Crosstalk in SiC power MOSFETs for evaluation of threshold voltage shift caused by bias temperature instability

Threshold voltage drift from Bias Temperature Instability is known to be a reliability concern for SiC MOSFETs. Negative bias temperature instability (NBTI) results from positive charge trapping at the gate dielectric interface and is more problematic in SiC due to the higher interface trap density. Turning SiC MOSFETs OFF with negative voltages to avoid Miller coupling induced cross-talk can cause VTH shifts in periods with long standby duration and high temperatures. This paper proposes a novel test method for BTI characterization that relies on measuring the shoot-through current and charge during switching transients. The method exploits the Miller coupling between 2 devices in the same phase and uses the shoot-through current from parasitic turn-ON to monitor VTH. Standard techniques require the use of static measurements (typically from a parameter analyzer or a curve tracer) to determine the threshold voltage shift. These conventional methods can underestimate the VTH shift since the recovery from charge de-trapping can mask the true extent of the problem. The proposed methodology uses the actual converter environment to investigate the VTH shift and should therefore be of more interest to applications engineers as opposed to device physicists. Furthermore, it avoids the problem of VTH recovery and is therefore more accurate in VTH shift characterization

Impact of the gate oxide reliability of SiC MOSFETs on the junction temperature estimation using temperature sensitive electrical parameters

Bias temperature instability (BTI) is more problematic in SiC power MOSFETs due to the occurrence of higher interface state traps and fixed oxide traps compared to traditional silicon MOS interfaces where there are no carbon atoms degrading the atomically smooth Si/SiO2 interface. The use of temperature sensitive electrical parameters (TSEPs) for measuring the junction temperature and enabling health monitoring based on junction temperature identification is a promising technique for increasing the reliability of power devices, however in the light of increased BTI in SiC devices, this must be carefully assessed. This paper evaluates how BTI of SiC power MOSFETs under high temperature gate bias stresses affects the electrical parameters used as TSEPs and its impact on condition monitoring

Non-intrusive methodologies for characterization of bias temperature instability in SiC power MOSFETs

The gate oxide reliability of SiC power MOSFETs remains a challenge, despite the improvements of the new generation power devices. The threshold voltage drift caused by Bias Temperature Instability (BTI) has been subject of different studies and methods have been proposed to evaluate the real magnitude of the threshold voltage shift. These methodologies usually focus on the characterization of the threshold voltage shift, rather than its implications to the operation or how the threshold voltage shift can be detected during the application. This paper presents two non-intrusive methodologies which can assess and determine the impact of BTI-induced. The proposed methodologies are able to capture the peak shift and subsequent recovery after stress removal

A novel non-intrusive technique for BTI characterization in SiC MOSFETs

Threshold voltage ( $V_{TH}$ ) shift due to Bias Temperature Instability (BTI) is a well-known problem in SiC-MOSFETs that occurs due to oxide traps in the $SiC/SiO_2$ gate interface. The reduced band offsets and increased interface/fixed oxide traps in SiC-MOSFETs makes this a more critical problem compared to silicon. Before qualification, power devices are subjected to gate bias stress tests after which $V_{TH}$ shift is monitored. However, some recovery occurs between the end of the stress and $V_{TH}$ characterisation, thereby potentially under-estimating the extent of the problem. In applications where the SiC-MOSFET is turned OFF with a negative bias at high temperature, if $V_{TH}$ shift is severe enough there may be electrothermal failure due to current crowding since parallel devices lose synchronization during turn-ON. In this paper, a novel method that uses the forward voltage of the body diode during reverse conduction of a small sensing current is introduced as a technique for monitoring $V_{TH}$ shift and recovery due to BTI. This non-invasive method exploits the increased body effect that is peculiar SiC-MOSFETs due to the higher body diode forward voltage. With the proposed method, it is possible to non-invasively assess $V_{TH}$ shift dynamically during BTI characterization tests

Impact of BTI induced threshold voltage shifts in shoot-through currents from crosstalk in SiC MOSFETs

In this paper a method for evaluating the implications of threshold voltage (VTH) drift from gate voltage stress in SiC MOSFETs is presented. By exploiting the Miller coupling between two devices in the same phase leg, the technique uses the shoot-through charge from parasitic turn-ON to characterize the impact of Bias Temperature Instability (BTI) induced VTH shift. Traditional methods of BTI characterization rely on the application of a stress voltage without characterizing the implication of the VTH shift on the switching characteristics of the device in a circuit. Unlike conventional methods, this method uses the actual converter environment to investigate the implications of VTH shift and should therefore be of more interest to applications engineers as opposed to device physicists. Furthermore, a common problem is the underestimation of the VTH shift since recovery from charge de-trapping can mask the true extent of the problem. The impact of temperature, the recovery time after stress removal and polarity of the stress have been studied for a set of commercially available SiC MOSFETs

Performance of Parallel Connected SiC MOSFETs under Short Circuits Conditions

This paper investigates the impact of parameter variation between parallel connected SiC MOSFETs on short circuit (SC) performance. SC tests are performed on parallel connected devices with different switching rates, junction temperatures and threshold voltages (VTH). The results show that VTH variation is the most critical factor affecting reduced robustness of parallel devices under SC. The SC current conducted per device is shown to increase under parallel connection compared to single device measurements. VTH shift from bias–temperature–instability (BTI) is known to occur in SiC MOSFETs, hence this paper combines BTI and SC tests. The results show that a positive VGS stress on the gate before the SC measurement reduces the peak SC current by a magnitude that is proportional to VGS stress time. Repeating the measurements at elevated temperatures reduces the time dependency of the VTH shift, thereby indicating thermal acceleration of negative charge trapping. VTH recovery is also observed using SC measurements. Similar measurements are performed on Si IGBTs with no observable impact of VGS stress on SC measurements. In conclusion, a test methodology for investigating the impact of BTI on SC characteristics is presented along with key results showing the electrothermal dynamics of parallel devices under SC conditions

Bias temperature instability and junction temperature measurement using electrical parameters in SiC power MOSFETs

Junction temperature sensing is an integral part of both on-line and off-line condition monitoring where direct access the bare die surface is not available. Given a defined power input, the junction temperature enables the estimation of the junction-to-case thermal resistance, which is a key indicator of packaging failure mechanisms like solder voiding and cracks. The use of temperature sensitive electrical parameters has widely been proposed as a means of junction temperature sensing however, there are certain challenges regarding their use in SiC MOSFETs. Bias Temperature Instability from charge trapping in the gate dielectric causes threshold voltage drift, which in SiC affects some of the key temperature sensitive electrical parameters including ON-state resistance, body diode forward voltage as well as the current commutation rate. This paper reviews the impact of bias temperature instability on the accurate junction temperature measurement using temperature sensitive electrical parameters in SiC MOSFETs

Miniaturized Transistors, Volume II

In this book, we aim to address the ever-advancing progress in microelectronic device scaling. Complementary Metal-Oxide-Semiconductor (CMOS) devices continue to endure miniaturization, irrespective of the seeming physical limitations, helped by advancing fabrication techniques. We observe that miniaturization does not always refer to the latest technology node for digital transistors. Rather, by applying novel materials and device geometries, a significant reduction in the size of microelectronic devices for a broad set of applications can be achieved. The achievements made in the scaling of devices for applications beyond digital logic (e.g., high power, optoelectronics, and sensors) are taking the forefront in microelectronic miniaturization. Furthermore, all these achievements are assisted by improvements in the simulation and modeling of the involved materials and device structures. In particular, process and device technology computer-aided design (TCAD) has become indispensable in the design cycle of novel devices and technologies. It is our sincere hope that the results provided in this Special Issue prove useful to scientists and engineers who find themselves at the forefront of this rapidly evolving and broadening field. Now, more than ever, it is essential to look for solutions to find the next disrupting technologies which will allow for transistor miniaturization well beyond silicon’s physical limits and the current state-of-the-art. This requires a broad attack, including studies of novel and innovative designs as well as emerging materials which are becoming more application-specific than ever before

Cmos Rf Cituits Sic] Variability And Reliability Resilient Design, Modeling, And Simulation

The work presents a novel voltage biasing design that helps the CMOS RF circuits resilient to variability and reliability. The biasing scheme provides resilience through the threshold voltage (VT) adjustment, and at the mean time it does not degrade the PA performance. Analytical equations are established for sensitivity of the resilient biasing under various scenarios. Power Amplifier (PA) and Low Noise Amplifier (LNA) are investigated case by case through modeling and experiment. PTM 65nm technology is adopted in modeling the transistors within these RF blocks. A traditional class-AB PA with resilient design is compared the same PA without such design in PTM 65nm technology. Analytical equations are established for sensitivity of the resilient biasing under various scenarios. A traditional class-AB PA with resilient design is compared the same PA without such design in PTM 65nm technology. The results show that the biasing design helps improve the robustness of the PA in terms of linear gain, P1dB, Psat, and power added efficiency (PAE). Except for post-fabrication calibration capability, the design reduces the majority performance sensitivity of PA by 50% when subjected to threshold voltage (VT) shift and 25% to electron mobility (μn) degradation. The impact of degradation mismatches is also investigated. It is observed that the accelerated aging of MOS transistor in the biasing circuit will further reduce the sensitivity of PA. In the study of LNA, a 24 GHz narrow band cascade LNA with adaptive biasing scheme under various aging rate is compared to LNA without such biasing scheme. The modeling and simulation results show that the adaptive substrate biasing reduces the sensitivity of noise figure and minimum noise figure subject to process variation and iii device aging such as threshold voltage shift and electron mobility degradation. Simulation of different aging rate also shows that the sensitivity of LNA is further reduced with the accelerated aging of the biasing circuit. Thus, for majority RF transceiver circuits, the adaptive body biasing scheme provides overall performance resilience to the device reliability induced degradation. Also the tuning ability designed in RF PA and LNA provides the circuit post-process calibration capability

Advanced gate stacks for nano-scale CMOS technology

Ph.DDOCTOR OF PHILOSOPH