Olga Dmitriyeva and Garret Moddel
Abstract
A
recently issued patent [1] describes a method by which vacuum energy is
extracted from gas flowing through a Casimir cavity. According to
stochastic electrodynamics, the electronic orbitals in atoms are
supported by the ambient zero-point (ZP) field. When the gas atoms are
pumped into a Casimir cavity, where long-wavelength ZP field modes are
excluded, the electrons spin down into lower energy orbitals and release
energy in the process. This energy is collected in a local absorber.
When the electrons exit the Casimir cavity they are re-energized to
their original orbitals by the ambient ZP fields. The process is
repeated to produce continuous power. In this way, the device functions
like a heat pump for ZP energy, extracting it globally from the
electromagnetic quantum vacuum and collecting it in a local absorber.
This energy can be used for heating, or converted to electric power.
We
carried out a series of experiments to test whether energy is, in fact,
radiated from Casimir cavities when the appropriate gas flows through
them. The Casimir cavity devices we tested were nanopore polycarbonate
membranes with submicron pores having a density of 3x10^8 pores/cm^2.
Gas was pumped through the membranes in a stainless steel vacuum
system, and emitted energy was measured using a broadband pyroelectric
detector and lock-in amplifier. Emission in the infrared was clearly
observed. We analyzed the emission from different gases and cavities to
determine its origin. None of the conventional thermodynamic models we
applied to our data fully explain it, leaving open the possibility that
it is due to Casimir-cavity-induced emission from ZP fields.
Link to pdf: Test of Zero-point Energy Emission from Gases Flowing Through Casimir Cavities