Alex Krasnitz, Raju Venugopalan
Published 1999-09-01, updated 1999-10-01Version 3
In very high energy nuclear collisions, the initial energy of produced gluons per unit area per unit rapidity, $dE/L^2/d\eta$, is equal to $f(g^2\mu L) (g^2\mu)^3/g^2$, where $\mu^2$ is proportional to the gluon density per unit area of the colliding nuclei. For an SU(2) gauge theory, we perform a non--perturbative numerical computation of the function $f(g^2\mu L)$. It decreases rapidly for small $g^2\mu L$ but varies only by $\sim 25$%, from $0.208\pm 0.004$ to $0.257\pm 0.005$, for a wide range 35.36--296.98 in $g^2\mu L$, including the range relevant for collisions at RHIC and LHC. Extrapolating to SU(3), we estimate the initial energy per unit rapidity for Au-Au collisions in the central region at RHIC and LHC.
Comments: 11 pages, Latex, 3 figures; revised version-includes additional numerical data; reference added
Journal: Phys.Rev.Lett. 84 (2000) 4309-4312
Parton saturation, production, and equilibration in high energy nuclear collisions
Quantifying Baryon Stopping in High Energy Nuclear Collisions
Pionic Measures of Parity and CP Violation in High Energy Nuclear Collisions
