Section: Double Gatementioning
confidence: 99%
“…Recently, the JLMOSFETs have received significant attention for their technological feasibility and theoretical modeling. In the last decades, several device architectures for JLMOSFETs were proposed, such as Thin Film JLMOSFET [5], [6], FinFET [7], [8], Tunnel FET [9], [10], gate-all-around (GAA) FET [11], [12], singlegate JLT (SG-JLT) [13], [14], double-gate JLMOSFETs (DG-JLMOSFETs) [15]- [18], etc. The DG-JLMOSFETs are becoming more promising due to their superior performances in high speed and low power applications [19].…”
Section: Introductionmentioning
confidence: 99%