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Limitations of Ohm’s Law - Class 12 PDF Download

Although Ohm’s law is an important principle in the field of electronics, it cannot be considered as an actual physical law. We know that as per ohm’s law voltage / current = a constant and that constant is the resistance. But the resistance does not remain constant all the time. When the current passes through a material, it heats up. When the temperature of the material changes, the resistance changes. So when the resistance changes, and we divide the voltage across the resistor by the current passing through it, we will not get the same numbers always.

Ohm’s law is applicable and valid for many materials. But there are some materials that do not support the ohm’s law. Some materials and devices which are used in electric circuits do not have the proportionality between voltage and current. For Example, consider a diode and plot a graph between voltage and current. When the value of voltage is marked in the reverse direction by keeping the magnitude fixed, it produces the current with different magnitude in the opposite direction. The relationship between the voltage and current is not linear. 

Limitations of Ohm’s Law - Class 12

For Example when we p- n junction diode is forward biased, initially the current rises slowly even though the voltage increases and the current rises rapidly. Non – linear elements do not support ohm’s law. Thyristor and electric arc are examples for this. Materials like Ga As produces more than one value of V for the same value of current.

Limitations of Ohm’s Law - Class 12

Diode do not support Ohm’s law

Consider a water voltameter. Here although the voltage is increased the current increases only after a certain value of voltage. Ohm’s law is not applicable for unilateral networks. The conductors which does not obey ohm’s law is called Non – Ohmic Conductors. Semi – conductors like Germanium and silicon do not obey Ohm’s law.Other examples include transistor, vacuum tubes, diode and triode valve. The circuits which consists of non - ohmic conductors are known as Non – Ohmic Circuits. Ohm’s law is valid only when the temperature and other physical parameters do not affect the resistance of the metals conductors.

Another example is incandescent bulb. The tungsten filament which is present in the bulb is heated up when the voltage increases, the resistance of the wire changes. So the bulb filament does not support ohm’s law. The law is not applied for LED, which is a light emitting diode.
 

Summary

  • George Simon Ohm stated the Ohm’s law. He stated that the electric current flowing through a wire will be directly proportional to the potential difference across the ends when the temperature remains constant. That constant is the resistance. V = I R

  • As per ohm’s law voltage / current = a constant. The resistance of a material changes when the temperature changes. So when the resistance changes, the ratio of the voltage across the resistor and the current passing through it will not be a constant. We will not get the same numbers always.

  • Non – linear elements and unilateral networks do not support ohm’s law. Examples are diodes, transistor etc. The conductors which does not obey ohm’s law is called Non – Ohmic Conductors. Incandescent bulb do not support ohm’s law.

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FAQs on Limitations of Ohm’s Law - Class 12

1. What is Ohm's Law and why is it important in physics?
Ans. Ohm's Law states that the current flowing through a conductor is directly proportional to the voltage applied across it, given that the temperature and other physical conditions remain constant. It is important in physics as it helps in understanding and predicting the behavior of electric circuits by relating the current, voltage, and resistance.
2. What are the limitations of Ohm's Law?
Ans. Ohm's Law has certain limitations. These include: - Ohm's Law is applicable only to materials that have a linear relationship between current and voltage, known as ohmic conductors. Non-ohmic conductors, such as diodes and transistors, do not follow Ohm's Law. - It assumes that the temperature and other physical conditions of the conductor remain constant, which may not always be the case in practical scenarios. - Ohm's Law does not account for the effects of capacitance and inductance in circuits, which can significantly affect the behavior of the current and voltage.
3. Can Ohm's Law be applied to AC (alternating current) circuits?
Ans. Yes, Ohm's Law can be applied to AC circuits, but with some modifications. In AC circuits, the voltage and current are constantly changing, and Ohm's Law applies to the instantaneous values of voltage and current. However, since the impedance (equivalent of resistance) in AC circuits may vary with frequency, Ohm's Law is modified to include impedance (Z) instead of resistance (R). The modified form is given by V = IZ, where V is the instantaneous voltage, I is the instantaneous current, and Z is the impedance.
4. Is Ohm's Law applicable to all types of materials?
Ans. No, Ohm's Law is not applicable to all types of materials. It is specifically applicable to ohmic conductors, which have a linear relationship between current and voltage. Ohmic conductors follow Ohm's Law as long as the physical conditions remain constant. However, non-ohmic conductors, such as semiconductors, diodes, and transistors, do not follow Ohm's Law and have a nonlinear relationship between current and voltage.
5. Are there any practical examples where Ohm's Law is not applicable?
Ans. Yes, there are practical examples where Ohm's Law is not applicable. For instance: - In electronic devices like diodes and transistors, the relationship between current and voltage is nonlinear, and Ohm's Law cannot accurately predict their behavior. - In circuits containing capacitors and inductors, the behavior of current and voltage is influenced by factors like reactance and impedance, which are not considered in Ohm's Law. - In high-frequency circuits, the effects of capacitance and inductance become more prominent, and Ohm's Law alone is insufficient to describe their behavior.
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