See discussions, stats, and author profiles for this publication at: https://www.researchgate.

net/publication/358150548

CoVid vaccines based on graphene, nanonetwork and Internet of Nanothings

(IoNT)

Preprint · January 2022

DOI: 10.13140/RG.2.2.36070.29766/1

CITATIONS READS

0 442

1 author:

Kira Smith
MilMed Corporation
23 PUBLICATIONS   5 CITATIONS   

SEE PROFILE

Some of the authors of this publication are also working on these related projects:

Covid-19 View project

All content following this page was uploaded by Kira Smith on 27 January 2022.

The user has requested enhancement of the downloaded file.

27 Jan. 2022
I am writing this article because I think that the project behind CoVid-19 and vaccines is not yet fully
understood, as it may come to be.

Figure 0: is a Micrograph of a Carbon Cluster of Reduced Graphene Oxide (rGO or Graphene Hydroxide) Viewed in the Live Unstained Human
Blood with pHase Contrast Microscopy at 1500x. Note that the Red Blood Cells are Clotting in and Around the rGO Crystal in a Condition Known
as Rouleau! A French Word Which Means to Chain. Dr. Robert O. Young, Profiles in Medical Microscopy, Hikari Omni Publishing

It is now well established that the carbon-based, graphite-derived element graphene, which forms
nanotubes (CNTs), is present in sera, in addition to the presence of other materials derived from it, such
as graphene oxide (GO). Graphene is a nanomaterial that has outstanding physical, thermodynamic,
electronic, mechanical and magnetic properties; it can be used as a superconductor, transducer, absorber
of electromagnetic waves, emitter and receiver of signals. It has also been observed that, taking a vial of
Pfizer vaccine and letting the hydrogel dry, after 3-4 days the presence of nanocircuits can be noticed
under the microscope1: it is the graphene that reacts to electromagnetic fields and electromagnetic
microwaves, self-assembles, according to nanopatterns based on DNA13 to mark the order of construction
and electrophoresis/teslaphoresis to trigger the process in the materials of the solution (hydrogel, whose
existence in the "vaccine" has been confirmed by the micro-Raman analysis of Prof. Campra (2021), in
which as a result were obtained peaks with values close to 1450, which means it is precisely polypyrrole,
polyolefin, polyacrylamide, PVA or PQT-12, recognized in the scientific literature as gels and derivatives), in
electronic nanocircuits, with real nanoscale components, such as nanorouter, nanoantenna, etc., formed
of graphene, which acts as a signal repeater, since it is radio modulable, i.e. able to absorb
electromagnetic waves and multiply their radiation; these electronic components are organized in
Quantum Dots (GQDs) and Quantum Cells (QCA), particles that enjoy the above properties of graphene,
in an exponentially greater way, thanks to the Quantum Hall effect, especially in environments such as
the human body. This will create an intracorporeal network or nanonetwork, which will detect every vital
parameter, as well as every minimal variation inside and outside the body, through the epidermis, thanks
to the advanced and compressed electronics, superimposed on 3 dimensions.

Figure 1: Self-assembly of a quantum dot circuit from a DNA pattern. The circuit
wire lines are very similar to those observed in the vaccine sample (Hu, W.;
Sarveswaran, K.; Lieberman, M.; Bernstein, GH 2005)
In the blood of vaccinated persons and also in a vial of Pfizer vaccine, samples containing parallel and
perpendicular lines, quadrangular or cubic structures, composed of crystallized graphene, were
observed by various electron microscopy (TEM), phase-contrast, MRI and other techniques, suggesting
artificial products, referring to electronic circuits2. This was possible through a process of rasterization,
focusing and delimitation of the edges of the image. What was detected was the circuit of a nanorouter,
which we will see described later, and suggests, along with other images detected, the presence of a
nanonetwork inside the human body.
This is how a nanonetwork works in a biological environment.

Figure 2: Pfizer vaccine sample containing apparently artificial structures resembling electronic circuits (Campra P. 2021)

The packet routing system used is called CORONA (COordinate and ROuting System for
NAnonetworks) 3.

Figure 3: The cluster selection algorithm is shown in the left box and the DCCORONA routing process on the right. (Bouchedjera, IA; Louail, L.;
Aliouat, Z.; Harous, S. 2020)
This model requires the configuration of nanonodes distributed throughout the body, i.e., nanosensors
and nanoantennas, which have the ability to achieve high transmission rates over very short distances
when operating in the most promising operating spectrum of the Terahertz band (0.1 - 10.0 THz), which
propagate the signal to the other nanonodes; some of them must be fixed and are positioned on the
body tissue (endothelium, blood vessel walls and tissues of the various organs) like an anchor, and
triangulate the position of the other nanonodes, measuring their distance and the hops in the connection;
others are instead mobile, since they are present in the circulatory system, i.e. dynamic with the ability to
aim at specific targets. In the operational phase, the routing uses the appropriate subset of anchors,
required by the sender of the packet, to transmit the data. This system operates efficiently, resulting in
packet retransmission and very low loss rate, promoting energy efficiency4.

Figure 4: The figure on the left shows anchored nanonodes facilitating the routing and addressing of data packets, while on the right is shown a
limitation in anchor routing (Tsioliaridou, A.; Liaskos, C.; Ioannidis, S.; Pitsillides, A. 2015)

Sending data outside the body must be sufficiently powerful, while maintaining optimal signal clarity, since
skin hydration, propagation distance and frequency range affect the loss of trajectory that blurs the signal
and with it the message; it is therefore important to use different frequencies: 0.1 - 4 THz to pass through
the epidermis; for signal propagation through the blood and resistant gases in the lungs, the range is: 0.01
- 0.96 THz.
Subsequently, the CORONA model was improved and simplified, allowing the transmission of packets to
more distant anchors, avoiding intermediate steps: it was then completed with a multi-hop routing
scheme based on a distributed cluster, with cluster selection algorithm; it was then renamed
DCCORONA3.
 Figure 5: Data packet structure in the DCCORONA model (Bouchedjera, IA; Louail, L.; Alioutat, Z; Harous, S.
2020)

The protocol used in nanocommunications is called TS-OOK (Time-Spread On-Off Keying) 5, encoding
the activation and deactivation of time propagation on and off, It is the appropriate activation method
by which request-response/client-server mechanisms are enabled in this type of networks. A logical 0 or
1 is represented by silence (short pulsi) with a relatively long transmission interval (long pulse),
respectively; this simplifies the receiver and avoids the probability of collisions, as well as recovering the
signal and interpreting it without noise or interruptions, given its simplicity. Basically, data packets and
headers are encoded with 0s and 1s, according to IEEE communication protocols. The binary-coded signals
are then transformed into data packets by the demux circuit. The parallel-to-series converter, on the
other hand, is a circuit that can take different sets of input data, carry them on different QCA wires, and
transmit them at different times on the output wires.
 Figure 6: Demux circuit tests provide evidence of how TS-OOK signals are interpreted and converted
to binary code (Sardinha, LH; Costa, AM; Neto, OPV; Vieira, LF; Vieira, MA 2013)

This explains why devices with Bluetooth, such as smartphones, are able to detect MAC addresses,
originating from people who have received the "vaccine": it is inherently taken for granted the presence of
a Media Access Control (MAC), in particular it would be likely the DRIH-MAC model, which is a receiver-
initiated protocol for communication between nanonodes in a wireless electromagnetic nanoreticle, with
the aim of maximizing energy consumption; distributed and predictive technique to access the media;
the scheduling of communications is in coordination with the process of energy harvesting, which is
optimized by 50% compared to the MAC protocol and this is an essential factor for the limitations
related to the scale and application environment.
The phenomenon regarding the attraction of coins by inoculates could also be explained: although neither
graphene nor its derivatives are magnetic, both graphene and graphene oxide can conduct enough
electricity across cell membranes to magnetize nearby superparamagnetic particles, to cause
widespread magnetization of people receiving the vaccine.6
In order to synchronize communications between nanonodes, the presence of a nano-CPU is essential,
which requires at least one oscillator, which defines the clock frequency (oscillations per second), measured
in Hertz (Hz)7.
In-vivo interaction of nano-oscillators is given by the ability to activate them, via bioelectric signals and
can be used to selectively rectify the operating frequency of a given field. For example, nano-oscillators
can harvest wireless energy and produce wireless electrical stimulation of cells such as neurons.
 Figure 7: Circuit diagram of the RO integrated
monolayer graphene ring oscillator. (Guerriero, E.;
Polloni, L.; Bianchi, M.; Behnam, A.; Carrion, E.;
Rizzi, LG; Sordan, R. 2013)

In the topology hierarchy, there are next the nanorouters, which receive signals from the nanonodes,
process them and send them to the nanointerfaces, which will emit them outside the body, with signal
effective to cross the skin barrier. They are needed to route and decode the signals for sending, but
also for receiving.
To form a nanorouter it is necessary to have wire crossings that create several overlapping circuit
structures: logic gates, demultiplexer (demux) and parallel-series converter.5
 Figure 8: Circuit details to convert TS-OOK signals in series to a parallel output, confirming one of the typical tasks of a
router (Sardinha, LH; Costa, AM; Neto, OPV; Vieira, LF; Vieira, MA 2013)

Going back to the circuit observed by Prof. Campra during the observance with electron microscopy of
the blood of vaccinated people: the quantum cell (QCA) consists of 4 quantum dots (GQDs), whose
polarization is variable. It is possible to distinguish the binary code, consisting of 0 and 1, based on the
positive or negative charge of the quantum dots. A QCA cell would require 4 GQDs (regions where an
electric charge may or may not be localized) to compose itself. Each cell has 2 free moving electrons,
which can create tunnels between the quantum dots, but tunneling to the outside of the cell is not
allowed, due to a high potential barrier. This circuit represents a nanorouter, but through the combination
of QCA cells it is possible to obtain electronic schemes of transistors, processors, multiplexers,
demultiplexers, etc., with various functions and shapes.8
Figure 9: QCA cell consisting of 4 quantum dots (Sardinha, LH; Costa, AM; Neto, OPV;
Vieira, LF; Vieira, MA 2013 | Strukov, DB; Snider, GS; Stewart, DR; Williams, RS 2009)
Regarding the bidirectional capacity of the nanorouter, I point out that graphene -and therefore the entire
nanonetwork- can cross the blood-brain barrier, sometimes carrying other substances (e.g. improving the
targeting of some drugs); it is therefore likely that in the near future thoughts, memories, sensory
perceptions and everything that we now call "consciousness" will also be detected.
It is not known whether those who have already received the vaccine, once the nanonetwork within the
entire body will be formed, will be influenced in thought and behavior, in their actions, through a
controlled release of neurotransmitters and catecholamines (dopamine, serotonin, norepinephrine, etc.)
or other hormones, going to enhance or impair some characteristics, in favor or to the detriment of others:
it is possible to level emotions, change the degree of perceived satisfaction, increase attention, promote
learning or inhibit it, even enabling the phenomenon of subliminal (unconscious) conditioned learning.
For these reasons, however, future pandemics will be managed optimally, through predictive algorithms
of contagions, just as many of the current chronic diseases will be treatable, through sending stimuli to
the release or inhibition of certain elements in the body, depending on whether they are needed (or
deficient), or in excess.9

Figure 10: Network architecture diagram for the Internet of Things for biomedical
applications. (Lee, SJ; Jung, C.; Choi, K.; Kim, S. 2015)

The computing power of quantum computers and the flexibility of Machine Learning will be combined
with the speed and zero latency of the 5G network, to transmit the data of each individual.
After all, the Internet of Things (IoT) has made objects "smart" by sending them data, parameters,
sometimes the initial processing of the same, before reaching all destination clouds.
How much longer can humans stay out of it? It is already inside the Internet of NanoThings (IoNT), but
does not realize it, although it is not known whether the WNSN (Wireless Nanosensors Network) is
hierarchical architecture, i.e. with bottom-up transmission (from nanosensors to nanorouters) or non-
hierarchical, with autonomous components in data and signal recording, transmission, activation and
programming.11 The non-hierarchical topology, at the same time as the hierarchical topology, remains
the most likely option, given the properties of graphene: it is inherently tunable, so it is possible to create
an SDM (Software Defined Metamaterial) that allows drivers to modify the electrostatic bias applied to
different areas of the graphene sheet. Graphene can in essence be controlled and programmed like
software, in its various layers.10

Figure 11: Diagram of the logical structure of a software-defined metamaterial, graphene being the metamaterial
explicitly mentioned by the authors (Abadal, S.; Liaskos, C.; Tsioliaridou, A.; Ioannidis, S.; Pitsillides; Solé-Pareta, J.;
Cabellos-Aparicio, A. 2017)

Figure 12: Components of the three-tier nanocommunication network (Balghusoon, AO; Mahfoudh, S. 2020)
However, it must be pointed out that graphene is highly toxic in any form it is presented and taken into
the human body, in fact its presence has not been declared among the components of the "vaccine"
by the pharmaceutical company. From studies that have emerged, graphene, hence the basis for the
nanonetwork, seems to be present in all "vaccines", except for AstraZeneca, which, perhaps not by chance,
was eliminated from the market, claiming responsibility for numerous adverse effects, even lethal, even
though, in reality, it presented about the same probability (slightly higher) of developing pathologies or
incurring sudden cardio/cerebrovascular accidents, compared to other serums.

Returning to graphene and its derivatives, it is possible to say that it is highly thrombogenic, in fact,
coagulated blood has been examined by several researchers: first of all Prof. Campra, but also Dr. Robert
O. Young, who has published all his studies and findings, in great detail on his personal website: Nano
and Micro Graphene Tubes Cause Pathological Blood Coagulation Leading to Hypercapnia, Hypoxia
and Death, as said by Dr. Robert O. Young, MD., DSc, PhD, in Hikari Omni Publishing, 202112 and other
scientists, among which Dr. Jose Louis Sevillano has distinguished himself for the warnings launched against
the introduction of graphene in the population. In addition, the said nanomaterial presents genotoxicity,
mutagenicity, high pulmonary toxicity, causes damage to the circulatory and cardiovascular system,
nervous system, endocrine, reproductive, urinary, can lead to apoptosis (cell death), severe inflammatory
state, immunosuppression, up to multi-organ dysfunction.

Recall also, that the artificial electronics that are going to form from graphene in hydrogel, by
electrophoresis and teslaphoresis, in response to magnetic fields and electromagnetic (EM) waves, can easily
affect in a negative mode the electrical conduction of the heart and brain, thus leading to lethal
fibrillations (arrhythmias) or neurological disorders of considerable magnitude.

FROM DR. ROBERT O. YOUNG MD., DSc, PhD WEBSITE12:

Figure 13: Viewed Under Bright Field Microscopy a Nanotube and Microtubes of Graphene Oxide in the Dried Coagulated Blood Cells or a Blood
Clot

Figure 14: Shows he spectrum of a Pfizer “vaccine" nanoparticulates of reduced graphene oxide or graphene hydroxide, magnesium,
aluminum, silicon, chloride and calcium identified under an ESEM microscope coupled with an EDS x-ray microprobe
Figure 15: The "Corona-Effect"and the endogenous Birth of S1 protein Spikes caused by radiation and chemical poisoning Dr. Robert O. Young,
Hikari Omni Publishing, 2021

Figure 16: This Micrograph Shows the Endogenous Birth of the "Spike Protein" as an Outfection and NOT and Infection! Dr. Robert
O. Young, Hikari Omni Publishing, 2021
 Figure 17: Reveals the Nano Dots in the Reduced Graphene Oxide or Graphene Hydroxide Found in the Moderna "Vaccine"

So there are still many question marks, such as the premature demise that will happen to some
vaccinated, but will allow the eternal survival of consciousness for others. Certain aspects, behaviors (eg:
race to the vaccine and hatred for the unvaccinated) probably, are part of evolution and as such have an
explanation of instinctive matrix, unless it is not already in place an unknown form of mental control and
induction to act to achieve a goal unconsciously.
It is clear, then, how this is an obligatory step for humanity, beginning in these years to lay the foundations
for intracorporeal nanoreality and concluding, in my estimation, within a century.

There are links on the web to go deeper, but if you look for information on graphene material,
nanotechnology related to biology and the Internet of NanoThings, a new world will open up, where
academics already know and take for granted and normal everything I have described in this research.

Dr. Kira Smith killforthethrill@black-fox.it

MD., MSc in Experimental Medicine
REFERENCES:

1 Dr. Ricardo Delgado, 2021

2 Prof. P. Campra, 2021
3 Bouchedjera, IA; Louail, L.; Aliouat, Z.; Harous, S. 2020
4 Tsioliaridou, A.; Liaskos, C.; Ioannidis, S.; Pitsillides, A. 2015
5 Sardinha, LH; Costa, AM; Neto, OPV; Vieira, LF; Vieira, MA 2013
6 Dr. Andrew Goldsworthy 2021
7 Guerriero, E.; Polloni, L.; Bianchi, M.; Behnam, A.; Carrion, E.; Rizzi, LG; Sordan, R. 2013
8 Strukov, DB; Snider, GS; Stewart, DR; Williams, RS 2009
9 Lee, SJ; Jung, C.; Choi, K.; Kim, S. 2015
10 Balghusoon, AO; Mahfoudh, S. 2020
11 Abadal, S.; Liaskos, C.; Tsioliaridou, A.; Ioannidis, S.; Pitsillides; Solé-Pareta, J.; Cabellos-Aparicio, A. 2017
12 Dr. Robert O. Young, 2021 https://drrobertyoung.com
13 Hu, W.; Sarveswaran, K.; Lieberman, M.; Bernstein, GH 2005

View publication stats