What is the Difference Between Gauss Law and Coulomb Law?
🆚 Go to Comparative Table 🆚Gauss's Law and Coulomb's Law are two important laws in electromagnetic field theory, but they describe different aspects of electric charges and have different applications. Here are the key differences between the two:
- Scope: Coulomb's Law describes the force of interaction between two electric charges, while Gauss's Law is a statement about the electric field around a collection of charges. Coulomb's Law is applicable only to electric fields, whereas Gauss's Law is applicable to electric fields, magnetic fields, and gravitational fields.
- Applicability: Coulomb's Law is useful for calculating the force between two point charges, while Gauss's Law is useful for calculating the electric field around more complex charge distributions.
- Derivation: Coulomb's Law can be derived from Gauss's Law. To do this, you can set up a sphere around a singular charge and use Gauss's Law to determine the force any charge must feel on the surface of that sphere. However, this derivation assumes that the force is spread equally on the surface of the sphere and depends only on distance.
In summary, Coulomb's Law deals with point charges and calculates the force between them, while Gauss's Law deals with electric fields and calculates the flux through a surface. Both laws are important in understanding electromagnetism, and they are related but not interchangeable.
Comparative Table: Gauss Law vs Coulomb Law
Here is a table comparing Gauss' Law and Coulomb's Law:
Aspect | Gauss' Law | Coulomb's Law |
---|---|---|
Origin | Gauss' Law explains the electric field origin. | Coulomb's Law explains the electrical force between charged particles. |
Mathematical | Expressed in the form of differential and integral equations. | Expressed as a proportionality constant between the force and the product of the charges. |
Derivation | Can be derived using calculus and vector calculus. | Can be derived from Gauss' Law by considering a spherical surface of radius r. |
Scope | Applicable to electrostatics and electrodynamics. | Applicable to electrostatics only. |
Relationship | Gauss' Law and Coulomb's Law are equivalent, meaning that they are one and the same thing. | Gauss' Law implies Coulomb's Law, and vice versa. |
To understand the relationship between Gauss' Law and Coulomb's Law, consider that both laws describe the behavior of electric fields and forces in electrostatics. Gauss' Law, which is expressed in the form of differential and integral equations, describes the mathematical relationship between the electric field and the charge distribution that gives rise to it. On the other hand, Coulomb's Law, which states that the force between two charges is directly proportional to the product of the charges and inversely proportional to the square of the distance between them, describes the electrical force between charged particles.
The key difference between the two laws lies in their mathematical expression and the scope of their application. While Gauss' Law is applicable to both electrostatics and electrodynamics, Coulomb's Law is applicable only to electrostatics. Additionally, Gauss' Law is often derived using calculus and vector calculus, whereas Coulomb's Law can be derived from Gauss' Law by considering a spherical surface of radius r.
In summary, Gauss' Law and Coulomb's Law are interconnected laws in electrostatics that describe the behavior of electric fields and forces. Both laws can be derived from one another, and they provide a mathematical framework for understanding the interaction of charged particles in electrostatic systems.
- Coulomb’s Law vs Gravitational Law
- Lorentz Gauge vs Coulomb Gauge
- Ampere vs Coulomb
- Ohm’s Law vs Kirchhoff’s Law
- Faraday’s Law vs Lenz Law
- Gravitational Field vs Electric Field
- Electrostatics vs Magnetostatics
- Electrostatic Force vs Gravitational Force
- Magnetic Force vs Electric Force
- Electrostatic vs Electromagnetic
- Electric Field vs Magnetic Field
- Newton vs Joule
- Gravity vs Magnetism
- Electricity vs Magnetism
- Gravitational Force vs Magnetic Force
- Electric Potential vs Electric Field
- Gravity vs Gravitational Force
- Electromagnetism vs Magnetism
- Magnetic Field vs Magnetic Force