Ohm's law states: I = V / R . Jacaranda Preliminary HSC Physics states that measuring current on both sides of a resistor will give the same reading. But if you go by Ohm's law, increasing the variable R will decrease the value of the fraction V / R (k/x -> 0 as x -> infinity - basic maths). Therefore decreasing I (current). What's the deal here?
And how does a resistor reduce potential difference at a higher rate than when charge flows through a wire with very low resistance?
Please don't give me a textbook answer for these questions, as I have heard way too many already. They all seem to hide behind big, all-encompassing words. Please try and give me an explanation using "fundamental concepts" (i.e., in terms of the motion of the electrons, etc.).
This problem has been stressing me out for quite some time now, and anybody I have asked up until now has given me a textbook answer.
And how does a resistor reduce potential difference at a higher rate than when charge flows through a wire with very low resistance?
Please don't give me a textbook answer for these questions, as I have heard way too many already. They all seem to hide behind big, all-encompassing words. Please try and give me an explanation using "fundamental concepts" (i.e., in terms of the motion of the electrons, etc.).
This problem has been stressing me out for quite some time now, and anybody I have asked up until now has given me a textbook answer.
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) the electrons are raised to a higher potential, which is gradually decreased in the external circuit by the various components. Now rearrange Ohm's Law, you get V=IR. Since I is constant, V is directly proportional to R, therefore a resistor, with a higher resistance, reduces such potential difference to a greater extent than a low-resistance wire does.