Microimaging
Industrial ultrafast lasers have been widely and deeply applied in the field of advanced manufacturing research. Their advantages such as high resolution, low light damage, deep imaging, and multi-mode imaging have brought more innovation and breakthroughs to the field of microscopic imaging.
The combination of Shenglei Hercules femtosecond laser series and OPO technology can generate a wider tuning range, supporting imaging needs of various phosphors, dyes, and fluorescent proteins. In addition, longer wavelengths can reduce light scattering and light damage, achieving deeper imaging.
The Shenglei Hercules femtosecond laser series can serve as a light source, providing sufficient energy to excite fluorescent molecules with multiple photons. This imaging technique is particularly suitable for imaging research of living tissues, such as observing the activity of neurons, the direction of nerve fibers, and the release of neurotransmitters.
The Shenglei Hercules femtosecond laser series can generate high-quality thin sheet-like beams, making this imaging technology applicable to imaging studies of larger volume samples, such as entire embryos, small biological individuals, or tissue organs.
Quoted from "A Review of Multimodal Nonlinear Optical Microscopy Imaging Technology" by Li Yanping et al., Acta Photonica Sinica
Related Products
