The total resistance of a circuit is the sum of the supply's internal resistance and its load resistance, because they are in series with each other. This is true regardless of the magnitude of, or the variation in, the current.
Cell constant(C) = Resistance(R) X Specific Conductivity(K)
due to the electrolyte present between the two electodes of the cell
Internal resistance
i=F*sum(zi*Ci) where, i is the current density, F is Faradya's constant, zi is the velence of species i, Ci is the concentration
Ohm's law gives the relationship between current, voltage, and resistance. The law states that I=V/R, where I is current, V is voltage, and R is resistance. Source: university digital fundamentals
I think that the relation is R = k/L where R is the resistance, L is the length of the wire, and k is the constant of proportionality.
The higher the viscosity, the lower the flow-ability of a material.(Viscosity=internal resistance to flow)
The higher the viscosity, the lower the flow-ability of a material.(Viscosity=internal resistance to flow)
Both are same
ghandi's entire ethos was about passive resistance
ohm
A non-ohmic resistor doesn't have a constant resistance. A ohmic resistor has a constant resistance.
Resistivity R is the inverse of conductivity G, R=1/G.
Cell constant(C) = Resistance(R) X Specific Conductivity(K)
Ohm's Law: voltage = current * resistance. If resistance is a constant, then voltage is directly proportional to current.
The greater the inertia, the greater is the force required to produce a constant acceleration.(F=ma). But in general, acceleration is not taken constant, in this case, there is no relation between force and inertia.
I suppose that the relation is directly proportional, because the more is the velocity, the more is the power wasted to keep the body moving, thus the resistance will be greater. JW70