Scintillator crystal

Scintillation counting Scintillation crystals Scintillation detector Scintillation detectors... 

The scintillation counter is a solid state radiation detector which uses a scintillation crystal (phosphor) to detect radiation and produce light pulses. Figure 24 is important in the explanation of scintillation counter operation. 

As radiation interacts in the scintillation crystal, energy is transferred to bound electrons of the crystal s atoms. If the energy that is transferred is greater than the ionization energy, the electron enters the conduction band and is free from the binding forces of the parent atom. 

The distributions of americium on the fissure surfaces were then quantitatively determined by scanning the face of each fissure with a Nal scintillation crystal through a 0.3 cm slit in lead shielding. The 59 keV gamma ray emitted by Am was monitored. Histograms of the americium distributions on the fissure surfaces were produced and are presented in Figures 5, 7, and 9. 

Before injection, monitoring probes re placed on the outlet lines close a the exit from the tank being tested. These probes consist of a l-in.-diarr.-tter, thalium-activated sodium-iodide scintillation crystal, a small portable meter, and a recorder. 

The rate meter provides the required high voltage for (he photomultiplier iibes and converts the digital signal obtained from the scintillation crystal to an analog output for the recorder. 

Scintillation crystals -sodiumiodide for [SODIUMCOMPOUNDS - SODIUT TALIDES - SODIUMIODIDE] (Vol22)... 

Two important quantities relating to fluorescent solutions are the mean life of the excited state and the quantum yield. In the ideal case where every excited molecule loses its energy by radiation the emission intensity decays exponentially with time, and the time to drop to 1/e of the original intensity is called the radiational mean life. If only a fraction F of the molecules radiate, the remainder being degraded in some other competitive way, then the actual life, as would be found by measurement, is smaller by the fraction F. This relationship, however, would not be true if some of the molecules were almost instantly degraded by solvent molecules after excitation. Direct determinations of mean lives require special apparatus, sometimes of doubtful accuracy, because of the short times, 10-7 to 10 9 sec., involved. Although much work has been done in this field with scintillator crystals and solutions, there are... 

The recent general availability of solid state Ge(Li) gamma-ray detectors has made possible new applications of activation analysis to multielement trace analysis. A simplified schematic representation of a Ge(Li) detector is given in Fig. 6. The principal advantage of these detectors is their excellent energy resolution for gamma-ray spectrometry 52>. While a typical 3 X 3" NaI(Tl) scintillation crystal may have a photopeak resolution of 50 KeV fwhm (/ull width at Aalf maximum) for the 137Cs... 

Because a 2-D photon-counting detector was not available at the time of construction of the demonstrator, the detector was realized as a single 1-D vertical detector column based on scintillator crystals and photomultipliers, which can be rotated around the focus point, thereby acquiring one projection. Spatial resolution was ensured by a collimator made of thin tungsten lamellae placed in front of the detector. 

The availability of a new version of isotopically labeled ATP, [33P]ATP, provided benefits of safety and longer half-life. The lowered energy was also better suited for scintillation proximity assays (SPAs). The SPA was a major step forward because it eliminated the need for wash steps by capturing the [33P]-labeled peptide on a functionalized scintillating crystal, usually via a biotin-streptavidin interaction. 

Another commonly used detector is the scintillation detector. This makes use of a crystal that produces a scintillation (pulse of visible light) upon absorption of an x-ray photon. The visible light is detected by a photomultiplier tube and associated amplifier circuit, which is sensitive enough to detect nearly every scintillation. The scintillating crystal is usually sodium iodide doped with an activator such as thallous iodide. 

Scintillation counters are applied primarily for measuring y radiation and low energy radiation. If y radiation is to be measured, thick scintillating crystals of high density are used in order to absorb as much y radiation as possible. Nal or Csl crys-... 

This type of detector is one of the oldest and most often used in X-ray diffraction. Its response time is extremely low (= 0.2 pS). This feature is its main advantage compared to proportional gas detectors. It is sensitive to the energy of X-rays but has a poor energy resolution. Its efficiency is almost 100%. Compared to proportional gas counters, the background noise is more significant and scintillating crystals deteriorate in a humid atmosphere. 

Larobina M, Brunetti A, Salvatore M (2006). Small animal PET a review of commercially available imaging systems. Curr Med Imag Rev 2 187 Melcher CL (2000). Scintillation crystals for PET. J Nucl Med 41 1051 Patton JA (2002). Physics of PET. In Delbeke D, Martin WH, Patton JA, Sandler MP (eds) Practical FDG imaging. Springer, New York Turkington TG (2001). Introduction to PET instrumentation. J Nucl Med Technol 29(1) 89... 

The increase in the LnX3 concentration results in a rise in the solubility of the corresponding oxide in the melts the solubility values exceed 0.5 mass% at a concentration of CeCl3 in the order of 30 mol%. It shows that the homogeneous melt used for the growth of the scintillation crystals may... 

Consider a gamma source at a distance r from the detector. By assuming that the scintillation crystal is sufficiently small, an approximate relationship between the source activity S and the rate of scintillation n at the crystal is... 

Here, the first factor at the right-hand-side, which represents the fraction of gamma photons intercepted by the scintillating crystal, is equal to the solid angle extended by the detector crystal to the source, with dc denoting the crystal diameter. The efficiency of the crystal t depends on both the material and the size of the crystal. 

The scintillation-crystal type of detector is frequently used for y-rays with energies in the range 50-100 keV. A typical example is the Nal/Tl scintillator. The resolution of scintillators deteriorates with decreasing energy of the y-photon as shown in Fig. 2.10, and such detectors can only be used for very... 

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