Overview of 1.2kV &amp;#x2013; 2.2kV SiC MOSFETs targeted for industrial power conversion applications

Bolotnikov, Alexander; Losee, Peter A.; Permuy, Alfred; Dunne, Greg; Kennerly, Stacey; Rowden, Brian; Nasadoski, Jeffrey; Todorovic, Maja Harfman; Raju, Ravisekhar; Tao, Fengfeng; Cioffi, Philip; Mueller, Frank; Stevanovic, Ljubisa

doi:10.1109/apec.2015.7104691

Cited by 79 publications

(35 citation statements)

References 15 publications

(16 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Although the claimed superior performance of SiC power devices over traditional Si devices has been the major driving force for most applications, the ability to withstand stressful and harsh conditions may alter the attitude of this conclusion. For instance, prior-art research on the Short Circuit (SC) capability of 1.2 kV SiC MOSFETs has indirectly proved so [3]- [10]. The static and dynamic performances of SiC MOSFETs have been compared to Si IGBTs in [7], [11] and to Si MOSFETs in [11], [12], where the advantages of WBG devices have been demonstrated (i.e., lower losses, higher operation temperature).…”

Section: Introductionmentioning

confidence: 99%

A Short-Circuit Safe Operation Area Identification Criterion for SiC MOSFET Power Modules

Reigosa

Iannuzzo

Luo

et al. 2017

IEEE Trans. on Ind. Applicat.

View full text Add to dashboard Cite

show abstract

Section: Introductionmentioning

confidence: 99%

A Short-Circuit Safe Operation Area Identification Criterion for SiC MOSFET Power Modules

Reigosa

Iannuzzo

Luo

et al. 2017

IEEE Trans. on Ind. Applicat.

View full text Add to dashboard Cite

show abstract

“…Figure 5 shows the FIT results at sea level versus the bias drain voltage (at V GS = 0 V) of SiC MOSFETs with their 95% confidence intervals. For comparison, in the same figure, the data of the commercial SiC MOSFETs C2M0080120D-rating 1200 V (Cree), SCT20N120-1200 V (STMicroelectronics), SCT2120AFC-650 V (ROHM) reported in [13], and GE-1200 V (GE) from [27] are shown. Data of the commercial SiC MOSFETs C2M0080120D, SCT20N120-1200 V, and SCT2120AFC-650 V from [13] and GE-1200 V from [27].…”

Section: Analysis Of Degradation Phenomenamentioning

confidence: 99%

Accelerated Tests on Si and SiC Power Transistors with Thermal, Fast and Ultra-Fast Neutrons

Principato

Altieri

Abbene

et al. 2020

Sensors

View full text Add to dashboard Cite

Neutron test campaigns on silicon (Si) and silicon carbide (SiC) power MOSFETs and IGBTs were conducted at the TRIGA (Training, Research, Isotopes, General Atomics) Mark II (Pavia, Italy) nuclear reactor and ChipIr-ISIS Neutron and Muon Source (Didcot, U.K.) facility. About 2000 power transistors made by STMicroelectronics were tested in all the experiments. Tests with thermal and fast neutrons (up to about 10 MeV) at the TRIGA Mark II reactor showed that single-event burnout (SEB) failures only occurred at voltages close to the rated drain-source voltage. Thermal neutrons did not induce SEB, nor degradation in the electrical parameters of the devices. SEB failures during testing at ChipIr with ultra-fast neutrons (1-800 MeV) were evaluated in terms of failure in time (FIT) versus derating voltage curves according to the JEP151 procedure of the Joint Electron Device Engineering Council (JEDEC). These curves, even if scaled with die size and avalanche voltage, were strongly linked to the technological processes of the devices, although a common trend was observed that highlighted commonalities among the failures of different types of MOSFETs. In both experiments, we observed only SEB failures without single-event gate rupture (SEGR) during the tests. None of the power devices that survived the neutron tests were degraded in their electrical performances. A study of the worst-case bias condition (gate and/or drain) during irradiation was performed.

show abstract

“…In a cascaded cells system, the number of required cells follows from the peak phase voltage, , the semiconductor blocking voltage capability, V b,MV , and its utilization, u, as (1) With n cell = 5, the considered 1700 V SiC MOSFETs are utilized to about 65%, which is feasible regarding reliability [22]. 1) Transformer: Assuming unity power factor operation, the instantaneous power of the single-phase system at the SST's AC side is (2) Hence, the transformer RMS current of the IFE converter cell can be derived starting with the relation (3) where x denotes a local average value over half a switching cycle of the SRC.…”

Section: A Key Component Stressesmentioning

confidence: 99%

Analysis and Cell-Level Experimental Verification of a 25 kW All-SiC Isolated Front End 6.6 kV/400 V AC-DC Solid-State Transformer

et al. 2017

View full text Add to dashboard Cite

Abstract-Solid-state transformers (SSTs) could serve as interfaces between a medium-voltage (MV) AC grid and a low-voltage (LV) DC load or source, i. e., could be employed in applications with power supply character such as traction auxiliary supplies or rack-level power supplies in future datacenters. For handling the high input-side AC voltage and output side current, SSTs are typically realized as input-series output-parallel (ISOP) arrangements of multiple converter cells, whereby each cell comprises a medium-frequency isolation stage. This paper presents such a multi-cell 25 kW all-SiC MVAC-LVDC SST (6.6 kV AC to 400 V DC) based on the isolated front end (IFE) approach, which is an interesting alternative to the isolated back end (IBE) configuration mainly discussed in literature so far. The IFE concept is briefly explained, the main component stresses are derived, and a converter cell prototype is designed and tested. The 5 kW prototype cell features a power density of 1.5 kW/l (24.6 W/in3) and a measured peak efficiency of 97.5%. This is significantly higher than previously published data for IFEbased SSTs, and in the same range as what has been reported recently for industrial IBE-based SSTs. Thus, this paper confirms that the IFE approach can be a feasible and interesting alternative for realizing MVAC-LVDC SST systems with low complexity.

show abstract

Overview of 1.2kV – 2.2kV SiC MOSFETs targeted for industrial power conversion applications

Cited by 79 publications

References 15 publications

A Short-Circuit Safe Operation Area Identification Criterion for SiC MOSFET Power Modules

A Short-Circuit Safe Operation Area Identification Criterion for SiC MOSFET Power Modules

Accelerated Tests on Si and SiC Power Transistors with Thermal, Fast and Ultra-Fast Neutrons

Analysis and Cell-Level Experimental Verification of a 25 kW All-SiC Isolated Front End 6.6 kV/400 V AC-DC Solid-State Transformer

Contact Info

Product

Resources

About