Born rigidity is a concept in
special relativity
In physics, the special theory of relativity, or special relativity for short, is a scientific theory of the relationship between Spacetime, space and time. In Albert Einstein's 1905 paper, Annus Mirabilis papers#Special relativity,
"On the Ele ...
. It is one answer to the question of what, in special relativity, corresponds to the
rigid body of non-relativistic
classical mechanics
Classical mechanics is a Theoretical physics, physical theory describing the motion of objects such as projectiles, parts of Machine (mechanical), machinery, spacecraft, planets, stars, and galaxies. The development of classical mechanics inv ...
.
The concept was introduced by
Max Born
Max Born (; 11 December 1882 – 5 January 1970) was a German-British theoretical physicist who was instrumental in the development of quantum mechanics. He also made contributions to solid-state physics and optics, and supervised the work of a ...
(1909),
[Born (1909b)] who gave a detailed description of the case of constant
proper acceleration which he called
hyperbolic motion. When subsequent authors such as
Paul Ehrenfest (1909) tried to incorporate rotational motions as well, it became clear that Born rigidity is a very restrictive sense of rigidity, leading to the Herglotz–Noether theorem, according to which there are severe restrictions on rotational Born rigid motions. It was formulated by
Gustav Herglotz (1909, who classified all forms of rotational motions)
[Herglotz (1909)] and in a less general way by
Fritz Noether (1909).
[Noether (1909)] As a result, Born (1910)
[Born (1910)] and others gave alternative, less restrictive definitions of rigidity.
Definition
Born rigidity is satisfied if the
orthogonal
In mathematics, orthogonality (mathematics), orthogonality is the generalization of the geometric notion of ''perpendicularity''. Although many authors use the two terms ''perpendicular'' and ''orthogonal'' interchangeably, the term ''perpendic ...
spacetime
In physics, spacetime, also called the space-time continuum, is a mathematical model that fuses the three dimensions of space and the one dimension of time into a single four-dimensional continuum. Spacetime diagrams are useful in visualiz ...
distance between infinitesimally separated curves or
worldlines is constant,
or equivalently, if the length of the rigid body in momentary co-moving
inertial frames measured by standard measuring rods (i.e. the
proper length) is constant and is therefore subjected to
Lorentz contraction in relatively moving frames.
[Gron (1981)] Born rigidity is a constraint on the motion of an extended body, achieved by careful application of forces to different parts of the body. A body that could maintain its own rigidity would violate special relativity, as its
speed of sound
The speed of sound is the distance travelled per unit of time by a sound wave as it propagates through an elasticity (solid mechanics), elastic medium. More simply, the speed of sound is how fast vibrations travel. At , the speed of sound in a ...
would be infinite.
A classification of all possible Born rigid motions can be obtained using the Herglotz–Noether theorem. This theorem states that all
irrotational Born rigid motions (
class A) consist of
hyperplane
In geometry, a hyperplane is a generalization of a two-dimensional plane in three-dimensional space to mathematical spaces of arbitrary dimension. Like a plane in space, a hyperplane is a flat hypersurface, a subspace whose dimension is ...
s rigidly moving through spacetime, while any rotational Born rigid motion (
class B) must be an
isometric Killing motion. This implies that a Born rigid body only has three
degrees of freedom
In many scientific fields, the degrees of freedom of a system is the number of parameters of the system that may vary independently. For example, a point in the plane has two degrees of freedom for translation: its two coordinates; a non-infinite ...
. Thus a body can be brought in a Born rigid way from rest into any
translational motion, but it cannot be brought in a Born rigid way from rest into rotational motion.
Stresses and Born rigidity
It was shown by Herglotz (1911), that a relativistic
theory of elasticity can be based on the assumption, that stresses arise when the condition of Born rigidity is broken.
An example of breaking Born rigidity is the
Ehrenfest paradox: Even though the state of
uniform circular motion of a body is among the allowed Born rigid motions of
class B, a body cannot be brought from any other state of motion into uniform circular motion without breaking the condition of Born rigidity during the phase in which the body undergoes various accelerations. But if this phase is over and the
centripetal acceleration becomes constant, the body can be uniformly rotating in agreement with Born rigidity. Likewise, if it is now in uniform circular motion, this state cannot be changed without again breaking the Born rigidity of the body.
Another example is
Bell's spaceship paradox: If the endpoints of a body are accelerated with constant proper accelerations in rectilinear direction, then the leading endpoint must have a lower proper acceleration in order to leave the proper length constant so that Born rigidity is satisfied. It will also exhibit an increasing Lorentz contraction in an external inertial frame, that is, in the external frame the endpoints of the body are not accelerating simultaneously. However, if a different acceleration profile is chosen by which the endpoints of the body are simultaneously accelerated with same proper acceleration as seen in the external inertial frame, its Born rigidity will be broken, because constant length in the external frame implies increasing proper length in a comoving frame due to relativity of simultaneity. In this case, a fragile thread spanned between two rockets will experience stresses (which are called Herglotz–Dewan–Beran stresses
) and will consequently break.
Born rigid motions
A classification of allowed, in particular rotational, Born rigid motions in flat
Minkowski spacetime was given by Herglotz,
which was also studied by
Friedrich Kottler (1912, 1914),
[Kottler (1912); Kottler (1914a)] Georges Lemaître (1924),
Adriaan Fokker (1940), George Salzmann &
Abraham H. Taub (1954).
[Salzmann & Taub (1954)] Herglotz pointed out that a continuum is moving as a rigid body when the world lines of its points are
equidistant curves in
. The resulting worldliness can be split into two classes:
Class A: Irrotational motions
Herglotz defined this class in terms of equidistant curves which are the orthogonal trajectories of a family of
hyperplanes, which also can be seen as solutions of a
Riccati equation (this was called "plane motion" by Salzmann & Taub
or "irrotational rigid motion" by Boyer
). He concluded, that the motion of such a body is completely determined by the motion of one of its points.
The general metric for these irrotational motions has been given by Herglotz, whose work was summarized with simplified notation by Lemaître (1924). Also the
Fermi metric in the form given by
Christian Møller (1952) for rigid frames with arbitrary motion of the origin was identified as the "most general metric for irrotational rigid motion in special relativity". In general, it was shown that irrotational Born motion corresponds to those Fermi congruences of which any worldline can be used as baseline (homogeneous Fermi congruence).
Already Born (1909) pointed out that a rigid body in translational motion has a maximal spatial extension depending on its acceleration, given by the relation