#FamilyIsEverything. APL = 5.55/10 *Authorized conspiracy theorist *Not an authorized preacher.
Cuz just went to the Hospital. He was avoiding it for a week. Took all the right meds. High does of ivermectin, zinc, quercetin, Vit D. Oxegen. AntiVax household. Hate that he is in there right now. Strict orders on No Vent or Remdes. Aunt is a vaxxer and shaming them for not getting the Vax. What a web.
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Auto immune issues, the body having nanobots manipulating and controlling, causing imbalance?
Or the immune sytem cannot make a distinction between the body’s own fatty lipid cell membranes compared to the fatty acid lipids that come from fatty lipid membranes that encapsulate solid lipid nanoparticle vaccines?
Fusion is the process by which two lipid bilayers merge, resulting in one connected structure. If this fusion proceeds completely through both leaflets of both bilayers, a water-filled bridge is formed and the solutions contained by the bilayers can mix. Alternatively, if only one leaflet from each bilayer is involved in the fusion process, the bilayers are said to be hemifused. Fusion is involved in many cellular processes, in particular in eukaryotes, since the eukaryotic cell is extensively sub-divided by lipid bilayer membranes. Exocytosis, fertilization of an egg by sperm activation, and transport of waste products to the lysozome are a few of the many eukaryotic processes that rely on some form of fusion. Even the entry of pathogens can be governed by fusion, as many bilayer-coated viruses have dedicated fusion proteins to gain entry into the host cell.
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Absolutely love the information shared on the mac page.
Freshing and unique, Thank Q, blissing with information, creating fusion?
Viruses Or nanoparticles acting as viruses?
What kind, type of viruses?
What viruses are concerns for humans?
Where do viruses come from?
Are there viruses from nature?
Are viruses man made?
Tobacco mosaic virus was the first virus to be crystallized. It was achieved by Wendell Meredith Stanley in 1935 who also showed that TMV remains active even after crystallization.
The positive influence of ultrasound (US) on crystallization processes is shown by the dramatic reduction of the induction period, supersaturation conditions and metastable zone width. Manipulation of this influence can be achieved by changing US-related variables such as frequency, intensity, power and even geometrical characteristics of the ultrasonic device (e.g. horn type size). The volume of the sonicated solution and irradiation time are also variables to be optimized in a case-by-case basis as the mechanisms of US action on crystallization remain to be established. Nevertheless, the results obtained so far make foreseeable that crystal size distribution, and even crystal shape, can be ‘tailored’ by appropriate selection of the sonication conditions.
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Graphene oxide-black goo
There is proof that people have become magnetic after the covid shot. This document proves that graphene oxide has been considered as method for medical treatment and it also proves that graphene oxide is magnetic. There is proof in this document …
https://www.bitchute.com/video/fKa7EIKwtQke/QSI Telegram, learning about Quantum Stellar Financial System, Medbeds, Liberty/Freedom, Checks and Balances, disclosure, Ascension,💜♾️
Thank Q right back.
👏👏👏
QSI Telegram, learning about Quantum Stellar Financial System, Medbeds, Liberty/Freedom, Checks and Balances, disclosure, Ascension,💜♾️
Have you seen Freemason lodges in small towns or cities with large inverted pentagrams or Pentagram?
Lapis is the Latin word for "stone" and lazulī is the genitive form of the Medieval Latin lazulum, which is taken from the Arabic لازورد lāzaward, itself from the Persian لاجورد lājevard. It means "sky" or "heaven"; so this is a "sky stone" or "heaven stone". Historically, it was mined in Badakhshan region of upper Afghanistan, but also mined in Lājevard, Persia. Lazulum is etymologically related to the color blue and used as a root for the word for blue in several languages, including Spanish and Portuguese azul.
Lapis lazuli usually occurs in crystalline marble as a result of contact metamorphism
Metamorphic rocks can change without melting. Heat causes atomic bonds to break, and the atoms move and form new bonds with other atoms, creating new minerals with different chemical components or crystalline structures (neocrystallization), or enabling recrystallization.[3] When pressure is applied, somewhat flattened grains that orient in the same direction have a more stable configuration.
The term "recrystallization" broadly refers to the many metamorphic processes that change the size and/or shape of crystal formations and preserve the chemical composition and mineralogy of the original mineral. Because recrystallization accounts for the majority of all visible changes produced by neomorphism, the terms "neomorphism" and "recrystallization" implicitly allude to each other and can therefore be used interchangeably under most circumstances. In petrology, there are two forms of recrystallization: recrystallization by inversion and recrystallization by replacement.
Inversion is a complex form of neomorphism in which the recrystallization process transforms polymorphs into different polymorphs. Polymorphs, to be clear, are minerals that differ from one another in their crystalline structures but are otherwise composed of identical quantities and types of elements. As with any change in mineral structure, the alteration of polymorphs occurs most often in environments characterized by certain optimal temperatures and pressure levels. Optimal temperature and pressure levels vary in accordance to the type of mineral(s) under consideration.
Specifically, an increase in temperature incites an increase in atomic vibrations, which instigates atoms to distance themselves from each other. The excited atoms continue expanding until the increase in temperature can no longer provide the energy necessary for further expansion. Affected crystals and/or minerals are forced to adapt to the aforementioned atomic changes by expanding their skeletal structures, which results in visible changes of the aforementioned crystals and minerals. All the while, pressure continuously compresses the altered crystals and minerals into dense structures; the final product is a collection of chemically-identical crystals that differs structurally and visibly from its predecessor.
A molecular vibration is excited when the molecule absorbs energy, ΔE, corresponding to the vibration's frequency, ν, according to the relation ΔE = hν, where h is Planck's constant. A fundamental vibration is evoked when one such quantum of energy is absorbed by the molecule in its ground state. When multiple quanta are absorbed, the first and possibly higher overtones are excited.
Water-dispersible conjugated polymer microspheres were obtained by enwrapping with graphene oxide (GO) nanosheets. Simply mixing the polymer microspheres and GO in water results in an exclusive formation of GO-wrapped microspheres. The photoluminescence (PL) spectra of the GO-wrapped single microsphere show whispering gallery modes, in which the PL lines are broadened in comparison with bare microspheres without GO. The broadening is attributed to scattering and reabsorption of the confined PL.
Nanocarbons such as graphene and carbon nanotubes (CNTs) are materials with promising electronic and mechanical properties, such as high flexibility, high stiffness, and light weight.1 However, nanocarbons hardly disperse in a medium because of their poor solubility in both water and organic solvents, which makes it difficult to fabricate composites with other materials such as polymers.2 Recently, conjugated polymers (CPs) were found to adsorb strongly on nanocarbons via π–π interaction.3 As a result of the strong adsorption of CPs, the nanocarbon composites become highly dispersive in various organic solvents. On the other hand, graphene oxide (GO) has also received increasing attention due to its oxidizing, electron-accepting, and catalytic properties.4 Due to charged substituents such as carboxy, epoxy, and hydroxy groups at the periphery of GO, composites of GO with nanocarbons and CPs are highly dispersive in water.5
In this letter, we show that self-assembled CP microspheres can be entirely wrapped with GO. As a result of being wrapped by GO, the microspheres become dispersible in water. The GO-wrapping of the microspheres is confirmed by electron microscopy and surface potential studies, and further evidenced by micro-photoluminescence (µ-PL) spectroscopy. The whispering gallery mode (WGM) PL lines from GO-wrapped CP microspheres are noticeably broadened, possibly because of light scattering and reabsorption by the GO layers at the surface of the microspheres.
Whispering-gallery waves, or whispering-gallery modes, are a type of wave that can travel around a concave surface. Originally discovered for sound waves in the whispering gallery of St Paul's Cathedral, they can exist for light and for other waves, with important applications in nondestructive testing, lasing, cooling and sensing, as well as in astronomy.
Whispering-gallery waves were first explained for the case of St Paul's Cathedral circa 1878[3] by Lord Rayleigh, who revised a previous misconception[4][5] that whispers could be heard across the dome but not at any intermediate position. He explained the phenomenon of travelling whispers with a series of specularly reflected sound rays making up chords of the circular gallery. Clinging to the walls the sound should decay in intensity only as the inverse of the distance — rather than the inverse square as in the case of a point source of sound radiating in all directions. This accounts for the whispers being audible all round the gallery.
Rayleigh developed wave theories for St Paul's in 1910[6] and 1914. Fitting sound waves inside a cavity involves the physics of resonance based on wave interference; the sound can exist only at certain pitches as in the case of organ pipes. The sound forms patterns called modes, as shown in the diagram.
Many other monuments have been shown to exhibit whispering-gallery waves, such as the Gol Gumbaz in Bijapur and the Temple of Heaven in Beijing.
In the strict definition of whispering-gallery waves, they cannot exist when the guiding surface becomes straight. Mathematically this corresponds to the limit of an infinite radius of curvature. Whispering-gallery waves are guided by the effect of the wall curvature.
Whispering-gallery waves for sound exist in a wide variety of systems. Examples include the vibrations of the whole Earth or stars.
Such acoustic whispering-gallery waves can be used in nondestructive testing in the form of waves that creep around holes filled with liquid, for example. They have also been detected in solid cylinders and spheres, with applications in sensing, and visualized in motion on microscopic discs .
Whispering gallery waves are more efficiently guided in spheres than in cylinders because the effects of acoustic diffraction (lateral wave spreading) are then completely compensated.
Whispering-gallery waves exist for light waves.[18][19][20] They have been produced in microscopic glass spheres or tori,[21][22] for example, with applications in lasing,[23] optomechanical cooling,[24] frequency comb generation[25] and sensing.[26] The light waves are almost perfectly guided round by optical total internal reflection, leading to Q factors in excess of 1010 being achieved.[27] This is far greater than the best values, about 104, that can be similarly obtained in acoustics.[28] Optical modes in a whispering gallery resonator are inherently lossy due to a mechanism similar to quantum tunneling.
As a result, light inside a whispering gallery mode experiences a degree of radiation loss even in theoretically ideal conditions. Such a loss channel has been known from research on optical waveguide theory and is dubbed tunneling ray attenuation[29] in the field of fiber optics. The Q factor is proportional to the decay time of the waves, which in turn is inversely proportional to both the surface scattering rate and the wave absorption in the medium making up the gallery. Whispering-gallery waves for light have been investigated in chaotic galleries,[30][31] whose cross-sections deviate from a circle. And such waves have been used in quantum information applications.[32]
Whispering-gallery waves have also been demonstrated for other electromagnetic waves such as radio waves,[33] microwaves,[34] terahertz radiation,[35] infrared radiation,[36] ultraviolet waves[37] and x-rays.[38] More recently, with the rapid development of microfluidic technologies, many integrated whispering gallery mode sensors, by combining the portability of lab‐on‐chip devices and the high sensitivity of whispering gallery mode resonators have emerged.[39][40] The capabilities of efficient sample handling and multiplexed analyte detection offered by these systems have led to many biological and chemical sensing applications, especially for the detection of single particle or biomolecule.[41][42]
detection of single particle or biomolecule.[41][42]
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mid 17th century: from French détachement, from détacher ‘to detach’ (see detach).
disconnection (countable and uncountable, plural disconnections)
Severance of a physical connection.
detect ion
As we already have seen, a good inverse linear relationship was found between barrier height (ΔH‡) and ionization energy (electron detachment energy) of X−—a high electron detachment energy, as for F−, gives a low barrier.32 This indicates that a transition state with strong electrostatic character has a low barrier due to decreased electron repulsion, while one with strong covalent character gives a high barrier—in agreement with Bader's QTAIM analysis also discussed earlier.55,56 Further support comes from the studies of Ochran et al. and Galabov et al. of allylic and benzylic substitution reactions, as we also have seen above.116,117 In the latter study, it was even found that the barrier height correlates with the electrostatic potential calculated at central carbon atom. An equivalent descriptor is the orbital energy of the well-localized 1s orbital of the central carbon atom.120
ionization energy, also called ionization potential, in chemistry and physics, the amount of energy required to remove an electron from an isolated atom or molecule
radical, also called Free Radical, in chemistry, molecule that contains at least one unpaired electron. Most molecules contain even numbers of electrons, and the covalent chemical bonds holding the atoms together within a molecule normally consist of pairs of electrons jointly shared by the atoms linked by the bond.
The scientists propose that the DNA polymerase alpha protein, which sits on the double helix strand, sends electrons down the strand to DNA primase. DNA primase accepts the electrons, becomes reduced, and lets go of the DNA. This donation and acceptance of electrons is done with the help of the iron-sulfur clusters.