This end of the rope is pulling the tug of war team to the right. Each segment of the rope is pulled on by the two neighboring segments with a force due to tension. Tension can change along the length of a rope, as it does along the grip of each of the tug of war team members.
In physics, tension describes the pulling force exerted by each end of a string, cable, chain, or similar onedimensional continuous object, or by each end of a rod, truss member, or similar three dimensional object. At the atomic level, tension is produced when atoms or molecules are pulled apart from each other and gain electromagnetic potential energy. Each end of a string or rod under tension will pull on the object it is attached to, to restore the string/rod to its relaxed length.
Tension is the opposite of compression. Although not physics terms, slackening and tensioning are used when talking about fencing, for example.
In physics, although tension is not a force, it does have the units of force and can be measured in newtons (or sometimes poundsforce). The ends of a string or other object under tension will exert forces on the objects to which the string or rod is connected, in the direction of the string at the point of attachment. These forces due to tension are often called "tension forces." There are two basic possibilities for systems of objects held by strings:^{[1]} either acceleration is zero and the system is therefore in equilibrium, or there is acceleration and therefore a net force is present.
Contents

Tension in onedimensional continua 1

Tension in threedimensional continua 2

System in equilibrium 3

System under net force 4

Strings in modern physics 5

See also 6

References 7
Tension in onedimensional continua
Tension in a string is a nonnegative scalar. Zero tension is slack. A string or rope is often idealized as one dimension, having length but being massless with zero cross section. If there are no bends in the string (as occur with vibrations or pulleys), then tension is a constant along the string, equal to the magnitude of the forces applied by the ends of the string. By Newton's Third Law, these are the same forces exerted on the ends of the string by the objects to which the ends are attached. If the string curves around one or more pulleys, it will still have constant tension along its length in the idealized situation that the pulleys are massless and frictionless. A vibrating string vibrates with a set of frequencies that depend on the string's tension. These frequencies can be derived from Newton's Laws. Each microscopic segment of the string pulls on and is pulled upon by its neighboring segments, with a force equal to the tension at that position along the string. tension =\tau(x) where x is the position along the string.
If the string has curvature, then the two pulls on a segment by its two neighbors will not add to zero, and there will be a net force on that segment of the string, causing an acceleration. This net force is a restoring force, and the motion of the string can include transverse waves that solve the equation central to SturmLiouville theory:
 \frac{d}{dx} \bigg[ \tau(x) \frac{d\rho(x)}{dx} \bigg]+v(x)\rho(x) = \omega^2\sigma(x)\rho(x)
where v(x) is the force constant per unit length [units force per area] \omega^2 are the eigenvalues for resonances of transverse displacement \rho(x)on the string.,^{[2]} with solutions that include the various harmonics on a stringed instrument.
Tension in threedimensional continua
Tension is also used to describe the force exerted by the ends of a threedimensional, continuous material such as a rod or truss member. Such a rod elongates under tension. The amount of elongation and the load that will cause failure both depend on the force per crosssectional area rather than the force alone, so stress = axial force / cross sectional area is more useful for engineering purposes than tension. Stress is a 3x3 matrix called a tensor, and the \sigma_{11} element of the stress tensor is tensile force per area (or compression force per area, denoted as a negative number for this element, if the rod is being compressed rather than elongated).
System in equilibrium
A system is in equilibrium when the sum of all forces is zero.

\sum_ {} \vec{F} = 0 ^{[1]}
For example, consider a system consisting of an object that is being lowered vertically by a string with tension, T, at a constant velocity. The system has a constant velocity and is therefore in equilibrium because the tension in the string (which is pulling up on the object) is equal to the force of gravity, mg, which is pulling down on the object.

\sum_ {} \vec{F} = \vec{T} + m\vec{g} = 0 ^{[1]}
System under net force
A system has a net force when an unbalanced force is exerted on it, in other words the sum of all forces is not zero. Acceleration and net force always exist together.

\sum_ {} \vec{F} \ne 0^{[1]}
For example, consider the same system as above but suppose the object is now being lowered with an increasing velocity downwards (positive acceleration) therefore there exists a net force somewhere in the system. In this case, negative acceleration would indicate that mg > T.

\sum \vec{F} = T  mg \ne 0^{[1]}
In another example, suppose that two bodies A and B having masses m_1 and m_2 respectively are connected with each other by an inextensible string over a frictionless pulley. There are two forces acting on the body A: its weight (w_1=m_1g) pulling down, and the tension T in the string pulling up. If body A has greater mass than body B, m_1 > m_2. Therefore, the net force F_1 on body A is w_1T, so m_1a=m_1gT.
Strings in modern physics
Stringlike objects in relativistic theories, such as the strings used in some models of interactions between quarks, or those used in the modern string theory, also possess tension. These strings are analyzed in terms of their world sheet, and the energy is then typically proportional to the length of the string. As a result, the tension in such strings is independent of the amount of stretching.
In an extensible string, Hooke's law applies.
See also
References

^ ^{a} ^{b} ^{c} ^{d} ^{e} Physics for Scientists and Engineers with Modern Physics, Section 5.7. Seventh Edition, Brooks/Cole Cengage Learning, 2008.

^ A. Fetter and J. Walecka. (1980). Theoretical Mechanics of Particles and Continua. New York: McGrawHill.
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