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The three-dimensional structures of transparent objects, such as living cells, are captured by an imaging technique that uses white-light illumination and diffraction tomography to collect a stack of phase-based images.
Perovskite solar cells are currently generating great interest in the photovoltaics community, but a detailed understanding of why they are so efficient is lacking. Femtosecond laser spectroscopy and microwave photoconductivity measurements now reveal important insights into the photoinduced charge transfer processes and dynamics of such cells.
A solid-state device is demonstrated that can detect the absolute offset between the carrier wave and envelope of an ultrashort pulse, the carrier–envelope phase. It holds promise for routine measurement and monitoring of the carrier–envelope phase in attosecond experimental set-ups.
A means for localizing fluorescent molecules over distances of hundreds of nanometres exploits the energy transfer between a donor molecule and surface plasmons on a metal film. The technique is demonstrated by using it to profile the membranes of living cells.