Complex hydrogen bonded cations-V further asymmetric ions

Solutions have been prepared containing the complex cations (¹BH²B)⁺, where the differing bases may be pyridine, 4-Me pyridine, NMe imidazole, thiazole, isooxazole, trimethylamine or NMe piperidine. The infrared spectra usually show a double maximum in the v_s band, the intensity of the lower component decreasing as the difference in the pKa's of the bases increases. In the D-bridged analogues only a single v_sband occurs. Other features of the spectra indicate that the bridging proton potential is asymmetric. The lower frequency component of the v_s band of the H-bonded system is attributed to Fermi resonance, not proton tunnelling. The proton potential in these and the related symmetric complex cations is reviewed.     

Complex hydrogen bonded cations-IV further symmetric ions

Solutions containing the complex hydrogen bonded cations (NMe imidazole)₂ H⁺; (thiazole)₂H⁺ and (benzothiazole)₂H⁺ have been prepared. The spectra display a pronounced double maximum in the v_s infrared band, which is replaced by a single band in the D-bridged analogues. The activity of the far infrared v_s band, the frequency of the NH bending mode, and the observation of internal modes characteristic of both donor and acceptor all indicate that the hydrogen bonding proton is not located at the mid point of the NβN bridge.Salts of the complex (benzothiazole)₂H⁺ cation have been obtained in the solid state, and have a similar infrared spectrum to the complex in solution.     

Electronic structures and optical properties of wurtzite type LiBSe2 (B=Al, Ga, In): A first-principles study

The electronic structures of three wurtzite type isostructural compounds LiBSe₂ (B=Al, Ga, In) are studied by the density functional theory (DFT). The results reveal that the presence of Li cations has direct influence on neither the band gaps (Eg) nor the bonding levels, but plays an important role in the stabilization of the structures. The band structures and densities of states (DOS) are analyzed in detail, and the band gaps of LiBSe₂ adhere to the following trend Eg_(LiAlSe2)>Eg_(LiGaSe2)>Eg_(LiInSe2), which is in agreement with the decrease of the bond energy of the corresponding Se 4p-B s antibonding orbitals. The role of the active s electrons of B element on the band gaps is also discussed. Finally, the optical properties are predicted, and the results would be a guide to understand the experiments.     

Combined analysis of microwave and infrared spectra of methyl iodide: rotational and l-type doubling constants of the v5, v3+v6 and v2 states

The rotational constant B and the l-type doubling constant q were determined for the v₅, v₃+v₆ and v₂, states of CH₂I from the microwave transition frequencies, in combination with the infrared data previously reported. Since these vibrational states were coupled through the Fermi resonance and the xy-type E-E and A₁-E Coriolis resonances, the analysis was made by setting up and solving the complete form of the secular determinants of the energy matrices. The rotational and l-type doubling constants were determined as B₅, = 0.250 173 cm^?1, B₃₆ = 0.247 600 cm^?1, B₂ = 0.249 369 cm^?1, q₅ = ?0.000 027 cm^?1 and q₃₆ = ?0.000 179 cm^?1, which are unperturbed by Fermi and Coriolis interactions. Other band constants for v₅ and v₃+v₆ were also refined in accordance with the new values of B₅ and B₃₆. The present study indicated that the combined analysis of microwave and infrared spectral data was useful for the precise determination of vibration-rotation, levels in the perturbed system.     

Isotopic effects in NH…N hydrogen bonds

The value of the isotopic ratio (ISR) v_s(NH)/v_s(ND) has been determined for a number of crystalline compounds containing homoconjugated [NHN]⁺ cations, including various salts of 1,8-bis(N,N-dimethylamino)naphthalene (DMAN). The results obtained, together with the literature data, enabled us to plot a correlation between the ISR and v_s(NH) which appears to be similar to that found by Novak for OHO systems. For DMAN · HPF₆ the highest ISR value known so far (2.05) is reported. An empirical analytical form of the correlation is proposed.     

A CNDO/S study of the importance of electron repulsion parameters and charge density changes on the weakness of the v8(e2g) vibronic activity in the benzene 260 nm band

We investigate the disparity between the large observed ratio ( ≈100:1 ) of v₆ to v₈ vibrationally induced intensity in the 260 nm ( ¹B_2u–¹A_1g) absorption band of benzene and that computed from CNDO/S and INDO/S (typically 4:1). The calculated v₈ intensity is relatively insensitive to small admixtures of the v₆ mode, but is found to be quite sensitive to the nature of the semiempirical electron repulsion integral (γ) distance dependence. A new perturbation theory is applied successfully which relates the vibronic coupling directly to changes in the Fock matrix and the simple first-order transition density.     

The line profiles of single rotational lines of the H 2 B - X(3, 0) band in an intense infrared light field

The first investigation of the lineshape of single rotational lines of the H ₂ B - X(3, 0) band in an intense infrared light field (λ = 1064 nm) at intensities between 10¹⁰ W/cm² and 10¹² W/cm² is reported. The B - X(3, 0) band is excited with low intensity vacuum ultraviolet radiation (λ ≈ 106 nm). B-state excitation is observed by multiphoton ionization and dissociation of H ₂ with H ⁺ as final product. The lineshapes of the B-X(3, 0) band behave differently in both decay channels. This indicates that they branch before the molecule is photoionized. The intensity dependence of the lineshapes seems to show that at certain intensities in the focused infrared light beam the AC-Stark effect induces transient resonances into the multiphoton excitation process starting at the B(v = 3, J) rotational levels. A qualitative analysis of the states which may influence the B(v = 3, J) multiphoton excitation rate is given.     

Triplet—triplet absorption of some azanaphthalenes

Experimetnal and theoretical studies of TT spectra, previously restricted mostly to D_2h and C_2v hydrocarbons, are extended to C_s heterocyclics. The TT spectrum of quinoline and isoquinoline can be interpreted as resulting from a dilution of the naphthalene ³B^?_1g state over near lying levels in the azanaphthalenes.     

Infrared and paH correlation of proton transfer in and bridges in acetonitrile

Hydrogen bond complexing (BHB)⁺ between N-bases and their cations has been examined by infrared spectroscopy and potentiometry. In the acetonitrile (AN) solution there have been studied hetero-systems (B + B₁H⁺), where the differing bases, B, may be triethylamine, N-methylpiperidine, morpholine, N-methylimidazole, pyridine, 2- and 3-chloropyridine, quinoline and trimethyl-N-oxide with B₁H⁺ : trimethyl-N-oxideH⁺ and N-methylimidazoleH⁺. Homocomplex (Me₃NO)₂H⁺ has been distinguished. In the H-bridges cation the stretching band ν_s (NH⁺) and (−OH⁺) are dependent directly on the p_aH and formation constant K_f of the component bases.     

Hyperfine structure measurements in the B3IIo+u—X 1Σ+g electronic transition of Br2

Hyperfine splittings in some band heads of the B—X system of Br₂ were measured using laser molecular-beam spectroscopy. Quadrupole coupling constants were derived: eqQ(⁷⁹Br) = 810.0(5) MHz for X¹Σ⁺_g, v = 1, and eqQ(⁷⁹Br) = 179.1(16) MHz for B³πino⁺u, v' = 13.     

Monomere und dimere Chrom(III)-Phthalocyanine: Synthese und Eigenschaften von Hydroxopyridinophthalocyaninatochrom(III) und μ-Oxodi(pyridinophthalocyaninatochrom(III))

Monomeric and Dimeric Chromium(III) Phthalocyanines: Synthesis and Properties of Hydroxopyridinophthalocyaninatochromium(III) and μ-Oxodi(pyridinophthalocyaninatochromium(III)) Heating of ?[Cr(OH)Pc^2?]”? in pyridine (Py) gives the paramagnetic (T = 273 K) complexes [Cr(OH)(Py)Pc^2?] (μ_Cr = 3.84 μ_B) and [(Cr(Py)Pc^2?)₂O] (μ_Cr = 1.24 μ_B) by consecutive substitution and condensation reactions. The UV-VIS spectra are characterized by the typical B, Q, and N regions of the Pc^2? ligand being shifted hypsochromically for the dimer with respect to the monomer due to excitonic coupling (1.5 kK). Regions of weak absorbance between 8 and 13 resp. 19 kK are assigned to trip-quartet transitions for both complexes. A weak band at 870 cm^?1 in the FIR/MIR spectra is assigned to v_as(Cr? O? Cr). In the resonance Raman(RR) spectra v(Cr? O) at 514 cm^?1 resp. v_s(Cr? O? Cr) at 426 cm^?1 is selectively enhanced. Further strong RR-lines of the μ-Oxo dimer at 110 and 631 cm^?1 are assigned to a (Py? Cr? O)- resp. internal pyridine deformation of a_1g symmetry. An assignment as 2v_as(Cr? O? Cr) is proposed for the remarkable RR line at 1740 cm^?1.     

Production of the n2 herman infrared system by the energy pooling reaction of N2(Δ3Σ+u) metastable nitrogen molecules

Molecular N₂ emission, observed from an Ar(³Po, 2) and Xe(³P₂) + N₂ flowing afterglow apparatus, indicates that the energy pooling reaction by 2N₂(A ³Σ⁺_u) generates the emission from the Herman infrared system, which is an unassigned nitrogen band system. A lower limit to the formation rate constant for the upper state of the Herman infrared system was found to be 2.5 × 10^-11 cm³ molecule^?1 s^?1. The information presented here may help in the identification of the upper and lower states of the emission system. The 2N₂(A) energy pooling reaction also forms N₂(B³ Π_g, v? 8) but a rate constant cannot be assigned from the present data.     

The emission spectrum of the 1B1(π*-n+) state of 1,2-cyclobutanedione excited at 488.0 nm

The spectrum of the emission from the ¹B₁(π^*-n₊) state of 1,2-cyclobutanedione excited at 488.0 nm has been measured. Wavelengths and vibrational assignments are reported for 24 bands between 490 and 550 nm, 12 of which can be identified with hot bands in the absorption spectrum. Prominent bands in the emission spectrum are associated with excitation of V^''₈, the symmetric in-plane carbonyl bend (281 cm⁻¹); v^''₁₂, the asymmetric carbonyl wag (488 cm⁻¹); and v^''₇, a symmetric ring distortion (522 cm⁻¹). Sequences in v₁₃, the ring-twisting vibration, are also prominent; the initial excitation lies in the 13³₃ absorption band, while the emission shows intensity maxima for v^'₁₃ = 0 and 2, and a bimodal vibrational relaxation is suggested.     

Sub-doppler two-photon spectrum of asymmetric rotor molecules: analysis of the qqQ rotational branch of the S1(1B2u)141 ← S0(1A1g) system of benzene-d1

The Doppler-free two-photon excitation spectrum of the ^qqQ branch of the 14¹₀ vibrational band of the S₁(¹B_2u) ← S₀(₁A_1g) transition of benzene-d₁ has been recorded using a cw single-mode dye laser coupled to an external concentric resonator. The spectrum has been analysed using a non-rigid Watson Hamiltonian. More than 200 lines with J up to 20 have been assigned and the rotational constants which best reproduce the spectrum are A¹_v = 0.181435, B¹_v = 0.169990, C¹_v = 0.089055 cm⁻¹. The K_a = odd lines of the ^qqQ₅(J) subbranch show small and quite regular perturbations of 60 ± 5 MHz which are probably due to a coupling to another vibrational state of the S₁ manifold.     

A theoretical comparison of the lowest-lying singlet and triplet states of H2CBe and of HCBeH

The low-lying singlet and triplet states of H₂CBe and HCBeH are examined using ab inito molecular orbital theory. In agreement with earlier results, the lowest-lying structure of H₂CBe has C_2v symmetry and is a triplet with one π electron (³ B₁). The results presented here suggest that the lowest-energy singlet structure is the (¹B₁) open-shell singlet, also with C_2v symmetry, at least 2.5 kcal/mol higher in energy. The singlet C_2v structure with two π electrons (¹A₁) is 15.9 kcal/mol higher than ³B₁. All of these structures are bound with respect to the ground state of methylene and the beryllium atom. In HCBeH, linear equilibrium geometries are found for the triplet (³Σ) and singlet (¹Δ) states. The triplet is more stable than the singlet (¹Δ) by 35.4 kcal/mol, and is only 2.9 kcal/mol higher in energy than triplet H₂ CBe. Since the transition structure connecting these two triplet molecules is found to be 50.2 kcal/mol higher in energy than H₂ CBe, both triplet equilibrium species might exist independently. The harmonic vibrational frequencies of all structures are also reported.     

Electronic absorption spectrum of Fe3+ doped in ammonium chloride single crystal

The electronic absorption spectrum of the Fe²⁺ ion doped in ammonium chloride has been studied at room and liquid air temperatures. The observed bands have been assigned transitions from the ground ⁶A_1g(S) state to the excited ⁴A_1g(⁴E_g), ⁴T_1g(G) and ⁴T_2g(G) states. The cubic field approximation with D_q = 675 cm^?1, B = 645 cm^?1 and C = 4.4 B is found to give a good fit to the observed band positions.It is further concluded that the site symmetry of the Fe³⁺ ion in the crystal is lowered from O_h to C_4v symmetry at liquid air temperature.     

The photoperoxidation of unsaturated organic molecules--XV. O21Delta g quenching by bilirubin and biliverdin.

Abstract —The use of competitive methods with rubrene as reference acceptor provides values of the rate constants k^B_Q= 2.3 times 10⁹/ mol^-1 s^-1 and k^v_q= 3.3 times 10⁹ mol^-1 s^-1 for the physical quenching of O₂¹δg, by bilirubin (in CCl₄) and biliverdin (in CHCl₃) respectively attributed to electron and energy transfer processes. The rate constant k^B_R= 1.7 times 10⁸/ mol^-1 s^-1 for bilirubin reaction with O₂¹δg is considerably greater than that k^v_R 3 times 10⁸ mol^- s^-1 for the reaction of biliverdin which has identical O₂¹δa, acceptor sites, and is attributed to a primary Type I oxidation process followed by a slower Type II addition of O₂¹δg to the primary products.     

High-resolution UV photoelectron spectrum of CO2

The highly-resolved HeI photoelectron spectrum of CO₂ is presented and its vibrational structure studied in detail. In the X? ²Π_g ionic state the v₃ antisymmetric mode is found to be excited in double quanta (v_1-v_2-v₃ = 0. 0. 2) with energy hv₃ = 181 meV. In the C? ²Σ_g⁺ state a single quantum of the same mode is found to be excited (hv₃ = 189 meV) in combination with a v₁ excitation. Vibronic interaction with vibrational levels in the B? ²Σ_u⁺ state of the ion is suggested to promote this (1, 0, 1) excitation. It is established that inelastic scattering processes contribute to the vibrational structure in the C? ²Σ_g⁺ band. The spin-orbit splitting in the X? ²Π_g is determined to be 19±1 meV and 10±2 eV in the ā²Π_u state. Vibronic structure is resolved in the X? ²Π_g band where the Renner-Teller coupling constant is determined to be ? = 0.21±0.02 and the vibrational energy of the v₂ mode as 60±7 meV. In the ā²Π_u state the v₂ energy is found to be hv₂ = 60 meV from the observed hot-band structure.     

Laser-induced fluorescence in N2 and N+2 by multiple-photon excitation at 266 nm

The fluorescence transitions corresponding to the second positive system of N₂ (C³Π_u → B³Π_g) for Δv = 0, 1 and the first negative system of N⁺₂(B²Σ⁺_u → X²Σ⁺_g) for Δv = 0, 1, 2 have been observed following laser-induced mul excitation of N₂.     

The emission spectrum of AsH2(Ã2A1 → X̃2B1) via uv photolysis of AsH3

The AsH₂(òA₁ → X̃²B₁) emission spectrum (402–650 nm) following ArF laser photolysis of AsH₃ is reported. Seven bands are assigned and the relation ν = 19928 + (868v'₂-3v'₂²)-(987v″₂-6v″₂²) is obtained. The AsH₂ (òA₁) radiative lifetime is 130 ± 20 ns. Emission spectra from nascent As and a multiphoton ionization signal were also obtained.