The Superwave

Quote from Peter Ekstrom

1 Do people still believe in Superwaves for LENR?

Perhaps there are some people on the Internet who "believe in Superwaves." In addition I assume there are people such as myself who have no opinion about them and are curious to see where the experimental research goes.

Quote from AlainCo

about superwaves, if confirmed (it seems by McKubre & others) it means the phenomenon is very non-linear.
if the phenomenon was linear, just sending white or colored noise would do the job.
here the phase between the frequencies is important.

no surprise as it is clear LENR is non-linear.

Thank you all guys for answering my queries about superwaves. I gather it is related to Freak waves for mechanical waves:
http://folk.uio.no/karstent/waves/index_en.html

The problem is that they are random. Does that make LENR random?

Quote from Peter Ekstrom

Thank you all guys for answering my queries about superwaves. I gather it is related to Freak waves for mechanical waves:
folk.uio.no/karstent/waves/index_en.html

The problem is that they are random. Does that make LENR random?

I thought the freak-wave problem has been solved some years ago?

What is need: Two currents ( wave-flow caused by somewhat distant strong opposite winds) with the usuall wave interference and a middle soliton like wave added on "top" to the inference!
The recorded freak-waves didn't have a typical inference shape.

Of course the ocean soliton wave is more or less random!

As I posted above, we can electronically generate soliton waves! (not random!)

Freak waves at the ocean enjoy the positive feedback of wind: such a wave works like the sail capturing the wind the better, the higher it is than another waves, which occasionally leads into avalanche like development of freak waves. I don't see any analogy to cold fusion here.

The cold fusion runs apparently without support of any wave at all, when the deuterons impact the surface of molten lithium. On the other hand, the activation of LENR just by heating implies, the resonance of waves within material gets dominant.

Quote from axil

The superwave is a method to create a high frequency waveform using simple circuitry and cabling without the need for expensive wave generators or lasers.

What Dardik did was slightly different: F(t)=Asin²(ωt)(1+A sin²(ωt)).

Start with slide 5:

Once more: http://lenr-canr.org/acrobat/DardikIexcessheat.pdf

I wonder if Peter could offer his impression of Dubinko's paper cited above. It seems rigorous in development and clear in presentation.
For me it was the high point of the ICCF19 program (other than Padua itself).

AlanG

Quote from magicsound

I wonder if Peter could offer his impression of Dubinko's paper cited above. It seems rigorous in development and clear in presentation.
For me it was the high point of the ICCF19 program (other than Padua itself).

Which paper are you referring to?

/* It should be possible to differentiate occasional fusion arising from acceleration of small species under electric fields */

IMO it should be distinguishable with geometry of accelerating fields. So far the laser fusion experiments focused (literally) on creation of spherical compression field, whereas these smarter ones (Holmlid, LeClaire) already utilize the low-dimensional character of laser beam for local momentum magnification with Astroblaster-like effects.

@ Peter Ekstrom
Sorry, that reference was in a previous post by AlainCo. Here's the link again:

http://arxiv.org/ftp/arxiv/papers/1510/1510.06081.pdf

It is difficult to generate much power at frequencies over 100-300 GHz using electronic components. There exists a so called wavelength gap between the highest frequencies that can be generated by electronic means and the lowest IR frequencies, usually generated by lasers. Phonon frequencies fall into that gap. Low power (milliwatt) THz sources are available and typically consist of a ~10 ps pulsed laser exciting a nonlinear optical medium.

So far as superwave, assuming it is generated by conventional semiconductors, the max frequency is probably no more than a few hundred MHz. Note the risetime given for power FETs is typically in the tens of ns. Take the inverse of the risetime and that will give a good estimate of the max frequency in a signal. Higher frequency power sources are available but involve microwave semiconductors and special design techniques involving transmission lines, and matched impedance, etc. It also becomes increasingly difficult to transmit power across any distance due to the dielectric and conductor losses in cabling.

I do not see a thread to post a link about high temperature super-conductors, has the playground thread been removed by the moderator?

From the link... "While studying purple bronze, a molybdenum oxide, researchers discovered an unconventional charge density wave on its surface." I have been looking at SC lately, and any good links would be appreciated.
http://nextbigfuture.com/2016/…aterial-property-may.html

Also this is be best explanation I have seen on it if you have 2 hrs of free time. Sean Hartnoll has a very energetic and down to earth speaking style. It makes the a long lecture interesting.

This material (molybdenum bronze) is not a superconductor but so-called topological insulator. You may imagine such a material like the brick soaked with electrons in similar way like the sponge with mercury: due to surface tension the electrons will be expelled from its pores and they will concentrate at its surface. They will exist there in somewhat compressed state in similar way, like the electrons at the surface of graphene (which can be also considered as an infinitely thin topological insulator with no bulk) or like the electrons attracted to hole stripes within high-temperature superconductors.

And this is just the connection point of topological insulator with superconductors: the compression of electrons and their localization at lower number of dimensions, i.e. the 2D surface. Otherwise, the scientists are just ignorant idiots as usually. It was Johann Prins, who recognized first in 2002, that the surface electrons can be compressed even more by attracting them to the positive charge (ions implanted beneath the surface) and to prepare the room superconductor in this way - but his finding was attacked and subsequently ignored. So that when someone writes by now, that this finding "may lead into high-temperature superconductor", I just must shake my head in fascination about such ignorant hypocrisy, the main purpose of which is to preserve the jobs of existing theorists as long as possible and to maximize their profit in this way.

/* Well that is what superconducting holes do, they push the electons out to the surface and keeps them there where those electrons transform into a topological superconductor. */

You're just twaddling again about the things which you don't understand, while confusing concepts of different topics randomly. The holes are positively charged, so that they will attract the electrons instead. But the topological insulators contain no holes - on the contrary, their effect is caused by collective repulsion of electrons from the bulk by their atoms, thus making the topological insulator nonconductive there (as its name implies). The famous toy grapeball can serve as an illustrative model of electrons expelled from bulk into a surface of topological insulators

In addition, the superconductivity has very little to do with cold fusion, primarily because fusion is nuclear effect, while the superconductivity is electronic one.