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Justin Long edited subsection_Centripital_Quantum_Optical_Squeezing__.tex
over 8 years ago
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\subsection{Centripital Quantum Optical Squeezing Technique Using Attractive Photons}
Scalable production of negative energy is a larger problem than producing small specific amounts in laboratory experiments. Squeezed coherent states have been indirectly observed and the dynamical Casimir effect has been directly observed (Wilson, 2011). Therefore, we propose
an a highly experimental technique for generating negative energy based on attractive photon observations (Firstenberg et al., 2013), a quantum optical squeezing technique (Davis, 2006), and a method for direct observation of negative energy (Ford, 2009).
[squeeze trapped The experimental technique involves trapping photons by firing a laser into a super-cooled rubidium gas and accumulating a large number of photons. As observed by the Firstenberg et al. experiment, the photons will display attractive
behavior and form molecule-like structures. By \textbf{\textit{exciting the photons
together [need to
research how we can excite them]}}, we expect the photons to immediately squeeze their coherent states due to their close proximity and suppress vacuum fluctuations. This process will generate
gravitational waves - potentially a large area of negative energy
- and explore a potential path density.
\textbf{\textit{need to
tactile warping of spacetime] add calculations/graphs/supporting evidence}}