Decay Phosphors

Yellow-emitting (526 nm) phosphor decay time in nanoseconds... 

Nonradiative Decay. To have technical importance, a luminescent material should have a high efficiency for conversion of the excitation to visible light. Photoluminescent phosphors for use in fluorescent lamps usually have a quantum efficiency of greater than 0.75. AH the exciting quanta would be reemitted as visible light if there were no nonradiative losses. 

The occurrence of nonradiative losses is classically illustrated in Figure 3. At sufficiently high temperature the emitting state relaxes to the ground state by the crossover at B of the two curves. In fact, for many broad-band emitting phosphors the temperature dependence of the nonradiative decay rate P is given bv equation 1 ... 

Luminescent Pigments. Luminescence is the abihty of matter to emit light after it absorbs energy (see Luminescent materials). Materials that have luminescent properties are known as phosphors, or luminescent pigments. If the light emission ceases shortly after the excitation source is removed (<10 s), the process is fluorescence. The process with longer decay times is referred to as phosphorescence. 

P vapor is extremely toxic and causes bone decay however, it is not present after the smoke is formed. P pentoxide and phosphoric acid are not toxic in small concns, although they may be irritating to the eyes, respiratory tract and skin (Ref 3)... 

P-2 ZnS Cu ZnS, CuS, MgCl2, NaCl Green-emitting (520 nm) phosphor long decay for radar... 

P-12 (ZnMg)F2 Mn2+ ZnF2-4H20, MgF2, MnF2 Radar tubes where moderate decay was desirable. Orange-emitting phosphor (588 nm)... 

P-15 ZnO Zn ZnO (reducing atmosphere) Used originally in a flying spot scanner is applicable for any CRT requiring a highly visible screen and a fast decay. Green-emitting phosphor (515 nm). 

Long decay time phosphor for use in radar. Orange emission at 575 nm... 

Deep blue-emitting (centered at 415 nm) phosphor screen used wherever a very fast decay is needed, such as flying spot scanners... 

Organic scintillation phosphors include naphthalene, stilbene, and anthracene. The decay time of this type of phosphor is approximately 10 nanoseconds. This type of crystal is frequently used in the detection of beta particles. 

Plastic phosphors are made by adding scintillation chemicals to a plastic matrix. The decay constant is the shortest of the three phosphor types, approaching 1 or 2 nanoseconds. The plastic has a high hydrogen content therefore, it is useful for fast neutron detectors. 

In fact, an important advance in the phosphorescence theory was realized by Wiedemann in 1889, stating that a phosphor exists in two forms, a stable one, A, and an unstable one, B. Light absorption brings along conversion of form A to B, which then returns to A emitting light. This hypothesis was in agreement with the exponential decay law as postulated years before by Becquerel, but who did not provide any information about the nature of both forms [5],... 

This survey focuses on recent developments in catalysts for phosphoric acid fuel cells (PAFC), proton-exchange membrane fuel cells (PEMFC), and the direct methanol fuel cell (DMFC). In PAFC, operating at 160-220°C, orthophosphoric acid is used as the electrolyte, the anode catalyst is Pt and the cathode can be a bimetallic system like Pt/Cr/Co. For this purpose, a bimetallic colloidal precursor of the composition Pt50Co30Cr20 (size 3.8 nm) was prepared by the co-reduction of the corresponding metal salts [184-186], From XRD analysis, the bimetallic particles were found alloyed in an ordered fct-structure. The elecbocatalytic performance in a standard half-cell was compared with an industrial standard catalyst (bimetallic crystallites of 5.7 nm size) manufactured by co-precipitation and subsequent annealing to 900°C. The advantage of the bimetallic colloid catalysts lies in its improved durability, which is essential for PAFC applicabons. After 22 h it was found that the potential had decayed by less than 10 mV [187],... 

D. J. Morantz and J. W. Wigley, The contrasting phosphorescence decay kinetics of diacetyl and aromatic ketone phosphors in polymeric matrices, Polymer Communication 26, 170-171 (1985). 

The most important mineral example is natural scheelite. ScheeUte emits a bright blue emission in a broad band centered at 425 nm (Fig. 4.9) with a decay time of several ps. Calcium tungstate CaW04 has long been known as a practical phosphor, and has been carefully studied. The intrinsic blue luminescence center is the complex ion in which the central W metal ion is... 

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