When you're spinning, you have to spin around like a son of a bitch. Lee Iacocca

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Clear guys, not bought scientists, just as we have long argued: vaccines are not vaccines, but injections against false [Covid-19] contain nanotechnology and graphene oxide .

An urgent review of injections [Covid-19] has been published, which clearly shows the detection of nanotechnology and graphene oxide in injections of Pfizer and Moderna mRNA, as well as in injections of viral vectors AstraZeneca and Janssen. The new review confirms the findings of many other scientists from around the world.

Graphene oxide is detected in the immune system as if it were a pathogen. Once injected, it affects the central nervous system, potentially causing paralysis, strokes, and nervous system changes.

Source

https://expose-news.com/2022/11/02/scientists-covid-vaccines-nanotechnology-graphene/

Graphene oxide (nanocarbon) is the new hero of the Russians from Novosibirsk science Toli Chubais of Putin's left hand! And you all wonder why there are so many corpses and disabled people. So these guys don't work on the little things.

It is a dual-use material. You'll hear a lot more about him. It is used in electronics, medicine, military affairs - everywhere! It is found on masks and other household items in the form of black "worms" - these are carbon nanotubes. CNT can be found on the skin of a man who left Joe Biden.

Do you know the whispering degenerate freak grandfather what the Americans will do to you when it finally comes to these bad things that you have been doing all your adult worthless life as a communist degenerate?

Growing ultra-long carbon nanotubes

https://youtube.com/watch?v=VyULskYuGvg&feature=share

Graphene oxide

Abstract

This invention relates to a method for the production of graphene oxide and its use in various applications. The invention provides a method for the preparation of graphene oxide which involves treating a mixture of graphene oxide and impurities with a solution of a base. The impurities in the graphene oxide include oxygen-containing species that are associated with it i.e. bound to the graphene oxide but which are not covalently bonded to the graphene. The graphene oxide of the present invention has improved purity relative to the poorly characterised graphene oxide that is produced by existing methods.

Classifications

C01B32/19 Preparation by exfoliation

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WO2012046069A1

WIPO (PCT)

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Other languages French Inventor Ian KinlochRobert YoungJonathan P RourkeNeil R Wilson

Worldwide applications

2010 GB 2011 US KR EP CN JP WO

Application PCT/GB2011/051918 events

2010-10-07

Priority to GBGB1016925.8A

2010-10-07

Priority to GB1016925.8

2011-10-06

Application filed by The University Of Manchester

2012-04-12

Publication of WO2012046069A1

Info Patent citations (2) Non-patent citations (24) Cited by (41) Legal events Similar documents Priority and Related Applications External links EspacenetGlobal DossierPatentScopeDiscuss

https://patents.google.com/patent/WO2012046069A1/en

Graphene oxide

Classifications

C01B32/23 Oxidation

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GB201016925D0

United Kingdom

Find Prior Art Similar

Current Assignee University of Manchester

Worldwide applications

2010 GB 2011 US KR EP CN JP WO

Application GBGB1016925.8A events

2010-10-07

Application filed by University of Manchester

2010-10-07

Priority to GBGB1016925.8A

2010-11-24

Publication of GB201016925D0

Status

Ceased

Info Patent citations (2) Cited by (41) Legal events Similar documents Priority and Related Applications External links EspacenetGlobal DossierDiscuss

https://patents.google.com/patent/GB201016925D0/en

In general, graphene oxides in terms of sorption capacity are significantly superior to polymer-based ion exchange resins and other traditional sorbents. This is the essence of the interest in graphene oxides to create a new generation of super-sorbents.

Sorption records of graphene oxides can be realized in several ways, for example, absorption; adsorption; ion exchange; physical adsorption; chemosorption; with the establishment of covalent or non-covalent bonds; with the establishment of hydrogen bonds; Van der Waals interaction.

As a result of sorption, colloids can be formed, coagulation of the substance and the subsequent formation of precipitation can occur.

Specialists know five main varieties of graphene oxides in the shape of particles:

films on inert substrates;

nanopowders with a size of flat particles (scales) of the order of 905 nm;

flakes with a particle size of 1-5 μm;

ribbons (with a length-to-width ratio of more than 10);

pompoms with the size of spherical particles with a diameter of 3-6 μm.

The most unusual are pompoms, that is, intergrowths of graphene petals in the form of a pompom or in the form of children's balls made of corrugated paper. They were only obtained in 2014 at Yonse University (Seoul, South Korea).

Electronic photographs of graphene oxide pompoms

In terms of oxidation, graphene oxides vary greatly and can contain from 3% to 40% oxygen by weight. The wide limits of chemical composition (taking into account additional alloying atoms and groups) make it difficult to classify and standardize graphene oxides. Moreover, the composition can change not discretely, but continuously. However, for commercial needs, you can take the experience of classifications of natural diamonds, where the international classification consists of 3 thousand varieties that are absolutely understandable to professionals.

About 50 producers of graphene and its derivatives compete fiercely, including in pricing policy. Leading suppliers, Advanced Chemicals Suppliers (USA), Perpetuus Carbon (England), Graphenea (Spain).

In 2014, the price of an aqueous emulsion of graphene oxide of high quality was at the level of $ 50 / y. In China, products of variable quality were offered for $ 20 / g. These prices are comparable to the price of platinum and some rare earth metals, which are widely used in modern technical devices. That is, graphene oxides have already overcome the price psychological barrier and they are used on an industrial scale.

In the U.S., National Nanomaterials has on the market a commercial product, Graphenol, a family of functioned graphenes, including graphene oxide.

Methods for obtaining graphene oxides

Four main methods for producing graphene oxide are known. All of them use the oxidation of pieces of graphite in an aqueous medium of strong acids (for example, concentrated sulfuric acid) in the presence of highly active oxidants. These methods were followed by names: Staudenmaier, Hofmann, Brody and Hammers. There are many varieties of them.

Thus, in the Russian Russian Chemical Technical University named after D.I. Mendeleev, the Vietnamese researcher Nguyen Huu Van in 2014 proposed a two-stage method for obtaining graphene oxide without the use of strong oxidizing agents - by anodic oxidation of graphite in sulfuric acid with microwave activation of the process.

For exotic forms, such as pompoms, separate technologies were developed.

Raw materials for graphene oxides are relatively cheap. Industrial devices made of corrosion-resistant alloys are expensive, but not insane. The production infrastructure is obvious – on the basis of modern chemical plants. The only problem is in the technologies that the authors keep in the strictest confidence. Intellectual property in 2014 sat in the price of ~90% of the market value of goods based on graphene oxides.

First two-dimensional

Graphene oxide is the first two-dimensional material to reach the stage of commercial embodiment. Figuratively speaking, he paved the way for other two-dimensional materials, such as phosphorene (phosphorus mesh), silicene (silicon grid), silicatene (silicon dioxide mesh), germanene (germanium mesh), arsinen (arsenic grid), and two-dimensional polymers.

From nano- and microparticles of graphene oxide, they learned how to make centimeter samples. [Chinese] On the territory of China, more precisely, because we are sure there were scientists from other countries of the world (Russia, USA, Germany), since there are no Chinese scientists in nature and there is no Chinese science in the country of degenerates either. Nevertheless, in this territory, narrow-eyed savages allegedly developed a new material and announced it in 2012-2013. It is so light that it is held on to the flower petals. The material consists of graphene oxide and lyophilized carbon. This spongy matter has a density of only 0.16 mg/cm3, which makes the substance the lightest of the solid materials in the world.

Graphene oxide-based spongy fabric sample

Fortune tellers who call themselves experts predicted graphene and graphene oxides a phenomenal increase in commercial consumption.

In the report "Global Graphene Market (Product Type, Application, Geography) – Size, Share, Global Trends, Company Profiles, Demand, Insights, Analysis, Research, Report, Opportunities, Segmentation and Forecast, 2013-2020", the authors predicted market growth from $ 20 to $ 149 billion, or 44% per year.

In the global market, the following corporations are leading in terms of activity: CVD Equipment Corporation, Graphene Nanochem PLC, Vorbrck Materials, XG Sciences, Haydale Limited, Graphenea, Graphene Laboratories, Bluestone Global Tech, Angstron Material, Inc., ACS Material, LLC.

Chersha La Pham, as they say, look here.

Technological scheme for obtaining pompoms from graphene

The ultrasonic nozzle emits microdroplets of a suspension consisting of nanoscale flakes of graphene oxide. The droplets enter a hot (160°C) solution of reducing agent in an organic solvent. In the "hot bath" graphene oxide is reduced. The graphene scales then stick together in the shape of a pompom.

In the figure, the scheme of interaction of two peptides through the sorption stage of one of them on the surface of graphene oxide

Research staff at Fuzhou University, China 🇨🇳 Sorption system based on graphene oxide is an inexpensive method for determining protein-protein interactions. To develop peptide-based drugs, it is necessary to determine how a disease-related protein interacts with peptides. And for this it is necessary to be able to detect a signal indicating the interaction of proteins with peptides. Usually, fluorescence resonance energy transfer (FRET) spectroscopy is used for this.

Graphene oxide quenches the fluorescence of a peptide labeled with pyrene fragments (asterisk with a green chain) when the pyrene fragment approaches the carbon layer (the central fragment of the pattern). However, when a protein binds to a peptide, the peptide breaks away from the graphene oxide layer and fluorescence resumes (pink asterisk on the right fragment).

Why does unwashed Russia and the international terrorist Putin need all this below 👇

Financing of work on graphene oxide in the Russian Federation is carried out by dozens of grants in several areas, for example, Putin's grants to the Russian Federation MK-7155.2013.3 and MK-5847.2014.3; RFBR N12-03-00533, 12-03-00615, 14-23-01015 and 14-29-04071; within the framework of the Program for Basic Research of THE OHNM RAS N OH2.4; Rusnano grants (MSU-06/1 agreement) and the UMNIK program, etc.

Graphene and its derivatives include single-layer graphene, multi-layer graphene (FLG), graphene oxide (GO), reduced graphene oxide (rGO), graphene nanolayers (GNS), graphene nanofibers, etc. GO is one of the most important chemical derivatives of graphene from the graphene family of nanomaterials (GFNs), which is attracting increasing attention for its potential biomedical applications. Graphene-based materials typically range in size from a few to hundred nanometers and are 1-10 nm thick, which is also the definition of "nanoparticles" or "nanomaterials." Due to their exceptional physical and chemical properties, graphene materials are widely used in various fields, including energy storage; nanoelectronic devices; batteries; and biomedical applications such as antibacterial drugs, biosensors, cell imaging, drug delivery, and tissue engineering.

https://telegra.ph/Inglourious-Basterds-01-04

Anatoly Chubais will become the president's special representative for relations with international organizations. What exactly he will supervise is still unclear: formally, in the sphere of his competence - the "sustainable development" of the country