April 2000TMQFETQFETQFETQFETFQB6N50 / FQI6N50500V N-ChanneI MOSFETGeneraI Description FeaturesThese N-Channel enhancement mode power field effect 5.5A, 500V, RDS(on) = 1.3 @VGS = 10 Vtransistors are produced using Fairchilds proprietary, Low gate charge ( typical 17 nC)planar stripe, DMOS technology. Low Crss ( typical 11 pF)This advanced technology

TMQFETFQB6N40C/FQI6N40C400V N-Channel MOSFETGeneral Description FeaturesThese N-Channel enhancement mode power field effect 6A, 400V, RDS(on) = 1.0 @VGS = 10 Vtransistors are produced using Fairchilds proprietary, Low gate charge ( typical 16nC)planar stripe, DMOS technology. Low Crss ( typical 15pF)This advanced technology has been especially tailored to

December 2000TMQFETQFETQFETQFETFQB6N90 / FQI6N90900V N-Channel MOSFETGeneral Description FeaturesThese N-Channel enhancement mode power field effect 5.8A, 900V, RDS(on) = 1.9 @VGS = 10 Vtransistors are produced using Fairchilds proprietary, Low gate charge ( typical 40 nC)planar stripe, DMOS technology. Low Crss ( typical 17 pF)This advanced technology

November 2013FQB6N40CN-Channel QFET MOSFET400 V, 6 A, 1.0 Description FeaturesThese N-Channel enhancement mode power field effect 6 A, 400 V, RDS(on) = 1.0 (Max.) @ VGS = 10 V,transistors are produced using Fairchilds proprietary, ID = 3 Aplanar stripe, DMOS technology. This advanced Low Gate Charge (Typ. 16nC)technology has been especially tailored to min

May 2000TMQFETQFETQFETQFETFQB6N15 / FQI6N15150V N-ChanneI MOSFETGeneraI Description FeaturesThese N-Channel enhancement mode power field effect 6.4A, 150V, RDS(on) = 0.6 @VGS = 10 Vtransistors are produced using Fairchilds proprietary, Low gate charge ( typical 6.5 nC)planar stripe, DMOS technology. Low Crss ( typical 9.6 pF)This advanced technology h

QFETFQB6N60C / FQI6N60C600V N-Channel MOSFETGeneral Description FeaturesThese N-Channel enhancement mode power field effect 5.5A, 600V, RDS(on) = 2.0 @VGS = 10 Vtransistors are produced using Fairchilds proprietary, Low gate charge ( typical 16 nC)planar stripe, DMOS technology. Low Crss ( typical 7 pF)This advanced technology has been especially tailored to

October 2008QFETFQB6N60 / FQI6N60600V N-Channel MOSFETGeneral Description FeaturesThese N-Channel enhancement mode power field effect 6.2A, 600V, RDS(on) = 1.5 @VGS = 10 Vtransistors are produced using Fairchilds proprietary, Low gate charge ( typical 20 nC)planar stripe, DMOS technology. Low Crss ( typical 10 pF)This advanced technology has been especially

May 2000TMQFETQFETQFETQFETFQB6N25 / FQI6N25250V N-ChanneI MOSFETGeneraI Description FeaturesThese N-Channel enhancement mode power field effect 5.5A, 250V, RDS(on) = 1.0 @VGS = 10 Vtransistors are produced using Fairchilds proprietary, Low gate charge ( typical 6.6 nC)planar stripe, DMOS technology. Low Crss ( typical 7.5 pF)This advanced technology

October 2008QFETFQB6N80 / FQI6N80800V N-Channel MOSFETGeneral Description FeaturesThese N-Channel enhancement mode power field effect 5.8A, 800V, RDS(on) = 1.95 @VGS = 10 Vtransistors are produced using Fairchilds proprietary, Low gate charge ( typical 31 nC)planar stripe, DMOS technology. Low Crss ( typical 14 pF)This advanced technology has been especially

September 2000TMQFETFQB6N80 / FQI6N80800V N-Channel MOSFETGeneral Description FeaturesThese N-Channel enhancement mode power field effect 5.8A, 800V, RDS(on) = 1.95 @VGS = 10 Vtransistors are produced using Fairchilds proprietary, Low gate charge ( typical 31 nC)planar stripe, DMOS technology. Low Crss ( typical 14 pF)This advanced technology has been especi

April 2000TMQFETQFETQFETQFETFQB6N70 / FQI6N70700V N-ChanneI MOSFETGeneraI Description FeaturesThese N-Channel enhancement mode power field effect 6.2A, 700V, RDS(on) = 1.5 @ VGS = 10 Vtransistors are produced using Fairchilds proprietary, Low gate charge ( typical 30 nC)planar stripe, DMOS technology. Low Crss ( typical 15 pF)This advanced technolog

Is Now Part ofTo learn more about ON Semiconductor, please visit our website at www.onsemi.comPlease note: As part of the Fairchild Semiconductor integration, some of the Fairchild orderable part numbers will need to change in order to meet ON Semiconductors system requirements. Since the ON Semiconductor product management systems do not have the ability to manage part nomenclatur