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The Possible Mechanism of Creation of Light Magnetic Monopoles in Strong Magnetic Field of a Laboratory System V. Adamenko 1 and V. I. Vysotskii 1,2 1 Electrodynamics Laboratory "Proton-21", Kiev, Ukraine 2 Kiev Shevchenko National University, Faculty of Radiophysics, Kiev, Ukraine Abstract In this work the reasons and mechanism of the creation of unknown magnetocharged particles, which were observed in experiments on supercompression of condensed target in Kiev Electrodynamics Laboratory “Proton-21”, are discussed. It is shown that these particles are most probably the hypothetical light magnetic monopoles that were introduced by George Lochak as magnetoexcited neutrinos. The parameters of these particles (including mass of monopole and both size and binding energy of monopole-antimonopole pair) and the method of their creation are discussed and calculated. Introduction In our previous work [1,2] we have presented the results of observation and investigation of interaction of unknown magneto-charged particles (hypothetical magnetic monopoles) with surface of MDS (Al-SiO2-Si) structure. We have observed the traces of ordered thermomechanical impact on the surfaces (Fig. 1). The length of trace was L 2 mm. These results were observed during experiments in Kiev Electrodynamics Laboratory “Proton-21” on achieving the superdense state of matter by using the high-current electron driver [3]. In the experimental setup an impulse electron flux with a total energy about 100...200 J and duration 50 ns was used as a coherent driver in every cycle of supercompression. The energy of each electron in different experiments is about 300...400 kV, the total current - 50...70 kA . It was shown that the source of a great specific energy release, dQtot/dl -10 6 GeV/cm, spent on the formation of these traces, may be the processes of nuclear synthesis reactions Al 27 +C 12 = K 39 , Al 27 +C 13 = K 40 , which are running with the participation of MDS-structure surface nuclei and are stimulated by the action of magnetic monopoles [1,2]. 484
Figure 1. The general view and details of MDS-structure with the tracks In the present work the parameters of these monopoles and the mechanisms of their creation in Earth laboratory are discussed and calculated. 1. Parameters of magneto-charged particle In our previous work [1,2] it was shown that the process of formation of periodic tracks is connected with a magnetic interaction of magneto-charged particle with both magnetic field of anode current and multilayer MDS structure, which is the combination of diamagnetics (Si, SiO and melted ionized Al) and paramagnetic (solid Al) layers. In view of the form of a macrotrack (involving the great number of strictly periodic oscillations [1,2]), we may conclude that the controlling magnetic field is approximately the same along the entire trajectory. This corresponds to the fact that formation duration of mentioned track part is significantly less than the total duration 50 ns of the current pulse. If this duration was comparable with , then the period of oscillations at the beginning and at the end of the track would be essentially different. This result allows us to assume that the duration of the formation of this part of the track with the length L 2 mm is t 5 ns, and the mean longitudinal velocity of motion of the hypothetical magneto-charged particle is greater than L/t 4.10 7 cm/s. The maximal longitudinal velocity (in view of periodical stopping and periodical stimulation of fusion reactions along the trace [1,2]) is vg 10 8 cm/s. During detailed SIMS-researches it was shown that the area of unknown particle "point of reflection" (Fig. 2) is the foreign small-size (about 10 microns) object made of Fe 56 , Fe 57 and Co 59 isotopes and situated on the MDS structure. 485
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Proceedings of the 14th Internation
Page 3 and 4:
Table of Contents VOLUME 1 Preface
Page 5 and 6:
Photon Measurements 326 Excess Heat
Page 7 and 8:
Investigation of Deuteron-Deuteron
Page 9 and 10:
Introduction to Cavitation Experime
Page 11 and 12:
Bubble Driven Fusion Roger Stringha
Page 13 and 14:
to the density of muon fusion syste
Page 15 and 16:
4.184 Joules/calorie to give Qo. No
Page 17 and 18: References 1. M. P. Brenner, S. Hil
Page 19 and 20: Experiments on stimulation of cavit
Page 21 and 22: foil (thickness 0.1 mm) was situate
Page 23 and 24: the external surface of thick wall
Page 25 and 26: Introduction to Materials The outco
Page 27 and 28: the foils, and the effects of subse
Page 29 and 30: Material Science on Pd-D System to
Page 31 and 32: level required higher current compa
Page 33 and 34: morphology, and surface morphology
Page 35 and 36: Figure 11. Evolution of the input a
Page 37 and 38: Electrode Surface Morphology Charac
Page 39 and 40: fundamental peak; on the other hand
Page 41 and 42: RPSD@ max (x10 -32 m 4 ) 0.20 0.10
Page 43 and 44: 2. V. Violante, F. Sarto, E.Castagn
Page 45 and 46: Experimental Starting with the meta
Page 47 and 48: Figure 3.1. A typical database reco
Page 49 and 50: palladium lot as received. Differen
Page 51 and 52: Condensed Matter “Cluster” Reac
Page 53 and 54: Loading Measurements A high-vacuum
Page 55 and 56: Reaction Rate Estimates An estimate
Page 57 and 58: References 1. Andrei Lipson, Brent
Page 59 and 60: Introduction to the Theory Papers P
Page 61 and 62: Foundations: Experimental Evidence,
Page 63 and 64: Such results are applicable to a wi
Page 65 and 66: electrostatic fields, that could ge
Page 67: Theory Papers 1. V. Adamenko & V.I.
Page 71 and 72: So with a high probability the unkn
Page 73 and 74: Potential energy of pair (without m
Page 75 and 76: the corresponding electron wave fun
Page 77 and 78: applicable in case of interaction o
Page 79 and 80: The expression in the exponent of (
Page 81 and 82: Empirical System Identification (ES
Page 83 and 84: esults of the previous sections to
Page 85 and 86: The higher the mass of a particle (
Page 87 and 88: The Hubbard model [18, 19], along w
Page 89 and 90: A B Figure 2. Atomic Arrangements o
Page 91 and 92: deuterons, their interaction is aff
Page 93 and 94: expected in D-D reactions is that w
Page 95 and 96: It is being argued that, while heav
Page 97 and 98: with odd permutations weighted by -
Page 99 and 100: 20. C. Elsasser, K.M. Ho, C.T. Chan
Page 101 and 102: must have positive Bose Exchange sy
Page 103 and 104: these different statements that ref
Page 105 and 106: Fig.2 shows a pictorial representat
Page 107 and 108: (a) A Pictorial Representation of V
Page 109 and 110: esonance” can take place, in whic
Page 111 and 112: interior boundaries of the ordered
Page 113 and 114: Interface Model of Cold Fusion Talb
Page 115 and 116: D + Bloch "atom" sublayer, 3) epita
Page 117 and 118: sometimes stimulating an irreversib
Page 119 and 120:
Toward an Explanation of Transmutat
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Given the well-established validity
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The next question is, therefore, if
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An Experimental Device to Test the
Page 127 and 128:
Figure 1. Palladium/deuterium total
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Experimental Reaction enthalpies of
Page 131 and 132:
10. J. Dufour, X. Dufour, D. Murat
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Together with the Coulomb-repulsion
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“The Coulomb Barrier not Static i
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2 16 2 gc 27 3 So, a solution for
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Moreover, we study the “nuclear e
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Then, according to the loading quan
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Having mapped that the -phase depen
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Considering the attractive force, d
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The expression (45) was partially e
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Table 1. Using the phase potential
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10. A.De Ninno et al. Europhysics L
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Fusion system still outperformed th
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Van der Waals attraction occurs at
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Quantum Fusion (QF) Quantum Fusion
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Energy exchange There is some exper
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of the weak coupling matrix element
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Figure 3. Energy levels that contri
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Input to Theory from Experiment in
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substrate, and excess heat is obser
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4. Laser stimulation Letts and Crav
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energetic particles are produced, o
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15. K. Kunimatsu, N. Hasegawa, A. K
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A Theoretical Formulation for Probl
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at some point we will require tools
Page 179 and 180:
3. Matrix element example The appro
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Now the wavefunction on the RHS has
Page 183 and 184:
Theory of Low-Energy Deuterium Fusi
Page 185 and 186:
If mobile deuterons in a metal are
Page 187 and 188:
allowed since [Z1/m1] = [Z2/m2], an
Page 189 and 190:
traps (in 3g of Pd particles with a
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9. S.N. Bose, Z. Phys. 26, 178 (192
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system composed of host nuclei and
Page 195 and 196:
A simple specific form of beff (p)
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Nuclear Transmutations in Polyethyl
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Furthermore, there are interesting
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The NT’s in phenanthrene [7] may
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explains why there is no neutron em
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T+T Fusion CrossSection (Barn) T+T
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science, the incident energy is so
Page 209 and 210:
When the incident energy approaches
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9. Chadwick, M. B., Oblozinsky, P.,
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He = Em C + m Cm + tmn (C + m Cm
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where k 2 = (2 Md Ea / ħ ) = Md 2
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y altering the shape of the Coulomb
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Analysis and Confirmation of the
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This is the basic Langevin equation
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The fusion rate is calculated by th
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EQPET molecule must go back and con
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Introduction to Challenges and Summ
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notes that the common usage of the
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insufficient to allow us to reprodu
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in the early days of semiconductors
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Water In Acrylic Toppiece Gas Tube
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Much of this uncertainty would be r
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Figure 5. The effect of input power
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maximum values. From these values w
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considerably that they were enginee
Page 245 and 246:
Technogies”, in 11th Internationa
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Self-Polarisation of Fusion Diodes:
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We propose that in this field of on
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Results A. Self-sustained voltage O
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Figure 6. Differential calorimeter
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Weight of Evidence for the Fleischm
Page 257 and 258:
Figure 1. Multiple support for a hy
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P(D | T) = P(T | D) P(D) / P(T) = 0
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For more information about Bayesian
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positive is in the range 0.980 ± 0
Page 265 and 266:
With the notation Emn = “m heads
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3.1. Selected papers Cravens and Le
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Table 3. P(Eif | Pf) Table 4. P(Ein
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Condensed Matter Nuclear Science”
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4. J. Breese and D. Koller, “Tuto
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Taking the nuclear origin of copiou
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The evolution of protoscience into
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References 1. Mosier-Boss, P.A., et
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Cold fusion (CF) is a potentially r
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ISCMNS has initiated a CF-dedicated
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Table 2. Current Methods and Propos
Page 287 and 288:
For the CF/OSSc project, the ISCMNS
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ole of skeptical mainstream physici
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sized Pd and Pd alloy particles. Ap
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Honoring Pioneers For most fields o
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A&Z introduced new terms to describ
Page 297 and 298:
The top portion of Fig. 3 shows plo
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Figure 7. New catalyst shows nano-P
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catalyst to outer vessel wall is 7
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Establishment of the “Solid Fusio
Page 305 and 306:
Figure 1. Experimental Device Figur
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[The protocol for producing the ZrO
Page 309 and 310:
Figure 5A. Comparison of generation
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Figure 6. Gas pressure characterist
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Note on Sources The Abstract is a r
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37. Arata Y, Zhang Y-C; Proc. Japan
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LENR Research using Co-Deposition S
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that the tritium production was spo
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(a) (b) (c) Figure 4. Images obtain
Page 323 and 324:
SPAWAR Systems Center-Pacific Pd:D
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7. S. Szpak, P.A. Mosier-Boss, S.R.
Page 327 and 328:
17. S. Szpak, P.A. Mosier-Boss, and
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Preparata Prize Acceptance Speech I
Page 331 and 332:
Cold Fusion Country History Project
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2. “Condensed Matter Nuclear Scie
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need for a coordinated effort in ma
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Colloid J. USSR 48, 8(1986)). In 19
Page 339 and 340:
scientists on the problem of Cold F
Page 341 and 342:
Financial support for the conferenc
Page 343 and 344:
Author Index Pages are in Volume 1
Page 345:
Wang, J., 299 Watanabe, A., 338 Wei
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