You do recall that mitochondria make water, don't you?

Can water have a 'memory' of its previous solutes, environment or processing?
On the surface, this question sounds like quackery and pseudoscience. But the Black swan will go deeper than most to examine the evidence for themselves as the video above shows.
Montagnier experiments showed the effect. But he still has no idea how it happens. Today I am going to share with you how I think it does happen in your cells.
Water forms crystals that varied depending on the environment they sense. The electromagnetic radiations in that environment can change the crystalline structure of water at the atomic level. We know crystals are capable of creating memory. So, is the question as crazy as it first appears? What does the DATA say? All systems may retain a memory of their previous treatment, whether this is due to the formation of stable contamination, or to the production of energetic heterogeneities. It has been shown that the physical properties not only depends on the initial temperature but also on kurtosis; the distribution of the particles' kinetic energies from the mean value, a property that may depend on its past history. It should not be surprising that water also may retain a memory of its past history.

Are evolutionary changes stored magnetically in water around DNA?
In the literature it is well known that microwave irradiation gives rise to a memory effect on the surface tension of water that lasts for minutes after the effect of temperature rise alone has ended. Most scientists and the public have no idea these papers exist but Black Swans do. The first LINK below shows this effect in cite one.
This is why 5G concerns Black Swans. Microwaves induces topologic effects on water. This means it can affect its electric abilities in any aqueous system. CELLS are such a system.

More data to worry about: An extraordinary paper authored by Nobel prize-winning Luc Montagnier has described memory effects in aqueous DNA solutions that the authors propose to depend on interactions with the background electromagnetic field. These effects, if real, require the prior processing and dilution of the solutions and are explained by Montagnier as molecular resonance phenomena with nanostructures derived from the DNA and water.
So how could this happen in reality? Is there an explanation? What is the biophysics below the cell level a Black Swan can study?
Might the crystals in water vary in their electric abilities based upon the light around the water? Yep. Is water ferroelectric? Yep.
Ferroelectric materials are characterized by the spontaneous electric polarization that can be reversed by inverting an external electric field. Water molecules are dipolar and thus ferroelectric alignment of water molecules is conceivable when water freezes into special forms of ice. Spin ice experiments were discussed on my blog years ago. But now the new data published in early 2018 have raised the bar for the evidence.
Did you know that EZ water (exclusion zone) and ice share a lot of physical similarities?
Generally, ferroelectric materials have high dielectric constant. The EZ has a dielectric constant of 160 whereas regular tap water dielectric constant is only 78.
So it appears the water made in a mitochondrial matrix creates is a thin ferroelectric crystal. Ferroelectric materials have a spontaneous dipole moment which can point up or down. But does this unique ability explain WHY water MIGHT store memory?
Yes it does.
Being a ferroelectric crystal means that they can ALSO be used to store information, just like magnetic bits on a hard disk. The advantage of ferroelectric bits is that they can be written at a low voltage and power. The brain works at 20 volts. Magnetic bits in your tech gear require much larger currents to create a magnetic field for switching, and thus more power. The disadvantage of most ferroelectrics is that the aligned dipoles are only stable in fairly large groups, so if you make the crystals smaller, the dipole moment eventually disappears. When light hits the water, it builds a large EZ ferroelectric crystal that is uniform.

The common denominator in ferroelectric studies has been size and scale. This is no surprise to anyone who listened to my April 2016 webinar on what constitutes life. Water is a huge part of how life happens. In physics research, we know initially small crystals become ferroelectric, whereas larger crystals lose this property. This is exactly how ice and EZ water are initially built. So it does appear water made in the mitochondrial matrix is quite special because it can create a memory of things found in it. This might explain why the Kreb and urea cycle are designed by nature to be in this water. It appears the memory of the seasons on Earth can be magnetically stored in matrix water by its deuterium content. Might this be how metabolic rate of dofferent tissues is programmed in morphogenesis? I think so.
Is our circulatory system important in delivering memory to our cells by using water as its currency?

So to answer to the initial question this blog posed is: Can water have a memory? The answer appears to be yes. Why? Because water is ferroelectric at the nanoscale. When water is below 1.4 nm inside of a cell some rather bizarre things begin to occur at the quantum scale.

This means that very 'small bits' can be constructed from the crystals in EZ water. Furthermore, when a particular substrate is added to water that is magnetic, and this combination of magnetic and ferroelectric bits brings an extra degree of freedom, allowing each bit to store double the information. Could this be why the mouths of all the cytochrome proteins have iron-sulfur cores? Are they key to how life stores energy at low voltages and creates memory?
Does this imply that memory and consciousness might be a function of how good the water our mitochondria matrix creates is?
Yep.

CITES:
1. H. Parmar, M. Asada, Y. Kanazaw, Y. Asakuma, C.M. Phan, V. Pareek and G. M. Evans, Influence of microwaves on the water surface tension, Langmuir, 30 (2014) 9875-9879;M. T. Amiri and M. C. Amiri, Comment on “Influence of microwaves on the water surface tension”, Langmuir, 31 (2015) 10931-10932; H. Parmar, M. Asada, Y. Kanazaw, Y. Asakuma, C.M. Phan, V. Pareek and G. M. Evans, Reply to comment on “Influence of microwaves on the water surface tension”, Langmuir, 31 (2015) 10933-10934.
2. Yingfen Wei et al, A rhombohedral ferroelectric phase in epitaxially strained Hf0.5Zr0.5O2 thin films, Nature Materials (2018).
3. https://phys.org/news/2018-08-barrier-material-quirk-telecommunications.html
Dr. Jack Kruse
2018-10-25 22:27:28 +0000 UTCMatthew Jeffery
2018-10-25 02:42:06 +0000 UTCchristiangroth
2018-10-24 20:53:55 +0000 UTCchristiangroth
2018-10-24 20:48:25 +0000 UTCBastian
2018-10-24 05:53:26 +0000 UTCDr. Jack Kruse
2018-10-23 23:02:20 +0000 UTCBastian
2018-10-23 08:33:39 +0000 UTCAllin
2018-10-23 05:22:51 +0000 UTC