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- Scintillator - Wikipedia
The term "plastic scintillator" typically refers to a scintillating material in which the primary fluorescent emitter, called a fluor, is suspended in the base, a solid polymer matrix
- Stanford: Advanced Optical Ceramics Laboratory
Detectors based on scintillators (fig 1) are essentially composed of a scintillator material, and a photodetector that can be either a photomultiplier tube (PMT) or a photodiode The role of the photodetector is to convert the outcoming light of the scintillator to an electrical signal
- Scintillator | Description, Example Application
A scintillator is a material that emits light when it interacts with ionizing radiation like X-rays, gamma rays, or charged particles The word “scintillation” means the flash of light emitted by the material
- Scintillator - an overview | ScienceDirect Topics
A scintillator is defined as a material that emits photons in the ultraviolet-visible region of the electromagnetic spectrum when it absorbs energy from gamma rays, facilitating the conversion of this absorbed energy into electric signals
- How Do Scintillators Work? - Hilger Crystals
Once a scintillator crystal is exposed to ionized radiation, electrons within the crystal become excited and move from their locked position within the valence band to the conduction band where they are free to move around, leaving an associated hole behind it
- What Is a Scintillator and How Does It Work? - Biology Insights
A scintillator is a specialized material that emits light when exposed to high-energy radiation, such as X-rays, gamma rays, or energetic particles This unique property allows for the detection and measurement of otherwise invisible radiation
- Scattering-free lanthanide-ionic liquid scintillators for high . . . - Nature
Qiu et al report an intrinsic liquid scintillator which eliminates the light scattering by exploring in-situ coordination between lanthanide ions and ionic liquid ligands The liquid scintillator
- Scintillators | Research Starters - EBSCO
A scintillator can be used to detect electromagnetic radiations because these radiations can liberate electrons by photoelectric, Compton scattering, or pair production processes These electrons in turn traverse the detector, causing excitations that result in the scintillation events
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