Quasicrystal Research of Synthesization Techniques and Applications
"The method for which one synthesizes quasi-crystals should be one of form and function..."
An opening joke:
http://www.tcqp.fi/uploads/4/3/8/2/43820655/8636355_orig.jpg
If this research is hard to read it may be because the author had too much gravy on his keyboard
That is to say if you have trouble processing the information I'm showing you, its not your fault. Thanks for reading.
A process; by which there were to exist a form A...
Where A is a solid quasi-gem/crystal of specific shape (shapes similar to Hexagonal pyramid topped hexagonal shafts of 3"-6" in length; cubic design; or potentially even more interesting sacred geometric figures, depending on overall purpose or function)
see strangely shaped crystal here:
http://i.ebayimg.com/images/i/401039566814-0-1/s-l1000.jpg
or these non periodic quasicrystals
http://pubs.rsc.org/services/images/RSCpubs.ePlatform.Service.FreeContent.ImageService.svc/ImageService/Articleimage/2015/RA/c4ra09524c/c4ra09524c-f5_hi-res.gif
one could conceive of a method of quick computations or data detection devices made around the size and shape of a quasi-crystal matrix gem/crystal.
here is an example of 3d printed quasi-crystal diffraction layers
https://cdn.instructables.com/FEW/A46Z/IEX4NY2Q/FEWA46ZIEX4NY2Q.MEDIUM.jpg
and example would be a new type of quantum computer that would be capable of many many many more calculations than our current
concurrent cpu processors. These reason may be many fold but ther are a few that come to mind.
The ordered nature of a quasi/crystal is perodic and wave form photons can be used to induce states in the crystal's natural
structures.
This would lead to a quantum nature from North pole to South depending on the layers of the crystals themselves.
Think of the crystals topology from North to South with each whole natural layer being represented by the natural number from 1-N.
Each of the N layers could be thought of as a modern day Compact Disc. With N layers being the total makeup of the gem from pole
to pole. The south pole being used to integrate photons back into one-to-one symetry with our data stream.
http://www.pitt.edu/~jdnorton/teaching/HPS_0410/chapters/quantum_theory_origins/FW-spacetime_small.gif
This may be one interpretation of a "use" of quasi crystals...
Manipulating data between N number of layers (a lot) would enable many many more well ordered operations depending on several
things...
1. the original structure of the gem.
2. Whether or not the gem is continuosly structured or ordered. either periodicly ordered (repeting spirals, fibbonaci, sacred
geometrical recursive crystaline dynamics) or asymetrically ordered (in the case of gates) as in each layers function could look
simmilar to Phylogenetic Tree Circles, or
sigils of the Goetia (without lettering around the edges), layered ontop of differnt layers of graphene on different layers of
quasi crystals forming a new layered circuit. where some energy travels through its chennels. Difracted along another M ordered
folds where M is the number of sides of a gem.
here is a cross section of what that might look like:
http://www.chem.pku.edu.cn/issm/progress/LaBaCaMnO.jpg
Layer
A = La(N)O3
B = BaO3
C = Ca20 graphite like sheet for logic layers
(A1A2) B (A2A1) C (A1A2) B (A2A1)...
another illustration from another angle
http://www.chem.pku.edu.cn/issm/progress/La2Ca2MnO7.jpg
one could use Gold for a socket or possibly a fixed laser grid to move photons from one north to south or perpendicular/horizontal to the north/south poles.
https://www.echosciences-grenoble.fr/uploads/body_image/attachment/1005162286/1.jpeg
this would allow for anywhere from base 3 to base N fold symmetrical computations concurrently as photons traversed through periodic iterations of crystal structures / man made logic / and symertrical folding channels of cystaline
https://s-media-cache-ak0.pinimg.com/originals/91/38/13/9138131e5257935ebec60507559b060a.jpg
the above image is a good represenation of two dimensional rapid ray fractalization as photons pass through well ordered quasi-crystalines. Gold plated channel logic gates (or graphene, graphite, or fullerene structures) could be manipulated to fit particular "non-touching" parts of the grid.imagine putting a 4D hypercube tesseract of super conducting materials between your graphene and crystaline channels and nodes.
See: Graphene, Carbon nanotubes, carbon dots, carbon nanofibers, nanodiamonds, and buckminsterfullerene
http://pubs.rsc.org/services/images/RSCpubs.ePlatform.Service.FreeContent.ImageService.svc/ImageService/Articleimage/2015/NR/c5nr00585j/c5nr00585j-f1_hi-res.gif
Elphidium, spiral, Foraminifera could connect channels to channels. OF COURSE every layer of this N layered crystal would have be designed with overall form and function.
https://img1.etsystatic.com/164/1/8259588/il_570xN.1124660447_ggcv.jpg
But at some point in the future, there will be set a standard of organization to the overall
parts of the crystal.
like this:
http://www.i-sis.org.uk/graphics/Golden_Mean_Wins_Chemistry_Nobe_Prize2.jpg
while still other designs of a crystal might represent complicated logic structures.
Like lets construct a quasicrystal data model for logic tree edge traversal
it might look something like this:
http://starcage.org/workshop/qcmodel/CIMG0467s.jpg
EG
Our example is a hexagonal shaft of 3-6" Hexagonal pyramid topped
if we "designed" a hypotetical crystal with layers N(1)-N(A) where A was the end of the pyramid top. and layers N(A+1) - N(B) where
the center shafted layers and layers N(B+1) to the bottom of our cystal N(N)
we could seperate our cystal into 3 zones of information.
Zone 1 - energy fractalization (defraction) spreading along channels simultaneously
Zone 2 - logic processing, complex state storage and quantum computing (similar to solid state laser setups), "the memory of
surfaces" ie time crystals locked in a particular moment in time.
Zone 3 - compilation and subsequent layers of recompilation or reintegration to a single node of data either in an off or on.
from start of period to end
|photons--->0>0>0>_>0_<={crystal}=>(some altered state of photons**)--|
**changed by N(N) layers (minus the top and bottom zones) of layered transformations on our initially defracted data stream.
(notice we say zones, quadrants, and layers)
https://qph.ec.quoracdn.net/main-qimg-fa791fe5708a3e0985cdc7a69d049315
effectively "sampling" every layer
http://www.eyemaginary.com/Portfolio/QuasicrystalSamplingTest.JPEG
Zone (horizontal sub sections of a whole crystal)
trirants, Quadrants, quintants, etc (Semi-peroidic-rants) based on periodic shape of overall crystal structure
layer, the individual layer of the well ordered crystal structure. As in the bread slice in the loaf example:
https://i.stack.imgur.com/pFVe0.png
resources:
http://www.iycr2014.org/__data/assets/image/0008/78785/exhibit-Uppsala.png
interactions between invisible edges (like connecting the dots of logic
http://www.nature.com/nmat/journal/v14/n1/images/nmat4152-f4.jpg
and chemistry
applcation of which could be computing large sums of data sets to make a more aggrigate guess of the future almost clairvoiantly.
Processing Colloidal quasicrystals with 12-fold and 18-fold diffraction symmetry
http://www.pnas.org/content/108/5/1810/F5.expansion.html
the differnce in computing potential between these two diagrams:
https://www.researchgate.net/profile/J-C_Levy/publication/269275688/figure/fig7/AS:284016663121920@1444726257572/Figure-12-The-extrema-of-the-quasicrystalline-density-function-n-3-x-y-with.png
and
http://arandalasch.com/newsite/wp-content/uploads/2014/05/20140417-D600-DSC_5507_mag-320x245.jpg
...is that the 2nd diagram has more edges filling in empty space. That can always be symmetrically filled with an infinite number of fractal branches. Edges could be traversed through lowest energy conformations of Lattice folding maps for
quantum annealing.
http://www.nature.com/article-assets/npg/srep/2012/120813/srep00571/images/w582/srep00571-f2.jpg
example:
http://www.pnas.org/content/93/25/14271/F10.large.jpg
here we see a binary example of a Fibonacci cube edge computation of which there are a few properties of friction that we should invoke. at high temperature and low temperature. Here is an example of edge traversal through binary numbers!
https://upload.wikimedia.org/wikipedia/commons/thumb/3/39/Fibonacci_cube.svg/240px-Fibonacci_cube.svg.png
recources:
how many N many layers could be represented 2 dimension-ally sectioned out
http://payload1.cargocollective.com/1/5/162146/2320354/pia_0771.jpg (this is N=4 layers)
this example is how to make the 1st square into the 4th. But we would want to table
each individual layer. like a geometrically stable solid punch card
quantum mechanics in classical probability can apply linear transformations that conserve 1-norm of probability vectors while a quantum quasi-crystal computer could apply linear layered transformations that would conserve N-Norm amplitude vectors.
https://i.stack.imgur.com/NeOio.png
http://patternandbelief.com/wp-content/uploads/2013/04/quasi-crystal-geometry1.jpg
we can say that with confidence, because of the periodic nature of 2D quasi-crystalline structures.
Since these sacred geometry have been seen many places in nature including organic chemistry, we have already synthesized may tiny molecules of carbon chained together. (sometimes up to 60 or 70 carbon atoms at once)
https://www.researchgate.net/profile/Peter_Schwerdtfeger2/publication/236114642/figure/download/fig16/AS:268020606042150@1440912500755/Figure-15-Schlegel-diagrams-for-the-layered-D5h-fullerene-nanotubes-a-C30-b-C50-c.png
https://patentimages.storage.googleapis.com/US20070258329A1/US20070258329A1-20071108-P00012.png
This quality of sacred geometry is called fullerness
http://www.chem.qmul.ac.uk/iupac/fullerene/fu1gif/f6.gif
http://what-when-how.com/wp-content/uploads/2011/03/tmp1C183_thumb.jpg
https://s-media-cache-ak0.pinimg.com/736x/42/5e/0e/425e0ed595d89990fd2d4b6c9f647230.jpg
https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEiHVACtOiEAXFlYE1eVuNLMlsA0pCtbSIK-fh1-BWDgizBUktu-bL5YyKAoWk4BG2Ao8W860cBxSSG7-Dh-k8r8ua-5YLwqaEdapjPrAgyFrbmke5i2KzpkPCrzdBWXpwuyBYYUeszMzRAU/s1600/Figure1.png
the nature of these crystals are "channels" by which some energy passes through its medium...
To which I have no answer, as to what type of energy would pass through a channeled crystalline logic matrix... Unseen edge traversal energies, photonic energy, or even electron diffraction
http://www.psrd.hawaii.edu/WebImg/quasicrystal.gif
http://www.physik.uni-wuerzburg.de/EP3/Arbeitsgruppen/Quantentransport/QTNS-bmps/qshe.gif
we can even see some of the quantum properties of our conduit channels through edge traverseals and vertical energy transport
through out a crystals layers...
https://www.cfn.kit.edu/img/research_b_nano_electronics/B2_15_QSHE.jpg
http://patternandbelief.com/wp-content/uploads/2013/05/Analysis-of-Quasicrystal-Array.jpg
as they pass through the insulated structures in a vacuum
https://www.ntt-review.jp/archive_html/201508/images/fa7_fig03.jpg
https://www-ssrl.slac.stanford.edu/research/highlights_archive/topological_insulator_fig1.jpg
images like this, of molecular integration could have possible relation to Dianetics:
https://render.fineartamerica.com/images/images-profile-flow/350/images-medium-large-5/orange-quasicrystal-dan-gries.jpg
in a well ordered, sacred geometric way
http://www.pnas.org/content/93/25/14271/F9.large.jpg
on the nano scale:
http://www.nature.com/nmat/journal/v14/n1/images/nmat4152-f4.jpg
https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEhIxXf24OnCAQVVdi7BW-P7T0E2V8CvNW9DStQ2Jji_o1Ba1fFhJK-CDco0dWWG7ZuOBxjTmnLp2LZwMyWxawkhvDqkIzbGQa6xgPPUmaHJm5YEXsEZ-6v7T7L-AZzebtSZPyz0_Rq8ZxCD/w1200-h630-p-k-no-nu/femtoneedle.png
http://mrc.iisc.ernet.in/~nravi/images/Nanolett.jpg
See Nano twists, with hydrophobic internal tubes
http://d3a5ak6v9sb99l.cloudfront.net/content/advances/2/11/e1601421/F1.large.jpg
A process like this combined with the right torque of geometry could have significant particle collision effects, possible vortex
This could improve nanotube water nozzle implosion applications.
https://www.bibliotecapleyades.net/imagenes_ciencia/agua10_02.jpg
Self replicating nano-structures:
https://3c1703fe8d.site.internapcdn.net/newman/gfx/news/hires/2015/5566d675b82a0.jpg
Al Pd Mn labeled quasi crystal, neat way to think about how electrons would flow through the channels of layered defractions
http://www.sps.ch/fileadmin/_migrated/pics/quasicrystals.jpg
Application of a liquid quasi-crystallized display for flexible graphene circuits and devices
https://regmedia.co.uk/2017/02/13/graphene2_photo_via_shutterstock.jpg?x=1200&y=794
some quasi crystal designs could even take advantage of "magic squares"
http://www.jainmathemagics.com/Editor/assets/webjtdmsq5soln4xp36_80dpi.jpg
Other uses could include graphene cabling as a function of fiber optics like this patent mentions
https://www.google.com/patents/US20120298396
Further resources: Solid State Chemistry and its applications
https://www.slideshare.net/Xipanda/solid-state-chemistry-and-its-applications-west-anthony-r
Photographic Material Refrences:
http://www.chem.pku.edu.cn/issm/progress/La2Ca2MnO7.jpg
http://www.chem.pku.edu.cn/issm/progress/LaBaCaMnO.jpg
http://pubs.rsc.org/services/images/RSCpubs.ePlatform.Service.FreeContent.ImageService.svc/ImageService/Articleimage/2010/JM/b922149b/b922149b-f5.gif
http://cdn.iopscience.com/images/1367-2630/6/1/152/Full/nj183364fig5.jpg
http://www.chem.pku.edu.cn/issm/progress/LaCuZnMoO.jpg
http://patentimages.storage.googleapis.com/US20120202006A1/US20120202006A1-20120809-D00002.png
http://www.mdpi.com/materials/materials-07-06502/article_deploy/html/images/materials-07-06502-g004-1024.png
Experimental realization of colloidal quasi-crystals
http://opticaltweezers.org/wp-content/uploads/2015/11/Fig12_4-1024x747.png
reference: Method and apparatus for the exploitation of piezoelectric and other effects in carbon-based life forms
https://www.google.com.ar/patents/US20070258329
reference: Configuration Specification for the C60-Ih and C70-D5h(6) Fullerenes and Their Derivatives
http://www.chem.qmul.ac.uk/iupac/fullerene/Fu17.html
FURTHER EXPLORATION INTO THIS RESEARCH WILL LIKELY YIELD RESULTS IN:
-Strong Magnetic Fields
-Casimir Effects
-Van Der Waals Force
-optical computers
-Nonlinear Kerr Effects,
-exotic wormhole effects / space warping
-solid state quantum computing
-self assembling solids (
http://www.nanocrystal.fudan.edu.cn/paper%20TOC/%E5%9B%BE%E7%89%878.png)
An opening joke:
If this research is hard to read it may be because the author had too much gravy on his keyboard
That is to say if you have trouble processing the information I'm showing you, its not your fault. Thanks for reading.
A process; by which there were to exist a form A...
Where A is a solid quasi-gem/crystal of specific shape (shapes similar to Hexagonal pyramid topped hexagonal shafts of 3"-6" in length; cubic design; or potentially even more interesting sacred geometric figures, depending on overall purpose or function)
see strangely shaped crystal here:
or these non periodic quasicrystals
http://pubs.rsc.org/services/images/RSCpubs.ePlatform.Service.FreeContent.ImageService.svc/ImageService/Articleimage/2015/RA/c4ra09524c/c4ra09524c-f5_hi-res.gif
one could conceive of a method of quick computations or data detection devices made around the size and shape of a quasi-crystal matrix gem/crystal.
here is an example of 3d printed quasi-crystal diffraction layers
and example would be a new type of quantum computer that would be capable of many many many more calculations than our current
concurrent cpu processors. These reason may be many fold but ther are a few that come to mind.
The ordered nature of a quasi/crystal is perodic and wave form photons can be used to induce states in the crystal's natural
structures.
This would lead to a quantum nature from North pole to South depending on the layers of the crystals themselves.
Think of the crystals topology from North to South with each whole natural layer being represented by the natural number from 1-N.
Each of the N layers could be thought of as a modern day Compact Disc. With N layers being the total makeup of the gem from pole
to pole. The south pole being used to integrate photons back into one-to-one symetry with our data stream.
This may be one interpretation of a "use" of quasi crystals...
Manipulating data between N number of layers (a lot) would enable many many more well ordered operations depending on several
things...
1. the original structure of the gem.
2. Whether or not the gem is continuosly structured or ordered. either periodicly ordered (repeting spirals, fibbonaci, sacred
geometrical recursive crystaline dynamics) or asymetrically ordered (in the case of gates) as in each layers function could look
simmilar to Phylogenetic Tree Circles, or
sigils of the Goetia (without lettering around the edges), layered ontop of differnt layers of graphene on different layers of
quasi crystals forming a new layered circuit. where some energy travels through its chennels. Difracted along another M ordered
folds where M is the number of sides of a gem.
here is a cross section of what that might look like:
Layer
A = La(N)O3
B = BaO3
C = Ca20 graphite like sheet for logic layers
(A1A2) B (A2A1) C (A1A2) B (A2A1)...
another illustration from another angle
one could use Gold for a socket or possibly a fixed laser grid to move photons from one north to south or perpendicular/horizontal to the north/south poles.
https://www.echosciences-grenoble.fr/uploads/body_image/attachment/1005162286/1.jpeg
this would allow for anywhere from base 3 to base N fold symmetrical computations concurrently as photons traversed through periodic iterations of crystal structures / man made logic / and symertrical folding channels of cystaline
https://s-media-cache-ak0.pinimg.com/originals/91/38/13/9138131e5257935ebec60507559b060a.jpg
the above image is a good represenation of two dimensional rapid ray fractalization as photons pass through well ordered quasi-crystalines. Gold plated channel logic gates (or graphene, graphite, or fullerene structures) could be manipulated to fit particular "non-touching" parts of the grid.imagine putting a 4D hypercube tesseract of super conducting materials between your graphene and crystaline channels and nodes.
See: Graphene, Carbon nanotubes, carbon dots, carbon nanofibers, nanodiamonds, and buckminsterfullerene
http://pubs.rsc.org/services/images/RSCpubs.ePlatform.Service.FreeContent.ImageService.svc/ImageService/Articleimage/2015/NR/c5nr00585j/c5nr00585j-f1_hi-res.gif
Elphidium, spiral, Foraminifera could connect channels to channels. OF COURSE every layer of this N layered crystal would have be designed with overall form and function.
https://img1.etsystatic.com/164/1/8259588/il_570xN.1124660447_ggcv.jpg
But at some point in the future, there will be set a standard of organization to the overall
parts of the crystal.
like this:
while still other designs of a crystal might represent complicated logic structures.
Like lets construct a quasicrystal data model for logic tree edge traversal
it might look something like this:
EG
Our example is a hexagonal shaft of 3-6" Hexagonal pyramid topped
if we "designed" a hypotetical crystal with layers N(1)-N(A) where A was the end of the pyramid top. and layers N(A+1) - N(B) where
the center shafted layers and layers N(B+1) to the bottom of our cystal N(N)
we could seperate our cystal into 3 zones of information.
Zone 1 - energy fractalization (defraction) spreading along channels simultaneously
Zone 2 - logic processing, complex state storage and quantum computing (similar to solid state laser setups), "the memory of
surfaces" ie time crystals locked in a particular moment in time.
Zone 3 - compilation and subsequent layers of recompilation or reintegration to a single node of data either in an off or on.
from start of period to end
|photons--->0>0>0>_>0_<={crystal}=>(some altered state of photons**)--|
**changed by N(N) layers (minus the top and bottom zones) of layered transformations on our initially defracted data stream.
(notice we say zones, quadrants, and layers)
effectively "sampling" every layer
Zone (horizontal sub sections of a whole crystal)
trirants, Quadrants, quintants, etc (Semi-peroidic-rants) based on periodic shape of overall crystal structure
layer, the individual layer of the well ordered crystal structure. As in the bread slice in the loaf example:
resources:
interactions between invisible edges (like connecting the dots of logic
and chemistry
applcation of which could be computing large sums of data sets to make a more aggrigate guess of the future almost clairvoiantly.
Processing Colloidal quasicrystals with 12-fold and 18-fold diffraction symmetry
http://www.pnas.org/content/108/5/1810/F5.expansion.html
the differnce in computing potential between these two diagrams:
and
...is that the 2nd diagram has more edges filling in empty space. That can always be symmetrically filled with an infinite number of fractal branches. Edges could be traversed through lowest energy conformations of Lattice folding maps for
quantum annealing.
example:
here we see a binary example of a Fibonacci cube edge computation of which there are a few properties of friction that we should invoke. at high temperature and low temperature. Here is an example of edge traversal through binary numbers!
recources:
how many N many layers could be represented 2 dimension-ally sectioned out
http://payload1.cargocollective.com/1/5/162146/2320354/pia_0771.jpg (this is N=4 layers)
this example is how to make the 1st square into the 4th. But we would want to table
each individual layer. like a geometrically stable solid punch card
quantum mechanics in classical probability can apply linear transformations that conserve 1-norm of probability vectors while a quantum quasi-crystal computer could apply linear layered transformations that would conserve N-Norm amplitude vectors.
we can say that with confidence, because of the periodic nature of 2D quasi-crystalline structures.
Since these sacred geometry have been seen many places in nature including organic chemistry, we have already synthesized may tiny molecules of carbon chained together. (sometimes up to 60 or 70 carbon atoms at once)
This quality of sacred geometry is called fullerness
the nature of these crystals are "channels" by which some energy passes through its medium...
To which I have no answer, as to what type of energy would pass through a channeled crystalline logic matrix... Unseen edge traversal energies, photonic energy, or even electron diffraction
we can even see some of the quantum properties of our conduit channels through edge traverseals and vertical energy transport
through out a crystals layers...
as they pass through the insulated structures in a vacuum
images like this, of molecular integration could have possible relation to Dianetics:
in a well ordered, sacred geometric way
on the nano scale:
See Nano twists, with hydrophobic internal tubes
A process like this combined with the right torque of geometry could have significant particle collision effects, possible vortex
This could improve nanotube water nozzle implosion applications.
Self replicating nano-structures:
Al Pd Mn labeled quasi crystal, neat way to think about how electrons would flow through the channels of layered defractions
Application of a liquid quasi-crystallized display for flexible graphene circuits and devices
some quasi crystal designs could even take advantage of "magic squares"
Other uses could include graphene cabling as a function of fiber optics like this patent mentions
https://www.google.com/patents/US20120298396
Further resources: Solid State Chemistry and its applications
https://www.slideshare.net/Xipanda/solid-state-chemistry-and-its-applications-west-anthony-r
Photographic Material Refrences:
http://www.chem.pku.edu.cn/issm/progress/La2Ca2MnO7.jpg
http://www.chem.pku.edu.cn/issm/progress/LaBaCaMnO.jpg
http://pubs.rsc.org/services/images/RSCpubs.ePlatform.Service.FreeContent.ImageService.svc/ImageService/Articleimage/2010/JM/b922149b/b922149b-f5.gif
http://cdn.iopscience.com/images/1367-2630/6/1/152/Full/nj183364fig5.jpg
http://www.chem.pku.edu.cn/issm/progress/LaCuZnMoO.jpg
http://patentimages.storage.googleapis.com/US20120202006A1/US20120202006A1-20120809-D00002.png
http://www.mdpi.com/materials/materials-07-06502/article_deploy/html/images/materials-07-06502-g004-1024.png
Experimental realization of colloidal quasi-crystals
reference: Method and apparatus for the exploitation of piezoelectric and other effects in carbon-based life forms
https://www.google.com.ar/patents/US20070258329
reference: Configuration Specification for the C60-Ih and C70-D5h(6) Fullerenes and Their Derivatives
http://www.chem.qmul.ac.uk/iupac/fullerene/Fu17.html
FURTHER EXPLORATION INTO THIS RESEARCH WILL LIKELY YIELD RESULTS IN:
-Strong Magnetic Fields
-Casimir Effects
-Van Der Waals Force
-optical computers
-Nonlinear Kerr Effects,
-exotic wormhole effects / space warping
-solid state quantum computing
-self assembling solids (
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