Draft:C-energy

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Instructions · What links here · C-energy (talk: + · bio) · (log) · Copyvios report · reFill · Citation Bot · (Search: Google, Wikipedia) · Submitted 2 days ago by ~2025-40843-27 (talk: D · +) · Last edited 14 hours ago by ~2025-40843-27

Comment: more independent sources required. Theroadislong (talk) 17:41, 18 December 2025 (UTC)

In general relativity, C-energy (short for cylindrical energy) is a quasi-local definition of gravitational energy applicable to space-times with cylindrical symmetry. The concept was introduced by Kip Thorne in 1965 as an attempt to characterize the energy content of infinitely long, cylindrically symmetric systems.^[1]

C-energy has been widely used in the analysis of cylindrical gravitational waves, where it provides a useful measure of the gravitational field strength. In standing cylindrical wave solutions, the C-energy may be strictly constant in time (as in Chandrasekhar waves) or constant only on average (as in Einstein–Rosen waves).^[2]^[3] Although C-energy does not correspond to a globally conserved energy in general relativity, it remains a useful diagnostic tool for studying cylindrically symmetric space-times and gravitational radiation.^[4]

Definition

A space-time with cylindrical symmetry about an axis admits two commuting spacelike Killing vector fields, namely

$\partial _{\phi }$ , whose orbits are closed and represent axial symmetry, and
$\partial _{z}$ , whose orbits are open and represent translational symmetry along the axis.

The C-energy is defined geometrically in terms of these Killing vectors by^[5]^[6]

C=-{\frac {1}{2}}\ln \left({\frac {g^{ij}A_{,i}A_{,j}}{|\partial _{z}|^{2}}}\right),

where $g_{ij}$ is the metric tensor and $A=[|\partial _{\phi }|^{2}|\partial _{z}|^{2}-(\partial _{\phi }\cdot \partial _{z})^{2}]^{\frac {1}{2}}$ is the area (per unit axial length) of the two-dimensional surface spanned by the Killing vectors $\partial _{\phi }$ and $\partial _{z}$ .

When the space-time metric is written in the form

ds^{2}=e^{2\nu }[(dt)^{2}-(d\rho )^{2}]-e^{-2\mu }(\rho d\varphi )^{2}-e^{2\mu }(dz-qd\varphi )^{2}

with $\nu =\nu (t,\rho )$ , $\mu =\mu (t,\rho )$ and $q=q(t,\rho )$ , the C-energy reduces to the simple form^[5]

C=\nu +\mu .

In Chandrasekhar waves, for which $q\neq 0$ , the C-energy is constant in time, whereas in Einstein–Rosen waves, where $q=0$ , the C-energy varies periodically with time.

References

^ Thorne, K. S. (1965). Energy of infinitely long, cylindrically symmetric systems in general relativity. Physical Review, 138(1B), B251.
^ Bini, D., Geralico, A., & Plastino, W. (2019). Cylindrical gravitational waves: C-energy, super-energy and associated dynamical effects. Classical and Quantum Gravity, 36(9), 095012.
^ Nikiel, K., & Szybka, S. J. (2025). Halilsoy and Chandrasekhar standing gravitational waves in the linear approximation. Physical Review D, 111(10), 104015.
^ Bondi, H. (1990). The mass of cylindrical systems in general relativity. Proceedings of the Royal Society of London A, 427(1873), 259–264.
^ ^a ^b Chandrasekhar, S. (1986). Cylindrical waves in general relativity. Proceedings of the Royal Society of London A, 408(1835), 209–232.
^ Chandrasekhar, S., & Ferrari, V. (1987). On the dispersion of cylindrical impulsive gravitational waves. Proceedings of the Royal Society of London A, 412(1842), 75–91.

[1] Thorne, K. S. (1965). Energy of infinitely long, cylindrically symmetric systems in general relativity. Physical Review, 138(1B), B251.

[2] Bini, D., Geralico, A., & Plastino, W. (2019). Cylindrical gravitational waves: C-energy, super-energy and associated dynamical effects. Classical and Quantum Gravity, 36(9), 095012.

[3] Nikiel, K., & Szybka, S. J. (2025). Halilsoy and Chandrasekhar standing gravitational waves in the linear approximation. Physical Review D, 111(10), 104015.

[4] Bondi, H. (1990). The mass of cylindrical systems in general relativity. Proceedings of the Royal Society of London A, 427(1873), 259–264.

[chandra-5] Chandrasekhar, S. (1986). Cylindrical waves in general relativity. Proceedings of the Royal Society of London A, 408(1835), 209–232.

[6] Chandrasekhar, S., & Ferrari, V. (1987). On the dispersion of cylindrical impulsive gravitational waves. Proceedings of the Royal Society of London A, 412(1842), 75–91.

[1]