coulomb's law

(proper noun)

the mathematical equation calculating the electrostatic force vector between two charged particles

Related Terms

Examples of coulomb's law in the following topics:

  • Solving Problems with Vectors and Coulomb's Law

    • Coulomb's Law, which calculates the electric force between charged particles, can be written in vector notation as $F(E) = \frac{kq_1q_2}{r^2}$ r+.
    • Coulomb's Law using vectors can be written as:
    • Applying Coulomb's Law three times and summing the results gives us:
    • Coulomb's Law applied to more than one point source charges providing forces on a field charge.
    • Explain when the vector notation of Coulomb's Law can be used

  • Gauss's Law

    • Gauss's law can be used to derive Coulomb's law, and vice versa.
    • Note that since Coulomb's law only applies to stationary charges, there is no reason to expect Gauss's law to hold for moving charges based on this derivation alone.
    • In fact, Gauss's law does hold for moving charges, and in this respect Gauss's law is more general than Coulomb's law.
    • Gauss's law has a close mathematical similarity with a number of laws in other areas of physics, such as Gauss's law for magnetism and Gauss's law for gravity.
    • In fact, any "inverse-square law" can be formulated in a way similar to Gauss's law: For example, Gauss's law itself is essentially equivalent to the inverse-square Coulomb's law, and Gauss's law for gravity is essentially equivalent to the inverse-square Newton's law of gravity.

  • Properties of Electric Charges

    • Its SI unit is known as the Coulomb (C), which represents 6.242×1018e, where e is the charge of a proton.
    • This is known as Coulomb's Law.
    • The formula for gravitational force has exactly the same form as Coulomb's Law, but relates the product of two masses (rather than the charges) and uses a different constant.
    • The forces (F1 and F2) sum to produce the total force, which is calculated by Coulomb's Law and is proportional to the product of the charges q1 and q2, and inversely proportional to the square of the distance (r21) between them.

  • Spherical Distribution of Charge

    • The mathematical formula for the electrostatic force is called Coulomb's law after the French physicist Charles Coulomb (1736–1806), who performed experiments and first proposed a formula to calculate it.
    • Modern experiments have verified Coulomb's law to great precision.
    • Coulomb's law holds even within the atoms, correctly describing the force between the positively charged nucleus and each of the negatively charged electrons.
    • This simple law also correctly accounts for the forces that bind atoms together to form molecules and for the forces that bind atoms and molecules together to form solids and liquids.
    • Describe shape of a Coulomb force from a spherical distribution of charge

  • Superposition of Forces

    • For Coulomb's law, the stimuli are forces.
    • The scalar form of Coulomb's Law relates the magnitude and sign of the electrostatic force F, acting simultaneously on two point charges q1 and q2:
    • The principle of linear superposition allows the extension of Coulomb's law to include any number of point charges—in order to derive the force on any one point charge by a vector addition of these individual forces acting alone on that point charge.

  • Electric Field from a Point Charge

    • A point charge creates an electric field that can be calculated using Coulomb's law.
    • The above mathematical description of the electric field of a point charge is known as Coulomb's law.
    • Identify law that can be used to calculate an electric field created by a point charge

  • Stress and Strain

    • A point charge creates an electric field that can be calculated using Coulomb's Law.
    • The above mathematical description of the electric field of a point charge is known as Coulomb's Law.

  • Scientific Applications of Quadratic Functions

    • This is known as Coulomb's Law.

  • B.2 Chapter 2

    • For example, suppose we have a conducting medium so that the current density j is related to the electric field E by Ohm's law: ${\vec j} = \sigma {\vec E}$ where $\sigma$ is the conductivity (cgs unit = sec$^{-1}$.
    • Derive the equations describing the dynamics of the electric and vector potentials in the Coulomb gauge
    • Why is this called the Coulomb gauge?
    • How does the expression for the scalar potential in the Coulomb gauge differ from that in the Lorenz gauge?
    • That is why it is called the Coulomb gauge.

  • Electrolysis Stoichiometry

    • It takes 96,485 coulombs to constitute a mole of electrons, a unit known as the faraday (F).
    • This relation was first formulated by Michael Faraday in 1832, in the form of two laws of electrolysis:
    • Most stoichiometric problems involving electrolysis can be solved without explicit use of Faraday's laws.
    • current (in amperes) is the rate of charge transport: 1 amp = 1 $\frac {Coulombs}{second}$.
    • $0.39\ g\ Cu \times \frac {1\ mole\ Cu}{63.54\ g\ Cu} \times \frac{2\ moles\ e^-}{1\ mole\ Cu^{2+}} \times \frac {96485\ Coulombs}{1\ mole\ e^-} = 1184\ Coulombs$