Einstein's theory of General Relativity amounts to a description of the relationship between the curvature of space-time, on the one hand, and the distribution of matter throughout space-time on the other. This precise details of this relationship are determined by the Einstein equations

${\displaystyle G_{\mu \nu }=\kappa T_{\mu \nu }}$ .

Here, the Einstein tensor ${\displaystyle G_{\mu \nu }}$  describes the curvature of space-time, whilst the energy–momentum tensor ${\displaystyle T_{\mu \nu }}$  describes the local distribution of matter. (${\displaystyle \kappa }$  is a constant.) The Einstein equations express local relationships between the quantities involved—specifically, this is a system of coupled non-linear second order partial differential equations.

A very simple observation can be made at this point: the zero-point of energy-momentum is not arbitrary. Adding a "constant" to the right-hand side of the Einstein equations will effect a change in the Einstein tensor, and thus also in the curvature properties of space-time.

All known classical matter fields obey certain "energy conditions". The most famous classical energy condition is the "weak energy condition"; this asserts that the local energy density, as measured by an observer moving along a time-like world line, is non-negative. The weak energy condition is essential for many of the most important and powerful results of classical relativity theory—in particular, the singularity theorems of Hawking et al.

The situation in quantum field theory is rather different: the expectation value of the energy density can be negative at any given point. In fact, things are even worse: by tuning the state of the quantum matter field, the expectation value of the local energy density can be made arbitrarily negative.

For free, massless, minimally coupled scalar fields, for all ${\displaystyle \tau _{0}>0}$  the following inequality holds along any inertial observer worldline with velocity ${\displaystyle u^{i}}$  and proper time ${\displaystyle \tau }$ :^[2]

${\displaystyle {\frac {\tau _{0}}{\pi }}\int _{-\infty }^{\infty }{\frac {\langle T_{ij}u^{i}u^{j}\rangle d\tau }{\tau ^{2}+\tau _{0}^{2}}}\geq -{\frac {3}{32\pi ^{2}\tau _{0}^{4}}}.}$ 

This implies the averaged weak energy condition as ${\displaystyle \tau _{0}\rightarrow \infty }$ , but also places stricter bounds on the length of episodes of negative energy.

Similar bounds can be constructed for massive scalar or electromagnetic fields.^[3] Related theorems imply that pulses of negative energy need to be compensated by a larger positive pulse (with magnitude growing with increasing pulse separation).^[4]

Note that the inequality above only applies to inertial observers: for accelerated observers weaker or no bounds entail.^[5][6]

Distributions of negative energy density comprise what is often referred to as exotic matter, and allow for several intriguing possibilities: for example, the Alcubierre drive potentially allows for faster-than-light space travel.

Quantum inequalities constrain the magnitude and space-time extent of negative energy densities. In the case of the Alcubierre warp drive mentioned above, the quantum inequalities predict that the amount of exotic matter required to create and sustain the warp drive "bubble" far exceeds the total mass-energy of the universe.

The earliest investigations into quantum inequalities were carried out by Larry Ford and Tom Roman; an early collaborator was Mitch Pfenning, one of Ford's students at Tufts University. Important work was also carried out by Eanna Flanagan.^{[citation needed]} More recently, Chris Fewster (of the University of York, in the UK) has applied rigorous mathematics to produce a variety of quite general quantum inequalities. Collaborators have included Ford, Roman, Pfenning, Stefan Hollands and Rainer Verch.^{[citation needed]}

Websites edit

Quantum field theory on curved spacetime at the Erwin Schrödinger Institute

Quantum Energy Inequalities (University of York, UK)