aaps-Guide-to-Home-Based-Covid-Treatment.pdf
1.9 MB
A Guide to Home-Based COVID Treatment
Step-By-Step Doctors’ Plan That Could Save Your Life
Source
https://faculty.utrgv.edu/eleftherios.gkioulekas/zelenko/aaps-Guide-to-Home-Based-Covid-Treatment.pdf
[Dr. Peter] McCullough said he has organized groups around the world that emphasize early treatment.
“Governments have actually tried to block early treatment of COVID patients, so we created a home patient guide,” he said.
Step-By-Step Doctors’ Plan That Could Save Your Life
Source
https://faculty.utrgv.edu/eleftherios.gkioulekas/zelenko/aaps-Guide-to-Home-Based-Covid-Treatment.pdf
[Dr. Peter] McCullough said he has organized groups around the world that emphasize early treatment.
“Governments have actually tried to block early treatment of COVID patients, so we created a home patient guide,” he said.
https://www.quantamagazine.org/how-blue-animals-color-themselves-with-nanostructures-20210616/
How Blue Animals Color Themselves With Nanostructures | Quanta Magazine
By VIVIANE CALLIER
June 16, 2021
Animals sculpt the optical properties of their tissues at the nanoscale to give themselves “structural colors.” New work is piecing together how they do it.
How Blue Animals Color Themselves With Nanostructures | Quanta Magazine
By VIVIANE CALLIER
June 16, 2021
Animals sculpt the optical properties of their tissues at the nanoscale to give themselves “structural colors.” New work is piecing together how they do it.
Quanta Magazine
How Animals Color Themselves With Nanoscale Structures
Animals sculpt the optical properties of their tissues at the nanoscale to give themselves “structural colors.” New work is piecing together how they do it.
The stunning blue iridescence of the blue morpho butterfly (left) results from the way that structures in its wing scales (right) diffract and reflect blue light while absorbing other parts of the spectrum.
muffinman71xx; Jiri Hodecek
https://d2r55xnwy6nx47.cloudfront.net/uploads/2021/06/morpho_v2.jpg
muffinman71xx; Jiri Hodecek
https://d2r55xnwy6nx47.cloudfront.net/uploads/2021/06/morpho_v2.jpg
The stunning blue iridescence of the blue morpho butterfly (left) results from the way that structures in its wing scales (right) diffract and reflect blue light while absorbing other parts of the spectrum.
muffinman71xx; Jiri Hodecek
https://d2r55xnwy6nx47.cloudfront.net/uploads/2021/06/Morpho-Wings.jpg
muffinman71xx; Jiri Hodecek
https://d2r55xnwy6nx47.cloudfront.net/uploads/2021/06/Morpho-Wings.jpg
The distinctive blue stripes on the blue-rayed limpet (top) reflect out of a layered arrangement of transparent calcium carbonate crystals in the shell.
johndal; Ling Li
https://d2r55xnwy6nx47.cloudfront.net/uploads/2021/06/Limpet_v2.jpg
johndal; Ling Li
https://d2r55xnwy6nx47.cloudfront.net/uploads/2021/06/Limpet_v2.jpg
The distinctive blue stripes on the blue-rayed limpet (top) reflect out of a layered arrangement of transparent calcium carbonate crystals in the shell.
johndal; Ling Li
https://d2r55xnwy6nx47.cloudfront.net/uploads/2021/06/limpetStructure_SEM_opticalMicrograph_LingLi-mobile.jpg
johndal; Ling Li
https://d2r55xnwy6nx47.cloudfront.net/uploads/2021/06/limpetStructure_SEM_opticalMicrograph_LingLi-mobile.jpg
The gyroid, a continuous minimal surface that forms a highly periodic structure, is in a sense the reverse of a sphere: While a sphere has uniform positive curvature, the gyroid is a saddle-shaped object with uniform negative curvature. One of its special features is that it splits space into two labyrinths of tunnel systems, separated by a membrane, that perfectly mirror each other. When both sets of tunnels are filled with fluid inside a live cell, the structure is known as a double gyroid; when only one set of tunnels is filled, the structure is a single gyroid.
A micrograph of the crystalline structure found in leafbird feathers and a model of a single gyroid.
https://d2r55xnwy6nx47.cloudfront.net/uploads/2021/06/Leafbird-Saranathan_mobile.jpg
A micrograph of the crystalline structure found in leafbird feathers and a model of a single gyroid.
https://d2r55xnwy6nx47.cloudfront.net/uploads/2021/06/Leafbird-Saranathan_mobile.jpg
A micrograph of the crystalline structure found in leafbird feathers and a model of a gyroid.
The periodic arrangement of nanoscale bubbles in leafbird feathers (top) are produced by the self-organized growth of a gyroid structure (right) within the barbs of the feathers.
Vinodkumar Saranathan; Mersus
https://d2r55xnwy6nx47.cloudfront.net/uploads/2021/06/Gyroid.jpg
The periodic arrangement of nanoscale bubbles in leafbird feathers (top) are produced by the self-organized growth of a gyroid structure (right) within the barbs of the feathers.
Vinodkumar Saranathan; Mersus
https://d2r55xnwy6nx47.cloudfront.net/uploads/2021/06/Gyroid.jpg
https://www.nature.com/articles/s41566-020-0593-1
Luminescent surfaces with tailored angular emission for compact dark-field imaging devices | Nature Photonics
Published: 24 February 2020
Nature Photonics
volume 14, pages 310–315 (2020)
Luminescent surfaces with tailored angular emission for compact dark-field imaging devices | Nature Photonics
Published: 24 February 2020
Nature Photonics
volume 14, pages 310–315 (2020)
Nature Photonics
Luminescent surfaces with tailored angular emission for compact dark-field imaging devices
A luminescent photonic substrate with a controlled angular emission profile is introduced and its ability to generate high-contrast dark-field images of micrometre-sized living organisms is demonstrated using standard optical microscopy equipment.
https://www.pnas.org/content/107/26/11676
Structure, function, and self-assembly of single network gyroid (I4132) photonic crystals in butterfly wing scales | PNAS
PNAS June 29, 2010 107 (26) 11676-11681; https://doi.org/10.1073/pnas.0909616107
Structure, function, and self-assembly of single network gyroid (I4132) photonic crystals in butterfly wing scales | PNAS
PNAS June 29, 2010 107 (26) 11676-11681; https://doi.org/10.1073/pnas.0909616107
PNAS
Structure, function, and self-assembly of single network gyroid (I4132) photonic crystals in butterfly wing scales
Complex three-dimensional biophotonic nanostructures produce the vivid structural colors of many butterfly wing scales, but their exact nanoscale organization is uncertain. We used small angle X-ray scattering (SAXS) on single scales to characterize the 3D…
https://www.pnas.org/content/118/23/e2101357118
Evolution of single gyroid photonic crystals in bird feathers | PNAS
PNAS June 8, 2021 118 (23) e2101357118;
https://doi.org/10.1073/pnas.2101357118
Evolution of single gyroid photonic crystals in bird feathers | PNAS
PNAS June 8, 2021 118 (23) e2101357118;
https://doi.org/10.1073/pnas.2101357118
PNAS
Evolution of single gyroid photonic crystals in bird feathers
Vivid, saturated structural colors are conspicuous and important features of many animals. A rich diversity of three-dimensional periodic photonic ...
Fig. 1.
Single gyroid photonic crystals in the plumage of Blue-winged Leafbird (C. cochinchinensis kinneari). (A) Photograph with approximate sampling locations (white arrows).
Image credit: John C. Mittermeier (photographer).
https://www.pnas.org/content/pnas/118/23/e2101357118/F1.large.jpg?width=800&height=600&carousel=1
Single gyroid photonic crystals in the plumage of Blue-winged Leafbird (C. cochinchinensis kinneari). (A) Photograph with approximate sampling locations (white arrows).
Image credit: John C. Mittermeier (photographer).
https://www.pnas.org/content/pnas/118/23/e2101357118/F1.large.jpg?width=800&height=600&carousel=1
Luke 12:27
Consider the lilies, how they grow: they toil not, neither do they spin; yet I say unto you, Even Solomon in all his glory was not arrayed like one of these.
God's painting pallette is far more intricate than mankind has ever previously imagined.
Consider the lilies, how they grow: they toil not, neither do they spin; yet I say unto you, Even Solomon in all his glory was not arrayed like one of these.
God's painting pallette is far more intricate than mankind has ever previously imagined.
Like many animals, the blue-winged leafbird of Southeast Asia gets its iridescent hues from structural colors — materials with nanometer-scale features that diffract and reflect specific wavelengths of light.
Wulong Tommy
https://d2r55xnwy6nx47.cloudfront.net/uploads/2021/06/Leafbird_2880x1620_Lede.jpg
Wulong Tommy
https://d2r55xnwy6nx47.cloudfront.net/uploads/2021/06/Leafbird_2880x1620_Lede.jpg
https://www.livescience.com/earth-inner-core-lopsided-crystal-growth.html
Earth's core is growing 'lopsided' and scientists don't know why | Live Science
By Brandon Specktor - Senior Writer
10 June 2021
The core is losing heat faster under Indonesia than it is under Brazil, and that's messing with the seismic waves passing through it.
There's a mystery brewing at the center of the Earth.
Scientists can only see it when they study the seismic waves (subterranean tremors generated by earthquakes) passing through the planet's solid iron inner core. For some reason, waves move through the core significantly faster when they're traveling between the north and south poles than when they're traveling across the equator.
Researchers have known about this discrepancy — known as seismic anisotropy — for decades, but have been unable to come up with an explanation that's consistent with the available data. Now, using computer simulations of the core's growth over the last billion years, a new study in the June 3 issue of Nature Geoscience offers a solution that finally seems to fit: Every year, little by little, Earth's inner core is growing in a "lopsided" pattern, with new iron crystals forming faster on the east side of the core than on the west side.
...
Equally puzzling is whether or not the lopsided cooling in the core could be affecting Earth's magnetic field. The modern-day magnetic field is powered by the movement of liquid iron in the outer core; this liquid's movement is powered in turn by heat lost from the inner core. If the inner core is losing more heat in the east than the west, then the outer core will move more in the east too, Frost said.
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"The question is, does this change the strength of the magnetic field?" he added.
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Earth's core is growing 'lopsided' and scientists don't know why | Live Science
By Brandon Specktor - Senior Writer
10 June 2021
The core is losing heat faster under Indonesia than it is under Brazil, and that's messing with the seismic waves passing through it.
There's a mystery brewing at the center of the Earth.
Scientists can only see it when they study the seismic waves (subterranean tremors generated by earthquakes) passing through the planet's solid iron inner core. For some reason, waves move through the core significantly faster when they're traveling between the north and south poles than when they're traveling across the equator.
Researchers have known about this discrepancy — known as seismic anisotropy — for decades, but have been unable to come up with an explanation that's consistent with the available data. Now, using computer simulations of the core's growth over the last billion years, a new study in the June 3 issue of Nature Geoscience offers a solution that finally seems to fit: Every year, little by little, Earth's inner core is growing in a "lopsided" pattern, with new iron crystals forming faster on the east side of the core than on the west side.
...
Equally puzzling is whether or not the lopsided cooling in the core could be affecting Earth's magnetic field. The modern-day magnetic field is powered by the movement of liquid iron in the outer core; this liquid's movement is powered in turn by heat lost from the inner core. If the inner core is losing more heat in the east than the west, then the outer core will move more in the east too, Frost said.
⬇️
"The question is, does this change the strength of the magnetic field?" he added.
⬆️
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livescience.com
Earth's core is growing 'lopsided' and scientists don't know why
The core is losing heat faster under Indonesia than it is under Brazil, and that's messing with the seismic waves passing through it.
A new model by UC Berkeley seismologists proposes that Earth’s inner core grows faster on its east side (left) than on its west. Gravity equalizes the asymmetric growth by pushing iron crystals toward the north and south poles (arrows). This tends to align the long axis of iron crystals along the planet’s rotation axis (dashed line), explaining the different travel times for seismic waves through the inner core.
(Image credit: Marine Lasbleis)
https://cdn.mos.cms.futurecdn.net/548Z3YZ7TQTmJqTUurJSUc-650-80.jpeg.webp
(Image credit: Marine Lasbleis)
https://cdn.mos.cms.futurecdn.net/548Z3YZ7TQTmJqTUurJSUc-650-80.jpeg.webp
We wonder if the infamous Planet X System could be an influence on Earth's innards. Eventually the truth will be revealed. 🤔
https://www.nature.com/articles/s41561-021-00761-w
Dynamic history of the inner core constrained by seismic anisotropy | Nature Geoscience
Published: 03 June 2021
Abstract
Progressive crystallization of Earth’s inner core drives convection in the outer core and magnetic field generation. Determining the rate and pattern of inner-core growth is thus crucial to understanding the evolution of the geodynamo. The growth history of the inner core is probably recorded in the distribution and strength of its seismic anisotropy, which arises from deformation texturing constrained by conditions at the inner-core solid–fluid boundary. Here we show from analysis of seismic body wave travel times that the strength of seismic anisotropy increases with depth within the inner core, and the strongest anisotropy is offset from Earth’s rotation axis. Then, using geodynamic growth models and mineral physics calculations, we simulate the development of inner-core anisotropy in a self-consistent manner. From this we find that an inner core composed of hexagonally close-packed iron–nickel alloy, deformed by a combination of preferential equatorial growth and slow translation, can match the seismic observations without requiring hemispheres with sharp boundaries. Our model of inner-core growth history is compatible with external constraints from outer-core dynamics, and supports arguments for a relatively young inner core (~0.5–1.5 Ga) and a viscosity >1018 Pa s.
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Dynamic history of the inner core constrained by seismic anisotropy | Nature Geoscience
Published: 03 June 2021
Abstract
Progressive crystallization of Earth’s inner core drives convection in the outer core and magnetic field generation. Determining the rate and pattern of inner-core growth is thus crucial to understanding the evolution of the geodynamo. The growth history of the inner core is probably recorded in the distribution and strength of its seismic anisotropy, which arises from deformation texturing constrained by conditions at the inner-core solid–fluid boundary. Here we show from analysis of seismic body wave travel times that the strength of seismic anisotropy increases with depth within the inner core, and the strongest anisotropy is offset from Earth’s rotation axis. Then, using geodynamic growth models and mineral physics calculations, we simulate the development of inner-core anisotropy in a self-consistent manner. From this we find that an inner core composed of hexagonally close-packed iron–nickel alloy, deformed by a combination of preferential equatorial growth and slow translation, can match the seismic observations without requiring hemispheres with sharp boundaries. Our model of inner-core growth history is compatible with external constraints from outer-core dynamics, and supports arguments for a relatively young inner core (~0.5–1.5 Ga) and a viscosity >1018 Pa s.
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Nature
Dynamic history of the inner core constrained by seismic anisotropy
Nature Geoscience - The inner core underwent preferential equatorial growth and translation after nucleation ~0.5–1.5 billion years ago, according to an analysis of its seismic...
The forces we can't see are far more powerful than those we can see. We're in Psalm 91 territory now.
https://m.youtube.com/watch?v=RYz9GlqOagM
Two CERN Scientist Die Trying to Stop Evil Entity - YouTube
Uploaded on Jun 20, 2021
Two CERN Scientist Die Trying to Stop Evil Entity
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https://m.youtube.com/watch?v=RYz9GlqOagM
Two CERN Scientist Die Trying to Stop Evil Entity - YouTube
Uploaded on Jun 20, 2021
Two CERN Scientist Die Trying to Stop Evil Entity
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YouTube
Two CERN Scientist Die Trying to Stop Evil Entity