Electric current refers to the movement of electrically charged particles, typically electrons, through a conductive medium like a wire. When a voltage or potential difference is applied across a circuit, it creates an electric field that drives the flow of electrons. The rate at which these charges flow is measured in amperes (A).
The flow of electric current is similar to the flow of water in a pipe. Imagine the wire as the pipe, and the electrons as the water molecules. When you turn on a switch, it allows the electrons to move from the negative terminal of the power source (like a battery) to the positive terminal, completing the circuit.
The strength of the electric current is determined by the voltage (V) applied and the resistance (R) encountered in the circuit. According to Ohm's Law, the current (I) is equal to the voltage divided by the resistance (I = V/R).
Electric current has various applications, from powering electrical appliances to generating light and heat. It's a fundamental concept in understanding and working with electricity.
[tex] \red{ \huge{ \colorbox{aqua}{जय श्री राम }}}[/tex]
Electric current refers to the movement of electrically charged particles, typically electrons, through a conductive medium like a wire. When a voltage or potential difference is applied across a circuit, it creates an electric field that drives the flow of electrons. The rate at which these charges flow is measured in amperes (A).
The flow of electric current is similar to the flow of water in a pipe. Imagine the wire as the pipe, and the electrons as the water molecules. When you turn on a switch, it allows the electrons to move from the negative terminal of the power source (like a battery) to the positive terminal, completing the circuit.
The strength of the electric current is determined by the voltage (V) applied and the resistance (R) encountered in the circuit. According to Ohm's Law, the current (I) is equal to the voltage divided by the resistance (I = V/R).
Electric current has various applications, from powering electrical appliances to generating light and heat. It's a fundamental concept in understanding and working with electricity.
[tex] \red{ \huge{ \colorbox{aqua}{जय श्री राम }}}[/tex]
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☞[tex]\huge\mathcal{\fcolorbox{pink} {black} {\pink{Answer}}}[/tex]
Electric current refers to the movement of electrically charged particles, typically electrons, through a conductive medium like a wire. When a voltage or potential difference is applied across a circuit, it creates an electric field that drives the flow of electrons. The rate at which these charges flow is measured in amperes (A).
The flow of electric current is similar to the flow of water in a pipe. Imagine the wire as the pipe, and the electrons as the water molecules. When you turn on a switch, it allows the electrons to move from the negative terminal of the power source (like a battery) to the positive terminal, completing the circuit.
The strength of the electric current is determined by the voltage (V) applied and the resistance (R) encountered in the circuit. According to Ohm's Law, the current (I) is equal to the voltage divided by the resistance (I = V/R).
Electric current has various applications, from powering electrical appliances to generating light and heat. It's a fundamental concept in understanding and working with electricity.
[tex] \red{ \huge{ \colorbox{aqua}{जय श्री राम }}}[/tex]
Verified answer
☞[tex]\huge\mathcal{\fcolorbox{pink} {black} {\pink{Answer}}}[/tex]
Electric current refers to the movement of electrically charged particles, typically electrons, through a conductive medium like a wire. When a voltage or potential difference is applied across a circuit, it creates an electric field that drives the flow of electrons. The rate at which these charges flow is measured in amperes (A).
The flow of electric current is similar to the flow of water in a pipe. Imagine the wire as the pipe, and the electrons as the water molecules. When you turn on a switch, it allows the electrons to move from the negative terminal of the power source (like a battery) to the positive terminal, completing the circuit.
The strength of the electric current is determined by the voltage (V) applied and the resistance (R) encountered in the circuit. According to Ohm's Law, the current (I) is equal to the voltage divided by the resistance (I = V/R).
Electric current has various applications, from powering electrical appliances to generating light and heat. It's a fundamental concept in understanding and working with electricity.
[tex] \red{ \huge{ \colorbox{aqua}{जय श्री राम }}}[/tex]