Global fixed-point proof of time-dependent density-functional theory

Abstract

We reformulate the uniqueness and existence proofs of time-dependent density-functional theory. The central idea is to restate the fundamental one-to-one correspondence between densities and potentials as a global fixed-point question for potentials on a given time interval. We show that the unique fixed point, i.e. the unique potential generating a given density, is reached as the limiting point of an iterative procedure. The one-to-one correspondence between densities and potentials is a straightforward result provided that the response function of the divergence of the internal forces is bounded. The existence, i.e. the v-representability of a density, can be proven as well provided that the operator norms of the response functions of the members of the iterative sequence of potentials have an upper bound. The densities under consideration have second time-derivatives that are required to satisfy a condition slightly weaker than being square-integrable. This approach avoids the usual restrictions of Taylor-expandability in time of the uniqueness theorem by Runge and Gross (Phys. Rev. Lett., 52 (1984) 997) and of the existence theorem by van Leeuwen (Phys. Rev. Lett., 82 (1999) 3863). Owing to its generality, the proof not only answers basic questions in density-functional theory but also has potential implications in other fields of physics. Copyright © 2011 EPLA.