Energy–momentum relation

From Wikipedia, the free encyclopedia

In physics, the energy–momentum relation, or relativistic dispersion relation, is the relativistic equation relating any object's rest (intrinsic) mass, total energy, and momentum:

${\displaystyle E^{2}=(pc)^{2}+\left(m_{0}c^{2}\right)^{2}\,}$

(1)

holds for a system, such as a particle or macroscopic body, having intrinsic rest mass m₀, total energy E, and a momentum of magnitude p, where the constant c is the speed of light, assuming the special relativity case of flat spacetime.


The Dirac sea model, which was used to predict the existence of antimatter, is closely related to the energy-momentum equation.

Connection to E = mc²

The energy–momentum relation is consistent with the familiar mass–energy relation in both its interpretations: E = mc² relates total energy E to the (total) relativistic mass m (alternatively denoted m_rel or m_tot ), while E₀ = m₀c² relates rest energy E₀ to (invariant) rest mass m₀.

Unlike either of those equations, the energy–momentum equation (1) relates the total energy to the rest mass m₀. All three equations hold true simultaneously.

Special cases

1. If the body is a massless particle (m₀ = 0), then (1) reduces to E = pc. For photons, this is the relation, discovered in 19th century classical electromagnetism, between radiant momentum (causing radiation pressure) and radiant energy.
2. If the body's speed v is much less than c, then (1) reduces to E = 1/2m₀v² + m₀c²; that is, the body's total energy is simply its classical kinetic energy (1/2m₀v²) plus its rest energy.
3. If the body is at rest (v = 0), i.e. in its center-of-momentum frame (p = 0), we have E = E₀ and m = m₀; thus the energy–momentum relation and both forms of the mass–energy relation (mentioned above) all become the same.

A more general form of relation (1) holds for general relativity.

The invariant mass (or rest mass) is an invariant for all frames of reference (hence the name), not just in inertial frames in flat spacetime, but also accelerated frames traveling through curved spacetime. However the total energy of the particle E and its relativistic momentum p are frame-dependent; relative motion between two frames causes the observers in those frames to measure different values of the particle's energy and momentum; one frame measures E and p, while the other frame measures E′ and p′, where E′ ≠ E and p′ ≠ p, unless there is no relative motion between observers, in which case each observer measures the same energy and momenta. Although we still have, in flat spacetime:

${\displaystyle {E'}^{2}-\left(p'c\right)^{2}=\left(m_{0}c^{2}\right)^{2}\,.}$

The quantities E, p, E′, p′ are all related by a Lorentz transformation. The relation allows one to sidestep Lorentz transformations when determining only the magnitudes of the energy and momenta by equating the relations in the different frames. Again in flat spacetime, this translates to;

${\displaystyle {E}^{2}-\left(pc\right)^{2}={E'}^{2}-\left(p'c\right)^{2}=\left(m_{0}c^{2}\right)^{2}\,.}$

Since m₀ does not change from frame to frame, the energy–momentum relation is used in relativistic mechanics and particle physics calculations, as energy and momentum are given in a particle's rest frame (that is, E′ and p′ as an observer moving with the particle would conclude to be) and measured in the lab frame (i.e. E and p as determined by particle physicists in a lab, and not moving with the particles).

In relativistic quantum mechanics, it is the basis for constructing relativistic wave equations, since if the relativistic wave equation describing the particle is consistent with this equation – it is consistent with relativistic mechanics, and is Lorentz invariant. In relativistic quantum field theory, it is applicable to all particles and fields.

Origins and derivation of the equation

The Energy–momentum relation was first established by Paul Dirac in 1928 under the form ${\displaystyle E={\sqrt {c^{2}p^{2}+(m_{0}c^{2})^{2}}}+V}$, where V is the amount of potential energy.

The equation can be derived in a number of ways, two of the simplest include:

1. From the relativistic dynamics of a massive particle,
2. By evaluating the norm of the four-momentum of the system. This method applies to both massive and masseless particles, and can be extended to multi-particle systems with relatively little effort.

Heuristic approach for massive particles

For a massive object moving at three-velocity u = (u_x, u_y, u_z) with magnitude |u| = u in the lab frame:

${\displaystyle E=\gamma _{(\mathbf {u} )}m_{0}c^{2}}$

is the total energy of the moving object in the lab frame,

${\displaystyle \mathbf {p} =\gamma _{(\mathbf {u} )}m_{0}\mathbf {u} }$

is the three dimensional relativistic momentum of the object in the lab frame with magnitude |p| = p. The relativistic energy E and momentum p include the Lorentz factor defined by:

${\displaystyle \gamma _{(\mathbf {u} )}={\frac {1}{\sqrt {1-{\frac {\mathbf {u} \cdot \mathbf {u} }{c^{2}}}}}}={\frac {1}{\sqrt {1-\left({\frac {u}{c}}\right)^{2}}}}}$

Some authors use relativistic mass defined by:

${\displaystyle m=\gamma _{(\mathbf {u} )}m_{0}}$

although rest mass m₀ has a more fundamental significance, and will be used primarily over relativistic mass m in this article.

Squaring the 3-momentum gives:

${\displaystyle p^{2}=\mathbf {p} \cdot \mathbf {p} ={\frac {m_{0}^{2}\mathbf {u} \cdot \mathbf {u} }{1-{\frac {\mathbf {u} \cdot \mathbf {u} }{c^{2}}}}}={\frac {m_{0}^{2}u^{2}}{1-\left({\frac {u}{c}}\right)^{2}}}}$

then solving for u² and substituting into the Lorentz factor obtains its alternative form in terms of 3-momentum and mass, rather than 3-velocity:

${\displaystyle \gamma ={\sqrt {1+\left({\frac {p}{m_{0}c}}\right)^{2}}}}$

Inserting this form of the Lorentz factor into the energy equation:

${\displaystyle E=m_{0}c^{2}{\sqrt {1+\left({\frac {p}{m_{0}c}}\right)^{2}}}}$

followed by more rearrangement yields (1). The elimination of the Lorentz factor also eliminates implicit velocity dependence of the particle in (1), as well as any inferences to the "relativistic mass" of a massive particle. This approach is not general as massless particles are not considered. Naively setting m₀ = 0 would mean that E = 0 and p = 0 and no energy–momentum relation could be derived, which is not correct.

Norm of the four-momentum

The energy and momentum of an object measured in two inertial frames in energy–momentum space – the yellow frame measures E and p while the blue frame measures E′ and p′. The green arrow is the four-momentum P of an object with length proportional to its rest mass m₀. The green frame is the centre-of-momentum frame for the object with energy equal to the rest energy. The hyperbolae show the Lorentz transformation from one frame to another is a hyperbolic rotation, and ϕ and ϕ + η are the rapidities of the blue and green frames, respectively.

Special relativity

In Minkowski space, energy (divided by c) and momentum are two components of a Minkowski four-vector, namely the four-momentum;

${\displaystyle \mathbf {P} =\left({\frac {E}{c}},\mathbf {p} \right)\,,}$

(these are the contravariant components).

The Minkowski inner product ⟨ , ⟩ of this vector with itself gives the square of the norm of this vector, it is proportional to the square of the rest mass m of the body:

${\displaystyle \left\langle \mathbf {P} ,\mathbf {P} \right\rangle =|\mathbf {P} |^{2}=\left(m_{0}c\right)^{2}\,,}$

a Lorentz invariant quantity, and therefore independent of the frame of reference. Using the Minkowski metric η with metric signature (− + + +), the inner product is

${\displaystyle \left\langle \mathbf {P} ,\mathbf {P} \right\rangle =|\mathbf {P} |^{2}=-\left(m_{0}c\right)^{2}\,,}$

and

${\displaystyle \left\langle \mathbf {P} ,\mathbf {P} \right\rangle =P^{\alpha }\eta _{\alpha \beta }P^{\beta }={\begin{pmatrix}{\frac {E}{c}}&p_{x}&p_{y}&p_{z}\end{pmatrix}}{\begin{pmatrix}-1&0&0&0\\0&1&0&0\\0&0&1&0\\0&0&0&1\\\end{pmatrix}}{\begin{pmatrix}{\frac {E}{c}}\\p_{x}\\p_{y}\\p_{z}\end{pmatrix}}=-\left({\frac {E}{c}}\right)^{2}+p^{2}\,,}$

so

${\displaystyle -\left(m_{0}c\right)^{2}=-\left({\frac {E}{c}}\right)^{2}+p^{2}.}$

General relativity

In general relativity, the 4-momentum is a four-vector defined in a local coordinate frame, although by definition the inner product is similar to that of special relativity,

${\displaystyle \left\langle \mathbf {P} ,\mathbf {P} \right\rangle =|\mathbf {P} |^{2}=\left(m_{0}c\right)^{2}\,,}$

in which the Minkowski metric η is replaced by the metric tensor field g:

${\displaystyle \left\langle \mathbf {P} ,\mathbf {P} \right\rangle =|\mathbf {P} |^{2}=P^{\alpha }g_{\alpha \beta }P^{\beta }\,,}$

solved from the Einstein field equations. Then:

${\displaystyle P^{\alpha }g_{\alpha \beta }P^{\beta }=\left(m_{0}c\right)^{2}\,.}$

Performing the summations over indices followed by collecting "time-like", "spacetime-like", and "space-like" terms gives:

${\displaystyle \underbrace {g_{00}{\left(P^{0}\right)}^{2}} _{\text{time-like}}+2\underbrace {g_{0i}P^{0}P^{i}} _{\text{spacetime-like}}+\underbrace {g_{ij}P^{i}P^{j}} _{\text{space-like}}=\left(m_{0}c\right)^{2}\,.}$

where the factor of 2 arises because the metric is a symmetric tensor, and the convention of Latin indices i, j taking space-like values 1, 2, 3 is used. As each component of the metric has space and time dependence in general; this is significantly more complicated than the formula quoted at the beginning, see metric tensor (general relativity) for more information.

Units of energy, mass and momentum

In natural units where c = 1, the energy–momentum equation reduces to

${\displaystyle E^{2}=p^{2}+m_{0}^{2}\,.}$

In particle physics, energy is typically given in units of electron volts (eV), momentum in units of eV·c⁻¹, and mass in units of eV·c⁻². In electromagnetism, and because of relativistic invariance, it is useful to have the electric field E and the magnetic field B in the same unit (Gauss), using the cgs (Gaussian) system of units, where energy is given in units of erg, mass in grams (g), and momentum in g·cm·s⁻¹.

Energy may also in theory be expressed in units of grams, though in practice it requires a large amount of energy to be equivalent to masses in this range. For example, the first atomic bomb liberated about 1 gram of heat, and the largest thermonuclear bombs have generated a kilogram or more of heat. Energies of thermonuclear bombs are usually given in tens of kilotons and megatons referring to the energy liberated by exploding that amount of trinitrotoluene (TNT).

Special cases

Centre-of-momentum frame (one particle)

For a body in its rest frame, the momentum is zero, so the equation simplifies to

${\displaystyle E_{0}=m_{0}c^{2}\,,}$

where m₀ is the rest mass of the body.

Massless particles

If the object is massless, as is the case for a photon, then the equation reduces to

${\displaystyle E=pc\,.}$

This is a useful simplification. It can be rewritten in other ways using the de Broglie relations:

${\displaystyle E={\frac {hc}{\lambda }}=\hbar ck\,.}$

if the wavelength λ or wavenumber k are given.

Correspondence principle

Rewriting the relation for massive particles as:

${\displaystyle E=m_{0}c^{2}{\sqrt {1+\left({\frac {p}{m_{0}c}}\right)^{2}}}\,,}$

and expanding into power series by the binomial theorem (or a Taylor series):

${\displaystyle E=m_{0}c^{2}\left[1+{\frac {1}{2}}\left({\frac {p}{m_{0}c}}\right)^{2}-{\frac {1}{8}}\left({\frac {p}{m_{0}c}}\right)^{4}+\cdots \right]\,,}$

in the limit that u ≪ c, we have γ(u) ≈ 1 so the momentum has the classical form p ≈ m₀u, then to first order in (p/m₀c)² (i.e. retain the term (p/m₀c)²ⁿ for n = 1 and neglect all terms for n ≥ 2) we have

${\displaystyle E\approx m_{0}c^{2}\left[1+{\frac {1}{2}}\left({\frac {m_{0}u}{m_{0}c}}\right)^{2}\right]\,,}$

or

${\displaystyle E\approx m_{0}c^{2}+{\frac {1}{2}}m_{0}u^{2}\,,}$

where the second term is the classical kinetic energy, and the first is the rest mass of the particle. This approximation is not valid for massless particles, since the expansion required the division of momentum by mass. Incidentally, there are no massless particles in classical mechanics.

Many-particle systems

Addition of four momenta

In the case of many particles with relativistic momenta p_n and energy E_n, where n = 1, 2, ... (up to the total number of particles) simply labels the particles, as measured in a particular frame, the four-momenta in this frame can be added;

${\displaystyle \sum _{n}\mathbf {P} _{n}=\sum _{n}\left({\frac {E_{n}}{c}},\mathbf {p} _{n}\right)=\left(\sum _{n}{\frac {E_{n}}{c}},\sum _{n}\mathbf {p} _{n}\right)\,,}$

and then take the norm; to obtain the relation for a many particle system:

${\displaystyle \left|\left(\sum _{n}\mathbf {P} _{n}\right)\right|^{2}=\left(\sum _{n}{\frac {E_{n}}{c}}\right)^{2}-\left(\sum _{n}\mathbf {p} _{n}\right)^{2}=\left(M_{0}c\right)^{2}\,,}$

where M₀ is the invariant mass of the whole system, and is not equal to the sum of the rest masses of the particles unless all particles are at rest (see mass in special relativity for more detail). Substituting and rearranging gives the generalization of (1);

${\displaystyle \left(\sum _{n}E_{n}\right)^{2}=\left(\sum _{n}\mathbf {p} _{n}c\right)^{2}+\left(M_{0}c^{2}\right)^{2}}$

( 2 )

The energies and momenta in the equation are all frame-dependent, while M₀ is frame-independent.

Center-of-momentum frame

In the center-of-momentum frame (COM frame), by definition we have:

${\displaystyle \sum _{n}\mathbf {p} _{n}={\boldsymbol {0}}\,,}$

with the implication from (2) that the invariant mass is also the centre of momentum (COM) mass–energy, aside from the c² factor:

${\displaystyle \left(\sum _{n}E_{n}\right)^{2}=\left(M_{0}c^{2}\right)^{2}\Rightarrow \sum _{n}E_{\mathrm {COM} \,n}=E_{\mathrm {COM} }=M_{0}c^{2}\,,}$

and this is true for all frames since M₀ is frame-independent. The energies E_{COM n} are those in the COM frame, not the lab frame.

Rest masses and the invariant mass

Either the energies or momenta of the particles, as measured in some frame, can be eliminated using the energy momentum relation for each particle:

${\displaystyle E_{n}^{2}-\left(\mathbf {p} _{n}c\right)^{2}=\left(m_{n}c^{2}\right)^{2}\,,}$

allowing M₀ to be expressed in terms of the energies and rest masses, or momenta and rest masses. In a particular frame, the squares of sums can be rewritten as sums of squares (and products):

${\displaystyle \left(\sum _{n}E_{n}\right)^{2}=\left(\sum _{n}E_{n}\right)\left(\sum _{k}E_{k}\right)=\sum _{n,k}E_{n}E_{k}=2\sum _{n$

${\displaystyle \left(\sum _{n}\mathbf {p} _{n}\right)^{2}=\left(\sum _{n}\mathbf {p} _{n}\right)\cdot \left(\sum _{k}\mathbf {p} _{k}\right)=\sum _{n,k}\mathbf {p} _{n}\cdot \mathbf {p} _{k}=2\sum _{n$

so substituting the sums, we can introduce their rest masses m_n in (2):

${\displaystyle \sum _{n}\left(m_{n}c^{2}\right)^{2}+2\sum _{n$

The energies can be eliminated by:

${\displaystyle E_{n}={\sqrt {\left(\mathbf {p} _{n}c\right)^{2}+\left(m_{n}c^{2}\right)^{2}}}\,,\quad E_{k}={\sqrt {\left(\mathbf {p} _{k}c\right)^{2}+\left(m_{k}c^{2}\right)^{2}}}\,,}$

similarly the momenta can be eliminated by:

${\displaystyle \mathbf {p} _{n}\cdot \mathbf {p} _{k}=\left|\mathbf {p} _{n}\right|\left|\mathbf {p} _{k}\right|\cos \theta _{nk}\,,\quad |\mathbf {p} _{n}|={\frac {1}{c}}{\sqrt {E_{n}^{2}-\left(m_{n}c^{2}\right)^{2}}}\,,\quad |\mathbf {p} _{k}|={\frac {1}{c}}{\sqrt {E_{k}^{2}-\left(m_{k}c^{2}\right)^{2}}}\,,}$

where θ_nk is the angle between the momentum vectors p_n and p_k.

Rearranging:

${\displaystyle \left(M_{0}c^{2}\right)^{2}-\sum _{n}\left(m_{n}c^{2}\right)^{2}=2\sum _{n$

Since the invariant mass of the system and the rest masses of each particle are frame-independent, the right hand side is also an invariant (even though the energies and momenta are all measured in a particular frame).

Matter waves

Using the de Broglie relations for energy and momentum for matter waves,

${\displaystyle E=\hbar \omega \,,\quad \mathbf {p} =\hbar \mathbf {k} \,,}$

where ω is the angular frequency and k is the wavevector with magnitude |k| = k, equal to the wave number, the energy–momentum relation can be expressed in terms of wave quantities:

${\displaystyle \left(\hbar \omega \right)^{2}=\left(c\hbar k\right)^{2}+\left(m_{0}c^{2}\right)^{2}\,,}$

and tidying up by dividing by (ħc)² throughout:

${\displaystyle \left({\frac {\omega }{c}}\right)^{2}=k^{2}+\left({\frac {m_{0}c}{\hbar }}\right)^{2}\,.}$

(3)

This can also be derived from the magnitude of the four-wavevector

${\displaystyle \mathbf {K} =\left({\frac {\omega }{c}},\mathbf {k} \right)\,,}$

in a similar way to the four-momentum above.

Since the reduced Planck constant ħ and the speed of light c both appear and clutter this equation, this is where natural units are especially helpful. Normalizing them so that ħ = c = 1, we have:

${\displaystyle \omega ^{2}=k^{2}+m_{0}^{2}\,.}$

Tachyon and exotic matter

The velocity of a bradyon with the relativistic energy–momentum relation

${\displaystyle E^{2}=p^{2}c^{2}+m_{0}^{2}c^{4}\,.}$

can never exceed c. On the contrary, it is always greater than c for a tachyon whose energy–momentum equation is

${\displaystyle E^{2}=p^{2}c^{2}-m_{0}^{2}c^{4}\,.}$

By contrast, the hypothetical exotic matter has a negative mass and the energy–momentum equation is

${\displaystyle E^{2}=-p^{2}c^{2}+m_{0}^{2}c^{4}\,.}$