Complete Quantum Stress Tensor Inside a Four Dimensional Schwarzschild Black Hole: A Divergent Focusing Source
Abstract
We compute the complete renormalized stress-energy tensor (RSET) of a massless minimally coupled scalar field throughout the interior of a four-dimensional Schwarzschild black hole, in both the Unruh and Hartle--Hawking states. The complete RSET inside four-dimensional black holes has long been unavailable, leaving the local source term required for semiclassical backreaction unknown. This gap is even sharper near spacelike singularities. Taking the Schwarzschild interior as a concrete example, we close both gaps for the first time. Using an angular-splitting renormalization scheme together with a high-order large- asymptotic subtraction, we determine all independent components of Tab ren from the event horizon down to r/M10-4, and simultaneously obtain the corresponding vacuum polarization Φ2 ren. The tensor passes the cross-checks of the covariant conservation and the trace identity. Near the spacelike singularity, the Unruh and Hartle--Hawking states approach the same conserved scaling solution, M4 Tab ren (rM)-6τab, while the state-dependent Unruh flux is suppressed by (r/M)4 relative to the diagonal mixed components. The leading ultraviolet source is therefore a local vacuum-polarization stress rather than transported Hawking flux. The limiting tensor violates the dominant energy condition but satisfy the null energy condition. Thus, at the level of the complete fixed-background Schwarzschild RSET, the leading semiclassical source does not support the intuition that quantum defocusing smooths the singularity; instead, it supplies a divergent focusing source in the local Raychaudhuri equation. A genuine global conclusion, however, requires solving the backreacted semiclassical geometry.
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