AIAA_EXPL_02_2022-006587.pdf

Room Temperature Superconducting System (RTSC) 
for use on a Hybrid Aerospace-Undersea Craft (HAUC)  
(EXPL-02, 3003343); (EXPL-02, AIAA-2019-0869)
Dr. Salvatore Cezar Pais, Ph.D.
Department of the Navy / NAVAIR / NAWCAD 
2019 AIAA SciTech Forum and Exposition, January 7 - 11
San Diego, CA

RTSC for use on a HAUC
- Quantum Fields Fluctuations
• Everything that surrounds us, ourselves included, can be 
described as macroscopic collections of fluctuations, 
vibrations, oscillations in quantum mechanical fields.
• Under certain conditions, such as the coupling of high frequency 
axial spin with high frequency vibrations of electrically charged 
systems, the rules and special effects of quantum field behavior 
also apply to macroscopic physical entities.
• Consider that we are immersed in an ocean of energy, the 
vacuum energy state (VES), yet ordinarily we seem not to 
interact with…

RTSC for use on a HAUC
- VACUUM ENERGY STATE (VES)
• Aggregate/collective state (structure) comprised of the 
superposition of all quantum fields’ fluctuations 
permeating the spacetime continuum.
• Matter, energy and spacetime are emergent constructs 
which arise out of a fundamental framework, the 
foundational structure that is the VES.
• Artificially generated, high energy, electromagnetic (EM) 
fields interact strongly with the VES – inducing strong 
interactions between the VES fields, based on the mechanism of transfer 
of vibrational energy between the fields, further inducing local fl…

RTSC for use on a HAUC
- Solving the “Vacuum Catastrophe”
•
QFT and GR give 120 orders of magnitude discrepancy in Cosmological 
Constant value  - conundrum may source from ‘Planck Length’ (10^-35 m)
•
h* ω ~ k T  (with T ~ 2.7 deg. K for ‘outer-space’)
•
Equivalence of ‘Planck’ Vibrational Energy with ‘Boltzmann’ Thermal energy 
results in ‘space-cell’ configuration, with attributes:
•
Vib. Freq. ~ 10^12 (1/sec); Char. Length ~ 10^(-4) m; Vol. (space-cell) ~ 10^(-12) m^3
•
Vol. (observable Universe) ~ 10^81 m^3 ; Energy (obs. Univ.) ~ 10^71 Joules (based 
on Vib. Freq. of space-cell); Number …

RTSC for use on a HAUC
- Vacuum Energy Polarization
• Investigation of the quantum vacuum as a source of 
propulsion estimated the very short scales of time and distance 
(and hence the high energies) over which the quantum vacuum 
must be interacted with for extracting enough propulsive energy 
for relativistic interstellar flight. 
• it was suggested that a system’s inertia may be a 
consequence of quantum vacuum electromagnetic behavior, 
therefore by polarizing the vacuum in the proximity of the system, 
inertial mass reduction may be achieved.
• Polarization of the local vacuum energy sta…

RTSC for use on a HAUC
- High Energy EM Fields 
• For accelerated spin / accelerated vibration of charged matter, we can
write for the maximum EM energy flux (time rate of change of EM energy
transfer per unit surface area):
Smax = fG (σ2 / ε0) [ (Rvν2) top]
•
If we consider adding to the equation representing simple harmonic
motion an “energy/momentum-pumping” (negative damping) term
(bv), endemic of system acceleration, where b is a constant and v is
(dx/dt), namely the speed of a vibrating mass (m), under the condition
[Ω= (b/2m) >> Ω0 (natural frequency of vibration)]:
Smax ≈(Q2 / ε0) ( Rv…

RTSC for use on a HAUC
- Inertial Mass Modification
•
The resultant high energy EM flux, on the order of 1033 Watts/m2, 
and possibly much higher, when concentrated in a small area around 
the contour of the object (craft) can generate energy densities of 1025
Joules/m3, commensurate with Schwinger electric field values for 
vacuum polarization. This physical condition is representative of the 
QED vacuum breakdown and is indicative of possible inertia control 
by altering the local vacuum energy density.
•
If we consider cosmic space as a superfluid medium, we may be able to say 
that the IMR…

RTSC for use on a HAUC
- Macroscopic Quantum Coherence
•
Quantum field theory teaches that everything can be described in 
quantum mechanical terms. The complex interactions between a physical 
system and its surroundings (environment), disrupt the quantum mechanical 
nature of a system and render it classical under ordinary observation. This 
process is known as decoherence.
•
We can retard (delay) decoherence (and possibly even suppress it – namely 
decouple a physical system from the environment) by accelerated spin 
and/or accelerated vibration of electrically charged matter under rapid 
a…