Thursday, September 10, 2015

10 SEP 2015: LENR INFO


MOTTO

A bright definition:

"LENR is a multi-disciplinary art of science" (Gregory Goble)
Let's add: "and of technology".

DAILY NEWS

1) A polemics the author confronts a Cold Fusion skeptic
Lotta anti-FF (Fight against Cold Fusion) by Mistero
http://22passi.blogspot.ro/2015/09/lotta-anti-ff.html


2) Dr. Ryushin Ohmasa's new nuclear transmutation experiments by cavitation

http://amateur-lenr.blogspot.ro/2015/09/dr-ryushin-ohmasas-new-nuclear.html

3) Isotopic analysis of the of the 72 hours experiment by Songsheng Jiang
http://www.e-catworld.com/2015/09/10/isotopic-analysis-of-fuel-and-ash-after-72-hour-experiment-songsheng-jiang/
Actually not isotopic changes here- intelligence is i.a. the art of processing contradictory information- let's wait and see.

4) There will be energy for the entire world, clean energy. The method  is aimed 
 The method is aimed for shocking (for better( the world
Ci sarà energia per tutti, pulita. Il metodo è destinato a sconvolgere (in meglio) il mondo
http://www.italiaoggi.it/giornali/dettaglio_giornali.asp?preview=false&accessMode=FA&id=2017516&codiciTestate=1

5) Gregory Goble sends some info/papers useful in the LENR campaign
https://plus.google.com/107190105791959392745/posts/DCLYjU2HtH9
information about the following papers:

LENR is a multi-disciplinary art of science. These folks should be invited to participate in solving the 'cold fusion' theoretical puzzle.

WorldWideScience.org alert, 2015-09-09, for "Low Energy Nuclear Reaction".
1. "Random-matrix Approach to the Statistical Compound Nuclear Reaction at Low Energies Using the Monte-Carlo Technique"
Kawano, T 2015-01-01
http://cds.cern.ch/record/2048848

Using a random-matrix approach and Monte-Carlo simulations, we generate scattering matrices and cross sections for compound-nucleus reactions. In the absence of direct reactions we compare the average cross sections with the analytic solution given by the Gaussian Orthogonal Ensemble (GOE) triple integral, and with predictions of statistical approaches such as the ones due to Moldauer, to Hofmann, Richert, Tepel, and Weidenm\"{u}ller, and to Kawai, Kerman, and McVoy. We find perfect agreement with the GOE triple integral and display the limits of validity of the latter approaches. We establish a criterion for the width of the energy-averaging interval such that the relative difference between the ensemble-averaged and the energy-averaged scattering matrices lies below a given bound. Direct reactions are simulated in terms of an energy-independent background matrix. In that case, cross sections averaged over the ensemble of Monte-Carlo simulations fully agree with results from the Engelbrecht-Weidenm\"{u}ller ...
WWSCERN-EN

2. "My Research History on the Chemical Standpoint-From Molecular Structure to Surface Science"
Murata Y 2015-06-01
http://europepmc.org/abstract/MED/25755086

The structure of molecules using gas electron diffraction (GED) was my graduate study. However, I was making a new apparatus for precise measurements by GED and formulated a scheme for the least-squares analysis for a smooth continuous curve of scattering intensity. My research was completely shifted to the solid surface after moving to Gakushuin University, where I briefly studied the liquid structure of CCl4 molecules, and I then moved to the Institute for Solid State Physics, the University of Tokyo. My studies of surface science were focused on the electronic properties and related phenomena, and various experimental methods were developed. The plasmon dispersions elucidated the initial oxidation of aluminum and one-dimensional metal on Si(001)2 × 1-K. Irreversible phase transition was discovered on MgO(001) using the LEED Kikuchi pattern. The electronic structure of the dislocation was observed on MgO(001) by the electron time-of-flight method. The phase transition on Si(001) and the rotational epitaxy in a K monoatomic layer on Cu(001) were found. Next, I changed to studies of the dynamical phenomena on the surface, where very low energy reactive ion scattering on metal surfaces and laser-induced desorption caused by electronic transition of NO and CO molecules from metal surfaces were observed, and the hydrogen atom location at the surface and interface was measured with a high depth resolution using a resonance nuclear reaction of (1) H + (15) N(2+) at 6.385 MeV. Finally, I moved to the University of Electro-Communications and studied thin single-crystal oxide layers on transition metals, in which the band-gap narrowing was found, and then a Pt monoatomic layer was prepared on the α-Al(2)O(3) film.
UKPMC-EN
My Research History on the Chemical Standpoint-From Molecular Structure to Surface Science.
europepmc.org
The structure of molecules using gas electron diffraction (GED) was my graduate study. However, I was making a new apparatus for precise measurements by GED and formulated a scheme for the least-squares analysis for a smooth continuous curve of scattering intensity. My research was completely shifted to the solid surface after moving to Gakushuin University, where I briefly studied the liquid structure of CCl4 molecules, and I then moved to the I...

6) Battlefield news from Freethinker Lenr2:

Andrea Rossi
September 9th, 2015 at 9:49 PM

Kenko1:
Everything is taken on the many cameras in the factory. Many photos are done. One point five million data per month are collected from the measurement system.
Warm Regards,
A.R.

Andrea Rossi
September 9th, 2015 at 8:55 AM

Fyodor:
COP higher? yes ( F9); something else beyond heat? Possibly ( F9); better performance? yes ( F9).
Warm Regards,
A.R.

Andrea Rossi
September 9th, 2015 at 8:16 AM

John:
The E-Cat X is very, very promising and it is going so well, that I have also better understood from her some theoretical explications.
About theories: yesterday the CERN of Geneva has published on “Physical Review Letters” an important article regarding an anomalous effect discovered by the Large Hadrons Collider in the experiment LHCb on course since 2011 under the direction of Prof. Luigi Campana ( Director of the Frascati Laboratories of the INFN, Italy). The announcement is related to the fact that B mesons have an anomalous tendency to decay into tau leptons instead of into muons, in which they are supposed to decay along the Standard Model: if the Higgs turns out to be different , after it decays, from what we expect, it is sign the Standard Model has failed us; this anomalous effect could therefore open the gate to new Physics and maybe to new information indirectly introducing possible better theoretical explications of LENR, even if they cannot be directly connected with the high energy effects inside the LHC.
Warm Regards,
A.R.

8) Based on Rossi's third message here this was published:
Standard Model possibly under question after CERN experiment find anomalous effect
http://www.e-catworld.com/2015/09/10/standard-model-possibly-under-question-after-cern-experiment-find-anomalous-effect/

9) This was sent by dear old friend Nicolaie Vlad from Jassy; we have worked together at the Savinesti Synthetic Fibres Works in 1959-1961, he is a firtst class electric engineer, inventor, and a faithful reader of my publications INFO KAPPA (2002-2011Jan) and EGO OUT (2010 Dec-now) Thank you, dear Nicu!

"Major University Suppressed This ECE (Einstein-Cartan-Evans) Talk From Being Presented On Anniversary Of Pons & Fleischmann Cold Fusion Announcement!"
REVEALED: Explanation for cold fusion that was blocked by a major university is finally explained.

I hope our theorists will say what is the situation with this ECE theory.This is the blog of Dr. Myron Evans the 33.3% eponym of the ECE theory:
https://drmyronevans.wordpress.com/
It would be great to get explanations from him! But is he an EGO OUT reader? I am reading his blog frequently.


OTHER

RIO Research Ideas and outcomes- a new journal: http://rio.pensoft.net/


4 comments:

  1. In particle physics, the electroweak interaction is the unified description of two of the four known fundamental interactions of nature: electromagnetism and the weak interaction. Although these two forces appear very different at everyday low energies, the theory models them as two different aspects of the same force. Above the unification energy, on the order of 100 GeV, they would merge into a single electroweak force.

    The weak force is through by many to be the force that is responsible for LENR. For example, the L&W theory depends on the weak force to explain how protons become neutrons through a decay process.

    If the weak force does not behave like it is predicted to behave, that means that there is an unknown factor that is driving this weak force: the LENR force, into unexpected behavior.

    The connection between electromagnetism and the weak force may not be understood as current theory predicts. Since the B-meson decays into high energy tau particles, something is disturbing this decay process.

    Could the electromagnetic force combine with the weak force at lower energies, lower that 100 GeV? Could the electromagnetic force combine into the electroweak force at lower energies than expected?

    Electroweak activated LENR could be driven by a much lower power level than expected: a power level for the generation of the electroweak force that may be reached through engineering methods. The cross section for electroweak driven transmutation and nuclear binding energy release could be achieved through the application of very low electromagnetic power levels applied to the nucleus. Many LENR experiments point to this EMF based LENR mechanism. Rossi may be seeing indications of this electroweak anomaly occurring in his new E-Cat X reactor.

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  2. 1 of 3

    What does Rossi mean by this statement regarded the Higgs boson?

    “if the Higgs turns out to be different , after it decays, from what we expect, it is sign the Standard Model has failed us; this anomalous effect could therefore open the gate to new Physics and maybe to new information indirectly introducing possible better theoretical explications of LENR,”

    While the W particles are force carriers of the weak force, they themselves carry charges under the electromagnetic force. While it is not so strange that force carriers are themselves, the fact that it is electromagnetic charge suggests that QED and the weak force are connected. Glashow's theory of the weak force took this into account by allowing for a mixing between the weak force and the electromagnetic force. The amount of mixing is labeled by a measurable parameter.

    Unifying forces

    The full theory of electroweak forces includes four force carriers: W+, W-, and two uncharged particles that mix at low energies—that is, they evolve into each other as they travel. This mixing is analogous to the mixing of neutrinos with one another. One mixture is the massless photon, while the other combination is the Z. In order for a particle to gain speed, it must loss mass. Also the range of it influence increases as energy is added. So at high energies, when all particles move at nearly the speed of light, particles loss all mass.

    At high energy, the W particles behave like photons and QED and the weak interactions unify into a single theory that we call the electroweak theory. A theory with four massless force carriers has a symmetry that is broken in a theory where three of them have masses. In fact, the Ws and Z have different masses. Glashow put these masses determined by experiment into the theory by hand, but did not explain their origin theoretically.

    This single mixing parameter is critical in LENR, It predicts many different observable phenomena in the weak interactions. First, it gives the ratio of the W and Z masses (it is the cosine of ). It also gives the ratio of the coupling strength of the electromagnetic and weak forces (the sine of ). In addition, many other measurable quantities, such as how often electrons or muons or quarks are spinning one way versus another when they come from a decaying Z particle, depend on the single mixing parameter. Thus, the way to test the electroweak theory is to measure all of these things and see if you get the same number for this one parameter.

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  3. 2 of 3

    A sickness and a cure

    While the electroweak theory could successfully account for what was observed experimentally at low energies, one could imagine an experiment that could not be explained. If one takes this theory and tries to compute what happens when Standard Model particles scatter at very high energies (above 1 TeV) using Feynman diagrams, one gets nonsense. Nonsense looks like, for example, probabilities greater than 100%, measurable quantities predicted to be infinity, or simply approximations where the next correction to a calculation is always bigger than the last. If a theory produces nonsense when trying to predict a physical result, it is the wrong theory.

    A "fix" to a theory can be as simple as a single new fix-em-up field (and therefore, a new particle). We need a particle to help Glashow's theory, so we'll call it H. If a particle like H exists, and it interacts with the known particles, then it must be included in the Feynman diagrams we use to calculate things like scattering and decay cross sections. Thus, though we may never have seen such a particle, its virtual effects change the results of the calculations. Introducing H in the right way changes the results of the scattering calculation and gives sensible results.

    In the mid-1960s, a number of physicists, including Scottish physicist Peter Higgs, wrote down theories in which a force carrier could get a mass due to the existence of a new field. This field explains how a particle gets mass and therefore the range of its interactions. In 1967, Steven Weinberg (and independently, Abdus Salam), incorporated this effect into Glashow's electroweak theory producing a consistent, unified electroweak theory. It included a new particle, dubbed the Higgs boson, which, when included in the scattering calculations, completed a new theory—the Standard Model—which made sensible predictions even for very high-energy scattering. It predicted how a W particle changed mass as energy is added to became a photon at high energies.

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  4. 3 of 3

    A mechanism for mass

    The way the Higgs field gives masses to the W and Z particles, and all other fundamental particles of the Standard Model (the Higgs mechanism), is subtle. The Higgs field—which like all fields lives everywhere in space—is in a different phase than other fields in the Standard Model. Because the Higgs field interacts with nearly all other particles, and the Higgs field affects the vacuum, the state of the vacuum affect the Higgs field, the coupling constant, and the range that the weak force can act. the space (vacuum) particles travel through affects them in a dramatic way: It gives them mass and restricts the ranbe of interaction. The bigger the coupling between a particle and the Higgs, the bigger the effect, and thus the bigger the particle's mass.

    If the Higgs field does not act as the standards model predicts, the way the weak force and electromagnetism couples is not well defined. This variation in the state of the vacuum, the range of the weak force, and how electromagnetism affects the weak force come into question.

    If the vacuum can be manipulated such that a volume of space can be partitioned into a zone of high energy and an adjacent zone of low energy, the zone of negitive vacuum energy would allow the weak force to be more readily modified by EMF to increase it range and change its mode of interation. Such behavior has been seen when LENR increases the rate of nuclear decay of radio active isotopes in LENR experiments.

    This uncertainty in the coupling constant and the associated Higgs mechanism now seen in the standard model give LENR a opening and a place at the table in the full sunshine and acceptance by the standard model.

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