Showing results: 46 - 51 of 51 items found.
-
Teledyne e2v
EM (Electron Multiplication) is a technology that uses on-chip gain in the charge domain to effectively eliminate read noise from an image sensor. This enables advanced ultra-low light applications that require extreme sensitivity at fast frame rates. Examples include life science applications such as single molecule detection, super resolution microscopy and spinning disk confocal microscopy along with physical science applications such as nanotechnology imaging, Bose Einstein condensates and soft X-ray spectroscopy, and astronomy applications such as adaptive optics and lucky imaging. The inclusion of an additional conventional output allows further flexibility for applications such as true 24 hour surveillance.
-
Bruker Daltonics
Bruker’s suite of fluorescence microscopy systems provides a full range of solutions for life science researchers. Our multiphoton imaging systems provide the imaging depth, speed and resolution required for intravital imaging applications in neuroscience, oncology and immunology. Our confocal systems enable cell biologists to study function and structure using live-cell imaging in cell cultures and invertebrate model organisms at speeds and durations previously not possible. Bruker’s super-resolution microscopes are setting new standards with quantitative single molecule localization which allows for the direct investigation of the molecular positions and distribution of proteins within the cellular environment. Our latest addition, Luxendo light-sheet microscopes, are revolutionizing long-term studies in developmental biology and investigation of dynamic processes in cell culture and small animal models.
-
Bruker Corporation
Bruker’s suite of fluorescence microscopy systems provides a full range of solutions for life science researchers. Our multiphoton imaging systems provide the imaging depth, speed and resolution required for intravital imaging applications in neuroscience, oncology and immunology. Our confocal systems enable cell biologists to study function and structure using live-cell imaging in cell cultures and invertebrate model organisms at speeds and durations previously not possible. Bruker’s super-resolution microscopes are setting new standards with quantitative single molecule localization which allows for the direct investigation of the molecular positions and distribution of proteins within the cellular environment. Our latest addition, Luxendo light-sheet microscopes, are revolutionizing long-term studies in developmental biology and investigation of dynamic processes in cell culture and small animal models.
-
FV1000 -
Becker & Hickl GmbH
*Two Fully Parallel TCSPC FLIM Channels*Compact bh Simple-Tau or Power-Tau System*Two HPM-100-40 GaAsP Hybrid Detectors*Optional: HPM-100-06 Hybrid Detectors, IRF Width < 20 ps FWHM*Optional: HPM-100-50 Hybrid Detectors for NIR FLIM*Optional: Multi-Wavelength FLIM*Excitation by bh ps Diode Lasers*Excellent Time Resolution: Electrical IRF Width 6.5 ps FWHM*Time Channel Width Down to 813 fs*Megapixel FLIM, Up to 2048 x 2048 Pixels at 256 Time Channels*Simultaneous FLIM/PLIM*Detection Wavelength Range from 360 nm to 900 nm*Excitation by Ti:Sa Laser, OPO, or by bh ps Diode Lasers*Systems for Multiphoton FLIM and Confocal FLIM*Systems are Modular: More FLIM Channels can be Added
-
HORIBA, Ltd.
The AFM platform allows fully-integrated use of confocal Raman microscopy and AFM for Tip-Enhanced Optical Spectroscopies (such as Tip-Enhanced Raman Spectroscopy (TERS) and Tip-Enhanced PhotoLuminescence (TEPL)), but also for truly co-localized AFM-Raman measurements.The myriad of AFM (Atomic Force Microscope) techniques that allow study of topographical, electrical and mechanical properties can be performed with any laser source available in Raman spectrometer, or with other external illumination (e.g., solar simulator or other tunable or continuum source). TERS and TEPL can provide nanoscale chemical and structural information, making the AFM-Raman platform a two-way road; where complimentary techniques provide novel and unique imaging capabilities to each other.
-
Thorlabs, Inc.
Welcome to Thorlabs; below you will find links to our imaging systems and components. The products below are not only designed specifically for imaging applications, but they can be easily integrated into our entire line of photonics products. This makes it easy to modify or build custom imaging systems. Thorlabs’ Selection of Imaging Systems consists of our Laser Scanning Microscopy systems and OCT Imaging Systems. Our Laser Scanning Microscopy offering includes multiphoton and confocal fluorescence microscopy systems. Thorlabs is a leader in the development of Optical Coherence Tomography (OCT) Imaging Systems. We offer complete systems as well as a selection of components that are ideal for constructing a custom OCT system. Our series of Laser-Scanning Cytometry instruments are non-confocal systems that utilize laser-spot scanning illumination. The detection system, which combines PMTs for fluorescence detection and photodiodes for absorbance and scatter detection, offers excellent quantitative cytometric performance and imaging capabilities. Our Burleigh® line or microscope platforms, micromanipulators, and accessories provide leading edge stability and control for electrophysiology research, and our line of Optogenetics equipment includes fiber optic components and light sources for in vivo optical stimulation for neuroscience research.
