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205 lines
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205 lines
10 KiB
XML
<xml>
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<p> Here is explained a new kind of resonance: scalar EM resonance, or
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electrogravitational resonance. </p>
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<p> First, imagine we have a standard resonant cavity. In this cavity we
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have a resonant EM wave moving back and forth. In accordance with convention,
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the E-field vector and the B-field vector are at right angles in this moving
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wave front. As the wave moves back and forth, the vectors vary back and
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forth; however, at any one point between the walls, the two vectors always
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have the same value. Thus our resonant EM wave forms a standing wave in the
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cavity. </p>
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<p> Now imagine that a second wave front, precisely like the first and of
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the same frequency, is superposed over the first one and travels with it.
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This second wave -- the "antiwave" -- has its force vectors 180 degrees out
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of phase with the force vectors of the reference wave. Hence the E-fields
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and B-fields of the two superposed waves always sum to vector zeros, anywhere
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in the cavity. To an external observer, the cavity contains no ordinary
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electromagnetic force fields, hence no ordinary EM energy. </p>
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<p> However the energy density of a single EM sine wave in vacuum is given
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by:</p>
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<p> density 2
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[ E + B ]/8pi
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This energy density is always positive. Hence the energy density of the
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two waves at any point X between the walls is equal to: </p>
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<p>
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2 2
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[ E + B ]/4pi
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where
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E=E(x) ; B=B(x)
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Thus the energy density of vacuum varies with X. But, rigorously, since
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the resultant E and B fields are zero, this describes a standing
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gravitational wave. Hence we have a standing EG wave existing in the cavity.
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This is an example of scalar resonance. Rigorously the cavity has mass and
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inertia, to an outside observer, as a result of the two warps in spacetime it
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contains. </p>
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<p> Note that in one half cycle the energy density of vacuum is greater
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than ambient, and in the other half cycle it is less. In the region of one
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half cycle, time flows at a faster rate than to the ambient observer, and in
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the other half cycle time flows at a slower rate than to the ambient
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observer. One half cycle appears to contain negative electrical charge, and
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the other appears to contain positive charge. </p>
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<p> One half cycle appears to contain a north pole (positive magnetostatic
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scalar potential), and the other half cycle appears to contain a south pole
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(negative magnetostatic scalar potential). </p>
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<p> Perhaps n/w one can begin to understand why a continuously accelerated
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orbital electron in the atom does not radiate EM energy, completely in
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violation of Maxwell's equations. The electron is naught but a complex aspect </p>
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<p> Scalar resonance is not in the conventional textbook.</p>
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<p> Scalar resonance is a particular zero summed multi-resonance,
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electromagnetically, so that it does not act in an electromagnetic manner. </p>
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<p> A scalar resonance is a standing electromagnetic wave. It can be made
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electrically, but is not electrical in behavior.</p>
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<p> In any scalar resonance, spacetime is curved, and it is the magnitude
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(and direction) of this spacetime curvature that is oscillating in "standing
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wave" fashion. </p>
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<p> In respect to stress of the vacuum medium, one half of a standing sine
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wave of scalar resonance is tensile; the other half is compressive. However,
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this is with respect to the local ambient stress of the vacuum. </p>
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<p> "Mass" of a particle is just a characteristic exhibited by a trapped
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scalar resonance. Usually this trapping is done by the "spin" of the
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individual particle. </p>
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<p> The concept of "mass" may be compared with the concept of
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"capacitance." That is, a mass is an accumulator for scalar waves; that is,
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for scalar resonances. It is continually being "charged" and "discharged"
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by absorption and emission of scalar waves from and to the ambient vacuum
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scalar wave flux. </p>
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<p> Indeed the magnitude of a mass may be defined in terms of the absolute
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value of this "switching" (absorption = switch in; emission = switch out)
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rate. For details on this see (Bearden, T.E. "Quinton/Perception Physics: A
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Theory of Existence, Perception, and Physical Phenomena," March, 1973, AD
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763210, available through NTIS.) </p>
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<p> In the normal linear spacetime, the "charging" and "discharging" are
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equal in all directions; so the mass exhibited in any direction is the same. </p>
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<p> With respect to an "external observer's" equilibrium flux, a moving
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object encounters an increased amount of flux rate along its line of motion,
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just as a moving object in a rainstorm encounters more raindrops per second
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in the direction of its path, than does a stationary object. Encountering
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increased scalar wave flux (with respect to the external observer) forces the
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moving object to absorb and emit scalar waves at a higher rate along its
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direction of motion than when its not moving. Thus to the external observer,
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the mass of the object has increased, insofar as any disturbing force along
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its line of motion is concerned. </p>
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<p> At right angles to its line of motion however, the flux rate is
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precisely the same as when the object is at rest. Therefore the "mass" of the
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moving object with respect to any disturbing force at right angles to its
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line of motion has not changed, as seen by the external observer. </p>
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<p> Thus is explained both parts of one of the all time great mysteries of
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special relativity: (1) how the mass of an object increases with respect to
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its motion, and (2) why the mass only increases with respect to its line of
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motion, and not at any right angles to it. </p>
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<p> The inertia of a particle is due to its mass, i.e., to the total
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magnitude of its trapped scalar resonance. </p>
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<p> The gravitational attraction between two masses is due to their
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spacetime curvature. Further, mass is like a capacitance. It can trap
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additional scalar waves as trapped resonance; hence increase its magnitude or
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"inertial charge". Or, it can discharge more scalar waves than it absorbs;
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hence decrease its magnitude or "internal charge"... </p>
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<p> Those scalar waves emitted from resonance are emitted as a pattern
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ensemble of the resonance. Hence they may be regarded as constituting a
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current of scalar resonance leaving the mass accumulator object. Scalar waves
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absorbed into trapped resonance may be regarded as constituting a current of
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scalar resonance into the mass accumulator object. Thus it is proper to speak
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of scalar resonance as being able to "flow". </p>
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<p> Further, it is possible to increase the mass of an object directly, by
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transmitting scalar EM waves to it so that it absorbs them. (By absorbing
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scalar waves one means that more enter the object than leave it, so that the
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object acts as an internal accumulator charging up with internal charge. This
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is done by insuring the reference potential of the scalar wave transmitter is
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higher than the reference potential of the irradiated object.) </p>
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<p> It is also possible to decrease the mass of an object directly, by
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transmitting scalar EM waves to it so that it emits more than it absorbs. (By
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emitting scalar waves one means that more leave the object than enter it, so
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the object acts as if it were an internal accumulator that is discharging its
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internal charge. this is done by insuring that the reference potential of the
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scalar transmitter is lower than the reference potential of the irradiated
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object.) </p>
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<p> As can be seen, the scalar wave "transmitter" is actually somewhat
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comparable to a heat pump; it can either act as an "energy transmitter" or as
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an "energy extractor", depending on the difference in potential between
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"transmitter" and "receiver." </p>
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<p> Scalar resonance can have a specific pattern: both in frequency and in
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spatial curvature aspects, as well as "rate of flow of time" aspects. Indeed,
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scalar-wise every object has its individual "scalar pattern" which is a
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unique fingerprint. Since that print is spatiotemporal, it is a product of
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that objects entire past history. Thus --scalar wise-- no two objects are
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identical. </p>
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<p> This brings up another rather amazing potential: If a reasonably
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precise scalar pattern of an object can be "irradiated" and resonated with
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scalar waves, energy may be created in or extracted from the distant object,
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just as stimulating one tuning fork can excite another at a distance by
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sympathetic resonance. I leave it to you to ascertain the relavence of this
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statement to clairvoyance, radionics, remote viewing, etc.</p>
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<p> For the skeptic, however, we must point out that --rigorously--quantum
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mechanics requires that, continually, in any localized region of spacetime,
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the "pattern" of any object in the universe appears momentarily in the
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virtual state, purely from statistical considerations alone. So long as the
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situation remains statistical, any place in the universe can continue to have
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the "ghosts" of everything present there, in an ethereally thin pattern, and
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the observable world will not be affected by it. However if one can
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discriminate and scalarly "charge" or "discharge" individual patterns in this
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"ghost-realm", action at a distance is directly possible, as is
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materialization and dematerialization. If one accepts that even thought
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itself produces such virtual "ghost-patterns" in the virtual particle flux of
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vacuum, then it is at least theoretically possible to materialize thoughts
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and thought images.
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</p>
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<p> We have entered a new kind of reality where the old rules and the old
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limitations do not necessarily apply. </p>
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<p> As pointed out, we can greatly simplify matters by considering
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'currents of scalar resonance'. These currents flow from higher potential to
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lower potential, regardless of whether we are considering "transmission" or
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"reception". </p>
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<p> Indeed, to transmit at lower potential is to receive, and to receive
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at higher potential is to transmit. Thus the "transmitter-receiver" is a
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special system where simply biasing two nodes differently determines which
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way the scalar resonance will flow. We may increase or decrease an object's
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inertia and mass, simply by properly biasing the transmitter-receiver's two
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nodes.</p>
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<p> In one accidental experiment of some hours duration, Golden charged
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up an area so that, locally, all clocks became erratic. This included
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electrical clocks, battery driven watches, wind up kitchen clocks, and a
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pendulum operated grandfather clock. The rate of flow of time itself was
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apparently altered in the local area by the accumulated charge, which took
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four days to drain off and discharge. At the end of four days of discharge,
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all clocks and watches returned to normal.
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(Continued)
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</p></xml> |