Theoretical calculations were performed to study the effects of hydrogen bonding to various amines on the
oxidation of phenol to phenoxyl radical. It was found that with ammonia as the hydrogen bond acceptor the
phenol oxidation process was a barrierless proton-coupled electron transfer and the shift of the adiabatic
phenol oxidation potential by ammonia in the gas phase was as large as about 1 eV. For other amines, it was
found that depending on the basicity of the amine, the effects of hydrogen bonding to different amines on the
phenol oxidation varied. For those amines that had a proton affinity larger than ca. 204 kcal/mol, the oxidation
of the phenol−amine complexes caused a proton transfer and the proton-transferred structure was the only
minimum found on the potential surface after oxidation. When the proton affinity of the amine was located
in the range of ca. 190−197 kcal/mol, both the proton-transferred and nonproton-transferred structures were
found to be minima for the oxidized complex. However, when the proton affinity of the amine was smaller
than ca. 189 kcal/mol, no proton transfer occurred in the oxidation. The shift of the adiabatic oxidation potential
was found to be roughly in linear correlation with the proton affinity of the amine. For substituted
aminoacetylenes, the shift of the adiabatic oxidation potential was also found to be in linear correlation with
the Hammett σ
p
substituent constants. Finally, it was found that the phenol−imidazole−formate complex
was not a good model for the tyrosine oxidation in photosystem II, because this complex had a too low
oxidation potential. In fact, because of the strong electron donating effects of formate, in addition to phenol
the imidazole moiety in the complex could also be oxidized, which was not observed in the enzymatic systems.
Therefore, the Glu189 residue in photosystem II was proposed to be protonated under the physiological
condition.
In this paper, the (Ca, Ba) 3 (VO 4 ) 2 :Eu 31 red phosphors were prepared by the solid-state reaction method for the first time, and the preferable sintered condition was obtained at 10501C for 6 h. To improve the luminescence intensity of Ca 2.82 (VO 4 ) 2 :0.12Eu 31 , an attempt was made to replace Ca 21 by Ba 21 . It was found that the substitution of 6.7%-9.9% Ba 21 ions instead of the Ca 21 ions enhanced the emission intensity under 465 nm excitation. According to the changes of the lattice constants, this enhancement can originate from the lower site symmetry of the Eu 31 ion in the center with noninversion symmetry. And we observed the optimum value of the Ba 21 content (y) was at 9.9 mol% in (Ca 1Ày Ba y ) 2.82 (VO 4 ) 2 :0.12Eu 31 . Compared with commercial oxysulfide and sulfide red phosphors suitable for blue excitation, our synthesized phosphor (Ca, Ba) 3 (VO 4 ) 2 :Eu 31 has the advantages of no chemical instability or sulfur pollution. In addition, the emission peak at 614 nm and the CIE (International Commission on Illumination) chromaticity points of (0.644, 0.355) for the (Ca 0.901 Ba 0.099 ) 2.82 (VO 4 ) 2 :0.12Eu 31 phosphor indicate this phosphor can be used as a potential candidate for the phosphor-converted white light emitting diode with a blue chip (450-470 nm).
A novel blue-emitting phosphor KSrScSi 2 O 7 :Eu 2+ , synthesized from a water-soluble propylene glycol modified silane (PGMS) silicon precursor by a solution approach, exhibits high internal quantum efficiency and remarkable thermal stability, which are attributed to the rigid structural network of the host and weak electron-phonon coupling strength.
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