Specification	SCT3080KRC15

Current - Continuous Drain (Id) @ 25°C	31 A
Drain to Source Voltage (Vdss)	1.2 kV
Drive Voltage (Max Rds On, Min Rds On)	18 V
FET Type	N-Channel
Gate Charge (Qg) (Max) @ Vgs	60 nC
Input Capacitance (Ciss) (Max) @ Vds	785 pF
Mounting Type	Through Hole
Operating Temperature	175 °C
Package / Case	TO-247-4
Power Dissipation (Max) [Max]	165 W
Rds On (Max) @ Id, Vgs	104 mOhm
Supplier Device Package	TO-247-4L
Technology	SiC (Silicon Carbide Junction Transistor)
Vgs(th) (Max) @ Id	5.6 V

SCT3080 Series

650V, 30A, 4-pin THD, Trench-structure, Silicon-carbide (SiC) MOSFET for Automotive

Part	Vgs(th) (Max) @ Id	Supplier Device Package	Package / Case	Mounting Type	Rds On (Max) @ Id, Vgs	Current - Continuous Drain (Id) @ 25°C	Operating Temperature	Drain to Source Voltage (Vdss)	Gate Charge (Qg) (Max) @ Vgs [Max]	Input Capacitance (Ciss) (Max) @ Vds [Max]	FET Type	Drive Voltage (Max Rds On, Min Rds On)	Input Capacitance (Ciss) (Max) @ Vds	Gate Charge (Qg) (Max) @ Vgs	Power Dissipation (Max) [Max]	Technology	Power Dissipation (Max)	Qualification	Grade
Rohm Semiconductor SCT3080AW7TL	5.6 V	TO-263-7	D2PAK (7 Leads + Tab) TO-263-8 TO-263CA	Surface Mount	104 mOhm	29 A	175 °C	650 V	48 nC	571 pF	N-Channel
Rohm Semiconductor SCT3080KRC14	5.6 V	TO-247-4L	TO-247-4	Through Hole	104 mOhm	31 A	175 °C	1.2 kV			N-Channel	18 V	785 pF	60 nC	165 W
Rohm Semiconductor SCT3080ARC15	5.6 V	TO-247-4L	TO-247-4	Through Hole	104 mOhm	30 A	175 °C	650 V	48 nC	571 pF	N-Channel	18 V				SiC (Silicon Carbide Junction Transistor)	134 W
Rohm Semiconductor SCT3080ARC14	5.6 V	TO-247-4L	TO-247-4	Through Hole	104 mOhm	30 A	175 °C	650 V	48 nC	571 pF	N-Channel	18 V					134 W
Rohm Semiconductor SCT3080ALGC11	5.6 V	TO-247N	TO-247-3	Through Hole	104 mOhm	30 A	175 °C	650 V	48 nC	571 pF	N-Channel	18 V					134 W
Rohm Semiconductor SCT3080KW7TL	5.6 V	TO-263-7	D2PAK (7 Leads + Tab) TO-263-8 TO-263CA	Surface Mount	104 mOhm	30 A	175 °C	1.2 kV			N-Channel		785 pF	60 nC	159 W
Rohm Semiconductor SCT3080ARHRC15	5.6 V	TO-247-4L	TO-247-4	Through Hole	104 mOhm	30 A	175 °C	650 V	48 nC	571 pF	N-Channel	18 V				MOSFET (Metal Oxide)	134 W	AEC-Q101	Automotive
Rohm Semiconductor SCT3080KRHRC15	5.6 V	TO-247-4L	TO-247-4	Through Hole	104 mOhm	31 A	175 °C	1.2 kV			N-Channel	18 V	785 pF	60 nC	165 W	MOSFET (Metal Oxide)		AEC-Q101	Automotive
Rohm Semiconductor SCT3080KRC15	5.6 V	TO-247-4L	TO-247-4	Through Hole	104 mOhm	31 A	175 °C	1.2 kV			N-Channel	18 V	785 pF	60 nC	165 W	SiC (Silicon Carbide Junction Transistor)

Pricing

Prices provided here are for design reference only. For realtime values and availability, please visit the distributors directly

Distributor	Package	Quantity	$

Digikey	N/A	0	$ 13.80
	Tube	1	$ 13.88
		10	$ 9.81
		100	$ 8.62
Newark	Each	1	$ 16.32
		10	$ 14.83
		25	$ 14.34
		50	$ 13.86
		100	$ 13.37
		250	$ 13.09
		900	$ 13.08

Description

General part information

SCT3080 Series

SCT3080KR is anSiC MOSFETfeaturing a trench gate structure optimized for server power supplies, solar power inverters, andEV charging stationsrequiring high efficiency. A new 4-pin package is used that separates the power and driver source terminals, making it possible to maximize high-speed switching performance. This improves turn ON loss in particular, and as a result the total turn ON and turn OFF losses can be reduced by as much as 35% compared with the conventional 3-pin package (TO-247N).A pioneer and industry leader in SiC technology, ROHM was the first supplier to mass produce trench-type MOSFETs that further improve efficiency while reducing power consumption over existing SiC MOSFETs.

Documents

Technical documentation and resources

SCT3080KRC15

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Technical Specifications

SCT3080 Series

Pricing

Description

SCT3080 Series

Documents

Datasheet

How to measure the oscillation occurs between parallel-connected devices

Notes for Temperature Measurement Using Thermocouples

SiC THD Condition of Soldering

How to Use Thermal Models

Simulation Verification to Identify Oscillation between Parallel Dies during Design Phase of Power Modules

Example of Heat Dissipation Design for TO Packages: Effect of Heat Dissipation Materials

Impedance Characteristics of Bypass Capacitor

How to Suppress the Parallel Drive Oscillation in SiC Modules

Design Method for Comparator-less Miller Clamp Circuits

Notes for Calculating Power Consumption:Static Operation

Precautions during gate-source voltage measurement for SiC MOSFET

Overview of ROHM's Simulation Models(for ICs and Discrete Semiconductors)

LEADRIVE: Design, Test and System Evaluation of Silicon Carbide Power Modules and Motor Control Units

Cutting-Edge Web Simulation Tool "ROHM Solution Simulator" Capable of Complete Circuit Verification of Power Devices and Driver ICs

Oscillation countermeasures for MOSFETs in parallel

Thermal Resistance Measurement Method for SiC MOSFET

Types and Features of Transistors

Gate-source voltage behaviour in a bridge configuration

Calculation of Power Dissipation in Switching Circuit

Basics of Thermal Resistance and Heat Dissipation

800V Three-Phase Output LLC DC/DC Resonant Converter

Anti-Whisker formation

How to Use the Thermal Resistance and Thermal Characteristics Parameters

What Is Thermal Design

TO-247-4L_C15 Dimensions

Method for Monitoring Switching Waveform

θ<sub>JA</sub> and Ψ<sub>JT</sub>

Precautions for Thermal Resistance of Insulation Sheet

About Export Administration Regulations (EAR)

About Flammability of Materials

PCB Layout Thermal Design Guide

5kW High-Efficiency Fan-less Inverter

Solving the challenges of driving SiC MOSFETs with new packaging developments

Part Explanation

Power Eco Family: Overview of ROHM's Power Semiconductor Lineup

Compliance of the ELV directive

How to Use LTspice&reg; Models: Tips for Improving Convergence

Judgment Criteria of Thermal Evaluation

Notes on Gate Drive Voltage Setting and Linear Mode Application of SiC MOSFET

How to Use LTspice&reg; Models

Best practices for the connection of Driver Source/Emitter terminals in discrete devices

Precautions When Measuring the Rear of the Package with a Thermocouple

Basics and Design Guidelines for Gate Drive Circuits

Gate-Source Voltage Surge Suppression Methods

What is a Thermal Model? (SiC Power Device)

Method for Calculating Junction Temperature from Transient Thermal Resistance Data

Application Note for SiC Power Devices and Modules

How to Use PSIM Models

Generation Mechanism of Voltage Surge on Commutation Side (Basic)

Snubber circuit design methods for SiC MOSFET

Importance of Probe Calibration When Measuring Power: Deskew

Measurement Method and Usage of Thermal Resistance RthJC

Notes for Temperature Measurement Using Forward Voltage of PN Junction

Calculating Power Loss from Measured Waveforms

Two-Resistor Model for Thermal Simulation

SiC MOSFET Layout Design Considerations

The Problem with Traditional Vaccine Storage Freezers and How ROHM Cutting-edge Power Solutions Can Take them to the Next Level

θ<sub>JC</sub> and Ψ<sub>JT</sub>

How to Create Symbols for PSpice Models

4 Steps for Successful Thermal Designing of Power Devices

How to Use PLECS Models

How to Use LTspice® Models: Tips for Improving Convergence

How to Use LTspice® Models