With Laser TIRF 3, Carl Zeiss infuses its imaging system for Total Internal Reflection Fluorescence microscopy with an entirely new level of quality. The TIRF system is suitable for reproducible microscopic examinations of near-cell membrane dynamic processes and interactions of single molecules in cell-free systems with high time resolution.
IMEC, Europe's leading independent research center in the field of nanoelectronics, and AIXTRON, the world leader in metal-organic chemical-vapor deposition (MOCVD) equipment, have demonstrated the growth of high-qua...
In 2004 Lyncean Technologies announced the construction of the Compact Light Source (CLS), a miniature synchrotron which uses inverse Compton scattering to produce high-intensity, tunable, near-monochromatic x-ray beams.
Scientists in Sweden have discovered new ways to control the growth and structure of nanowires at the single-atom level. Their findings, which provide major insights into materials physics, have come out of the NODE (' Nanowire-based one-dimensional electronics') project, funded with approximately EUR 9.5 million under the EU's Sixth Framework Programme (FP6).
Bruker Daltonics and the Queensland Institute of Medical Research (QIMR) announced today the installation of the first maXis(TM) Ultra-High Resolution Time-Of-Flight (UHR-TOF) mass spectrometer in Australasia, thereby fu...
FEI Company (Nasdaq:FEIC), a leading provider of high-resolution imaging and analysis systems, today announced that it had acquired substantially all of the assets of Intellection Holdings Pty. Ltd. of Brisbane, Australia. Intellection's primary product is the QEMSCAN automated mineralogy system.
Using a beam of light shunted through a tiny silicon channel, researchers have created a nanoscale trap that can stop free floating DNA molecules and nanoparticles in their tracks. By holding the nanoscale material steady while the fluid around it flows freely, the trap may allow researchers to boost the accuracy of biological sensors and create a range of new 'lab on a chip' diagnostic tools.
Peering at structures only atoms across, researchers have identified the clockwork
that drives a powerful virus nanomotor.
Researchers have discovered the atomic structure of a powerful "molecular
motor" that packages DNA into the head segment of some viruses during their
assembly, an essential step in their ability to multiply and infect new host
organisms.
Nanoscience researchers at Lund University in Sweden have shown that they can control the growth and crystal structure of nanowires down to the single atom level. How this can be done is described in an article to appear...
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