Posted on 10/16/2021 11:02:58 AM PDT by Kevmo
Swartz: Pulsing Sideband at 327.37 MHz May Herald Movements within an Active Loaded PdD Lattice
Mitchell R. Swartz, MD, ScD, EE AC1ER JET Energy, Inc. July 14, 2019 © 2019
Active LANR (lattice assisted nuclear reaction) systems, both aqueous and dry nanomaterial, emit very narrow bandwidth radiofrequency (RF) emission lines (circa 327.37 MHz) in the Deuteron-Line (DL) region [1]. The maser line can include sidebands which appear by resonance broadening and energy exchange processes [2].
The superhyperfine sideband line (SHFL) structure (Figure 1) has been analyzed for the aqueous nickel MOAC system in its active mode [3]. In that light, the pulsatile superhyperfine RF line (PSHFL) is evident with periods of minutes. It is unlike everything else examined over two years from Earth and galactic origin, and only associated with Excess Heat from an ordinary water nickel CF/LANR system.
This is not mode-locking [4]. Laser mode locking involves hundreds of half-wavelengths, enabling interaction of different mode orders; but this 327 MHz LANR maser has only single-mode (half wavelength) operation. Laser mode locked pulses are separated by the Fabry-Perot cavity transit time but the 327 MHz LANR maser pulsing sideband is characterized by times which are minutes.
Finally, laser mode locked pulses have a Gaussian or a hyperbolic-secantsquared (sech2) pulse shape but the 327 CF/LANR maser’s pulses appear as near step functions.
What this is, instead, might be new information obtained from these unique pulsing RF bands which may herald deuteron density movements between, and to other, lattice regions, as revealed by the PSHFL (and interpreted, depending upon the model used: Band States, Bose Einstein condensates, and other quasiparticles).
It is a fact that thirty years of data demonstrate that deuterons loaded into Group VIII metals DO work together in active LANR systems to generate de novo 4He.
There are inverted populations of atomic D [1] with RF D-line emission sidebands [2] and this RF pulsing from active LANR systems might indicate part of an active-necessary deuteron redistribution in the lattice. Is such redistribution a sine qua non for successful movement through the Coulomb barrier?
Efforts are underway to examine this further, including intensities, pulsations and transfer-movements; which together suggest a need for an intralattice kinetoscope.
Figure 1 – Pulsatile RF Emissions in a Background of other RF SHF Lines The Radiofrequency Superhyperfine D-L spectrum of hydrogen loaded nickel MOAC during its active state [40 volts, 200 milliamperes]. This is a ‘waterfall’ plot and intensity is shown as a function of frequency. Note the arrow appears to almost be a horizontal mirror axis.
[1] Swartz M., Atomic Deuterium in Active LANR Systems Produces 327.37 MHz Superhyperfine RF Maser Emission (ICCF-22, 2019)
[2] Swartz M., Superhyperfine Sideband Structure of the Deuteron Line Emission from the ZrO2PdD Active Site May Herald an FCC Vacancy (ICCF-22, 2019)
[3] Swartz, M. R, C. Haldemann, A. Weinberg, B. Ahern, Possible Deuterium Loss During Excess Heat From Ordinary Water-Carbonate Electrolyte using Nickel, J. Condensed Matter Nucl. Sci. (Proc. ICCF21, 2018)
[4] Herman A. Haus, Mode-Locking of Lasers, IEEE J Sel. Topics in Quantum Electronics, 6, 6, (2000) , 1173
[5] The author thanks David Nagel and Bo Gardmark.
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Swartz: Atomic Deuterium in Active LANR Systems Produces 327.37 MHz Superhyperfine RF Maser Emission
Mitchell R. Swartz AC1ER JET Energy, Inc. June 21, 2019
Active lattice assisted nuclear reaction (LANR) systems, both aqueous and dry nanomaterial, emit very narrow bandwidth radiofrequency (RF) emission peaks (circa 327.37 MHz), in the Deuteron-line (“DL”; 327.348 MHz) region.
Figure 1 shows RF maser emission from a preloaded ZrO2PdD Nanor®-type LANR component [1,2] operated below its avalanche voltage in a well-grounded resonant Fabry Perot chamber. The high Q [> 1.2 x 106 ] and Zeeman response indicate maser activity.
There are superhyperfine sidebands. Nearest neighbor resonance analysis of those superhyperfine emissions heralds reactions occurring in a Pd lattice palladium face center cubic vacancy.
D-loaded active nickel is far more complex. Figure 1 –Software Defined Radio Identification of LANR D-Line Maser Emission
In this dual graph, there are two regions; in both, the frequency increases from left to right. The upper portion shows RF intensity peaks as a function of frequency (horizontal) at a single moment in time. On the bottom, each peak appears as a dot on a line for each one moment in time, and time increases from top to bottom, as in a waterfall.
The DL RF CF/LANR maser emission line is indicated in both portions of the display.
[1] Swartz M. R., Verner G., Tolleson, J, Energy Gain From Preloaded ZrO2–PdNi–D Nanostructured CF/LANR Quantum Electronic Components, JCMNSci. 13, 528 (2014).
[2] Swartz, M. R. G. Verner, J. Tolleson, P. Hagelstein, Dry, preloaded NANOR®-type CF/LANR components, Current Science, 108, 4, 595 (2015)
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Swartz: Superhyperfine Structure of the Deuteron Line Emission from Active ZrO2PdD Heralds an FCC Vacancy
Mitchell R. Swartz AC1ER Nanortech, Inc. June 29, 2019 ©
Analysis of non-Zeeman superhyperfine line (SHFL) splitting in LANR-induced RF DLemissions [1] yields insight into the LANR active site not otherwise available [Figure 1]. The SHFL emitted at 327.37 MHz from an active ZrO2PdD component [2] have been analyzed for asymmetry, amplitude and position as a function of frequency.
The asymmetry is 7-15% (1st through 3rd closest positions); smaller than the ~50% noted for some Zeeman splittings [3]. Most importantly, the SHFL arise from resonance broadening (RB) which occurs from perturbing deuterons in other vacancies through energy exchange processes.
RB impact was derived for the first four closest neighbor sites. The RB interaction decreases as 1/r^3 .
Figure 1 demonstrates the better overlap of the expected FCC locations in the midgraph, unlike the BCC lattice. The coordination numbers (CN) also better match for the FCC lattice.
Thus, analysis of the CN and RB sideband positions as a function of frequency strongly suggest that the location of the excited state deuterium is a palladium (Pd) vacancy within a slightly modified FCC lattice.
The modification shows a multiplet near the second nearest neighbor which might indicate nearby zirconia at a rhombic corner (isoequivalent to a FCC vacancy) or an atom of zirconium (or impurity) within the PdD lattice.
The results in nickel are more complex and demonstrate a range of FCC and body centered cubic (BCC) vacancies, possibly heralding new metallurgic phases.
This discovery adds semiquantitative material science support to theories that cite vacancies [4] as the site of the desired LANR reactions.
Figure 1 – Lattice Analysis of Active PdD Component’s Frequency-Time Plot This top shows the actual SHFL sideband structure for Nanor®-type component #7-4, driven at ~10 volts. This is a ‘waterfall’ plot and intensity is shown as a function of frequency. The middle and bottom of the fig. show the expected results for two different gendanken active sites, face and body centered cubic (FCC, BCC) respectively: both the coordination numbers (height) and expected deviation (to the right for frequency).
[1] Swartz M., Atomic Deuterium Produces 327.37 MHz Superhyperfine RF Maser Emission (ICCF-22, 2019) [2] Swartz M. R., Verner, G., Hagelstein, P., Imaging of an Active NANOR®-type LANR Component using CR-39, J. Condensed Matter Nucl. Sci. 15, (2015), p 81; www.iscmns.org/CMNS/JCMNS-Vol15.pdf
[3] J. E. Mack and O. Laporte, Asymmetric Zeeman Effect Patterns in a Complex Spectrum, Physical Review Journals Archive, Phys. Rev. 51, 291 (February 1937); DOI:https://doi.org/10.1103/PhysRev.51.291.2
[4] Swartz M., Catastrophic Active Medium (CAM) Theory of Cold Fusion, Proc. ICCF4 4, (1993), p 255
[5] The author thanks David Nagel, Bo Gardmark, Dennis Craven, Peter Hagelstein, Michael Staker, and Louis Dechiaro
I’m off to watch a Hallmark movie now.
Regards
Just heat a body of water in a closed system reliably and you’d have trillion dollar invention. No one has.
What are your credentials for being this arbitrator of what level of skepticism is appropriate? Scientific papers published? University degrees? Successful experiments run?
You act as if you have a lot of go fund me projects looking for suckers. Any vested interest you should be disclosing?
There's a whole book about that....title "Excess Heat" by Charles Beaudette. The short answer is...it's been done.
For the non-trolls on this thread, the Beaudette book is an excellent starting point for accessing the science of LENR.
J. Condensed Matter Nucl. Sci. 7 (2012) 11–25
Review Article
Biological Transmutations: Historical Perspective
Jean-Paul Biberian ∗
http://vernoux.org/agronomie/Biberian-Biological_Transmutations-Historical_Perspective.pdf
At 7:50 into this video, the experimenters replicated the effect AND boiled water, but of course skeptopaths aren’t going to accept such information.
http://ikkem.com/iccf23/speakervideo/1a-IN01-Mckubre.mp4
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