Lorentz scalar

In a relativistic theory of physics, a Lorentz scalar is a scalar expression whose value is invariant under any Lorentz transformation. A Lorentz scalar may be generated from, for example, the scalar product of vectors, or by contracting a tensor. While the components of the contracted quantities may change under Lorentz transformations, the Lorentz scalars remain unchanged.

A simple Lorentz scalar in Minkowski spacetime is the spacetime distance ("length" of their difference) of two fixed events in spacetime. While the "position"-4-vectors of the events change between different inertial frames, their spacetime distance remains invariant under the corresponding Lorentz transformation. Other examples of Lorentz scalars are the "length" of a 4-velocity (see below), or the Ricci curvature at a point in spacetime in general relativity, which is a contraction of the Riemann curvature tensor.

In special relativity the location of a particle in 4-dimensional spacetime is given by $${\displaystyle x^{\mu }=(ct,𝐱)}$$ where ${\displaystyle 𝐱=𝐯t}$ is the position in 3-dimensional space of the particle with respect to a reference event, ${\displaystyle 𝐯}$ is the velocity in 3-dimensional space and ${\displaystyle c}$ is the speed of light.

The "length" of the vector is a Lorentz scalar and is given by $${\displaystyle x_{\mu }{x}^{\mu }={\eta }_{\mu \nu }{x}^{\mu }{x}^{\nu }=(ct{)}^2-𝐱\cdot 𝐱\stackrel{\mathrm{d}\mathrm{e}\mathrm{f}}{=}(c\tau {)}^2,}$$ where ${\displaystyle \tau }$ is the proper time as measured by a clock in the rest frame of the particle and the Minkowski metric is given by $${\displaystyle {\eta }^{\mu \nu }={\eta }_{\mu \nu }=\left(\begin{array}{cccc}1& 0& 0& 0\\ 0& -1& 0& 0\\ 0& 0& -1& 0\\ 0& 0& 0& -1\end{array}\right).}$$ This is a time-like metric.

Often the Minkowski metric is given on a form in which the overall sign is reversed. $${\displaystyle {\eta }^{\mu \nu }={\eta }_{\mu \nu }=\left(\begin{array}{cccc}-1& 0& 0& 0\\ 0& 1& 0& 0\\ 0& 0& 1& 0\\ 0& 0& 0& 1\end{array}\right).}$$ This is a space-like metric.

In the Minkowski metric the space-like interval ${\displaystyle s}$ is defined as $${\displaystyle x_{\mu }{x}^{\mu }={\eta }_{\mu \nu }{x}^{\mu }{x}^{\nu }=𝐱\cdot 𝐱-(ct{)}^2\stackrel{\mathrm{d}\mathrm{e}\mathrm{f}}{=}{s}^2.}$$

We use the space-like Minkowski metric in the rest of this article.

The velocity in spacetime is defined as $${\displaystyle v^{\mu }\stackrel{\mathrm{d}\mathrm{e}\mathrm{f}}{=}\frac{d{x}^{\mu }}{d\tau }=(c\frac{dt}{d\tau },\frac{dt}{d\tau }\frac{d𝐱}{dt})=(\gamma c,\gamma 𝐯)=\gamma (c,𝐯),}$$ where $${\displaystyle \gamma \stackrel{\mathrm{d}\mathrm{e}\mathrm{f}}{=}\frac{1}{\sqrt{1-\frac{𝐯\cdot 𝐯}{c^2}}}.}$$

The magnitude of the 4-velocity is a Lorentz scalar, $${\displaystyle v_{\mu }{v}^{\mu }=-c^2.}$$

Hence, ⁠${\displaystyle c}$⁠ is a Lorentz scalar.

The 4-acceleration is given by $${\displaystyle a^{\mu }\stackrel{\mathrm{d}\mathrm{e}\mathrm{f}}{=}\frac{d{v}^{\mu }}{d\tau }.}$$

The 4-acceleration is always perpendicular to the 4-velocity $${\displaystyle 0=\frac{1}{2}\frac{d}{d\tau }\left(v_{\mu }{v}^{\mu }\right)=\frac{d{v}_{\mu }}{d\tau }{v}^{\mu }=a_{\mu }{v}^{\mu }.}$$

Therefore, we can regard acceleration in spacetime as simply a rotation of the 4-velocity. The inner product of the acceleration and the velocity is a Lorentz scalar and is zero. This rotation is simply an expression of energy conservation: $${\displaystyle \frac{dE}{d\tau }=𝐅\cdot 𝐯}$$ where ${\displaystyle E}$ is the energy of a particle and ${\displaystyle 𝐅}$ is the 3-force on the particle.

The 4-momentum of a particle is $${\displaystyle p^{\mu }=m{v}^{\mu }=(\gamma mc,\gamma m𝐯)=(\gamma mc,𝐩)=(\frac{E}{c},𝐩)}$$ where ${\displaystyle m}$ is the particle rest mass, ${\displaystyle 𝐩}$ is the momentum in 3-space, and $${\displaystyle E=\gamma m{c}^2}$$ is the energy of the particle.

Consider a second particle with 4-velocity ${\displaystyle u}$ and a 3-velocity ${\displaystyle {𝐮}_2}$. In the rest frame of the second particle the inner product of ${\displaystyle u}$ with ${\displaystyle p}$ is proportional to the energy of the first particle $${\displaystyle p_{\mu }{u}^{\mu }=-E_1}$$ where the subscript 1 indicates the first particle.

Since the relationship is true in the rest frame of the second particle, it is true in any reference frame. ${\displaystyle E_1}$, the energy of the first particle in the frame of the second particle, is a Lorentz scalar. Therefore, $${\displaystyle E_1={\gamma }_1{\gamma }_2{m}_1{c}^2-{\gamma }_2{𝐩}_1\cdot {𝐮}_2}$$ in any inertial reference frame, where ${\displaystyle E_1}$ is still the energy of the first particle in the frame of the second particle.

In the rest frame of the particle the inner product of the momentum is $${\displaystyle p_{\mu }{p}^{\mu }=-(mc{)}^2.}$$

Therefore, the rest mass (m) is a Lorentz scalar. The relationship remains true independent of the frame in which the inner product is calculated. In many cases the rest mass is written as ${\displaystyle m_0}$ to avoid confusion with the relativistic mass, which is ${\displaystyle \gamma m_0}$.

Note that $${\displaystyle {\left(\frac{p_{\mu }{u}^{\mu }}{c}\right)}^2+p_{\mu }{p}^{\mu }=\frac{E_1^2}{c^2}-(mc{)}^2=({\gamma }_1^2-1)(mc{)}^2={\gamma }_1^2{𝐯}_1\cdot {𝐯}_1{m}^2={𝐩}_1\cdot {𝐩}_1.}$$

The square of the magnitude of the 3-momentum of the particle as measured in the frame of the second particle is a Lorentz scalar.

The 3-speed, in the frame of the second particle, can be constructed from two Lorentz scalars $${\displaystyle v_1^2={𝐯}_1\cdot {𝐯}_1=\frac{{𝐩}_1\cdot {𝐩}_1}{E_1^2}{c}^4.}$$

Scalars may also be constructed from the tensors and vectors, from the contraction of tensors (such as ${\displaystyle F_{\mu \nu }{F}^{\mu \nu }}$), or combinations of contractions of tensors and vectors (such as ${\displaystyle g_{\mu \nu }{x}^{\mu }{x}^{\nu }}$).

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