CY2519 Sodium Iodide Scintillation Crystal (NaI)

Natriumjodid-Szintillationskristall Description:

Natriumjodid-Szintillationskristall is employed in industry due to its defined physical and chemical properties. Stanford Advanced Materials (SAM) supplies Natriumjodid-Szintillationskristall and has extensive experience in its manufacture and distribution. The product is provided at a price conforming to current market benchmarks.

Natriumjodid-Szintillationskristall Specifications:

Natriumjodid-Szintillationskristall Applications:

It can be employed in the following fields:

- Medicine – SPECT (gamma camera), whole-body counting, radioimmunoassay (RIA)
- Safety – thermal neutron activation
- Industry – thickness or density measurement, coal/mineral screening
- Oil and gas exploration – borehole measurement
- Environmental monitoring
- Aerial survey
- Nuclear physics

Natriumjodid-Szintillationskristall Characteristics:

Scintillation efficiency: The NaI crystals convert incident radiation into quantifiable light signals. This conversion is measured and suitable for scientific detection.

Gamma-ray detection: Their sensitivity to gamma radiation enables their use in gamma spectroscopy and radiation monitoring.

Energy resolution: The crystals facilitate the measurement of radiation energy levels, thereby permitting the identification and quantification of distinct energy bands.

Decay time: A decay time of 250 ns is recorded, which permits prompt response and data acquisition in radiation detection systems.

Advantages ofNatriumjodid-Szintillationskristallen :

Accurate radiation detection: Natriumjodid-Szintillationskristalle enable the detection of ionising radiation with a defined accuracy, thereby supporting research and ensuring safety in specified applications.

Sensitivity: The measurable sensitivity to gamma radiation renders these crystals appropriate for applications in nuclear medicine, radiography and environmental monitoring.

Energy measurement accuracy: The crystals facilitate the measurement of incident radiation energy levels, thereby allowing the identification and quantification of specific isotopes and sources.