From these, the centers of gravity of the spin-orbit components of the triplet terms can ..... (24) R. M. Rush, D. S. Martin, Jr., and R. G. LeGrand, ...
1-pentene in 3MP glass increasedthe luminescence.41 The absorption spectra (S0 -* ... The 86 K warm-up luminescence peak with Xmax at. 480-520 nm which we have .... (001) planes in ref 30. ... Instruments CF200 continuous-flow liquid heliumcryostat.
Optical spectrum of the hexachloromolybdate(V) ion in single crystals of cesium hexachlorozirconate(IV) at 4.deg.K. Howard H. Patterson, and John L. Nims.
The optical absorption and emission properties of Rh" in CS2NaMCI6 (M = Y , In, Sc) and of Ir3+ (M = In) were studied and compared to the more highly resolved ...
Page 2224, eq 5 should read: 1 - A2 - 2B2 - 3C? + A2B2 + ... Model 5: D. = -0.37 to ... The I4C. KIE calculated from eq 7 should read (line 32, p 6677) 1.0150.
Page 2224, paragraph 2: The effect of the above change is to make D vary within a given model for models 3-5. ... ond-order rate constant of 4.2 X. M-I s-l.
DifferentiaI PoIarization Spectroscopy on Single Crystals of Transition Metal Complexes. Hans Peter Jensen. Applied Spectroscopy Reviews 1982 18 (3), 305- ...
Determination of the state equation of NiX 2 from the high-pressure spectra shifts. Zhao Min-Guang , Du Mao-Lu. Journal of Physics C: Solid State Physics 1987 ...
... of the host.9-18 CsPbX3 (X = Cl, Br, I) perovskites nanocrystals with a 3D ..... ideal systems to study the effect of Mn doping on the intensity of the excitonic ...
The Ultraviolet Absorption Spectrum of Oxalyl Chloride Vapor; Spectral Evidence for Rotational Isomerism1. Jerome W. Sidman. J. Am. Chem. Soc. , 1956, 78 (8) ...
UV-Vis Vapor Absorption Spectrum of Antimony(III) Chloride, Antimony(V) Chloride, and Antimony(III) Bromide. The Vapor Pressure of Antimony(III) Bromide.
2672
D. R. Rosseinsky and I. A. Dorrity
to the e< concentration in experiments where the latter reached a plateau at low doses. Likewise, the re-irradiation tests do not prove that radiation-produced olefins are unimportant since the olefin concentration in the melted and refrozen samples would be much lower than the local olefin concentration in the radiation-produced spurs. Thus the reasons for discarding excited olefins as the source of the observed luminescence do not now appear compelling. It has been reportedlo" that the presence of mole fraction of olefins or diolefins in alkane glasses greatly increases the luminescence observed after y irradiation and, in other work, that mole fraction of 2-methyl1-pentene in 3MP glass increased the lumine~cence.~~ The absorption spectra (So SI) of various olefins show red limits near 200 nm1.l5The 230-nm luminescence of yirradiated 3MP is in the correct energy region to represent olefin fluorescence and has a lifetime
