Oxygen Microscopy by Two-Photon-Excited Phosphorescence

The cover picture illustrates the chemical structure of a dendritic phosphorescent nanoprobe for two-photon microscopy of oxygen. Several antenna chromophores (yellow) capture the excitation energy from a pulsed femtosecond laser and channel it to the central platinum porphyrin (orange) via intramol

The two-photon excited phosphorescenceof triphenyiene in PMMA matrix at 77 K was measured using a tunable flashramp-pumped rhodamine dye laser in the effective spectral region 32000-36000 cm-\*. The band origin of the So-S2 transition, which is uncertain in the one-photon absorption spectrum, was ob

Precise knowledge of the properties of semiconductor nanocrystallites (NCs) may determine their use in future optical devices. However, since synthesis methods are not able to yield perfectly homogeneous NCs. spectral and dynamic responses are usually averaged properties. We examine single NCs using

## Abstract In 1931, Maria Göppert‐Mayer published her doctoral dissertation on the theory of two‐photon quantum transitions (two‐photon absorption and emission) in atoms. This report describes and analyzes the theoretical and experimental work on nonlinear optics, in particular two‐photon excitati

The in-depth imaging properties of two-photon excitation microscopy were investigated and compared with those of confocal microscopy. Confocal imaging enabled the recording of images from dental biofilm down to a depth of 40 microm, while two-photon excitation images could be recorded at depths grea