Glossary

13.2 Maxwell's equations in integral and differential forms

4 min readaugust 7, 2024

are the cornerstone of electromagnetism. They describe how electric and magnetic fields interact and evolve. These equations come in two forms: integral and differential, each offering unique insights into electromagnetic phenomena.

The integral form gives a big-picture view, showing how fields behave over larger areas or volumes. The differential form, on the other hand, zooms in on specific points, revealing local field behavior. Together, they paint a complete picture of electromagnetic theory.

Gauss's Laws

Gauss's Law for Electricity and Magnetism

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Top images from around the web for Gauss's Law for Electricity and Magnetism

  • Gauss’s Law for Electric Fields — Electromagnetic Geophysics View original

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  • for electricity relates the electric flux through a closed surface to the total electric charge enclosed within that surface
  • Mathematically expressed as EdA=Qencϵ0\oint \vec{E} \cdot d\vec{A} = \frac{Q_{enc}}{\epsilon_0}, where E\vec{E} is the , dAd\vec{A} is the area element, QencQ_{enc} is the enclosed charge, and ϵ0\epsilon_0 is the of free space
  • Gauss's law for magnetism states that the magnetic flux through any closed surface is always zero
  • Mathematically expressed as BdA=0\oint \vec{B} \cdot d\vec{A} = 0, where B\vec{B} is the and dAd\vec{A} is the area element
  • Implies that magnetic monopoles do not exist and magnetic field lines always form closed loops

Integral and Differential Forms of Gauss's Laws

  • Integral form of Gauss's law for electricity relates the total electric flux through a closed surface to the total electric charge enclosed within that surface
  • Differential form of Gauss's law for electricity is E=ρϵ0\nabla \cdot \vec{E} = \frac{\rho}{\epsilon_0}, where ρ\rho is the volume charge density
  • Relates the of the electric field at a point to the charge density at that point
  • Integral form of Gauss's law for magnetism states that the magnetic flux through any closed surface is always zero
  • Differential form of Gauss's law for magnetism is B=0\nabla \cdot \vec{B} = 0
  • Implies that the divergence of the magnetic field is always zero at any point in space

Faraday's and Ampère-Maxwell Laws

Faraday's Law of Induction

  • Faraday's law of describes how a changing magnetic flux induces an electromotive force (EMF) in a loop of wire
  • Mathematically expressed as Edl=dΦBdt\oint \vec{E} \cdot d\vec{l} = -\frac{d\Phi_B}{dt}, where E\vec{E} is the electric field, dld\vec{l} is the line element, and ΦB\Phi_B is the magnetic flux
  • Negative sign indicates that the induced EMF opposes the change in magnetic flux (Lenz's law)
  • Example: A moving magnet near a coil of wire induces an electric current in the coil

Ampère-Maxwell Law

  • Ampère-Maxwell law relates the magnetic field circulating around a closed loop to the electric current and the rate of change of electric flux through the loop
  • Mathematically expressed as Bdl=μ0Ienc+μ0ϵ0dΦEdt\oint \vec{B} \cdot d\vec{l} = \mu_0 I_{enc} + \mu_0 \epsilon_0 \frac{d\Phi_E}{dt}, where B\vec{B} is the magnetic field, dld\vec{l} is the line element, IencI_{enc} is the enclosed current, μ0\mu_0 is the of free space, ϵ0\epsilon_0 is the permittivity of free space, and ΦE\Phi_E is the electric flux
  • The term μ0ϵ0dΦEdt\mu_0 \epsilon_0 \frac{d\Phi_E}{dt} is Maxwell's displacement current, which accounts for the fact that a changing electric field can generate a magnetic field
  • Example: A charging capacitor produces a magnetic field in the surrounding space

Integral and Differential Forms of Faraday's and Ampère-Maxwell Laws

  • Integral form of Faraday's law relates the EMF induced in a closed loop to the rate of change of magnetic flux through the loop
  • Differential form of Faraday's law is ×E=Bt\nabla \times \vec{E} = -\frac{\partial \vec{B}}{\partial t}, which relates the of the electric field to the time rate of change of the magnetic field
  • Integral form of Ampère-Maxwell law relates the magnetic field circulating around a closed loop to the electric current and the rate of change of electric flux through the loop
  • Differential form of Ampère-Maxwell law is ×B=μ0J+μ0ϵ0Et\nabla \times \vec{B} = \mu_0 \vec{J} + \mu_0 \epsilon_0 \frac{\partial \vec{E}}{\partial t}, where J\vec{J} is the current density
  • Relates the curl of the magnetic field to the current density and the time rate of change of the electric field

Vector Calculus Operators

Nabla Operator

  • The nabla operator \nabla is a vector differential operator used in vector calculus
  • In Cartesian coordinates, =i^x+j^y+k^z\nabla = \hat{i} \frac{\partial}{\partial x} + \hat{j} \frac{\partial}{\partial y} + \hat{k} \frac{\partial}{\partial z}, where i^\hat{i}, j^\hat{j}, and k^\hat{k} are unit vectors in the x, y, and z directions, respectively
  • Used to define the , divergence, and curl of a vector field

Curl and Divergence

  • The curl of a vector field F\vec{F} is defined as ×F\nabla \times \vec{F} and measures the infinitesimal rotation of the field
  • In Cartesian coordinates, ×F=(FzyFyz)i^+(FxzFzx)j^+(FyxFxy)k^\nabla \times \vec{F} = \left(\frac{\partial F_z}{\partial y} - \frac{\partial F_y}{\partial z}\right) \hat{i} + \left(\frac{\partial F_x}{\partial z} - \frac{\partial F_z}{\partial x}\right) \hat{j} + \left(\frac{\partial F_y}{\partial x} - \frac{\partial F_x}{\partial y}\right) \hat{k}
  • The divergence of a vector field F\vec{F} is defined as F\nabla \cdot \vec{F} and measures the infinitesimal flux of the field per unit volume
  • In Cartesian coordinates, F=Fxx+Fyy+Fzz\nabla \cdot \vec{F} = \frac{\partial F_x}{\partial x} + \frac{\partial F_y}{\partial y} + \frac{\partial F_z}{\partial z}
  • The curl and divergence appear in the differential forms of Maxwell's equations, relating the electric and magnetic fields to their sources and each other

Key Terms to Review (18)

Curl: Curl is a vector operator that describes the rotation or the twisting of a vector field in three-dimensional space. It helps to understand how much and in what direction a field 'curls' around a point, playing a critical role in the formulation of electromagnetic theory and fluid dynamics. This concept is crucial when analyzing the behavior of electric and magnetic fields, as it relates directly to Maxwell's equations, where curl operations are used to express the relationship between electric fields, magnetic fields, and their sources.
Divergence: Divergence is a mathematical operator that measures the magnitude of a field's source or sink at a given point. It indicates how much a vector field is expanding or contracting, playing a crucial role in understanding fluid flow and electromagnetic fields. In the context of Maxwell's equations, divergence helps describe how electric and magnetic fields behave and interact with charges and currents.
Electric Field: An electric field is a region around a charged particle where a force would be exerted on other charged particles. This field represents the influence of an electric charge, dictating how other charges will move or behave when placed within that field. The strength and direction of an electric field are determined by the source charge and can be visualized using field lines, which show how the field extends through space and interact with other charges.
Electromagnetic radiation: Electromagnetic radiation is a form of energy that travels through space at the speed of light, consisting of oscillating electric and magnetic fields. This energy manifests as waves that can vary in wavelength and frequency, spanning a wide spectrum from radio waves to gamma rays. Understanding electromagnetic radiation is essential for exploring how these waves are generated, how they carry energy and momentum, and their role in various physical phenomena.
Electrostatics: Electrostatics is the branch of physics that deals with the study of electric charges at rest and the forces, fields, and potentials associated with these charges. It focuses on understanding how stationary electric charges interact with each other and how they generate electric fields around them. The principles of electrostatics form the foundation for concepts such as electric fields, potential energy, and the behavior of conductors and insulators.
Gauss's Law: Gauss's Law states that the electric flux through a closed surface is proportional to the charge enclosed within that surface. This law is a key principle in electrostatics and helps us understand how electric fields behave around charged objects, leading to insights about charge distributions and field calculations.
Gradient: The gradient is a vector that represents the rate and direction of change of a scalar field. It provides crucial information about how quantities such as electric potential or temperature vary in space, pointing in the direction of the steepest increase and having a magnitude that indicates how steep that increase is. In the context of electromagnetic fields, gradients help describe how field strengths change and are vital for understanding Maxwell's equations.
Induction: Induction refers to the process by which a changing magnetic field can produce an electric current in a conductor, fundamentally described by Faraday's law of electromagnetic induction. This principle is key to understanding how electric fields can be generated in response to time-varying magnetic fields, connecting it to the broader framework of electromagnetic theory.
James Clerk Maxwell: James Clerk Maxwell was a Scottish physicist who is best known for formulating the classical theory of electromagnetic radiation, bringing together electricity, magnetism, and light as manifestations of the same phenomenon. His groundbreaking work led to the development of Maxwell's equations, which describe how electric and magnetic fields interact and propagate, influencing many aspects of modern physics and engineering.
Laplacian: The Laplacian is a second-order differential operator that represents the divergence of the gradient of a function. It plays a crucial role in various fields, including physics and engineering, particularly in the study of wave propagation, heat conduction, and electrostatics. The Laplacian is denoted by the symbol $$ abla^2$$ and is commonly used to describe how a function behaves in space.
Magnetic Field: A magnetic field is a region around a magnetic material or a moving electric charge within which the force of magnetism acts. This field is represented by magnetic field lines that indicate the direction and strength of the magnetic force, which plays a vital role in various physical phenomena, including the behavior of charged particles and electromagnetic waves. Understanding magnetic fields is essential for grasping concepts like symmetry in physics, how charges interact with these fields, and the fundamental laws governing electromagnetism.
Maxwell's equations: Maxwell's equations are a set of four fundamental equations in electromagnetism that describe how electric and magnetic fields interact and propagate. They unify the concepts of electricity and magnetism into a coherent framework, highlighting the relationships between electric charges, currents, and electromagnetic fields. These equations are essential for understanding phenomena like electromagnetic waves, which play a crucial role in technologies such as radio, microwaves, and light.
Michael Faraday: Michael Faraday was a 19th-century scientist known for his groundbreaking work in electromagnetism and electrochemistry. He is widely recognized for establishing principles that laid the foundation for electromagnetic induction and the concept of the electric field, influencing various aspects of physics and engineering.
Permeability: Permeability is a measure of how easily a material allows magnetic field lines to pass through it. It indicates the ability of a substance to support the formation of a magnetic field within itself, which is crucial in understanding magnetostatic fields compared to electrostatic fields. The concept of permeability connects with electric and magnetic phenomena, influencing how materials respond to magnetic fields in various contexts.
Permittivity: Permittivity is a fundamental property of materials that indicates how easily electric fields can pass through them. It quantifies the ability of a substance to store electrical energy in an electric field, and is essential in understanding how electric charges interact within different media. The concept of permittivity connects directly to electrostatic fields, influencing capacitance and the behavior of electric fields in various materials, while also being crucial for understanding displacement current and its role in extending Ampère's law.
Photon: A photon is a quantum of electromagnetic radiation, representing the smallest discrete amount of energy associated with an electromagnetic wave. Photons have no mass and travel at the speed of light in a vacuum, linking their properties to Maxwell's equations, which describe the behavior of electric and magnetic fields and their interaction with charged particles.
Polarization: Polarization refers to the orientation of the electric field of electromagnetic waves, which can be altered by various materials or influences in the environment. It plays a crucial role in understanding how light interacts with matter, particularly in terms of dielectric materials and how they affect electric fields. This concept is essential for grasping the behavior of electromagnetic fields as described by fundamental equations governing electricity and magnetism.
Wave equation: The wave equation is a fundamental mathematical expression that describes the propagation of waves through a medium, representing how wave functions evolve over time and space. It emerges from the principles of electromagnetism and is deeply connected to Maxwell's equations, which provide the foundation for understanding electromagnetic waves. The wave equation is essential for deriving solutions that describe electromagnetic radiation and plays a crucial role in explaining the behavior of light and other forms of radiation in the electromagnetic spectrum.
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