D= diffusion
Temprature=T=Ln(D) N=amount of particles
E=Energy =kTN=kNLn(D) F=E/x= kNLn(D)/x x=distance meters
F(Flo,Qv,W)= kNLn(D)/x=PV/x=(kNLn(D))^0.5(Pressure*Volume)^0.5/x=(kNLn(D))^0.5(Pressure*Volume(t/t))^0.5/x=(kNLn(D))^0.5(Pressure*Phit)^0.5/x ) Ln(D)=Temprature Resistance=alpha*R0*Temprature=Ln(D)alphaR0 V=iR=voltage=icurrent*Rresistance i=charge/time=Q/t V=Q/tR R=Vt/Q=Ln(D)alphaR0 Ln(D)=/QVt/alpha/R0 F(phi,Qv,W)=(/QVolt*time/alphta/R0))^0.5(Pressure*Phit)^0.5/x F(phi,Qv,W)=(/QVolt*time/alphta/R0))^0.5(Pressure(V/V)*Phit)^0.5/x Work=W=Volume*Pressure F(phi,Qv,W)=(/QVolt*time/alphta/R0))^0.5(/V*W*Phit)^0.5/x*KonstantFloQuatreWhorlsDn 16 juli 2015 20:15 by Flo, Quatre Whorls AKA PhD Alborz Seddigh Afshar.
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