A major advance in mimicking protein function has been made by scientists working with peptoids.
A major advance in mimicking protein function has been made by scientists working with peptoids.
The recently demonstrated ability to visualize individual atoms of carbon and hydrogen on a graphene surface opens new avenues for studying the behavior of hydrocarbon chains.
A recent review describes the advantages to nanotech of advances in electron microscopy that allow mapping electron states localized at or between atoms.
A nanotech approach assembles flexible electronic circuits from random networks of single-walled carbon nanotubes.
Single walled carbon nanotube (SWNT) bundles may provide a nanotech method to activate certain cancer-fighting white blood cells outside a patient’s body in the hope that they will more effectively fight the patient’s cancer upon being returned to the patient.
Japanese researchers have succeeded in visualizing the motion of a molecular rotor.
Researchers at Columbia University have demonstrated that graphene is the strongest known material.
A nanotech method to capture cancer cells and remove them from the body might be useful for combating ovarian cancer, in particular.
An international team of scientists has shown that semiconductor nanotubes can be attracted to and aligned on surfaces chemically modified with amino groups, while surfaces with phenyl groups attract metallic nanotubes.
Researchers expect protein-conjugated quantum rods to be able to transport multiple agents across the blood-brain barrier so that they could function synergistically.
