Professor Robert Feidenhans» l explains that there is great potential in
such nanowires.
They also predicted that a Majorana could reveal itself in the way current flows through
such a nanowire.
Not exact matches
The
nanowires collect sunlight, much like the light - absorbing layer on a solar panel, and the bacteria use the energy from that sunlight to carry out chemical reactions that turn carbon dioxide into a liquid fuel
such as isopropanol.
«We demonstrate that other asymmetric materials,
such as asymmetric
nanowires, thin films, and quantum dots of a single material can also be high - performance thermal rectifiers, as long as you have lateral confinement,» Ruan said.
The
nanowires are grown from a specially etched substrate
such that they form exactly the desired network which they then expose to a stream of aluminium particles, creating layers of aluminium, a superconductor, on specific spots on the wires — the contacts where the Majorana particles emerge.
In this new work, he and his colleagues have shown that desirable characteristics for
such devices,
such as high power density, are not unique to carbon - based nanoparticles, and that niobium
nanowire yarn is a promising an alternative.
M.I.T. breeds viruses that coat themselves in selected substances, then self - assemble into
such devices as liquid crystals,
nanowires and electrodes
The IBM team fabricated single crystal nanostructures,
such as
nanowires, nanostructures containing constrictions, and cross junctions, as well as 3 - D stacked
nanowires, made with so - called III - V materials.
It is covered with bendy
nanowires tipped with lectin — a protein that binds to carbohydrates
such as the sugars bacteria have on their surface.
The things that we have demonstrated —
such as the fact that the vertical
nanowires can deliver any biological effector to any cell type in a spatially selected fashion — have drawn interest from many different people, and we have been working with stem cell institutes and others to demonstrate the unique utility of this particular platform.
Resume: Transparent conducting oxides
such as Sn doped In2O3
nanowires (NWs) have been investigated in the past since they are important building blocks for the realization of novel electronic and optoelectronic devices like solar cells, but In is rare and expensive [1].
«For example, the morphology of the
nanowire array protects the bacteria like Easter eggs buried in tall grass so that these usually - oxygen sensitive organisms can survive in environmental carbon - dioxide sources
such as flue gases.»
''... researchers have created assemblies of
nanowires that show potential in applications
such as armor, flame - retardant fabric, bacteria filters, oil cracking, controlled drug release, decomposition of pollutants and chemical warfare agents.»