Simple approach to include external resistances in the Monte Carlo simulation of MESFETs and HEMTs

Babiker, S.; Asenov, A.; Cameron, N.; Beaumont, S.P.

doi:10.1109/16.543047

Cited by 35 publications

(16 citation statements)

References 9 publications

(1 reference statement)

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“…In order to carry out the comparison of the measured results ͑extrinsic͒ with those obtained from the simulation ͑intrinsic͒, it is necessary to include, in a postprocessing stage, the parasitic elements that are not considered in the intrinsic MC model. 17 This behavior is the opposite of that found for latticematched InGaAs/InAlAs HEMTs, in which the increase in I D is lower for higher V GS . This occurs because although the electron concentration in the channel is larger when the channel opens, the maximum electron energy is reduced due to the lower gate-to-drain potential.…”

Section: Physical Modelcontrasting

confidence: 40%

Monte Carlo study of kink effect in isolated-gate InAs/AlSb high electron mobility transistors

Vasallo

Rodilla

González

et al. 2010

Journal of Applied Physics

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A semiclassical two-dimensional ensemble Monte Carlo simulator is used to perform a physical analysis of the kink effect in InAs/AlSb high electron mobility transistors ͑HEMTs͒. Kink effect, this is, an anomalous increase in the drain current I D when increasing the drain-to-source voltage V DS , leads to a reduction in the gain and a rise in the level of noise, thus limiting the utility of these devices for microwave applications. Due to the small band gap of InAs, InAs/AlSb HEMTs are very susceptible to suffer from impact ionization processes, with the subsequent hole transport through the structure, both implicated in the kink effect. The results indicate that, when V DS is high enough for the onset of impact ionization, holes thus generated tend to pile up in the buffer ͑at the gate-drain side͒ due to the valence-band energy barrier between the buffer and the channel. Due to this accumulation of positive charge the channel is further opened and I D increases, leading to the kink effect in the I-V characteristics and eventually to the device electrical breakdown. The understanding of this phenomenon provides useful information for the development of kink-effect-free InAs/AlSb HEMTs.

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Section: Physical Modelcontrasting

confidence: 40%

Monte Carlo study of kink effect in isolated-gate InAs/AlSb high electron mobility transistors

Vasallo

Rodilla

González

et al. 2010

Journal of Applied Physics

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“…Dirichlet boundary conditions) and assume ad-hoc modifications of the injection rate to achieve "local" charge neutrality (Bulashenko et al, 1998;Fischetti & Laux, 2001;Gomila et al, 2002;Gonzalez et al, 1997;Gonzalez & Pardo, 1993;Jacoboni & Lugli, 1989;Reklaitis & Reggiani, 1999;Wordelman & Ravaioli, 2000). Some works do also include analytically the series resistances of a large reservoir which can be considered an improvement over the previous boundary conditions (Babiker et al, 1996). Other MC simulators do also consider Neumann boundary conditions (i.e.…”

Section: Overview On the Treatment Of Coulomb Correlationsmentioning

confidence: 99%

Many-particle Monte Carlo Approach to Electron Transport

Albareda¹,

Traversa²,

Benali³

et al. 2011

Applications of Monte Carlo Method in Science and Engineering

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“…2b. In order to perform the comparison of the measured results (extrinsic) with those obtained from the simulation (intrinsic), it is necessary to include, in a postprocessing stage, the parasitic elements that are not considered in the intrinsic MC simulation [14]. Thus, drain and source parasitic resistances associated with the contact metallization and part of the ohmic regions not included in the simulation domain have been incorporated into the original MC results, with the best fit being obtained for R S = 0.13 Ω mm and R D = 0.38 Ω mm.…”

Section: Physical Modelmentioning

confidence: 99%

Monte Carlo Analysis of Impact Ionization in Isolated-Gate InAs/AlSb High Electron Mobility Transistors

et al. 2011

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We perform a physical analysis of the kink effect in InAs/AlSb high electron mobility transistors by means of a semiclassical 2D ensemble Monte Carlo simulator. Due to the small bandgap of InAs, InAs/AlSb high electron mobility transistors are very susceptible to suffer from impact ionization processes, with the subsequent hole transport through the structure, both implicated in the kink effect. When the drain-to-source voltage VDS is high enough for the onset of impact ionization, holes generated tend to pile up at the gate-drain side of the buffer. This occurs due to the valence-band energy barrier between the buffer and the channel. Because of this accumulation of positive charge, the channel is further opened and the drain current ID increases, leading to the kink effect in the I-V characteristics.PACS: 85.30.De, 85.30.Tv IntroductionDue to the high mobility of electrons in InAs and the excellent electron confinement in the channel, InAs/AlSb heterostructures are being considered to further improve the performance of high electron mobility transistors (HEMTs) for low-power, high-frequency and low-noise applications [1][2][3][4]. However, there are some problems to be eliminated, as the kink effect, an anomalous increase of the drain current I D when increasing the drain--to-source voltage V DS , caused by impact ionization and the subsequent hole dynamics in the structure. Kink effect leads to a reduction in the gain and a rise in the level of noise, thus limiting the utility of these devices for microwave applications. Thus, the development of strategies to reduce the negative consequences of kink effect on the operation of InAs/AlSb HEMTs is indispensable. In order to overcome the appearance of the associated excessive gate leakage current related to impact-ionization generated holes, the conventional Schottky contact has been replaced by an insulated gate by means of a native oxide [5]. Nevertheless, impact ionization events are extremely frequent because of the low band-gap in the channel material, and thus these devices can be much affected by kink effect.The purpose of this work is to perform an analysis of the physical origin of the kink effect in recessed isolated--gate AlSb/InAs HEMTs. With this aim, we make use of a semi-classical 2D ensemble Monte Carlo (MC) simulator [6] adequately adapted to correctly model InAs/ AlSb heterostructures [7], in which both impact ionization and hole dynamics are included [8,9]. The MC technique is the most adequate simulation tool for this

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Simple approach to include external resistances in the Monte Carlo simulation of MESFETs and HEMTs

Cited by 35 publications

References 9 publications

Monte Carlo study of kink effect in isolated-gate InAs/AlSb high electron mobility transistors

Monte Carlo study of kink effect in isolated-gate InAs/AlSb high electron mobility transistors

Many-particle Monte Carlo Approach to Electron Transport

Monte Carlo Analysis of Impact Ionization in Isolated-Gate InAs/AlSb High Electron Mobility Transistors

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