GRAPHENE & HYDROGEL. EX FEMA- CELESTE SOLUM ‘REVEALS’ THE DETAILS / The Zeta Agenda: The Zetas don’t just want our planet — they want our bodies to incarnate in, but our present DNA does not resonate with their Soul group. / Various research papers on Graphene Hydrogel / DARPA Hydrogel in COVID Vaccine can create crystals, nano-antennas to receive signals from 5G Tower: expanding antenna inside human body. These antenna can receive signals and commands from 5G towers. These antenna can expand the whole body as DARPA hydrogel invades the whole body. No organ nor cell is spared by DARPA hydrogel.

VSF: Celeste Solum gives us the benefit of her reading hundreds of publications we are not subscribed to. What she says is not for the faint of heart, but I believe that it is always better to know. For me this is simply the technology of the Zeta Reticuli who are taking over our bodies. Graphene Oxide can be distributed through the air, breathed, thus aerosolized, and could have been in the chemtrail operations for years! The photos are mine.

I have included what I could find on graphene hydrogel as evidence that this is real and has been in the works for some time now. Look at the long list of ‘citings’ and notice how many are Chinese. As I have said, I believe China is the control seat of the Zeta Agenda.

We all have decisions to make about our future. Better that we are informed.


Graphene quantum dots synthesis and energy application: a review / 10 June 2020
• S. Akash Prabhu,
• V. Kavithayeni,
• R. Suganthy &
• K. Geetha 
Carbon Letters volume 31, pages 1–12 (2021)Cite this article
Graphene Quantum Dots (GQDs), zero-dimensional nanoparticles which are derived from carbon-based sources owned the new pavement for the energy storage applications. With the varying synthesis routes, the in-built properties of GQDs are enhanced in different categories like quantum efficiency, nominal size range, and irradiation wavelength which could be applied for the several of energy and optoelectronics applications. GQDs are especially applicable in the specific energy storage devices such as super capacitors, solar cells, and lithium-ion batteries which were demonstrated in this work. This paper critically reviews about the synthesis techniques used for the GQDs involving energy storage applications with increased capacitance, energy conversion, retention capability, and stability.

Graphene quantum dot-based hydrogels for photocatalytic degradation of organic dyes
Author links open overlay panelAnttonIbarbiaaLauraSánchez-AbellaaLuisLezamabHans J.GrandeaVirginiaRuiza


Graphene oxide quantum dots with enzymatic activity were crosslinked in hydrogels.

GOQD-based hydrogels exhibited high peroxidase activity for TMB oxidation with H2O2.

Hydrogels had high catalytic activity for degradation of Rhodamine B in darkness.

Catalytic activity of hydrogels was notably enhanced by visible light irradiation.

Hydrogels retained photoactivity after months stored wet and being dried-rehydrated.

Graphene oxide quantum dots (GOQD) covalently immobilized in hydrogels have shown great promise as artificial enzymes for the photodegradation of the organic dye rhodamine B (RhB). Suitably functionalized with cross-linkable 3-(triethoxysilyl)propyl methacrylate (MPS) units, GOQD-MPS were incorporated by free radical copolymerization into poly[2-(Methacryloyloxy)ethyl]trimethylammonium]-co-(3-Sulfopropylmethacrylate) 50:50 (A50coS50) hydrogels with known antiadhesive properties. The peroxidase mimetic activity of GOQD solutions for the oxidation of chromogenic peroxidase substrate 3,3′,5,5′-tetramethylbenzidine (TMB) in presence of hydrogen peroxide increased significantly upon functionalization with MPS. Consequently, composite GOQD-A50coS50 hydrogels also exhibited high peroxidase activity for TMB oxidation. Moreover, GOQD-MPS solutions and GOQD-A50coS50 hydrogels showed remarkable catalytic activity for degradation of model RhB dye in darkness, an activity that was notably enhanced by visible light irradiation. The photoactivity depended on GOQD-MPS loading and hydrogel volume. Interestingly, GOQD-A50coS50 hydrogels retained the high photocatalytic activity after several months stored wet as well as after undergoing drying-rehydration processes, key from a practical point of view for applications in water treatment. The activity of rehydrated hydrogels for RhB photodegradation was only reduced by 15% compared to the activity of a non-dried hydrogel under the same test conditions.

Self-assembly of graphene quantum dots into hydrogels and cryogels: Dynamic light scattering, UV–Vis spectroscopy and structural investigations
Author links open overlay panelAhmadAllahbakhshAhmad RezaBahramian

Graphene quantum dots aerogels are fabricated through the self-assembly process.
The self-assembly process is investigated using dynamic light scattering technique.
Fabricated hydrogels and aerogels are hyper porous and have a high surface area.

In this work, the gelation mechanism of graphene quantum dots (GQDs) into hydrogels is investigated using dynamic light scattering and ultraviolet-visible techniques. Hydrogels are prepared through the hydrothermal reduction of concentrated GQDs solutions (20–50 mg/mL) using l-ascorbic acid as the reducing agent. At early stages of the gelation process (first 2 h), J-type aggregation of GQDs results in the formation of particles with dimensions around 10 nm. As the gelation process proceeds, formation of larger particles through the aggregation of almost all GQDs results in slower dynamics and hindered Brownian motions in the solution. With the reduction of a majority of edge-carboxyl groups through six first hours of the hydrothermal process, a change in the self-assembly mechanism takes place (from J-type to H-type). A GQDs hydrogel, with an interconnected colloidal morphology and a very low density (~0.009 g/cm3) can be obtained after 8 h of the hydrothermal process. The specific surface area of the prepared GQDs hydrogel, fabricated through the hydrothermal reduction of the 20 mg/mL GQDs precursor solution, is >1000 m2/g. Hydrogels and cryogels prepared using GQDs as the building units can be applicable where hyper-porous structures with large number of available sites are needed.

Space Traveler in Alabama

DARPA Hydrogel in COVID Vaccine can create crystals, nano-antennas to receive signals from 5G Tower
they live2 Uncategorized May 19, 2021 3 Minutes

DARPA Hydrogel & lithium mixture immediately reacts with living structures to form crystals that are directionally oriented to the pineal gland, which has its own electromagnetic field.
The crystals are conductive due to the lithium contained in it. The crystals can receive the signal from the transmitter to the cell and transmit signals from the cell to the transmitter. These are actually nano-antennas.

DARPA Hydrogel Crystals

That looks really expanding antenna inside human body. These antenna can receive signals and commands from 5G towers. These antenna can expand the whole body as DARPA hydrogel invades the whole body. No organ nor cell is spared by DARPA hydrogel.

Vaccine for Coronavirus makes you a Biological Robot!
Graphene Hydrogel & Quantum Dot Vaccine Application is animal tagging. We are considered as animals in Global Governance System.
Anti-counterfeiting dyes and paints basically that is the patenting of a human being who has taken the mark of his owner.
Chemical sensing and fluorescent tagging as what we’ve seen in genetic modification GMO foods. They started out Jellyfish fluorescent tagging to see when they altered species if it would carry on to the next generation.
The quantum dots are part of the hydrogel network. In this form, quantum dots can be utilized in several applications that benefit from their unique properties.
As a new carbon based nano material, graphene has exhibited unique advantages in significantly improving the combination properties of traditional polymer hydrogels. The specific properties of graphene such as a high electrical conductivity, high thermal conductivity and excellent mechanical properties have made graphene not only a gel later to self-assemble into graphene-based hydrogels (GBH) but also a filler to blend with small molecules and macromolecules for the preparation of mutifunctional graphene based hydrogels.
People allowing hydrogel into their bodies are hybridizing their body shape-shifting into a biological robot.
The hydrogel filler acts as glue within your body to network with Artificial Intelligence (AI) as a computer interface, and you are being reduced to a node in the Internet of things.
Graphene is a new nano material with strict 2 dimensional layer structure with excellent mechanical highly electrical and thermal properties. Graphene is the ideal filler for polymer-based nanocomposites.
Your body becomes a living polymer, a substance that has a molecular structure consisting deeply and entirely of large number of synthetic organic materials that are used in plastics and resins that will eventually replace your DNA, your blood, your cells, your tissues and your organs as the hydrogel nanoparticles self-assemble.
Think of this as an invisible invasion transforming you from a human to a synthetic entity known as SynBio.
Hydrogel is a moderate cross-linked and branched polymer with 3 dimensional network structures that means it will fill every crack and crevice of your body. There will be nothing hidden or safe that it does not invade.
Hydrogel has ability to absorb large quantities of water, and it swells quickly. It is soft, lasting and biologically compatible. Your body will not reject this invasion because it does not see it as an enemy or being hostile to your humanity.
As it absorbs the water, your body will wither (become dry and shriveled), and it will become sickly and like a rubber band stretched to its maximum, you are going to break physically, mentally and spiritually.
Graphene also has magical and conductive qualities making your body and mind a receptor for any message that the controllers want to embed.
Scientists and researchers are using the self-assembling gel later to create a synthetic scaffold system inside your body while the filler replaces your human parts with artificial ones that are predisposed to a collective or global fascist order.
a synthetic scaffold system

Self-assembly process is spontaneous, and you become bonded to the network system. Your human bonding that you naturally have in your body is replaced. Your body and mind will respond the applied electrical currents, and you become a mandatory transmitter that transmits essential information about your body and mind to Government and Spiritual Controllers.
Do not think that hydrogel does NOT alter your DNA. Someday, it is going to replace the DNA for anyone allowing hydrogel to enter their body.
Your body become a mechanical slave!

Synthesis of graphene quantum dots and their applications in drug delivery

•   October 2020
•   Journal of Nanobiotechnology 18(1):142


Changhong Zhao

Xuebin Song

Ya Liu
• Chalmers University of Technology

Yifeng Fu

Abstract and Figures
This review focuses on the recent advances in the synthesis of graphene quantum dots (GQDs) and their applications in drug delivery. To give a brief understanding about the preparation of GQDs, recent advances in methods of GQDs synthesis are first presented. Afterwards, various drug delivery-release modes of GQDs-based drug delivery systems such as EPR-pH delivery-release mode, ligand-pH delivery-release mode, EPR-Photothermal delivery-Release mode, and Core/Shell-photothermal/magnetic thermal delivery-release mode are reviewed. Finally, the current challenges and the prospective application of GQDs in drug delivery are discussed.

VSF: My term for these bizarre cloud forms is the “Drippers” as they appear to drip and spread down their toxic metal particles.

Preparation of Graphene Quantum Dots from Pyrolyzed Alginate
• Pedro Atienzar†

• Ana Primo†

• Cristina Lavorato†‡

• Raffaele Molinari‡

• Hermenegildo García*†

Pyrolysis at 900 °C under an inert atmosphere of alginate, a natural widely available biopolymer, renders a graphitic carbon that upon ablation by exposure to a pulsed 532 nm laser (7 ns, 50 mJ pulse–1) in acetonitrile, water, and other solvents leads to the formation of multilayer graphitic quantum dots. The dimensions and the number of layers of these graphitic nanoparticles decrease along the number of laser pulses from 100 to 10 nm average and from multiple layers to few layers graphene (1–1.5 nm thickness), respectively, leading to graphene quantum dots (GQDs). Accordingly, the emission intensity of these GQDs increases appearing at about 500 nm in the visible region along the reduction of the particle size. Transient absorption spectroscopy has allowed detection of a transient signal decaying in the microsecond time scale that has been attributed to the charge separation state.

Cited By

This article is cited by 55 publications.
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