Nano.gov
Progress and Plans of NNI Agencies—December 2019 1 PROGRESS AND PLANS OF N ATIONAL NANOTECHNOLOGY INITIATIVE (NNI) A GENCIES
I
wanted to post not just the Budget but the actual progress report of
the National Nanotechnology Initiative. This is to explain to people how
much the military is working on human augmentation and transhumanist
technologies under the auspices of increasing soldier capabilities. I
have been writing about the technologies of the military and their push
for the Cyborg future for a long time.
Please
see that biosensing capabilities, brain computer interface and MEDICAL
DEVICE DEVELOPMENT is all part of this. As the world is under the 2030
Agenda, the National Defense Strategy and Air Force 2030 Science and
Technology Strategy is all about the nanotechnology development,
specifically metamaterials, quantum materials, energy harvesting
technologies, nanochemistry, bio-nanotechnology, nanoelectronics. Please
note it is all about bioelectronics and how cells can be fused with
technology.
_________________________________________________________________________
These
approaches include the development of “protonic” devices for actuating
cells and self-assembled nanoscale transducers that can wirelessly
control living cells.
__________________________________________________________________________
All
of these have been deployed against humanity as is visible in human
blood. Last night I went out on my balcony with a UV light looking at
the fog… and it is fluorescent dancing particles, that we get to inhale.
Do the test yourself, 365nm flashlight will show you what is in the
air. Then go to the mirror and look at your face or after a hot shower
at your skin. You will see the same fluorescent filaments and particles
come out of your skin.
I wrote about this here in relationship to the Covid 19 bioweapons and shedding:
Fluorescent Filaments Coming Out Of C19 Vaccinated Individuals Skin Glowing Under UV Light: Darkfield Microscopy
C19
Uninjected Individuals Expelling Fluorescent Filaments Through Skin -
Similar To C19 Injected - Darkfield Microscopy Of Filaments And
Correlation To Live Blood
Recognizing
the revolutionary impact that nanotechnology and nanomaterials may have
on our future warfighting capabilities, the Department of Defense
continues to pursue foundational research in these technologies to
support the modernization of the current force. Nanotechnology shows
great promise to allow the ability to design unique materials to achieve
improved properties and capabilities, including novel sensing
capabilities/modalities, lightweight, stronger materials for protective
applications, and expanded uses in medical devices, environmental
remediation, and additive manufacturing.
Air Force
Summary
Nanoscience
underpins innovations that are critical to future air, space, and cyber
capabilities outlined in the Air Force (AF) 2030 Science and Technology
(S&T) Strategy and the 2018 National Defense Strategy, such as
universal situational awareness, the delivery of precision effects
anywhere, protection of our airmen, and ability to access and survive in
the battlespace. Due to extensive global investment, research in
nanoscience has exploded over the past two decades, creating many new
self-sustaining research communities, such as metamaterials, quantum
materials, energy harvesting technologies, nanochemistry,
bio-nanotechnology, nanoelectronics, etc.
·
Physiological and biological sensors in the form of disposable patches
to monitor human performance in stressful missions, improve
airman-machine interface, and enable autonomy for operators such as
pilots, air traffic controllers, and first responders.
·
Increased security, bandwidth, data storage, and processing through
miniaturized electronic and optical devices to enable encryption, as
well as seamless spatial and temporal fusion of diverse sensor streams
with trust.
·
Agile intelligence, surveillance, and reconnaissance (ISR) components
with increased broadband data transfer including radio frequency (RF)
systems and hyperspectral electro-optic sensors through the use of
nanostructured materials and structures to increase resolution, spectral
performance, operating temperature, and autonomous distributed analysis
of extremely large data sets to obtain meaningful and actionable
information.
Goal 1. Advance a World-Class Nanotechnology Research and Development Program
AFRL
scientists, in collaboration with Ohio State University, the Indian
Institute of Technology (Madras), and Western Digital, recently
demonstrated a new method for detecting magnetic dynamics using
incoherent relaxation of nitrogen vacancy centers in diamond. This
technique enables high-resolution imaging of magnetic dynamics at the
nanoscale, potentially uncovering new mechanisms for, and elucidating
existing mysteries in, how energy moves in a ferromagnetic system. This
capability will be instrumental in the improvement of technologies
relying on low-damping magnetic materials, such as conventional
microwave and RF components for ISR and electronic warfare (EW).
An
AFRL-funded program at the University of Southern California
established mechanisms that mediate energy conversion and charge
transmission at the interface between living cells and synthetic
surfaces. These findings have implications for cell physiology and
bioelectronics, and may lead to the development of new hybrid materials
and renewable energy technologies that combine the exquisite biochemical
control of nature with the synthetic building blocks of nanotechnology.
An
AFRL-funded international program, including activities at the
University of Texas at Dallas and multiple Asian institutions, has
resulted in the invention of several types of strong, powerful
artificial muscles using materials ranging from high-tech carbon
nanotubes (CNTs) to ordinary fishing line. Concepts such as sheath- run
artificial muscles, or SRAMs, provide even greater design flexibility,
allowing for the replacement of CNT yarns with less expensive yarns.
These muscles are very attractive for intelligent structures, such as
robotics and comfort-adjusting clothing.
AFRL's
Nano-Bio Materials Consortium (NBMC), including industrial, academic,
and venture capital partners, is advancing aeromedical monitoring
capabilities for En Route Care and Aeromedical Evacuation missions.
$5.7
million in R&D activities, and an associated $6.1 million in member
cost share, will advance technologies and components that enable stress
monitoring, tissue-level oxygen/biochemical monitoring, AI for
multi-modal physiological monitoring, and wireless vital sign monitoring
devices for ambulatory patient monitoring. These efforts
focus on establishing a foundation for new dual-use products in digital
health and personnel medicine that address strategic requirements
within the AFRL Operational & Aeromedical Health Product Line.
An
AFRL-funded program at Harvard University demonstrated nanoscale
devices for intracellular recording, the first nanotechnology developed
to record electrical chatter inside a live cell. The team has recently
designed a way to make thousands of these devices at once, creating a
nanoscale army that could speed efforts to find out what’s happening
inside our cells.
Navy
NRL Nanoscience Program
FY 2021 Plans and Priorities
Signature Initiatives and Grand Challenge (PCA 1)
In
the area of nanoelectronics, NRL is developing heterostructures of 2D
materials for spintronic applications. For the Sensors Nanotechnology
Signature Initiative (NSI), NRL plans to investigate chemical sensor
platforms for detecting the cellular signals that control wound healing.
In the area of the Future Computing Grand Challenge, NRL
is investigating nanophotonic approaches to quantum information
processing and reservoir computing.
Foundational Research (PCA 2)
NRL
anticipates continued efforts in the area of foundational research.
This research includes efforts in phonon-polariton lattices, controlling
magnetism in metamagnetic nanostructures, enhanced optical properties
in hybrid nanostructures, and quantum-coherent networks in DNA origami
structures.
Nanotechnology-Enabled Applications, Devices, and Systems (PCA 3)
NRL is developing new approaches to interface with and control biological systems.
These approaches include the development of “protonic” devices for
actuating cells and self-assembled nanoscale transducers that can
wirelessly control living cells. Additionally, NRL is developing dimensionally-confined biological catalysts and multiscale architectures for chemical catalysts.
NRL
scientists are exploring methods to exploit DNA as both a structural
and informational molecule to develop modular transducers that convert
enzyme activity into DNA signals, which can subsequently be amplified,
combined, or processed, e.g., to reduce false positives. A new class of
transducers has been devised and demonstrated based on small circular
DNA oligomers (~80 bases). In operation, these assemblies undergo a
rearrangement if and only if the target enzyme is present, and this has
been shown to occur with high fidelity. This new approach to enzyme
sensing has promise for future DNA-based “smart” sensors that can
operate both in vitro and in vivo.
Photonic
quantum information technologies such as computing, communication, and
sensing have a critical need for integrated quantum optics platforms. A
long-standing challenge in developing such platforms is integrating more
than one or two solid-state quantum bits (so-called qubits). NRL
scientists have developed a technique that overcomes this challenge for
semiconductor quantum dots—one of the most advanced solid-state
qubits—by tuning multiple quantum dots into resonance with micro-laser
processing. They demonstrated photon-mediated quantum interactions
between multiple dots, a critical test of an integrated quantum optics
platform
Scientists
from three divisions at NRL have developed self-assembled nanoparticle
enzyme systems that exploit channeling processes and are capable of
overcoming diffusion limitations and increasing enzyme pathway activity
by several orders of magnitude. This advancement paves the way for
creating designer enzyme clusters that are capable of synthesizing
molecules such as nutraceuticals, drugs, critical chemicals, and food
from common simple molecule feedstocks and even waste at points of need
such as a deployed ship, submarine, or forward operating base. Such
systems are critically needed to enable Navy distributed maritime
operations, increase autonomy, and reduce supply line dependency.
Given
the significant challenge of traumatic brain injury, DOD has a
continued interest in the development of new technologies (for both
imaging and modulating brain activity) for new diagnostics and
therapeutics. NRL materials scientists have developed small gold
nanoparticles (AuNPs) that bind to the plasma membrane of neurons,
harvest incident visible light, and heat the plasma membrane just enough
to open ion channels and activate neurons. This is a
fundamentally new application of these types of materials and
demonstrates the fine degree of control that can be elicited over cells
using functional nanomaterials.
NRL
scientists have verified a new mechanism for modifying chemical
reaction rates. Specifically, by flowing reactive chemicals through a
tuned optical cavity, reaction rates could be modulated by ~80%. This
capability represents a new tool for energy collection and storage
(solar- or bio-fuel) and toxin remediation (for countering chemical or
biological weapons).
ONR Bionanotechnology Program
FY 2021 Plans and Priorities
PCA 2. Foundational Research
The
Office of Naval Research (ONR) will continue to support
bionanotechnology research with emphases on fabrication techniques for
hierarchical, biologically-based materials with defined properties, DNA
nanotechnology and applications for functional device platforms,
synthesis and patterning of materials by
microorganisms,
and design and fabrication of bio-inspired and biomimetic materials and
devices using nature’s design principles.
Key Technical Accomplishments by Goal
Goal 1. Advance a World-Class Nanotechnology Research and Development Program
Researchers
supported by ONR developed and validated a new algorithmic approach for
the autonomous design of all DNA staple sequences needed to fold any
free-form 2D scaffolded DNA origami wireframe object from a long single
strand of DNA scaffold. Such nanostructures offer the ability to
organize secondary molecules, such as dyes, nucleic acids, proteins, and
semiconductor nanocrystals, for applications in fields such as
nanophotonics, nanoscale energy transport, and biomolecular sensing. The
algorithm is available online as a stand-alone software tool, and
complements recent advances in DNA scaffold generation to bring the use
of scaffolded DNA origami to the wider scientific community.5
Researchers supported by ONR fabricated 3D
self-rolled biosensor arrays of either active field-effect transistors
or passive microelectrodes and used them to demonstrate, for the first
time, 3D multisite and simultaneous electrophysiological recordings from
a 3D multicellular system, specifically stem-cell-derived engineered
cardiac spheroids. The arrays provided continuous and stable multiplexed
recordings of field potentials with high sensitivity and spatiotemporal
resolution, supported with simultaneous calcium imaging. Use of this
approach can enhance our basic understanding of signal transduction in
complex cellular assemblies, the relationship between signals and
disease (e.g., arrhythmias), and tissue maturation. Additionally, the
approach can be used in the development and assessment of the efficacy
of drugs for disease treatment.6
Researchers
supported by ONR engineered a microbial process to produce covalently
linked repeats of mussel foot proteins (Mfp), specifically Mfp type 5,
and characterized the adhesive properties of those recombinant proteins.
A positive correlation between the molecular weight of the Mfp5
oligomers (i.e., longer protein chain) and underwater adhesive
properties was detected. Additionally, modification of the Mfp5
oligomers with 3,4-dihydroxyphenylalanine was shown to yield comparable
or higher force of adhesion and work of adhesion values for a 200 second
cure time than those of previously reported Mfp-mimetic adhesives. This
research demonstrates the power of synthetic biology in exploring the
mechanisms that control underwater adhesion.7
Researchers
supported by ONR fabricated activators from dormant bacterial spores
suspended in water-resistant, UV-curable adhesives that achieve work
densities an order of magnitude higher than synthetic
humidity-responsive polymers, and respond directly to liquid water,
increasing their actuation speed and power by nearly 100-fold. Potential
applications of this material include humidity-driven and water-driven
actuators for robotics, adaptive textiles and architectures, and energy
harvesting
Summary:
The
military is front and center in the transhumanist technocratic agenda,
and considering the aerogel fog, the saturation of our air with polymer
filaments, metals and other materials that make people sick a warfare
field that people need to be aware of. Couple that with directed energy
weapons destroying large areas in California, Hawaii for smart grid
progression purposes and one can now begin to see war against the
civilian population with open eyes.
Support
your health and wellbeing during this aerogel chemical assault by
detoxification and nutritional optimization. Remember Vitamin C is a
chelator and universal antidote for toxic exposures and doses of
10000mg, as Linus Pauling recommended are certainly indicated in these
times.
I
also highly recommend Dr Tennants Restore for full mitochondrial
optimization in the morning which also contains all the minerals you
need and Global healings microsomal EDTA in the evening. For more
details on detox protocols see my book Transhuman Vol 2.
Tennants Restore
You
can also use Chlorophyll in your water for DNA protection and Methylene
Blue to help prevent the rubbery clots and improve mitochondrial
function.
Global healing CaEDTA
Liquid Chlorophyll
Methylene Blue
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