Advantage:
High refractive index
Application:
Fiber laser
Detector
Specification Parameter
| Properties | Value | Unit |
| Density | 5.2 | g/cm³ |
| Melting Point | 1056 | K |
| Wavelength of emission max. | 380 | nm |
| Energy Resolution | <4.5% | @662KeV |
| Light yield | 60,000 | ph/MeV |
| Decay Constant | 20 | ns |
| Refractive Index | 2.1 | |
| Hygroscopic | Yes |
CeBr3(Cerium Bromide) is a high-performance inorganic scintillator crystal known for its high light output, fast decay time, and excellent energy resolution, CeBr3 offers superior timing characteristics and is well-suited for applications requiring precise radiation detection and spectroscopy.EBO proudly offers high-performance CeBr3 Crystal, a superior scintillation crystal material designed for precise and efficient radiation detection applications. Our CeBr3 Crystal products are manufactured with advanced techniques to ensure exceptional light output, fast decay times, and excellent energy resolution.
Compared to traditional scintillators like NaI(Tl), CeBr3 provides lower intrinsic background radiation, enabling highly sensitive measurements even in low-radiation environments. Its excellent optical properties and compatibility with photomultiplier tubes (PMTs) and silicon photodetectors make it ideal for use in nuclear medicine imaging, gamma-ray spectroscopy, homeland security, and high-energy physics research.
High Light Yield: The CeBr3 Crystal delivers an intense scintillation light output, facilitating highly sensitive detection.
Fast Decay Time: With a rapid decay time (~20 ns), our CeBr3 Crystal supports high counting rates and precise timing measurements.
Superior Energy Resolution: Provides sharp spectral peaks essential for accurate radiation spectroscopy.
Low Intrinsic Background: Reduces noise and improves detection accuracy in low-radiation environments.
Excellent Mechanical Stability: Robust structure suitable for diverse industrial and scientific applications.
Related Products
LYSO(Ce) - Lutetium Yttrium Orthosilicate (Lu₂SiO₅:Ce) is a relatively new scintillator crystal that features high density, high light output, short decay time and good radiation resistance. These properties make it ideal for detecting and measuring ionizing radiation such as gamma rays and positrons.
Advantage:
Excellent Energy Resolution
High Charge Collection Efficiency
High Speed Detection
Direct Conversion – True Semiconductor
High Density and Effective Z
Advantage: High density CdWO4 scintillator、Strong anti-radiation ability、No background radiation
Advantage: High energy resolution、High light output、High photon yield
Advantage:
High sensitivity
Low afterglow
Fast conversion
BGO (Bismuth Germanate) is a high-Z, high-density scintillating crystal. The material has a high atomic number (Z=83 for bismuth) and a density of 7.13 g/cm³, making it a highly efficient gamma-ray absorber.
Due to the high-Z properties of the material, the gamma-ray-induced light absorption fraction is significantly enhanced, resulting in an excellent peak-to-total ratio.
Cesium iodide (CsI(Tl)), activated by thallium, is one of the most efficient scintillators discovered so far. CSI Crystal exhibits thallium-activated luminescence with an emission peak at 550 nm and a light output of 45% relative to NaI(Tl). In contrast, cesium iodide activated by sodium (CsI(Na)) features a sodium-activated emission peak at 420 nm and a higher light output (85% of NaI(Tl)). Both materials share properties such as deliquescence, soft and plastic mechanical behavior, radiation resistance, high-temperature tolerance, and fast timing characteristics (for pure CsI). They are widely used in particle detection for high-energy physics experiments, medical SPECT imaging, baggage/container security inspection, industrial level sensing and non-destructive testing, and cosmic ray research in space physics.
Advantage:
High sensitivity
Low afterglow
Fast conversion
Advantage:High photon yield、High energy resolution、Non-hygroscopicity
GAGG Scintillation Crystal Gadolinium Aluminum Gallium Garnet
Advantage:
High light outputs
Best energy resolution
Fast emission
Excellent radiation hardness
Fast decay times