HOME

TheInfoList



OR:

Flux describes any effect that appears to pass or travel (whether it actually moves or not) through a surface or substance. Flux is a concept in
applied mathematics Applied mathematics is the application of mathematical methods by different fields such as physics, engineering, medicine, biology, finance, business, computer science, and industry. Thus, applied mathematics is a combination of mathemat ...
and vector calculus which has many applications to
physics Physics is the natural science that studies matter, its fundamental constituents, its motion and behavior through space and time, and the related entities of energy and force. "Physical science is that department of knowledge which rel ...
. For transport phenomena, flux is a vector quantity, describing the magnitude and direction of the flow of a substance or property. In vector calculus flux is a scalar quantity, defined as the surface integral of the perpendicular component of a vector field over a surface.


Terminology

The word ''flux'' comes from
Latin Latin (, or , ) is a classical language belonging to the Italic branch of the Indo-European languages. Latin was originally a dialect spoken in the lower Tiber area (then known as Latium) around present-day Rome, but through the power ...
: ''fluxus'' means "flow", and ''fluere'' is "to flow". As '' fluxion'', this term was introduced into differential calculus by
Isaac Newton Sir Isaac Newton (25 December 1642 – 20 March 1726/27) was an English mathematician, physicist, astronomer, alchemist, theologian, and author (described in his time as a " natural philosopher"), widely recognised as one of the g ...
. The concept of heat flux was a key contribution of Joseph Fourier, in the analysis of heat transfer phenomena. His seminal treatise ''Théorie analytique de la chaleur'' (''The Analytical Theory of Heat''), defines ''fluxion'' as a central quantity and proceeds to derive the now well-known expressions of flux in terms of temperature differences across a slab, and then more generally in terms of temperature gradients or differentials of temperature, across other geometries. One could argue, based on the work of
James Clerk Maxwell James Clerk Maxwell (13 June 1831 – 5 November 1879) was a Scottish mathematician and scientist responsible for the classical theory of electromagnetic radiation, which was the first theory to describe electricity, magnetism and ligh ...
, that the transport definition precedes the definition of flux used in electromagnetism. The specific quote from Maxwell is: According to the transport definition, flux may be a single vector, or it may be a vector field / function of position. In the latter case flux can readily be integrated over a surface. By contrast, according to the electromagnetism definition, flux ''is'' the integral over a surface; it makes no sense to integrate a second-definition flux for one would be integrating over a surface twice. Thus, Maxwell's quote only makes sense if "flux" is being used according to the transport definition (and furthermore is a vector field rather than single vector). This is ironic because Maxwell was one of the major developers of what we now call "electric flux" and "magnetic flux" according to the electromagnetism definition. Their names in accordance with the quote (and transport definition) would be "surface integral of electric flux" and "surface integral of magnetic flux", in which case "electric flux" would instead be defined as "electric field" and "magnetic flux" defined as "magnetic field". This implies that Maxwell conceived of these fields as flows/fluxes of some sort. Given a flux according to the electromagnetism definition, the corresponding flux density, if that term is used, refers to its derivative along the surface that was integrated. By the
Fundamental theorem of calculus The fundamental theorem of calculus is a theorem that links the concept of differentiating a function (calculating its slopes, or rate of change at each time) with the concept of integrating a function (calculating the area under its graph, ...
, the corresponding flux density is a flux according to the transport definition. Given a current such as electric current—charge per time, current density would also be a flux according to the transport definition—charge per time per area. Due to the conflicting definitions of ''flux'', and the interchangeability of ''flux'', ''flow'', and ''current'' in nontechnical English, all of the terms used in this paragraph are sometimes used interchangeably and ambiguously. Concrete fluxes in the rest of this article will be used in accordance to their broad acceptance in the literature, regardless of which definition of flux the term corresponds to.


Flux as flow rate per unit area

In transport phenomena ( heat transfer, mass transfer and fluid dynamics), flux is defined as the ''rate of flow of a property per unit area,'' which has the dimensions uantity
ime Ime is a village in Lindesnes municipality in Agder county, Norway. The village is located on the east side of the river Mandalselva, along the European route E39 highway. Ime is an eastern suburb of the town of Mandal. Ime might be considered ...
sup>−1· reasup>−1. The area is of the surface the property is flowing "through" or "across". For example, the amount of water that flows through a cross section of a river each second divided by the area of that cross section, or the amount of sunlight energy that lands on a patch of ground each second divided by the area of the patch, are kinds of flux.


General mathematical definition (transport)

Here are 3 definitions in increasing order of complexity. Each is a special case of the following. In all cases the frequent symbol ''j'', (or ''J'') is used for flux, ''q'' for the physical quantity that flows, ''t'' for time, and ''A'' for area. These identifiers will be written in bold when and only when they are vectors. First, flux as a (single) scalar: j = \frac where: I = \lim_\frac = \frac In this case the surface in which flux is being measured is fixed, and has area ''A''. The surface is assumed to be flat, and the flow is assumed to be everywhere constant with respect to position, and perpendicular to the surface. Second, flux as a scalar field defined along a surface, i.e. a function of points on the surface: j(\mathbf) = \frac(\mathbf) I(A,\mathbf) = \frac(A,\mathbf) As before, the surface is assumed to be flat, and the flow is assumed to be everywhere perpendicular to it. However the flow need not be constant. ''q'' is now a function of p, a point on the surface, and ''A'', an area. Rather than measure the total flow through the surface, q measures the flow through the disk with area ''A'' centered at ''p'' along the surface. Finally, flux as a vector field: \mathbf(\mathbf) = \frac(\mathbf) \mathbf(A,\mathbf) = \underset\, \mathbf_ \frac(A,\mathbf, \mathbf) In this case, there is no fixed surface we are measuring over. ''q'' is a function of a point, an area, and a direction (given by a unit vector, \mathbf), and measures the flow through the disk of area A perpendicular to that unit vector. ''I'' is defined picking the unit vector that maximizes the flow around the point, because the true flow is maximized across the disk that is perpendicular to it. The unit vector thus uniquely maximizes the function when it points in the "true direction" of the flow. trictly speaking, this is an abuse of notation because the "arg max" cannot directly compare vectors; we take the vector with the biggest norm instead.]


Properties

These direct definitions, especially the last, are rather unwieldy. For example, the argmax construction is artificial from the perspective of empirical measurements, when with a Weathervane or similar one can easily deduce the direction of flux at a point. Rather than defining the vector flux directly, it is often more intuitive to state some properties about it. Furthermore, from these properties the flux can uniquely be determined anyway. If the flux j passes through the area at an angle θ to the area normal \mathbf, then \mathbf\cdot\mathbf= j\cos\theta where · is the dot product of the unit vectors. That is, the component of flux passing through the surface (i.e. normal to it) is ''j'' cos ''θ'', while the component of flux passing tangential to the area is ''j'' sin ''θ'', but there is ''no'' flux actually passing ''through'' the area in the tangential direction. The ''only'' component of flux passing normal to the area is the cosine component. For vector flux, the surface integral of j over a surface ''S'', gives the proper flowing per unit of time through the surface. \frac = \iint_S \mathbf\cdot\mathbf\, dA = \iint_S \mathbf\cdot d\mathbf A (and its infinitesimal) is the vector area, combination of the magnitude of the area through which the property passes, ''A'', and a unit vector normal to the area, \mathbf. The relation is \mathbf = A \mathbf. Unlike in the second set of equations, the surface here need not be flat. Finally, we can integrate again over the time duration ''t''1 to ''t''2, getting the total amount of the property flowing through the surface in that time (''t''2 − ''t''1): q = \int_^\iint_S \mathbf\cdot d\mathbf A\, dt


Transport fluxes

Eight of the most common forms of flux from the transport phenomena literature are defined as follows: # Momentum flux, the rate of transfer of momentum across a unit area (N·s·m−2·s−1). ( Newton's law of viscosity) # Heat flux, the rate of
heat In thermodynamics, heat is defined as the form of energy crossing the boundary of a thermodynamic system by virtue of a temperature difference across the boundary. A thermodynamic system does not ''contain'' heat. Nevertheless, the term is ...
flow across a unit area (J·m−2·s−1). ( Fourier's law of conduction) (This definition of heat flux fits Maxwell's original definition.) # Diffusion flux, the rate of movement of molecules across a unit area (mol·m−2·s−1). ( Fick's law of diffusion) # Volumetric flux, the rate of
volume Volume is a measure of occupied three-dimensional space. It is often quantified numerically using SI derived units (such as the cubic metre and litre) or by various imperial or US customary units (such as the gallon, quart, cubic inch). Th ...
flow across a unit area (m3·m−2·s−1). ( Darcy's law of groundwater flow) # Mass flux, the rate of mass flow across a unit area (kg·m−2·s−1). (Either an alternate form of Fick's law that includes the molecular mass, or an alternate form of Darcy's law that includes the density.) # Radiative flux, the amount of energy transferred in the form of photons at a certain distance from the source per unit area per second (J·m−2·s−1). Used in astronomy to determine the magnitude and spectral class of a star. Also acts as a generalization of heat flux, which is equal to the radiative flux when restricted to the electromagnetic spectrum. # Energy flux, the rate of transfer of
energy In physics, energy (from Ancient Greek: ἐνέργεια, ''enérgeia'', “activity”) is the quantitative property that is transferred to a body or to a physical system, recognizable in the performance of work and in the form of hea ...
through a unit area (J·m−2·s−1). The radiative flux and heat flux are specific cases of energy flux. # Particle flux, the rate of transfer of particles through a unit area ( umber of particlesm−2·s−1) These fluxes are vectors at each point in space, and have a definite magnitude and direction. Also, one can take the divergence of any of these fluxes to determine the accumulation rate of the quantity in a control volume around a given point in space. For incompressible flow, the divergence of the volume flux is zero.


Chemical diffusion

As mentioned above, chemical molar flux of a component A in an isothermal, isobaric system is defined in Fick's law of diffusion as: \mathbf_A = -D_ \nabla c_A where the nabla symbol ∇ denotes the
gradient In vector calculus, the gradient of a scalar-valued differentiable function of several variables is the vector field (or vector-valued function) \nabla f whose value at a point p is the "direction and rate of fastest increase". If the gr ...
operator, ''DAB'' is the diffusion coefficient (m2·s−1) of component A diffusing through component B, ''cA'' is the concentration ( mol/m3) of component A. This flux has units of mol·m−2·s−1, and fits Maxwell's original definition of flux. For dilute gases, kinetic molecular theory relates the diffusion coefficient ''D'' to the particle density ''n'' = ''N''/''V'', the molecular mass ''m'', the collision cross section \sigma, and the absolute temperature ''T'' by D = \frac\sqrt where the second factor is the mean free path and the square root (with the Boltzmann constant ''k'') is the mean velocity of the particles. In turbulent flows, the transport by eddy motion can be expressed as a grossly increased diffusion coefficient.


Quantum mechanics

In
quantum mechanics Quantum mechanics is a fundamental theory in physics that provides a description of the physical properties of nature at the scale of atoms and subatomic particles. It is the foundation of all quantum physics including quantum chemistry, q ...
, particles of mass ''m'' in the quantum state ''ψ''(r, ''t'') have a probability density defined as \rho = \psi^* \psi = , \psi, ^2. So the probability of finding a particle in a differential volume element d3r is dP = , \psi, ^2 \, d^3\mathbf. Then the number of particles passing perpendicularly through unit area of a
cross-section Cross section may refer to: * Cross section (geometry) ** Cross-sectional views in architecture & engineering 3D *Cross section (geology) * Cross section (electronics) * Radar cross section, measure of detectability * Cross section (physics) **Ab ...
per unit time is the probability flux; \mathbf = \frac \left(\psi \nabla \psi^* - \psi^* \nabla \psi \right). This is sometimes referred to as the probability current or current density, or probability flux density.


Flux as a surface integral


General mathematical definition (surface integral)

As a mathematical concept, flux is represented by the surface integral of a vector field, :\Phi_F=\iint_A\mathbf\cdot\mathrm\mathbf :\Phi_F=\iint_A\mathbf\cdot\mathbf\,\mathrmA where F is a vector field, and d''A'' is the vector area of the surface ''A'', directed as the surface normal. For the second, n is the outward pointed unit normal vector to the surface. The surface has to be orientable, i.e. two sides can be distinguished: the surface does not fold back onto itself. Also, the surface has to be actually oriented, i.e. we use a convention as to flowing which way is counted positive; flowing backward is then counted negative. The surface normal is usually directed by the right-hand rule. Conversely, one can consider the flux the more fundamental quantity and call the vector field the flux density. Often a vector field is drawn by curves (field lines) following the "flow"; the magnitude of the vector field is then the line density, and the flux through a surface is the number of lines. Lines originate from areas of positive divergence (sources) and end at areas of negative divergence (sinks). See also the image at right: the number of red arrows passing through a unit area is the flux density, the
curve In mathematics, a curve (also called a curved line in older texts) is an object similar to a line, but that does not have to be straight. Intuitively, a curve may be thought of as the trace left by a moving point. This is the definition that ...
encircling the red arrows denotes the boundary of the surface, and the orientation of the arrows with respect to the surface denotes the sign of the inner product of the vector field with the surface normals. If the surface encloses a 3D region, usually the surface is oriented such that the influx is counted positive; the opposite is the outflux. The divergence theorem states that the net outflux through a closed surface, in other words the net outflux from a 3D region, is found by adding the local net outflow from each point in the region (which is expressed by the divergence). If the surface is not closed, it has an oriented curve as boundary.
Stokes' theorem Stokes's theorem, also known as the Kelvin–Stokes theorem Nagayoshi Iwahori, et al.:"Bi-Bun-Seki-Bun-Gaku" Sho-Ka-Bou(jp) 1983/12Written in Japanese)Atsuo Fujimoto;"Vector-Kai-Seki Gendai su-gaku rekucha zu. C(1)" :ja:培風館, Bai-Fu-Kan( ...
states that the flux of the curl of a vector field is the line integral of the vector field over this boundary. This path integral is also called
circulation Circulation may refer to: Science and technology * Atmospheric circulation, the large-scale movement of air * Circulation (physics), the path integral of the fluid velocity around a closed curve in a fluid flow field * Circulatory system, a bio ...
, especially in fluid dynamics. Thus the curl is the circulation density. We can apply the flux and these theorems to many disciplines in which we see currents, forces, etc., applied through areas.


Electromagnetism


Electric flux

An electric "charge," such as a single proton in space, has a magnitude defined in coulombs. Such a charge has an electric field surrounding it. In pictorial form, the electric field from a positive point charge can be visualized as a dot radiating electric field lines (sometimes also called "lines of force"). Conceptually, electric flux can be thought of as "the number of field lines" passing through a given area. Mathematically, electric flux is the integral of the normal component of the electric field over a given area. Hence, units of electric flux are, in the MKS system, newtons per coulomb times meters squared, or N m2/C. (Electric flux density is the electric flux per unit area, and is a measure of strength of the normal component of the electric field averaged over the area of integration. Its units are N/C, the same as the electric field in MKS units.) Two forms of electric flux are used, one for the E-field: : and one for the D-field (called the electric displacement): : This quantity arises in Gauss's law – which states that the flux of the electric field E out of a closed surface is proportional to the electric charge ''QA'' enclosed in the surface (independent of how that charge is distributed), the integral form is: : where ''ε''0 is the permittivity of free space. If one considers the flux of the electric field vector, E, for a tube near a point charge in the field of the charge but not containing it with sides formed by lines tangent to the field, the flux for the sides is zero and there is an equal and opposite flux at both ends of the tube. This is a consequence of Gauss's Law applied to an inverse square field. The flux for any cross-sectional surface of the tube will be the same. The total flux for any surface surrounding a charge ''q'' is ''q''/''ε''0. In free space the electric displacement is given by the constitutive relation D = ''ε''0 E, so for any bounding surface the D-field flux equals the charge ''QA'' within it. Here the expression "flux of" indicates a mathematical operation and, as can be seen, the result is not necessarily a "flow", since nothing actually flows along electric field lines.


Magnetic flux

The magnetic flux density ( magnetic field) having the unit Wb/m2 ( Tesla) is denoted by B, and magnetic flux is defined analogously: : with the same notation above. The quantity arises in Faraday's law of induction, where the magnetic flux is time-dependent either because the boundary is time-dependent or magnetic field is time-dependent. In integral form: :- \frac = \oint_ \mathbf \cdot d \boldsymbol where ''d'' is an infinitesimal vector line element of the
closed curve In mathematics, a curve (also called a curved line in older texts) is an object similar to a line, but that does not have to be straight. Intuitively, a curve may be thought of as the trace left by a moving point. This is the definition tha ...
\partial A, with magnitude equal to the length of the infinitesimal line element, and direction given by the tangent to the curve \partial A, with the sign determined by the integration direction. The time-rate of change of the magnetic flux through a loop of wire is minus the electromotive force created in that wire. The direction is such that if current is allowed to pass through the wire, the electromotive force will cause a current which "opposes" the change in magnetic field by itself producing a magnetic field opposite to the change. This is the basis for inductors and many electric generators.


Poynting flux

Using this definition, the flux of the Poynting vector S over a specified surface is the rate at which electromagnetic energy flows through that surface, defined like before: : The flux of the Poynting vector through a surface is the electromagnetic power, or
energy In physics, energy (from Ancient Greek: ἐνέργεια, ''enérgeia'', “activity”) is the quantitative property that is transferred to a body or to a physical system, recognizable in the performance of work and in the form of hea ...
per unit
time Time is the continued sequence of existence and events that occurs in an apparently irreversible succession from the past, through the present, into the future. It is a component quantity of various measurements used to sequence events, t ...
, passing through that surface. This is commonly used in analysis of
electromagnetic radiation In physics, electromagnetic radiation (EMR) consists of waves of the electromagnetic (EM) field, which propagate through space and carry momentum and electromagnetic radiant energy. It includes radio waves, microwaves, infrared, (visible ...
, but has application to other electromagnetic systems as well. Confusingly, the Poynting vector is sometimes called the ''power flux'', which is an example of the first usage of flux, above. p.357 It has units of
watt The watt (symbol: W) is the unit of power or radiant flux in the International System of Units (SI), equal to 1 joule per second or 1 kg⋅m2⋅s−3. It is used to quantify the rate of energy transfer. The watt is named after James Wa ...
s per square metre (W/m2).


SI radiometry units


See also

* AB magnitude * Explosively pumped flux compression generator * Eddy covariance flux (aka, eddy correlation, eddy flux) * Fast Flux Test Facility *
Fluence In radiometry, radiant exposure or fluence is the radiant energy ''received'' by a ''surface'' per unit area, or equivalently the irradiance of a ''surface,'' integrated over time of irradiation, and spectral exposure is the radiant exposure per un ...
(flux of the first sort for particle beams) * Fluid dynamics * Flux footprint * Flux pinning * Flux quantization * Gauss's law * Inverse-square law * Jansky (non SI unit of spectral flux density) * Latent heat flux * Luminous flux * Magnetic flux * Magnetic flux quantum * Neutron flux *
Poynting flux In physics, the Poynting vector (or Umov–Poynting vector) represents the directional energy flux (the energy transfer per unit area per unit time) or '' power flow'' of an electromagnetic field. The SI unit of the Poynting vector is the watt ...
* Poynting theorem * Radiant flux * Rapid single flux quantum * Sound energy flux * Volumetric flux (flux of the first sort for fluids) * Volumetric flow rate (flux of the second sort for fluids)


Notes

* *


Further reading

*


External links

* {{Wiktionary-inline Physical quantities Vector calculus Rates