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The most prominent example of a conservative force is the force of gravity. According to Newton's law of gravitation, the gravitational force, , acting on a mass m, due to a mass M which is a distance r away, obeys the equation where G is the Gravitational Constant and gravity is conservative because is a unit vector pointing from M towards m. The force of , where is the Gravitational potential. For a conservative forces, path independence can be interpreted to mean that the work done in going from a point A to a point B is independent of the path chosen, and that the work W done in going around a closed loop is zero: The total energy of a particle moving under the influence of conservative forces is conserved, in the sense that a loss of potential energy is converted to an equal quantity of kinetic energy or vice versa. Conservative vector field In vector calculus a conservative vector field is a vector field which is the gradient of a scalar potential. There are two closely related concepts: path independence and irrotational vector fields. Every conservative vector field has zero curl (and is thus irrotational), and every conservative vector field has the path independence property. In fact, these three properties are equivalent in many 'real-world' applications. Definition A vector field Here is said to be conservative if there exists a scalar field denotes the gradient of . When the above equation holds, such that is called a scalar potential for . Path independence A key property of a conservative vector field is that its integral along a path depends only on the endpoints of that path, not the particular route taken. Suppose that is a region of three-dimensional space, and that P is a path in S with start point A and end point B. If then is a conservative vector field This holds as a consequence of the Chain Rule and the Fundamental Theorem of Calculus. An equivalent formulation of this is to say that for every closed loop in S. The converse of the above statement is also true provided that S is a connected region. That is, if the circulation of around every closed loop in a connected region S is zero, then is a conservative vector field. Irrotational vector fields A vector field is said to be irrotational if its curl is zero. That is, if For this reason, such vector fields are sometimes referred to as curl-free vector fields. It is an identity of vector calculus that for any scalar field : Therefore every conservative vector field is also an irrotational vector field. Provided that S is a simply-connected region, the converse of this is true: every irrotational vector field is also a conservative vector field. The above statement is not true if S is not simply-connected. Let S be the usual 3-dimensional space, except with the z-axis removed; that is . Now define a vector field by Then exists and has zero curl at every point in S; that is is irrotational. However the circulation of around the unit circle in the x,y-plane is equal to 2π. Therefore v does not have the path independence property discussed above, and is not conservative. In a simply-connected region an irrotational vector field has the path independence property. This can be seen by noting that in such a region an irrotational vector field is conservative, and conservative vector fields have the path independence property. The result can also be proved directly by using Stokes' theorem. In a connected region any vector field which has the path independence property must also be irrotational. More abstractly, a conservative vector field is an exact 1-form. That is, it is a 1-form equal to the exterior derivative of some 0-form (scalar field) φ. An irrotational vector field is a closed 1-form. Since d2 = 0, any exact form is closed, so any conservative vector field is irrotational. The domain is simply connected if and only if its first homology group is 0, which is equivalent to its first cohomology group being 0. The first de Rham cohomology group is 0 if and only if all closed 1-forms are exact. Irrotational flows The flow velocity If of a fluid is a vector field, and the vorticity of the flow is (usually) defined by is irrotational then the flow is said to be an irrotational flow. The vorticity of an irrotational flow is zero. For a two-dimensional flow the vorticity acts as a measure of the local rotation of fluid elements. Note that the vorticity does not imply anything about the global behaviour of a fluid. It is possible for a fluid traveling in a straight line to have vorticity, and it is possible for a fluid which moves in a circle to be irrotational. For more information see: Vortex. Non-conservative forces For certain physical scenarios, it is impossible to model forces as being due to gradient of potentials. This is often due to macrophysical considerations which yield forces as arising from a macroscopic statistical average of microstates. For example, friction is caused by the gradients of numerous electrostatic potentials between the atoms, but manifests as a force model which is independent of any macroscale position vector. Non-conservative forces other than friction include other contact forces, tension, compression, and drag. However, for any sufficiently detailed description, all these forces are the results of conservative ones since each of these macroscopic forces are the net results of the gradients of microscopic potentials. The connection between macroscopic non-conservative forces and microscopic conservative forces is described by detailed treatment with statistical mechanics. In macroscopic closed systems, nonconservative forces act to change the internal energies of the system, and are often associated with the transfer of heat. According to the Second Law of Thermodynamics, non-conservative forces necessarily result in energy transformations within closed systems from ordered to more random conditions as entropy increases. Non-conservative forces arise due to neglected degrees of freedom. For instance, friction may be treated without resorting to the use of non-conservative forces by considering the motion of individual molecules; however that means every molecule's motion must be considered rather than handling it through statistical methods. For macroscopic systems the non-conservative approximation is far easier to deal with than millions of degrees of freedom. Examples of non-conservative forces are friction and non-elastic material stress.