# divergence là gì The divergence of different vector fields. The divergence of vectors from point (x,y) equals the sum of the partial derivative-with-respect-to-x of the x-component and the partial derivative-with-respect-to-y of the y-component at that point:

In vector calculus, divergence is a vector operator that operates on a vector field, producing a scalar field giving the quantity of the vector field's source at each point. More technically, the divergence represents the volume mật độ trùng lặp từ khóa of the outward flux of a vector field from an infinitesimal volume around a given point.

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As an example, consider air as it is heated or cooled. The velocity of the air at each point defines a vector field. While air is heated in a region, it expands in all directions, and thus the velocity field points outward from that region. The divergence of the velocity field in that region would thus have a positive value. While the air is cooled and thus contracting, the divergence of the velocity has a negative value.

## Physical interpretation of divergence

In physical terms, the divergence of a vector field is the extent lớn which the vector field flux behaves lượt thích a source at a given point. It is a local measure of its "outgoingness" – the extent lớn which there are more of the field vectors exiting from an infinitesimal region of space phàn nàn entering it. A point at which the flux is outgoing has positive divergence, and is often called a "source" of the field. A point at which the flux is directed inward has negative divergence, and is often called a "sink" of the field. The greater the flux of field through a small surface enclosing a given point, the greater the value of divergence at that point. A point at which there is zero flux through an enclosing surface has zero divergence.

The divergence of a vector field is often illustrated using the simple example of the velocity field of a fluid, a liquid or gas. A moving gas has a velocity, a tốc độ and direction at each point, which can be represented by a vector, so sánh the velocity of the gas forms a vector field. If a gas is heated, it will expand. This will cause a net motion of gas particles outward in all directions. Any closed surface in the gas will enclose gas which is expanding, so sánh there will be an outward flux of gas through the surface. So the velocity field will have positive divergence everywhere. Similarly, if the gas is cooled, it will contract. There will be more room for gas particles in any volume, so sánh the external pressure of the fluid will cause a net flow of gas volume inward through any closed surface. Therefore the velocity field has negative divergence everywhere. In contrast, in a gas at a constant temperature and pressure, the net flux of gas out of any closed surface is zero. The gas may be moving, but the volume rate of gas flowing into any closed surface must equal the volume rate flowing out, so sánh the net flux is zero. Thus the gas velocity has zero divergence everywhere. A field which has zero divergence everywhere is called solenoidal.

If the gas is heated only at one point or small region, or a small tube is introduced which supplies a source of additional gas at one point, the gas there will expand, pushing fluid particles around it outward in all directions. This will cause an outward velocity field throughout the gas, centered on the heated point. Any closed surface enclosing the heated point will have a flux of gas particles passing out of it, so sánh there is positive divergence at that point. However any closed surface not enclosing the point will have a constant mật độ trùng lặp từ khóa of gas inside, so sánh just as many fluid particles are entering as leaving the volume, thus the net flux out of the volume is zero. Therefore the divergence at any other point is zero.

## Definition The divergence at a point x is the limit of the ratio of the flux through the surface Si (red arrows) lớn the volume for any sequence of closed regions V1, V2, V3, … enclosing x that approaches zero volume:

The divergence of a vector field F(x) at a point x0 is defined as the limit of the ratio of the surface integral of F out of the closed surface of a volume V enclosing x0 lớn the volume of V, as V shrinks lớn zero    where |V| is the volume of V, S(V) is the boundary of V, and is the outward unit normal lớn that surface. It can be shown that the above limit always converges lớn the same value for any sequence of volumes that contain x0 and approach zero volume. The result, div F, is a scalar function of x.

Since this definition is coordinate-free, it shows that the divergence is the same in any coordinate system. However it is not often used practically lớn calculate divergence; when the vector field is given in a coordinate system the coordinate definitions below are much simpler lớn use.

A vector field with zero divergence everywhere is called solenoidal – in which case any closed surface has no net flux across it.

## Definition in coordinates

### Cartesian coordinates

In three-dimensional Cartesian coordinates, the divergence of a continuously differentiable vector field is defined as the scalar-valued function: Although expressed in terms of coordinates, the result is invariant under rotations, as the physical interpretation suggests. This is because the trace of the Jacobian matrix of an N-dimensional vector field F in N-dimensional space is invariant under any invertible linear transformation.

The common notation for the divergence ∇ · F is a convenient mnemonic, where the dot denotes an operation reminiscent of the dot product: take the components of the operator (see del), apply them lớn the corresponding components of F, and sum the results. Because applying an operator is different from multiplying the components, this is considered an abuse of notation.

### Cylindrical coordinates

For a vector expressed in local unit cylindrical coordinates as where ea is the unit vector in direction a, the divergence is The use of local coordinates is vital for the validity of the expression. If we consider x the position vector and the functions r(x), θ(x), and z(x), which assign the corresponding global cylindrical coordinate lớn a vector, in general , , and . In particular, if we consider the identity function F(x) = x, we find that: .

### Spherical coordinates

In spherical coordinates, with θ the angle with the z axis and φ the rotation around the z axis, and F again written in local unit coordinates, the divergence is ### Tensor field

Let A be continuously differentiable second-order tensor field defined as follows: the divergence in cartesian coordinate system is a first-order tensor field and can be defined in two ways: and We have If tensor is symmetric Aij = Aji then . Because of this, often in the literature the two definitions (and symbols div and ) are used interchangeably (especially in mechanics equations where tensor symmetry is assumed).

Expressions of in cylindrical and spherical coordinates are given in the article del in cylindrical and spherical coordinates.

### General coordinates

Using Einstein notation we can consider the divergence in general coordinates, which we write as x1, …, xi, …, xn, where n is the number of dimensions of the domain name. Here, the upper index refers lớn the number of the coordinate or component, so sánh x2 refers lớn the second component, and not the quantity x squared. The index variable i is used lớn refer lớn an arbitrary component, such as xi. The divergence can then be written via the Voss-Weyl formula, as: where is the local coefficient of the volume element and Fi are the components of with respect lớn the local unnormalized covariant basis (sometimes written as ). The Einstein notation implies summation over i, since it appears as both an upper and lower index.

The volume coefficient ρ is a function of position which depends on the coordinate system. In Cartesian, cylindrical and spherical coordinates, using the same conventions as before, we have ρ = 1, ρ = r and ρ = r2 sin θ, respectively. The volume can also be expressed as , where gab is the metric tensor. The determinant appears because it provides the appropriate invariant definition of the volume, given a mix of vectors. Since the determinant is a scalar quantity which doesn't depend on the indices, these can be suppressed, writing . The absolute value is taken in order lớn handle the general case where the determinant might be negative, such as in pseudo-Riemannian spaces. The reason for the square-root is a bit subtle: it effectively avoids double-counting as one goes from curved lớn Cartesian coordinates, and back. The volume (the determinant) can also be understood as the Jacobian of the transformation from Cartesian lớn curvilinear coordinates, which for n = 3 gives .

Some conventions expect all local basis elements lớn be normalized lớn unit length, as was done in the previous sections. If we write for the normalized basis, and for the components of F with respect lớn it, we have that using one of the properties of the metric tensor. By dotting both sides of the last equality with the contravariant element , we can conclude that . After substituting, the formula becomes: See § In curvilinear coordinates for further discussion.

## Properties

The following properties can all be derived from the ordinary differentiation rules of calculus. Most importantly, the divergence is a linear operator, i.e., for all vector fields F and G and all real numbers a and b.

There is a product rule of the following type: if φ is a scalar-valued function and F is a vector field, then or in more suggestive notation Another product rule for the cross product of two vector fields F and G in three dimensions involves the curl and reads as follows: or Xem thêm: shampoo là gì

The Laplacian of a scalar field is the divergence of the field's gradient: The divergence of the curl of any vector field (in three dimensions) is equal lớn zero: If a vector field F with zero divergence is defined on a ball in R3, then there exists some vector field G on the ball with F = curl G. For regions in R3 more topologically complicated phàn nàn this, the latter statement might be false (see Poincaré lemma). The degree of failure of the truth of the statement, measured by the homology of the chain complex serves as a nice quantification of the complicatedness of the underlying region U. These are the beginnings and main motivations of de Rham cohomology.

## Decomposition theorem

It can be shown that any stationary flux v(r) that is twice continuously differentiable in R3 and vanishes sufficiently fast for |r| → ∞ can be decomposed uniquely into an irrotational part E(r) and a source-free part B(r). Moreover, these parts are explicitly determined by the respective source densities (see above) and circulation densities (see the article Curl):

For the irrotational part one has with The source-free part, B, can be similarly written: one only has lớn replace the scalar potential Φ(r) by a vector potential A(r) and the terms −∇Φ by +∇ × A, and the source mật độ trùng lặp từ khóa div v by the circulation mật độ trùng lặp từ khóa ∇ × v.

This "decomposition theorem" is a by-product of the stationary case of electrodynamics. It is a special case of the more general Helmholtz decomposition, which works in dimensions greater phàn nàn three as well.

## In arbitrary finite dimensions

The divergence of a vector field can be defined in any finite number of dimensions. If in a Euclidean coordinate system with coordinates x1, x2, ..., xn, define In the 1D case, F reduces lớn a regular function, and the divergence reduces lớn the derivative.

For any n, the divergence is a linear operator, and it satisfies the "product rule" for any scalar-valued function φ.

## Relation lớn the exterior derivative

One can express the divergence as a particular case of the exterior derivative, which takes a 2-form lớn a 3-form in R3. Define the current two-form as It measures the amount of "stuff" flowing through a surface per unit time in a "stuff fluid" of mật độ trùng lặp từ khóa ρ = 1 dxdydz moving with local velocity F. Its exterior derivative dj is then given by where is the wedge product.

Thus, the divergence of the vector field F can be expressed as: Here the superscript is one of the two musical isomorphisms, and is the Hodge star operator. When the divergence is written in this way, the operator is referred lớn as the codifferential. Working with the current two-form and the exterior derivative is usually easier phàn nàn working with the vector field and divergence, because unlike the divergence, the exterior derivative commutes with a change of (curvilinear) coordinate system.

## In curvilinear coordinates

The appropriate expression is more complicated in curvilinear coordinates. The divergence of a vector field extends naturally lớn any differentiable manifold of dimension n that has a volume size (or density) μ, e.g. a Riemannian or Lorentzian manifold. Generalising the construction of a two-form for a vector field on R3, on such a manifold a vector field X defines an (n − 1)-form j = iXμ obtained by contracting X with μ. The divergence is then the function defined by The divergence can be defined in terms of the Lie derivative as This means that the divergence measures the rate of expansion of a unit of volume (a volume element) as it flows with the vector field.

On a pseudo-Riemannian manifold, the divergence with respect lớn the volume can be expressed in terms of the Levi-Civita connection : where the second expression is the contraction of the vector field valued 1-form X with itself and the last expression is the traditional coordinate expression from Ricci calculus.

An equivalent expression without using a connection is where g is the metric and denotes the partial derivative with respect lớn coordinate xa. The square-root of the (absolute value of the determinant of the) metric appears because the divergence must be written with the correct conception of the volume. In curvilinear coordinates, the basis vectors are no longer orthonormal; the determinant encodes the correct idea of volume in this case. It appears twice, here, once, so sánh that the can be transformed into "flat space" (where coordinates are actually orthonormal), and once again so sánh that is also transformed into "flat space", so sánh that finally, the "ordinary" divergence can be written with the "ordinary" concept of volume in flat space (i.e. unit volume, i.e. one, i.e. not written down). The square-root appears in the denominator, because the derivative transforms in the opposite way (contravariantly) lớn the vector (which is covariant). This idea of getting lớn a "flat coordinate system" where local computations can be done in a conventional way is called a vielbein. A different way lớn see this is lớn note that the divergence is the codifferential in disguise. That is, the divergence corresponds lớn the expression with the differential and the Hodge star. The Hodge star, by its construction, causes the volume size lớn appear in all of the right places.

## The divergence of tensors

Divergence can also be generalised lớn tensors. In Einstein notation, the divergence of a contravariant vector Fμ is given by where μ denotes the covariant derivative. In this general setting, the correct formulation of the divergence is lớn recognize that it is a codifferential; the appropriate properties follow from there.

Equivalently, some authors define the divergence of a mixed tensor by using the musical isomorphism : if T is a (p, q)-tensor (p for the contravariant vector and q for the covariant one), then we define the divergence of T lớn be the (p, q − 1)-tensor that is, we take the trace over the first two covariant indices of the covariant derivative.[a] The symbol refers lớn the musical isomorphism.