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Gary Stephenson - UAPs, AATIP & Gravitomagnetic Propulsion
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Gary Stephenson discusses the Pentagon's AATIP program, Jack Sarfatti’s "Tic Tac" UAP warp-drive, and describes a method for gravitomagnetic propulsion proposed by Dr. Robert L. Forward.
Gary has had a deep interest in gravity modification and advanced propulsion for decades, and has published numerous scientific articles on various topics, especially related to the detection & generation of High-Frequency Gravitational Waves.
Gary Stephenson is an aerospace systems engineer with wide-ranging industry experience at organizations including NASA, United Technologies, Linquest, Boeing, ITT, and Hughes Aircraft Company.
Gary has had a deep interest in gravity modification and advanced propulsion for decades, and has published numerous scientific articles on various topics, especially related to the detection & generation of High-Frequency Gravitational Waves.
Stephenson is also a well-established contributor to many authoritative scientific papers by other researchers, and is a past participant in notable advanced propulsion conference such as the 2003 Mitre HFGW and 2005-2008 INPS STAIF (Section-F) conference events.
Gary's presentation begins with a review of Hal Puthoff's 2018 talk on the AATIP program and Jack Sarfatti’s 2021 analysis for "Tic Tac" UAP Warp Drive. He will discuss how the AATIP program has benefited his work in general, and help the audience understand some of the motivations and provide context behind my current paper related to Gravitomagnetism.
In his presentation on Gravitomagnetism, he describes a method for creating a measurable unbalanced gravitational acceleration using a gravitomagnetic field surrounding a superconducting toroid as described by Forward (1962). An experimental Superconducting Magnetic Energy Storage (SMES) toroid configuration of wound superconducting nanowire is proposed to create a measurable acceleration field along the axis of symmetry, providing experimental confirmation of the additive nature of a Lense-Thirring derived gravitomagnetic field.
In the present paper gravitational coupling enhancement of this effect is explored using high permittivity material, as predicted by Sarfatti (2020) in his modification to Einstein’s General Relativity Field Equations for gravitational coupling in matter.
Gary has had a deep interest in gravity modification and advanced propulsion for decades, and has published numerous scientific articles on various topics, especially related to the detection & generation of High-Frequency Gravitational Waves.
Gary Stephenson is an aerospace systems engineer with wide-ranging industry experience at organizations including NASA, United Technologies, Linquest, Boeing, ITT, and Hughes Aircraft Company.
Gary has had a deep interest in gravity modification and advanced propulsion for decades, and has published numerous scientific articles on various topics, especially related to the detection & generation of High-Frequency Gravitational Waves.
Stephenson is also a well-established contributor to many authoritative scientific papers by other researchers, and is a past participant in notable advanced propulsion conference such as the 2003 Mitre HFGW and 2005-2008 INPS STAIF (Section-F) conference events.
Gary's presentation begins with a review of Hal Puthoff's 2018 talk on the AATIP program and Jack Sarfatti’s 2021 analysis for "Tic Tac" UAP Warp Drive. He will discuss how the AATIP program has benefited his work in general, and help the audience understand some of the motivations and provide context behind my current paper related to Gravitomagnetism.
In his presentation on Gravitomagnetism, he describes a method for creating a measurable unbalanced gravitational acceleration using a gravitomagnetic field surrounding a superconducting toroid as described by Forward (1962). An experimental Superconducting Magnetic Energy Storage (SMES) toroid configuration of wound superconducting nanowire is proposed to create a measurable acceleration field along the axis of symmetry, providing experimental confirmation of the additive nature of a Lense-Thirring derived gravitomagnetic field.
In the present paper gravitational coupling enhancement of this effect is explored using high permittivity material, as predicted by Sarfatti (2020) in his modification to Einstein’s General Relativity Field Equations for gravitational coupling in matter.
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