deletions | additions       diff --git a/subsection_Scalable_Quantum_Optical_Squeezing__.tex b/subsection_Scalable_Quantum_Optical_Squeezing__.tex  index 7c5b174..23719cb 100644  --- a/subsection_Scalable_Quantum_Optical_Squeezing__.tex  +++ b/subsection_Scalable_Quantum_Optical_Squeezing__.tex 
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Detection is possible by indirect observation. By firing atoms into the regions of negative energy densities, the decay rates of the atoms are expected to change (Ford et al., 2009). This particular method of observation was developed by Ford & Roman while researching negative energy observations in squeezed states and probability distributions for negative energy densities (Fewster et al., 2010).  Although the most up-to-date experimentation still upholds the quantum inequalities and their limits on negative energy (Ford et al., 2013), we push to discover scalable methods of negative energy production for the purpose of discovering new theory. Because gravity is the only direct method of observing negative energy and not enough of it can be produced in current laboratory experiments (Ford et al., 2009), it's possible that scalable production of negative energy will assist development of new quantum gravity  theory by allowingsuch  direct observable methods. observation.  \textbf{\textit{need to add calculations/graphs/supporting evidence}}