The photodissociation of gaseous molecular nitrogen has been investigated intensively, but the corresponding knowledge in a solid phase is lacking. Irradiation of pure solid nitrogen at 3 K with vacuum-ultraviolet light from a synchrotron produced infrared absorption lines of product l-N3 at 1657.8 and 1652.6 cm(-1). The threshold wavelength to generate l-N3 was determined to be (143.7±1.8) nm, corresponding to an energy of (8.63±0.11) eV. Quantum-chemical calculations support the formation of l-N3 from the reaction N2 +N2, possibly through an activated complex l-N4 upon photoexcitation with energy above 8.63 eV. The results provide a possible application to an understanding of the nitrogen cycle in astronomical environments.
Samples of pure methane and of methane dispersed in solid neon at 3 K subjected to irradiation at wavelengths less than 165 nm with light from a synchrotron yielded varied products that were identified through their infrared absorption spectra, including CH3, C2H2, C2H3, C2H4, C2H6, C4H2, C4H4, C5H2, C8H2, CnH with n = 1-5, and carbon chains Cn with n = 3-20. The efficiency of photolysis of methane and the nature of the photoproducts depended on the concentration of methane and the wavelength selected for irradiation; an addition of H2 into solid neon enhanced the formation of long carbon chains.
We recorded absorption spectra of diborane(6), B2H6 and B2D6, dispersed in solid neon near 4 K in both mid-infrared and ultraviolet regions. For gaseous B2H6 from 105 to 300 nm, we report quantitative absolute cross sections; for solid B2H6 and for B2H6 dispersed in solid neon, we measured ultraviolet absorbance with relative intensities over a wide range. To assign the mid-infrared spectra to specific isotopic variants, we applied the abundance of (11)B and (10)B in natural proportions; we undertook quantum-chemical calculations of wavenumbers associated with anharmonic vibrational modes and the intensities of the harmonic vibrational modes. To aid an interpretation of the ultraviolet spectra, we calculated the energies of electronically excited singlet and triplet states and oscillator strengths for electronic transitions from the electronic ground state.
Fluorescent nanodiamonds
(FNDs) containing nitrogen-vacancy (NV)
centers as built-in fluorophores exhibit a nearly constant emission
profile over 550–750 nm upon excitation by vacuum-ultraviolet
(VUV), extreme ultraviolet (EUV), and X-radiations from a synchrotron
source over the energy (wavelength) range of 6.2–1450 eV (0.86–200
nm). The photoluminescence (PL) quantum yield of FNDs increases steadily
with the increasing excitation energy, attaining a value as great
as 1700% at 700 eV (1.77 nm). Notably, the yield curve is continuous,
having no gap in the VUV to X-ray region. In addition, no significant
PL intensity decreases were observed for hours. Applying the FND sensor
to measure the absorption cross-sections of gaseous O2 over
110–200 nm and comparing the measurements with the sodium-salicylate
scintillator, we obtained results in agreement with each other within
5%. The superb photostability and broad applicability of FNDs offer
a promising solution for the long-standing problem of lacking a robust
and reliable detector for VUV, EUV, and X-radiations.
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