The images below are from electron micrographs of biological tissue. The tissue has been frozen, sliced, stained and finally subject to an electron beam.
The images are claimed to represent nuclear pores seen from different angles but there are good arguments from Harold Hillman to suggest that this is not the case and that what we are seeing are merely artefacts of the microscopy process.
The artefacts on the right consist of what look like small toroidal structures comprised of a dozen or so smaller torii seen at right angles.
Fractal electron ring vortices
In the image below from a video by Bob Greenyer we see the results of electron streams impacting a metal plate(?) or something similar.
The patterns look like the results of the formation of fractal ring vortices in the substrate. A clear ring is seen, as is a subdivision into numerous smaller elements which could also be interpreted as ring vortices.
The similarity to the images above from Hillman is perhaps confirmation of his claims and we can see now that the patterns observed originate not from the tissue at all but from the electron beam itself even before it has impacted the material on the microscope slide.
Electron micrograph images therefore seem more closely related to the fundamental laws of field physics than they are to the structure of a living cell. Certainly the shapes seen above did not exist in the sample prior to being ‘photographed’ and are completely fabricated by the process itself.
Fractal ring vortices
The image below is of a fractal ring vortex taken from the Substack of Michael Clarage: https://michaelclarage.substack.com/p/fractal-toroids-part-1-geometry
These seem natural if regarded as electromagnetic field structures, as the field laws are (almost) scale invariant. If a ring vortex can form at a large scale then it can form at a smaller scale.
Time to consider that what an electron beam really consists of is a stream of charged electromagnetic field vortices which have been mis-interpreted as a stream of charged particles.
Field vortices are slightly different to particles, though, in that they are:
- Mutable (they can alter their shape)
- Possess an intrinsic energy
- Consist of both electric and magnetic fields
Maybe the electrons leave the generator one at a time looking like particles, but they soon use their energy and magnetic fields to organise into a least energy solution appropriate to their new environment which consists of filaments of flowing ring vortices.
The principle of energy cascade drives energy inwards and there is nowhere for it to go so it compresses down into smaller and smaller vortices to form the fractal structures illustrated.
These ring vortices are formed in the beam independently of the target substrate but form similar patterns whether they impact a metal plate or biological tissue.
Longer exposure times create more fractal structure
The Effects of Electron Beam Exposure Time on Transmission Electron Microscopy Imaging of Negatively Stained Biological Samples
http://www.appmicro.org/journal/view.html?doi=10.9729/AM.2015.45.3.150
Biological samples are often stained with metallic dyes and subject to a powerful beam for several seconds or longer.
If the beam is left on for extended periods, more detail becomes apparent: “The results presented here suggest that longer electron beam exposure times provide more electron densities of bio-materials analyzed by TEM imaging, ultimately resulting in optimal visualization of their detailed structural features. “
We can re-interpret this now as meaning that the effect of an electron beam is to arrange particles of metallic dye into stereotypical vortex structures and that the longer a sample is targeted, the more fine detail is created by the beam.
The basic structure of beam and image are set at the outset and longer exposures initiate an energy cascade leading to accumulation at smaller scales. This creates the fractal structures which are misinterpreted as fine-grained biological artefacts.
Exosomes
The pattern here is slightly different but still fractal in nature, with distinct circular structures surrounded by a ring of smaller circles. However, if the method of photography is the same in each case then the electron beam will be adopting a similar fractal structure long before it touches the tissue sample.
See also: Exosomes and anthrobots
Sars CoV-2
Enough said.
