I remember at work there was a compartmentalized team doing R&D with graphene back in 2010. This was started as they knew much less than 10 nanometer chips were going to be very difficult (heat issues for one) with standard silicon and will have to find something new by 2020. No idea how far they got with graphene and lost track of it all years ago.
Corona didn’t just launch DARPA’s mRNA technology. Corona accelerated launching nanotechnology for immunology. Gold nanoparticles, Silver NPs, Iron Oxide NPs, Silicon dioxide NPs, and Graphene NPs all being researched under the auspices of COVID applications.
More on graphene/nano bytes...
Graphene-Based Nanomaterials: From Production to Integration With Modern Tools in Neuroscience
Trans-Watermelon? I know nothing about the 'science' of it but sure does not sound natural nor safe for consumption...
Vaccines Deliver Graphene Oxide Nanotubes for 5G Mind Control
Nanotech everywhere...
INBRAIN Neuroelectronics Secures $17M for AI-Powered Graphene-Brain Interface
“We’ll have nanobots that connect our neocortex to a synthetic neocortex in the cloud. Our thinking will be a... biological and non-biological hybrid.”
― Ray Kurzweil, TED Talk 2014
Breakfast break, how about some Graphene on toast...
Every technology has its pros & cons. The ways its been for thousands of years. Chips, sure. New man 2.0, No!
Quote:Graphene Monoxide Bilayer As a High-Performance on/off Switching Media for Nanoelectronics
Abstract
The geometries and electronic characteristics of the graphene monoxide (GMO) bilayer are predicted via density functional theory (DFT) calculations. All the possible sequences of the GMO bilayer show the typical interlayer bonding characteristics of two-dimensional bilayer systems with a weak van der Waals interaction. The band gap energies of the GMO bilayers are predicted to be adequate for electronic device application, indicating slightly smaller energy gaps (0.418–0.448 eV) compared to the energy gap of the monolayer (0.536 eV). Above all, in light of the band gap engineering, the band gap of the GMO bilayer responds to the external electric field sensitively. As a result, a semiconductor-metal transition occurs at a small critical electric field (EC = 0.22–0.30 V/Å). It is therefore confirmed that the GMO bilayer is a strong candidate for nanoelectronics.
Quote:Atom-width Graphene Sensors Could Provide Unprecedented Insights into Brain Structure and Function (DARPA 2014)
New technology funded by DARPA’s RE-NET program enables monitoring and stimulation of neurons using optical and electronic methods simultaneously
The technology demonstration draws upon three cutting-edge research fields: graphene, which earned researchers the 2010 Nobel Prize in Physics; super-resolved fluorescent microscopy, which earned researchers the 2014 Nobel Prize in Chemistry; and optogenetics, which involves genetically modifying cells to create specific light-reactive proteins.
RE-NET is part of a broader portfolio of programs within DARPA that support President Obama’s brain initiative.
Corona didn’t just launch DARPA’s mRNA technology. Corona accelerated launching nanotechnology for immunology. Gold nanoparticles, Silver NPs, Iron Oxide NPs, Silicon dioxide NPs, and Graphene NPs all being researched under the auspices of COVID applications.
More on graphene/nano bytes...
Quote:Graphene-Based Nanomaterials: From Production to Integration With Modern Tools in Neuroscience
The promises of nanomedicine are extensive. Graphene (Gr), the first true two-dimensional material to exist in isolation, is the type of new nanomaterial that results in interest for novel biomedical applications. From Michael Chrichton’s tragic protagonist in The Terminal Man to the recent growth in start-up companies seeking to transfer consciousness, the fictive present and future call to mind visions of devices that enable neural interfacing and control.
Although these ideas may create questions as to ethics for neuroscience in the future, the current state-of-the-art for implanted devices is far more limited in scope. Progress in brain-computer interfaces holds great promise for patients following stroke (Ramos-Murguialday et al., 2013), to control prosthetic limbs (Hochberg et al., 2006; Donoghue et al., 2007), with the motor degeneration characteristic of Parkinson’s disease (Little et al., 2013), and for a variety of other disorders and diseases (Chaudhary et al., 2016). Gr may be poised for incorporation into such devices.
Graphene-Based Nanomaterials: From Production to Integration With Modern Tools in Neuroscience
Quote:The worldwide estimate is that disposable masks or face shields are discarded at a rate of 3,4 billion per day. The presence of a diversity of plastics, toxic and cancerous compounds like perfluorocarbon, aniline, phthalate, formaldehyde, bisfenol A as well as heavy metals, biocides (zinc oxide, graphene oxide) and nanoparticles are found. An increasing number of environmental experts worry about the long-term effects. Most (85%) of the masks used worldwide are made in China where no environmental qualification is needed.
A total breakdown of these dangerous compounds is expected to last 450 years.
Brownstone Institute
Trans-Watermelon? I know nothing about the 'science' of it but sure does not sound natural nor safe for consumption...
Vaccines Deliver Graphene Oxide Nanotubes for 5G Mind Control
Nanotech everywhere...
INBRAIN Neuroelectronics Secures $17M for AI-Powered Graphene-Brain Interface
“We’ll have nanobots that connect our neocortex to a synthetic neocortex in the cloud. Our thinking will be a... biological and non-biological hybrid.”
― Ray Kurzweil, TED Talk 2014
Breakfast break, how about some Graphene on toast...
Every technology has its pros & cons. The ways its been for thousands of years. Chips, sure. New man 2.0, No!
"It is hard to imagine a more stupid or more dangerous way of making decisions than by putting those decisions in the hands of people who pay no price for being wrong." – Thomas Sowell