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Symmetry is usually prized in nature, but the deliberate skewing of symmetry in nanofluidic devices can lead to elegant new ways of sorting biomolecules.
A new approach to sensing mechanical motion allows high-frequency measurements to be made with cantilevers that are smaller than the wavelength of light.
Single-walled carbon nanotubes can now effectively target tumours in mice, which suggests that nanotubes could form the basis of a safe drug-delivery system for cancer therapy.
Most methods for making carbon nanotubes require further processing to separate tubes with different chirality. Now, seeding growth from an existing nanotube segment ties synthesis and selectivity into a single step.
The response of a cantilever to bacteria deposited on it depends on the mechanical properties of the sample, as well as its mass. This effect needs to be considered in sensor design.
By coating a nanotube with a molecular layer that is thicker on one end than the other, it is possible to make a thermal rectifier that allows heat to flow easily along the tube in one direction, but not so easily in the opposite direction.