User:Maschen/Relativistic angular momentum

Main article: angular momentum

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In physics, relativistic angular momentum refers to the mathematical formalisms and physical concepts that define angular momentum in special relativity (SR) and general relativity (GR). The relativistic quantity is subtly different from the three dimensional quantity in classical mechanics. Angular momentum is a dynamical quantity derived position and momentum, and is important; in the same way momentum conservation corresponds to translational symmetry, angular momentum conservation corresponds to rotational symmetry - the connection between symmetries and conservation laws is made by Noether's theorem. More abstractly, invariance of angular momentum, four momentum, and other symmetries, in spacetime, are described by the Poincaré group and Lorentz group.

Physical quantities which remain separate in classical physics are naturally combined in SR and GR by enforcing the postulates of relativity, an appealing characteristic. Most notably; space and time coordinates combine into the four position, and energy and momentum combine into the four momentum. These four vectors depend on the frame of reference used, and change under Lorentz transformations to other inertial frames or accelerated frames.

Relativistic angular momentum is less obvious. The classical definition of angular momentum is the cross product of position x with momentum p to obtain a pseudovector x×p, or alternatively as the exterior product to obtain a 3d bivector x∧p. What does this combine with, if anything? There is another vector quantity not often discussed - it is the time-varying moment of mass (not the moment of inertia) related to the boost of the centre of mass of the system, and this combines with the classical angular momentum to form an antisymmetric tensor of second order.

In general relativity, angular momentum becomes complicated, since even for an isolated system, the total angular momentum is not conserved in curved spacetime.

In relativistic quantum mechanics it is important to make it clear that the angular momentum tensor is for orbital motion, since in quantum theory elementary particles have spin and this is an additional contribution to the total angular momentum tensor operator of relativistic quantum mechanics.^[1]

Special relativity

The 3-angular momentum as a bivector (plane element) and axial vector, of a particle of mass m with instantaneous 3-position x and 3-momentum p.

Orbital 3d angular momentum

Cross product definition

In classical mechanics, the orbital angular momentum of a particle with instantaneous three dimensional position vector x and momentum vector p, is defined as the axial vector

${\displaystyle \mathbf {L} =\mathbf {r} \times \mathbf {p} }$

which has three components:

${\displaystyle L_{3}=x_{1}p_{2}-x_{2}p_{1}}$

${\displaystyle L_{1}=x_{2}p_{3}-x_{3}p_{2}}$

${\displaystyle L_{2}=x_{3}p_{1}-x_{1}p_{3}\,.}$

This quantity is additive, and for an isolated system, the total angular momentum of a system is conserved. However, this definition can be used in three dimensions only - considering that the cross product in the definition defines an axial vector perpendicular to the plane spanned by x and p. In four dimensions, there is not one axis uniquely perpendicular to a two-dimensional plane, but two such axes, allowed by the additional dimension.

Exterior product definition

An alternative definition, which avoids any axes about which objects rotate, is to conceive orbital angular momentum as a plane element. This can be achieved in the language of exterior algebra or geometric algebra^[2] as a contravariant second order antisymmetric tensor:^[3]

${\displaystyle \mathbf {L} =2\mathbf {x} \wedge \mathbf {p} }$

with components

${\displaystyle L^{ij}=x^{i}p^{j}-x^{j}p^{i}=2x^{[i}p^{j]}}$

where the indices i and j take the values 1, 2, 3. The components can be systematically collected into a 3 × 3 antisymmetric matrix:

${\displaystyle \mathbf {L} ={\begin{pmatrix}L^{11}&L^{12}&L^{13}\\L^{21}&L^{22}&L^{23}\\L^{31}&L^{32}&L^{33}\\\end{pmatrix}}={\begin{pmatrix}0&L_{xy}&L_{xz}\\L_{yx}&0&L_{yz}\\L_{zx}&L_{zy}&0\end{pmatrix}}={\begin{pmatrix}0&L_{xy}&-L_{zx}\\-L_{xy}&0&L_{yz}\\L_{zx}&-L_{yz}&0\end{pmatrix}}}$

This is generalized below.

Dynamic mass moment

Additionally in classical mechanics, the three dimensional quantity for a particle of mass m moving with velocity u:^[4][5][3]

${\displaystyle \mathbf {N} =m\left(\mathbf {x} -t\mathbf {u} \right)=m\mathbf {x} -t\mathbf {p} }$

has the dimensions of mass moment - length multiplied by mass. It is related to the boost (relative velocity) of the centre of mass (COM) of the particle or system of particles, as measured in the lab frame. There is no universal symbol, nor even a universal name, for this quantity - different authors denote it by various other symbols (including e.g. μ), may designate other names, and may define N to be the negative of what is used here - the above form has the advantage that it resembles the familiar Galilean transformation for position, which in turn is the classical boost transformation between classical inertial frames. This vector is also additive: for a system of particles, the vector sum is the resultant:

${\displaystyle \sum _{n}\mathbf {N} _{n}=\sum _{n}m_{n}\left(\mathbf {x} _{n}-t\mathbf {u} _{n}\right)=\left(\mathbf {x} _{\mathrm {com} }\sum _{n}m_{n}-t\sum _{n}m_{n}\mathbf {u} _{n}\right)}$

where the system's centre of mass is:

${\displaystyle \mathbf {x} _{\mathrm {com} }={\frac {\sum _{n}m_{n}\mathbf {x} _{n}}{\sum _{n}m_{n}}}}$

For an isolated system, N is conserved in time, apparent by differentiating with respect to time. Unlike L, N is a (polar) vector, not a pseudovector, and is therefore invariant under rotations.

The resultant N_total for a multiparticle system has the physical visualization that, whatever the complicated motion of all the particles are, they move in such a way that the system's COM moves in a straight line. This doesn't necessarily mean all particles "follow" the COM, nor that all particles all move in almost the same direction simultaneously, just that the motion of each particle is coupled with respect to the COM.

In special relativity, if the particle moves with velocity u relative to the lab frame, then

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

where γ is the Lorentz factor and m₀ the rest mass of the particle. Some authors use relativistic mass:

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

The corresponding relativistic mass moment in terms of m₀, m, u, p, E, in the same lab frame is:

${\displaystyle \gamma (\mathbf {u} )\mathbf {N} =m\mathbf {x} -\mathbf {p} t={\frac {E}{c^{2}}}\mathbf {x} -\mathbf {p} t=\gamma (\mathbf {u} )m_{0}(\mathbf {x} -\mathbf {u} t)}$

defined here so that the relativistic equation in terms of the rest mass, and classical definition, have the same form.

The relativistic mass simplifies the expressions in this context as it removes extra Lorentz factors. However rest mass is discouraged by some authors since it can be a misleading quantity to apply in certain equations. In the following, N is given in terms of the rest and relativistic masses.

4d Angular momentum as a bivector

In relativistic mechanics, the COM boost and orbital 3-angular momentum of a rotating object are combined into a four dimensional bivector in terms of the 4-position X and the 4-momentum P of the object:^[6][7][8]

${\displaystyle \mathbf {M} =2\mathbf {X} \wedge \mathbf {P} }$

In components:

${\displaystyle M^{\alpha \beta }=X^{\alpha }P^{\beta }-X^{\beta }P^{\alpha }=2X^{[\alpha }P^{\beta ]}}$

which are six independent quantities altogether. Three components:

${\displaystyle M^{ij}=x^{i}p^{j}-x^{j}p^{i}=L^{ij}}$

are the components of the familiar classical 3-orbital angular momentum, and the other three:

${\displaystyle M^{0i}=x^{0}p^{i}-x^{i}p^{0}=c\,\left(tp^{i}-x^{i}{\frac {E}{c^{2}}}\right)=c\,\left(tp^{i}-mx^{i}\right)=\gamma (u)m_{0}c\,\left(tu^{i}-x^{i}\right)=-\gamma (u)cN^{i}}$

correspond to the relativistic mass moment given above, multiplied by c. The quantities L^ij and N⁰ⁱ are all frame-dependent as they are derived from the frame-dependent quantities t, x, E, and p. Consequently, the mass moment is also frame-dependent.

The components of the tensor can be systematically displayed as a matrix:

${\displaystyle \mathbf {M} ={\begin{pmatrix}M^{00}&M^{01}&M^{02}&M^{03}\\M^{10}&M^{11}&M^{12}&M^{13}\\M^{20}&M^{21}&M^{22}&M^{23}\\M^{30}&M^{31}&M^{32}&M^{33}\end{pmatrix}}=\left({\begin{array}{c|ccc}0&-\gamma (u)N^{1}c&-\gamma (u)N^{2}c&-\gamma (u)N^{3}c\\\hline \gamma (u)N^{1}c&0&L^{12}&-L^{31}\\\gamma (u)N^{2}c&-L^{12}&0&L^{23}\\\gamma (u)N^{3}c&L^{31}&-L^{23}&0\end{array}}\right)=\left({\begin{array}{c|c}0&-\gamma (\mathbf {u} )\mathbf {N} c\\\hline \gamma (\mathbf {u} )\mathbf {N} ^{\mathrm {T} }c&2\mathbf {x} \wedge \mathbf {p} \\\end{array}}\right)}$

in which the last array is a block matrix formed by treating N as a row vector which matrix transposes to the column vector N^T, and 2x∧p as a 3 × 3 antisymmetric matrix.

The components of the angular momentum pseudovector enter the angular momentum tensor in the same way as if it were a 3d bivector.

Again, this tensor is additive: the total angular momentum of a system is the sum of the angular momentum tensors for each constituent of the system:

${\displaystyle \mathbf {M} _{\mathrm {total} }=\sum _{n}\mathbf {M} _{n}=2\sum _{n}\mathbf {X} _{n}\wedge \mathbf {P} _{n}\,.}$

Each of the six components forms a conserved quantity when aggregated with the corresponding components for other objects and fields.

Lorentz transformation

The angular momentum tensor M is indeed a tensor which changes according to a Lorentz transformation matrix Λ, as illustrated in the usual way by tensor index notation:

${\displaystyle {\begin{aligned}{\bar {M}}^{\alpha \beta }&={\bar {X}}^{\alpha }{\bar {P}}^{\beta }-{\bar {X}}^{\beta }{\bar {P}}^{\alpha }\\&=\Lambda ^{\alpha }{}_{\gamma }X^{\gamma }\Lambda ^{\beta }{}_{\delta }P^{\delta }-\Lambda ^{\beta }{}_{\delta }X^{\delta }\Lambda ^{\alpha }{}_{\gamma }P^{\gamma }\\&=\Lambda ^{\alpha }{}_{\gamma }\Lambda ^{\beta }{}_{\delta }\left(X^{\gamma }P^{\delta }-X^{\delta }P^{\gamma }\right)\\&=\Lambda ^{\alpha }{}_{\gamma }\Lambda ^{\beta }{}_{\delta }M^{\gamma \delta }\\\end{aligned}}}$

In fact, one can Lorentz-transform the four position and four momentum separately, and then antisymmetrize those newly-found components to obtain the angular momentum tensor in the new frame.

Angular momentum in general relativity

Angular momentum is more complicated in GR, and the stress-energy tensor and killing vectors from general relativity become involved with calculating the angular momentum tensor. See the references.

See also

• Thomas precession
• Ehrenfest paradox
• Angular momentum of light
• Two-body problem in general relativity
• Kepler problem in general relativity

References

Notes

1. D.S.A. Freed, K.K.A. Uhlenbeck. Geometry and quantum field theory (2nd ed.). Institute For Advanced Study (Princeton, N.J.): American Mathematical Society. ISBN 0-821-886-835.
2. D. Hestenes (1999). New Foundations for Classical Mechanics. Fundamental Theories of Physics. Vol. 99 (2nd ed.). Springer. ISBN 0792355148.
3. R. Penrose (2005). The Road to Reality. Vintage books. p. 433. ISBN 978-00994-40680.
4. M. Fayngold (2008). Special Relativity and How it Works. John Wiley & Sons. p. 138. ISBN 3527406077.
5. N. Menicucci (2001). "Relativistic Angular Momentum" (PDF).
6. R. Penrose (2005). The Road to Reality. Vintage books. pp. 437–438, 566–569. ISBN 978-00994-40680. Note: Some authors, including Penrose, use Latin letters in this definition, even though it is conventional to use Greek indices for vectors and tensors in spacetime.
7. C. Schiller. Motion Mountain. Vol. 2.
8. M. Fayngold (2008). Special Relativity and How it Works. John Wiley & Sons. p. 137-139. ISBN 3527406077.

• C. Chryssomalakos, H. Hernandez-Coronado, E. Okon (2009). "Center of mass in special and general relativity and its role in an effective description of spacetime" (PDF). J. Phys. Conf. Ser. Mexico. arXiv:0901.3349. doi:10.1088/1742-6596/174/1/012026. {{cite news}}: line feed character in |title= at position 57 (help)

• U.E. Schroder (1990). Special relativity. Lecture Notes in Physics Series. Vol. 33. World Scientific. p. 139. ISBN 981-020-132-X.

Further reading

Special relativity

• R. Torretti (1996). Relativity and Geometry. Dover Books on Physics Series. Courier Dover Publications. ISBN 0-486-690-466.

General relativity

• L. Blanchet, A. Spallicci, B. Whiting (2011). Mass and motion in general relativity. Fundamental theories of physics. Vol. 162. Springer. p. 87. ISBN 904-813-015-8.

• M. Ludvigsen (1999). General Relativity: A Geometric Approach. Cambridge University Press. p. 77. ISBN 0-5216-3976-X.

• N. Ashby, D.F. Bartlett, W.Wyss (1990). General Relativity and Gravitation 1989: Proceedings of the 12th International Conference on General Relativity and Gravitation. Cambridge University Press. ISBN 0-521-384-281.

• B.L. Hu, M.P. Ryan, M.P. Ryan, C.V. Vishveshwara (2005). Directions in General Relativity: Volume 1: Proceedings of the 1993. Directions in General Relativity: Proceedings of the 1993 International Symposium, Maryland: Papers in Honor of Charles Misner. Vol. 1. Cambridge University Press. p. 347. ISBN 0-521-021-391.

• A. Papapetrou (1974). Lectures on General Relativity. Springer. ISBN 9-027-705-143.

External links

category:special relativity category:general relativity category:dynamics