Schematic Time-Space Displacement System Design

TEC

Time Enforcement Commission
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Thanks to: Neil Harris for the information

1.0 Classical Assumptions vs Quantum Electro-Dynamics (QED) Data and Dual Function Modes:

If time is transitional from state to state (on an incremental scale) of physical existence, this describes a continuum (ie. continuous) and therefore disallows for discrete packets or particles of time. We know from classical empirical data that at absolute zero (0 Kelvin = - 459 Fahrenheit) the atoms of physical material remain at rest, that is no motion. Note: This is not consistent with data supporting Quantum Electrodynamics (QED). Time continues during this phase even though the material is in stasis; time does not stop however the animation of the material has.

Physical time travel can be approached in two distinct, however, linked, methods. One system employs a gateway function which is described as using an external device to move an object along a time continuum. An object can be imparted momentum before activation of the device or it may be in stasis during the operation of the device. The other major approach is to have the time displacement system integrated into the physical makeup of the temporal-space vehicle. This, not only allows the vehicle to travel in multi-axis and variable velocities but also through the time continuum itself. Advantages are not being traped to a specific local as a temporal shift occurs. This, you can see, has many distinct possibilities for improving time travel as a whole.

1.1 Gateway Technology Development

The following discussion will describe the assumed functionality of a time displacement system. The pictorial below identifies specific systems and subsystems that will be discussed.

1.1.1 Large Scale Aperture Systems

Large Scale Aperture systems are located in space for several reasons. Allows for a cleaner environment and minimal contamination effects. Allows for use/manipulation of high momentum target device system and therefore the application of the TSA as a true time-space transport augmentation system. Minimizes the need for high vacuum environments, difficult to establish and control in an atmospheric environment. Minimizes the number of materials needed to assure system rigidity and strength. Minimizes potential negative effects based on radiation, time rift, gravimetric, and unknown risks. Enhances functionality of the Primary Aperture Alignment Platform and minimizes any associated equipment needed for target alignment and insertion into the Time-Space Aperture.

1.1.2 Time-Space Aperture (TSA) Gateway

The Time-Space Aperture (TSA) gateway design is based upon a combination of known and theoretical sciences to develop a method to transport an object through time. As identified in the study of black-hole singularities, an extreme gravitational field is generated with a known event horizon within the aperture. The gravimetric field is allowed to rotate along the primary axis within the aperture in a method to move the target device either forward or backward on the time continuum. A method is used to modify the gravimetric field to introduce a faster-than-light (FTL) functionality. Another important feature of the TSA is allowing devices with preexisting device momentum to be manipulated. This adds spatial translation into the aperture functionality. This, thereby, gives the TSA the ability to either time displace a target and/or give the target three-dimensional movement. NOTE: Small-scale systems can be built that emulate the following assemblage of full-scale systems.

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1.1.3 Definitions

High-Density Laser Alignment System (HDLA) - Laser array used in conjunction with the VLAPFM for device alignment within the PAAP and as part of the optical data link telemetry system.

Primary Aperture Alignment Platform (PAAP) - Entry device for the Time-Space Aperture

Time-Space Aperture (TSA) - a device used to modify the time continuum and inject devices through the time/space event horizon

Time-Space Torroidal Focal Field (TTFF) - Time-space modified envelope that allows time travel generated by the SEFG.

Synchronous Event Field Generator (SEFG) - Circumferential mounted Tokamak fusion reactors around the TSA which have an open core design. The open core design allows for the development of high magnetic field density development as well as modifying flux direction and field confinement. It also allows for field/flux rapid intensification using magnetic enhancement core enhancement techniques associated with solenoid theory and momentum effects.

Very Large Array Primary Focus Mirrors (VLAPFM) - Mirror system used to disperse the HDLA output for augmenting device alignment within the PAAP and as part of the TSNA.

Time-Space Navigational Aid - A navigational system using Doppler ranging and alignment capability of the HDLA and multi-waveguide radar acquisition systems for high-speed approach devices. Directs and aligns momentum devices through the PAAP and into the TSA.

Magnetic Enhancement Plasma Deposition (MEPD) - System used to deposit a micro-thin layer of magnetic property materials to the outer surface of the target device. This plasma deposition is very uniform in property and application in a vacuum/microgravity environment. It is used to increase the time-space focal field effect.

Gas Augmented Photon Emitter - Cerenkov Radiation Field Generator (GAPE) - System used to generate and maintain a condition within the TTFF that allows a faster-than-light (FTL) condition to exist and react upon bodies in the TTFF.

1.2 Primary Aperture Alignment Platform (PAAP)

1.2.1 Function


The PAAP functions to ensure the device entering the Time-Space Aperture (TSA) has correct and precise 3-axis alignment before Aperture engagement. It not only allows for physical manipulation of the devices but also allows for navigational symmetry with the TSA for devices with internal alignment capability, augmentation of the autonomous alignment process, and, in essence, a waveguide for TSA entry.

1.2.2 Design Overview

The PAAP consists of a hexagonal cross-sectional shape allowing for the greatest utilization of interior space, strength, minimal material and mass, and ease in application of the HDLA/VLAPFM array and the TSNA.

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A three-dimensional rendition showing the HDLA axis is shown below for the PAAP. Note that the central axis is also used in the TNSA as mentioned in the PAAP overview. [Axis shown for illustration only]

1.2.3 Design Specifics

A 3-axis array of 8 GJ continuous/pulse lasers assisted by a VLAPFM group located on six parallel hexagonal axes and one central axis to stabilize, align and manipulate the incoming target devices. The laser alignment system (HDLA) focuses energy along with the device on specified areas to cause localized, high-density photon pressure. Associated with the laser alignment system, a navigational system (Time-Space Navigational Aid - TSNA), using the Doppler ranging and alignment capability of the HDLA and multi-waveguide radar acquisition systems for high-speed approach devices, and directs and aligns momentum devices through the PAAP and into the TSA. If necessary (based upon the target device's configuration), the Magnetic Enhancement Plasma Deposition (MEPD) system deposits a 1-micron layer of magnetic property enhancement material (may employ different elements) on the surface of the target device. This enhances the effects of the TSA activities.

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1.2.4 Operations Overview

Target acquisition by the PAAP automatically triggers the TSA to begin startup actions based on the type of device, device momentum, and mass, time-to-target, and alignment processing type. Device data download of mission specifics is derived from either optical beam-ride technology using the central axis HDLA and/or electronic telemetry. This information is passed to the TSA to develop TTFF parameters. The major components of the PAAP consist of the HDLA, the VLAPFM, and the TSNA. Power is generated via a combination of technologies using solar, SNAP Thermionic converters, Standard Orbital Atomic Reactor, and/or fusion tap from the SEFGs.

1.3 Time-Space Aperture (TSA)

1.3.1 Function


The Time-Space Aperture (TSA) is the device used to modify the time continuum and transport target devices through a time/space event envelope referred to below as the Time-Space Torroidal Focal Field. In essence, the TSA represents a system that produces two effects. [1] The Synchronous Event Field Generators develop an environment that manipulates electron spin states and corresponding quantum numbers to form a superparamagnetic field effect. [2] A Gas Augmented Photon Emitter produces an energetic polarization medium with properties that allow (a) electron tunneling to occur and (b) a flux that exhibits faster-than-light (FTL) properties. The combined functionality allows a device to be transported through the time-space continuum similarly as seen in electron tunneling in semiconductors. In a few words, the device generates a time-space wormhole.

1.3.2 Theory Overview

Tunneling is the quantum mechanical process by which a particle can penetrate a classically forbidden region of space (for example, passing from two separate points A and B without passing through intermediate points). The phenomenon is so named because the particle, traveling from A to B, creates a sort of tunnel for itself, bypassing the usual route. In 1927 the possibility of the phenomenon of tunneling, called barrier penetration, in a calculation of the splitting of the ground state in a double-well potential was identified. The phenomenon arises, for example, in the inversion transitions of the ammonia molecule, which is allowed in quantum mechanics for classically forbidden. Later, the Schrödinger equation was applied to the calculation of the reflection coefficient of an electron from various kinds of interfaces and noted that an electron, whose energy was insufficient to go over the barrier classically, could still tunnel through the barrier in the case of a rectangular potential barrier. This extended the case of tunneling between bound states noticed earlier to the case of tunneling between continuum states. George Gamow and, independently, R. W. Gurney and E.U. Condon applied the tunneling phenomenon to explain the range of alpha decay rates of radioactive nuclei. Although tunneling may seem abstract and far removed from reality, it is a basic and important process of Nature. It is vital, for example, in the very first step of the thermonuclear reaction that powers the Sun. The expansion (big-bang) theory of the universe even proposes that the universe began at a state of no geometry (i.e., a universe with nothing, not even time), and then tunneling occurred, allowing the Universe to pass from the state of nothing to something (the false vacuum) by tunneling.

1.3.3 Design Overview

Basic TSA design features include the Time-Space Torroidal Focal Field (TTFF) produced via the Synchronous Event Field Generators (SEFG), the Gas Augmented Photon Emitter (GAPE), and the Standard Orbital Atomic Reactor (SOAR). Electromagnetic waves under certain circumstances have properties indistinguishable from those of matter. The application of quantum mechanics allows us to extrapolate terms associated with the momentum of a photon and apply them (using a relativistic formula) to the properties of matter based on several physical (universal) constants, known mass, and velocity, and other specifics of the target device.

1.3.4 Design Specifics

Given information gathered from these and other sources of data, a localized time gradient in the scalar gravitational potential is superimposed across the symmetric gravitational potential already present from the mass of the vehicle. This induced effect is represented by a magnitude and is localized by a Gaussian distribution over the distance and centered at the target device. With a known circumference of the TSA, calculations can deduce orbital frequencies necessary to impart the required energy input from the SEFGs to develop the magnetic field densities and direction of rotation thereof to develop the time event envelope. These gravimetric and time alterations are applied to the target device like magnetic field applications associated with core solenoid functionalities since the target device was initially blown with a plasma arc of magnetic-enhancing material.

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1.3.5 Operation Overview

The TSA design draws upon several interactive functionalities to produce the time dilation or wormhole. Some of these functionalities, properties, and mathematics include magnetic field flux density and field induction, Poynting Vectoring effects, De Broglie wavelength theorems, the Heisenberg principle, Plank's constant, and Lorentz Contraction functions (as applied to a given medium) in development of the time-space focal field. Further, the time-space displacement system noted in this paper incorporates the properties of Cerenkov radiation, the superparamagnetic effect, and semi-conductor electron tunneling theorems. Once the target device leaves the PAAP, the TSA structure allows for the target device to be captured for some time and exposed to the TTFF being generated from the synchronous event field generators while enveloped in a Cerenkov radiation field from the GAPE. This causes an aperture effect within the boundaries of the TSA similar to electron tunneling {see PII-C1-1.3.2} and allows the device/vehicle to time. Depending upon target and mission specifics, the TTFF is modified to accomplish the required effects.

1.4 Gas Augmented Photon Emissions (GAPE) - Cerenkov Radiative Field Emitter

1.4.1 Function


To take advantage of the FTL properties of Cerenkov radiation and employ its use in the TSA for time-space travel, a suitable medium (ie. field) must be generated. The Time-Space Torroidal Focal Field is filled with a medium of correct refraction index properties and is charged using a Free-Electron LASER (FEL) or continuous electron bleed from the Synchronous Event Field Generator. This process generates a Cerenkov radiation field with properties within the TTFF where the development of the time-space focal field occurs.

1.4.2 Theory Overview

The speed of light is 2.9979E8 meters per second in a vacuum. This is not the velocity of light in another medium (s). The speed of light is associated specifically with a time barrier. If the one can be exceeded, so is the other, ergo -- time travel. Cerenkov radiation is emitted whenever charged particles pass through matter with a velocity v exceeding the velocity of light in that medium. The charged particles polarize the molecules, which then turn back rapidly to their ground state, emitting prompt radiation (in the form of photons). The emitted light forms a coherent wavefront if v>vt=c/n; Cerenkov light is emitted under a constant Cerenkov angle with the particle trajectory and at a given maximum emission angle. Cerenkov light is emitted only during the time in which the particle is slowing down and therefore has very fast time characteristics. Cerenkov light is emitted along the surface of a forward-directed cone centered on the particle velocity vector. The wavelength of the light is preferentially shifted toward the short-wavelength (blue) end of the spectrum.

1.4.3 Design Overview

Development and application of a Cerenkov Radiative Field Emitter would be used to produce a field of particles with a frequency equal to the Cerenkovvelocity for a given medium. This field can be applied to the space surrounding the vehicle to be propelled or projected through. Cerenkov radiation is a consequence of the motion of a charged particle with a speed that is greater than the speed of light in the same medium. No particle can exceed the speed of light in a vacuum (c), but in materials with an index of refraction represented by n, the particle velocity v will be greater than the velocity of light if v > c/n. For materials with an index of refraction in the common range between 1.3 and 1.8, this velocity requirement corresponds to the minimum kinetic energy of many hundreds of MeV for heavy-charged particles. Cerenkov radiation, when it is intense, appears as a weak bluish-white glow. The Cherenkov radiation in cases such as this is caused by electrons traveling at speeds greater than the speed of light in water, which is 75 percent of the speed of light in a vacuum. The energetically charged particle traveling through the medium displaces electrons in some of the atoms along its path. The electromagnetic radiation that is emitted by the displaced atomic electrons combines to form a strong electromagnetic wave analogous to the bow wave caused by an airplane traveling faster than the speed of sound in the air. The process effects are expressed in the Compton Effect. Given that we can calculate the velocity of Cerenkov radiation emanations in a given medium, revisiting the wave/particle duality, we can negate the need for finding its velocity and concentrate on? knowing where it is. We also know that the particle is also in. The direction of travel of the particle (and hypothetically a device) would (should) be derived and identified via the unified mathematics as described above. This direction should be identical to the Cerenkov angle (and corresponding Compton scattering angle).

1.4.4 Design Specifics

Fast electrons with relatively small kinetic energy can reach this minimum velocity, however, and the application of the Cerenkov process to radiations with energy below 20 MeV is restricted to primary or secondary fast electrons. Assuming a minimum refraction index of 1.300 and given radiation energy ranging >20 MeV, one medium that meets the requirements for the development of a Cerenkov radiation field is Freon 114, (1,2 dichlorotetrafluoroethane, C2Cl2F4). Some of its physical properties include an index of refraction of 1.30153.

1.4.5 Operation Overview

A large amplitude (up to 100 GeV/m) electrostatic (ES) TTFF is generated by the SEFG. The Freon-114 gas is injected into the TTFF resulting in a low m/a cloud. The cloud is excited either by FEL pulses or electron bunches (perturbations) discharges from the SEFG. As the vehicle enters the TTFF, its perpendicular travel through the TTFF (field and cloud rotation along the axis of the TSA) causes coherent electromagnetic radiation (Cerenkov) to be generated perpendicular to the trajectory of the vehicle. The radiation at the plasma frequency propagates essentially in the same direction as the perturbation. Estimates indicate that one gigawatt of 1 THz Cerenkov field radiation could be produced through this process.

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