EVALUATION OF D/D REACTION RATES IN METALLIC LATTICES AS A FUNCTION OF DEUTERON ENERGY

Similar documents
Screening Potential for Nuclear Reactions in Condensed Matter

Solid state modified nuclear processes

Electron screening effect in nuclear reactions and radioactive decays

Deuterium (Hydrogen) Flux Permeating through Palladium and Condensed Matter Nuclear Science

Dynamic Mechanism of TSC Condensation Motion

Clusters with Picometer Distance of Deuterons and LENR

Low Energy Nuclear Fusion Reactions in Solids

MockTime.com. Ans: (b) Q6. Curie is a unit of [1989] (a) energy of gamma-rays (b) half-life (c) radioactivity (d) intensity of gamma-rays Ans: (c)

SPAWAR Systems Center-Pacific Pd:D Co-Deposition Research: Overview of Refereed LENR Publications

2

The 2 H(d, p) 3 H reaction in metallic media at very low energies

Are Nuclear Transmutations Observed At Low Energies Consequences Of Qed Coherence?

New experimental constraints on the electron screening effect in astrophysical plasma

CALCULATIONS OF NUCLEAR REACTIONS PROBABILITY IN A CRYSTAL LATTICE OF LANTHANUM DEUTERIDE

SUPER-ABSORPTION CORRELATION BETWEEN DEUTERIUM FLUX AND EXCESS HEAT

Large electron screening effect in different environments

Multiple Scattering Theory (MST) and Condensed Matter Nuclear Science Super-Absorption in a Crystal Lattice

QUANTUM MECHANICAL STUDY OF THE FLEISCHMANN-PONS EFFECT

Pd D-D Fusion and Jitterbug Structure

SEARCH FOR COHERENT DEUTERON FUSION BY BEAM AND ELECTROLYSIS EXPERIMENTS

Fundamental of Rate Theory for CMNS

Mechanism Of Deuteron Cluster Fusion By EQPET Model

Violante, V. and F. Sarto, eds. Proceedings 15th International Conference on Condensed Matter Nuclear Science (Part 2). 2009, ENEA: Rome, Italy. 385.

CR-39 Results Obtained Using Pd/D Co-deposition. Pamela A. Mosier-Boss Lawrence P.G. Forsley

Hypothesis of a Double Barrier Regarding the D-D Interaction in a Pd Lattice: A Possible Explanation of CF Experiment Failures

Energetic Particles Generated in Earlier Pd + D Nuclear Reactions

Studies on 3D Fusion Reactions in TiDx under Ion Beam Implantation

A Project for High Fluence 14 MeV Neutron Source

Experimental and theoretical screening energies for the

Decay modes of excited 4 He below the fragmentation levels A. Meulenberg a and K P Sinha b

Laboratori Nazionali di Frascati

Strongly Enhanced DD Fusion Reaction in Metals Observed for kev D þ Bombardment

Chapter IX: Nuclear fusion

MODELING EXCESS HEAT IN THE FLEISCHMANN-PONS EXPERIMENT

Low Energy D+D Reactions in Metal

ANALYSIS OF NUCLEAR TRANSMUTATION INDUCED FROM METAL PLUS MULTIBODY-FUSION- PRODUCTS REACTION

Properties of the nucleus. 8.2 Nuclear Physics. Isotopes. Stable Nuclei. Size of the nucleus. Size of the nucleus

Enhanced Tc Superconductivity and Anomalous Nuclear Emissions in YBCO and Palladium

Experimental Evidence for LENR in a Polarized Pd/D Lattice

DEEP-ORBIT-ELECTRON RADIATION EMISSION IN DECAY

Exothermic reaction induced by high density current in metals Possible nuclear origin JACQUES DUFOUR, DENIS MURAT, XAVIER DUFOUR, JACQUES FOS

Bose-Einstein Condensation Nuclear Fusion: Theoretical Predictions and Experimental Tests

Physics of Cold Fusion by TSC Theory

Alternate Interpretation of the Original Fleischmann and Pons Experiments

Anomalous enhancement of DD reaction in Pd and Au/Pd/PdO heterostructure targets under low-energy deuteron bombardment

DEUTERIDE-INDUCED STRONG FORCE REACTIONS

The Coulomb Barrier not Static in QED A correction to the Theory by Preparata on the Phenomenon of Cold Fusion and Theoretical hypothesis

Measurements of the D + D Reaction in Ti Metal with Incident Energies between 4.7 and 18 kev

A simple calorimetric method to avoid artifacts in a controversial field: the ice calorimeter

Hydrogen Embrittlement,, Microcracking, and Piezonuclear Fission Reactions at the Ni and Pd Electrodes of Electrolysis Cold. Fusion Experiments

Synthesis Of A Copper Like Compound From Nickel And Hydrogen And Of A Chromium Like Compound From Calcium And Deuterium

Properties of the nucleus. 9.1 Nuclear Physics. Isotopes. Stable Nuclei. Size of the nucleus. Size of the nucleus

DEUTERON FLUXING AND THE ION BAND STATE THEORY

New Visions of Physics through the Microscope of Cold Fusion

Neutrons and Radiation From Deuteron Stripping in Metals That Absorb Hydrogen

OPTIMAL LASER WAVELENGTH FOR RESONANT TRANSMISSION THROUGH THE COULOMB BARRIER

= : K A

Nuclear Fusion and Radiation

Analysis of Nuclear Transmutation Induced from Metal Plus Multibody-Fusion-Products Reaction

Enhancement Of Nuclear Reactions Due To Screening Effects Of Core Electrons

NUCLEAR TRANSMUTATION IN DEUTERED PD FILMS IRRADIATED BY AN UV LASER

SYMPOSIUM ON NEW ENERGY TECHNOLOGY (Cosponsored with the Committee on Environmental Improvement) Organized by. J. Marwan

NUCLEAR EMISSIONS FROM TITANIUM HYDRIDE/DEUTERIDE INDUCED BY POWERFUL PICOSECOND LASER BEAM

22.54 Neutron Interactions and Applications (Spring 2004) Chapter 1 (2/3/04) Overview -- Interactions, Distributions, Cross Sections, Applications

DD Fusion in Conducting Crystals

Enhancement of the electron screening effect for d+d fusion reactions in metallic environments

Phys 102 Lecture 27 The strong & weak nuclear forces

Nice Try. Introduction: Development of Nuclear Physics 20/08/2010. Nuclear Binding, Radioactivity. SPH4UI Physics

1 Stellar Energy Generation Physics background

Fundamental Forces. Range Carrier Observed? Strength. Gravity Infinite Graviton No. Weak 10-6 Nuclear W+ W- Z Yes (1983)

The dd Cold Fusion-Transmutation Connection

Full atomic theory of cold fusion

Class XII Chapter 13 - Nuclei Physics

Composite Model for LENR in linear defects of a lattice

Atomic and nuclear physics

CHAPTER 12 The Atomic Nucleus

COMMENTS ON EXOTIC CHEMISTRY MODELS AND DEEP DIRAC STATES FOR COLD FUSION

Thursday, April 23, 15. Nuclear Physics

Atomic and Nuclear Radii

A Theoretical Summary of Condensed Matter Nuclear Effects

PFC/JA NEUTRAL BEAM PENETRATION CONSIDERATIONS FOR CIT

NUCLEAR PRODUCTS IN A GAS-LOADIND D/PD AND H/PD SYSTEM

Recent Status of Polarized Electron Sources at Nagoya University

Observation of Optical Phonon in Palladium Hydrides Using Raman Spectroscopy

The strong & weak nuclear forces

High Energy D 2 Bond from Feynman s Integral Wave Equation

Developing an Efficient Low-Temperature Nuclear Fusion Reactor

An update on Condensed Matter Nuclear Science (cold fusion) JEAN-PAUL BIBERIAN, a NICOLAS ARMAMET b

CONTEXT FOR UNDERSTANDING WHY PARTICULAR NANO- SCALE CRYSTALS TURN-ON FASTER AND OTHER LENR EFFECTS

E. Fermi: Notes on Thermodynamics and Statistics (1953))

Chem 481 Lecture Material 1/30/09

A

D DAVID PUBLISHING. Theoretical Study of the Phenomenon of Cold Fusion within Condensed Matter and Analysis of Phases (,, ) I.

Compound Nucleus Reactions

Solar Neutrinos. Solar Neutrinos. Standard Solar Model

Response to the comments of Professor of Nuclear Physics, Plasma Physics, and Microelectronics at Moscow M.V. Lomonosov State University, A. M. Popov.

Nuclear Physics and Astrophysics

Estimations of Beam-Beam Fusion Reaction Rates in the Deuterium Plasma Experiment on LHD )

THE NUCLEUS OF AN ATOM

Today in Astronomy 142

Transcription:

Theory (II) Session 8 O_5 EVALUATION OF D/D REACTION RATES IN METALLIC LATTICES AS A FUNCTION OF DEUTERON ENERGY J. Dufour Laboratoire des Sciences Nucléaires CNAM, 2 rue Conté 75003 Paris France Recently, experimental observations were made, showing an enhancement of d/d reaction rates, for energies of the deuteron between 3000 and 10000 ev on the one hand [1] and at very low energy of the deuteron on the other hand [2]. For both experiments, this enhancement was ascribed to the screening effect of the electrons of the metallic lattice where the reactions take place. In [3], the contribution to the d/d reaction rate enhancement, of an attractive Yukawa type of potential, acting between nucleons, was evaluated. The combined effect of this potential and of the screening of the lattice electrons was shown not to be sufficient to explain the whole enhancement observed for both experiments [1] and [2]. A coupling between the deuterons in the target with the incident deuteron beam was thus invoked [3] to explain the enhancement observed, by fusion reactions taking place between the deuterons already trapped in the target. Using the model developed in [3], the energy production resulting from the interaction of a 1 W beam of deuterons with a metallic target loaded with deuterium (1 mmole d), was evaluated as a function of the incident deuteron energy. 3 zones of interest were identified: a zone corresponding to hot fusion (deuteron energy round 100 000 ev), a zone corresponding to Cold Fusion (SPAWAR experiments - deuteron energy round 10 ev) and a potentially interesting intermediate zone (deuteron energy between 500 and 1000 ev) were sizeable and industrially significant amounts of energy production can be expected. It is proposed to call this last zone CMAF zone (Condensed Matter Assisted Fusion). This approach will be detailed and practical ways to generate deuterons in the CMAF energy window will be presented. References [1] A. Huke, K. Czerski, P. Heide, G. Ruprecht N. Targosz and W.Zebrowski Enhancement of deuterons fusion reactions in metals and experimental implications. Physical Review C, 78:015803, 2008. [2] P.A Mossier Boss, S.Szpak, F.E Gordon, and L.P.G Forsley. Use of CR-39 in Pd/D co-deposition experiments. Eur. Phys. J.appli. Phys. 40, 293-303 (2007) [3] J. Dufour. Possible existence of an attractive Yukawa type of potential and consequences on the understanding of alpha disintegration constants and d/d reactions at low energy of the deuteron. Submitted 18-02-2009 to Physical Review C. ICCF-15 67

THE CMAF WINDOW Possible sizeable energy production from 500/1000 ev deuterons

Main topics covered I The physics and maths used in alpha disintegration constants and d/d fusion reaction rates. The Yukawa potential. II Determination of the coupling constant of the Yukawa potential (alpha disintegration) III Determination of d/d reaction rates IV Comparison with experimental data (Huke and SPAWAR). V The coupling resonnance and the CMAF window.

I - Physics and Maths The Gamow penetration factor γ Plays a major role In alpha disintegration constants In d/d fusion reactions rates 2 2m R 2 R 1 B r E dr ( m reduced mass)

I - Physics and Maths Expression of the barrier The barrier equation is: With r 2 2 1 l l1 ' 2 e B() r ke k Cg 2 r r r Coulomb Centrifugal Yukawa ' k 1 and k 4 in the d / d case ' ' ' k 2 Z and k 4 A in the case. Calculation of the tunnelling probability P(Ed) using a spreadsheet

I - Physics and Maths Expression of the barrier The boson carrying the Yukawa interaction might be a neutral and virtual 2m e electron/ positron pair, with mass 2m e (electron mass) (A. Meulenburg suggestion August 2008) Its range would be: 193 fm 2mc e The coupling constant C can be calculated from known experimental values of the alpha disintegration constants.

II - Alpha disintegration case Following relations allow the determination of C (Yukawa coupling constant) by fitting calculated alpha disintegration constants λ with measured ones: P 1 E 2R 2m P e 1 C 3.79*10 g 7.53*10 e 6 2 3 2

III - d/d reaction rates case For a thick target, the reaction rate is: 3 1 2 2 1 3 0 r cm s cm cm s N cm ( ) ( ) ( ) ( ) cross sec tion PE geom. d probability of tunnelling N 0 deuteron concentration in palladium 2 1 incident deuteron flux ( cm s ) The energy produced is: W r W cm 13 3 1 3 0.83 2.44 1.6*10

III - d/d reaction rates case The d/d reaction rates were calculated (with P(E d ) given by the model) for an incident deuteron flux corresponding to 1 W with energy E d (varying from 2 to 100,000 ev) on a 1 cm2 target, containing 1 mmole of d (d/pd = 0.7) Calculations were run in 2 cases : no screening and screening + action of the Yukawa potential (with strength C from the alpha case). The influence of the Yukawa was found negligible at a few ev (huge impact of the screening) and of the same order of magnitude as the electron screening at a few kev.

III - d/d reaction rates case With these hypothesis, the number of incident deuterons is: and their flux: n 1 m 100E 2E d 3 (cm ) The palladium target thickness is 126 µm, containing 1 mmole d (6*10 20 d) corresponding to 22 3 N0 4.74*10 ( cm ) 1 E d d d cm s 2 1 E in ev d

d/d reaction rate (log 10 (s -1 )) IV - Comparison with experimental data Calculated d/d reaction rates Figure 1 d/d reaction rates for 1 W in 15 5-5 -15-25 -35-45 -55-65 -75 1,0 1,5 2,0 2,5 3,0 3,5 4,0 4,5 5,0 Deuteron energy (log 10 (ev)) No Screening Screening+Yukawa

Power out (log 10 (W)) IV Comparison with experimental data Calculated Power out Figure 2 Power out for 1 W in 5-5 -15 1 2 3 4 5-25 -35-45 -55 No screening -65-75 -85-95 Deuteron energy (log 10 (ev)) Screening+Yukawa

IV - Comparison with experimental data Hucke results (ref.1) show experimental reaction rates r ex higher than calculated ones r cal, with screening and Yukawa (ref.3) r F r, with F 1.5 to 2 ex c cal c SPAWAR results (ref.2) show experimental reaction rates r ex very much higher than calculated ones r cal, with screening and Yukawa (the latter negligible) r F r, with F 10 ex c cal c 18

IV - Comparison experimental data versus calculated reaction rates Typical energies for Hucke experiments are 2000 to 10000 ev. For SPAWAR experiments they are round 2 ev The huge variation of F c with E d (energy of the deuteron) suggest a resonnant coupling between the impidging deuteron flux and the deuterons already present in the target (inducing fusion reactions between them). EdEf ( F( Ef )) E f coupl. ( d ) coupl. ( f ) with E f F E F E e fermi energy

V - The coupling resonnance and the CMAF window - The resonnance curve 1,2E+18 Figure 5 F Coup. Coupling factor F Coupl. as a function of deuteron energy 1E+18 8E+17 6E+17 4E+17 2E+17 0 Deuteron energy (ev) 0 500 1000 1500 2000

d/d reaction rate (log 10 (s -1 )) V - The coupling resonnance and the CMAF window - d/d reaction rates Figure 3 d/d reaction rate for 1 W in 15 10 5 0-5 -10-15 -20 1,0 1,5 2,0 2,5 3,0 3,5 4,0 4,5 5,0 Deuteron energy (log 10 (ev)) No screening Screening+Yukawa Screening+Yukawa+Coupling

Power out (log 10 (W)) V - The coupling resonnance and the CMAF window - Energy out for 1 W in Figure 4 Power out for 1 W in 5 3 1-1 -3-5 -7-9 -11 1 2 3 4 5 "No screening" "Screening + Yukawa" -13-15 Deuteron energy (log 10 (ev)) Screening + Yukawa+ Coupling"

V - The coupling resonnance and the CMAF window - Energy out for 1 W in At low energy of the deuteron, the reaction rates are in line with SPAWAR results for a huge value of the coupling (#10 18 ) The Yukawa potential has a negligible role.the energy production is very small (10-10 W). At a few kev, the Yukawa potential has an influence comparable to that of the electrons screening and with a coupling factor of 1.5 to 2, the results are in line with Huke measurements. At high energy of the deuteron, the reaction rates are in line with hot fusion. At energy of the deuteron between 500 and 1000 ev, sizeable energy production levels are expected. CMAF window (Condensed Matter Assisted Fusion)

V - The coupling resonnance and the CMAF window - Production of deuterons beam in the CMAF window and target optimization Prototype for screening studies Ion guns for industrial applications Importance of Fc, depending upon physical and chemical characteristics of the target (optimization required).

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback