哌嗪二酮的气相Hel光电子能谱及其量化计算

给出了哌嗪二酮的气相HeI紫外光电子能谱(UPS), 并进行了化合物分子的HAM/3, MNDO, MINDO/3, INDO, CNDO/2和EHMO等量子化学计算研究. UPS谱低电离能(<11.00 eV)区的四重峰被指认为分子体系中氧-氧, 氮-氮原子孤对轨道间的通过键相互作用导致的分裂峰. 表明HAM/3和MNDO计算法是预指该化合物实验电离能正确次序、轨道对称性类型以及通过键相互作用导致分裂大小的较好方法.     

Vibrational spectra and gas phase structure of N-cyanoimidosulfurous difluoride, NCN=SF2

The vibrational spectra, IR (gas) and Raman (liquid) of N-cyanoimidosulfurous difluoride, NCN=SF2, were recorded, and the molecular structure was determined by gas electron diffraction. The spectra were assigned by comparing the vibrational frequencies with those in related molecules and with calculated (HF, MP2, B3LYP with 6-31G(d) basis sets) values, and a normal coordinate analysis was performed. The molecule possesses a syn conformation (Ctriple bondN syn with respect to the bisector of the SF2 angle). This has been rationalized by orbital interactions of the electron lone pairs of sulfur and nitrogen with the N-C and S-F bonds, respectively, which are antiperiplanar or anticlinal to these lone pairs (anomeric effects). Quantum chemical calculations with the B3LYP and MP2 methods reproduce the experimental structure reasonably well if large basis sets (6-311G(2d,f)) are used.     

UPS of multilayer nitrogen‐bearing compounds on the Si(100) surface

Ultraviolet photoemission spectra (UPS) are presented for condensed layers of three ethylated amines; mono‐, di‐, and triethylamine (TEA) on the Si(100) surface at 100 K. The photoemission peaks associated with the nitrogen lone pair electrons are identified in the amines and compared with the corresponding spectra for condensed ammonia. Shifts in the lone pair binding energy for the ethyl‐substituted amines are shown to be consistent with conventional chemical paradigms. Also, for comparison purposes spectra for two nonethylated amines, trimethylamine (TMA), and its silicon analog, trisilylamine (TSA), are presented and discussed. Copyright © 2008 John Wiley & Sons, Ltd.     

Through space and through bond interactions in [2,2] metacyclo-2,6-pyridinophane studied by ultraviolet photoelectron spectroscopy

The UV photoelectron spectrum of [2,2] metacyclo-2,6-pyridinophane has been analyzed on the basis of a perturbational molecular orbital analysis and CNDO/2 calculations. Through space and through bond interactions are shown to be present between the two pyridine rings. In particular a strong interaction has been found between the nitrogen lone pairs and the π systems of the rings.     

On the heavy atom on light atom relativistic effect in the NMR shielding constants of phosphine tellurides

The relativistic HALA effect has been shown to depend on the spatial deformation of the lone electron pairs of a heavy atom, as demonstrated for alkyl and alkene phosphine tellurides. It was found that HALA effect on phosphorous nuclear magnetic resonance shielding constant is strongly dependent on the spatial arrangements of light substituents on phosphorus, resulting in the deformation of the lone electron pairs of tellurium.     

A theoretical exploration of unexpected amine···π interactions

Counterintuitive amine lone pair···π interactions are computationally revealed by MP2 and CCSD(T) methods, attractive lone pair···π interactions are observed when the lone pair of nitrogen points toward the π system. Symmetry adapted perturbation theory (SAPT) calculations and atoms in molecules (AIM) analyses were performed and the origin of the calculated attractive interaction between nitrogen lone pairs and π rings is discussed. Dispersion effects were revealed to play a crucial role in the attractive lone pair···π interaction.     

Ionization of the Conformers of cis Nanotubular Cyclic Peptides in the Gas Phase: Effect of Size and Conformation on Ionization

Cyclic peptides, because of their unique spatial conformations, simplicity, and limited conformational freedom, are widely used as model molecules for larger peptides in chemistry and biochemistry. In this work, the ionization energies and photoelectron spectra of different conformers of the cyclic peptides (n = 2–15) were calculated using the symmetry‐adapted cluster‐configuration interaction (SAC‐CI) method and D95 + (d,p) basis set in the gas phase. The calculated photoelectron spectra were used to study the electronic structures of the cyclic peptides. It was observed that the first ionization energy of the cyclic peptides decreases with the ring size, reaches a minimum, and then increases. In addition, the first ionization band of the cyclic peptides was assigned to the ionization of the lone electron pairs of the nitrogen atoms, although there are π electrons of the CO bond and the lone electron pairs of oxygen atoms in the structure of the peptides.     

The 1H NMR spectra of zinc complexes of pyridine-2-carbaldehyde 2′-pyridylhydrazone

Proton magnetic resonance spectra at 100 MHz are described for some zinc complexes of the E- and Z-isomers of pyridine-2-carbaldehyde 2′-pyridylhydrazone in d₆-dimethylsulphoxide solution. Chemical shift data are discussed qualitatively in relation to factors such as the charge on the metal ion, the anisotropy of ligand nitrogen atoms, electric field effects caused by the dipole moment of nitrogen lone pairs, metal-nonbonded-hydrogen interactions, ring current effects and the conformational changes undergone by each isomer on coordination.     

The electronic structure of heteroaromatic molecules; ab initio calculations and photoelectron spectra for the isomeric-oxazoles and some -oxadiazoles

The UV photoelectron spectra are reported for isoxazole and 1,3,4-oxadiazole (He(I) region), oxazole and 1,2,5-oxadiazole (He(I) and He(II) regions). Marked fine structure is apparent on some of the spectra. The spectra have been assigned on the basis of ab initio calculations, and by comparison with the azoles and thiazoles. Variations in the lone pairs levels at O-, S- and N- across the azoles, oxazoles, thiazoles and azines are discussed. It is suggested that “through-bond” interactions are more widespread in the azines than previously noted.     

Electronic structure of hydantoin studied by He I photoelectron spectroscopy and MNDO quantum—chemical calculations

The He I photoelectron spectra of hydantoin, 1-methyl-hydantoin, 3-methylhydantoin and 1,3-dimethylhydantoin are reported. Displacement of the bands upon the N-methylsubstitution indicates that HOMO and the third highest occupied MO are localized on the nitrogen atoms, the former on the amidic nitrogen and the latter on the imidic one. The second and the fourth highest occupied MO's are oxygen lone pairs. The MNDO method provides the same picture.     

Adjacent Lone Pair (ALP) Effect: A Computational Approach for Its Origin

The adjacent lone pair (ALP) effect is an experimental phenomenon in certain nitrogenous heterocyclic systems exhibiting the preference of the products with lone pairs separated over other isomers with lone pairs adjacent. A theoretical elucidation of the ALP effect requires the decomposition of intramolecular energy terms and the isolation of lone pair–lone pair interactions. Here we used the block‐localized wavefunction (BLW) method within the ab initio valence bond (VB) theory to derive the strictly localized orbitals which are used to accommodate one‐atom centered lone pairs and two‐atom centered σ or π bonds. As such, interactions among electron pairs can be directly derived. Two‐electron integrals between adjacent lone pairs do not support the view that the lone pair–lone pair repulsion is responsible for the ALP effect. Instead, the disabling of π conjugation greatly diminishes the ALP effect, indicating that the reduction of π conjugation in deprotonated forms with two σ lone pairs adjacent is one of the major causes for the ALP effect. Further electrostatic potential analysis and intramolecular energy decomposition confirm that the other key factor is the favorable electrostatic attraction within the isomers with lone pairs separated.     

Chemical Bonding and Electronic Localization in a GaI Amide

The electron density in a one‐coordinate [Ga^IN(SiMe₃)R] complex has been determined from ab initio calculations and multipole modeling of 90 K X‐ray data. The topologies of the Laplacian distribution and the ELI‐D match a situation having an sp³‐hybridized nitrogen with a tetrahedral arrangement of two single σ‐bonds (to carbon and silicon) and two lone pairs pointing towards gallium in a scissor‐grasping fashion. The analysis of the Laplacian distribution furthermore reveals a ligand‐induced charge concentration (LICC) in the outer core of gallium oriented directly towards the nitrogen atom, and thus in between the two lone pairs. These observations might suggest that the trigonal planar nitrogen geometry result from a dative Ga?N bond, in which the roles of the metal and the ligand have been reversed with respect to a “standard” metal–ligand interaction, that is, the metal is here electron‐donating. The ELI‐D reveals a diffuse and directional lone pair on gallium, suggesting that this complex could serve as a σ‐donor.     

Luminescence and photochemical properties of hydrazones of aromatic aldehydes

Luminescence and photochemical properties found by us earlier for several hydrazones of aromatic aldehydes have been shown to be characteristic also of other compounds of this class. The structure of the product of reversible photochemical reaction of hydrazones of aromatic aldehydes is explained by specific interactions between the lone electron pairs of the two vicinal nitrogen atoms in the molecule of hydrazine. Compounds possessing photochromic properties have been suggested and prerequisites of application of luminescent hydrazones as luminophors have been formulated.     

Ionization potentials of some azoalkanes by photoelectron spectroscopy

Photoelectron spectra have been obtained for a set of azo compounds consisting of three pairs of cis, trans isomers, seven bridgehead substituted 2,3-diazabicyclo[2.2.2]oct-2-enes (DBO's), and one arylazoalkane. The lowest ionization potentials, which range from 7.83 to 9.21 eV, do not correlate with cis ground state energy or photolability of the DBO derivatives. Vibrational fine structure was observed in three DBO's, allowing verification that the lowest ionization takes place from the antibonding combination of nitrogen lone pairs.     

The complexing ability and structure of Si-substituted silatranes

The proton NMR spectra of Si-substituted silatranes, a new class of biologically active compounds, measured in the presence of Co²⁺, Ni²⁺ and Eu³⁺ ions are examined. These silatranes coordinate with Co²⁺ and Ni²⁺ through a nitrogen atom and with Eu³⁺ through an oxygen atom mainly without transition to the exo-form. The electronic structure of nitrogen in silatranes is the same as that of pyrrol nitrogen. This suggests that in silatranes a nitrogen lone pair and oxygen lone pairs form common electron system analogous, for example, to the π-system of unsaturated cycles.     

Halogen-halogen interactions in halomethanes

We report the study of the electronic structure of CHFI(2), CHBrI(2), CHBr(2)I, CHClI(2), and CHCl(2)I using VUV photoelectron spectroscopy (UPS). The lone pair orbital interactions are discussed on the basis of experimental results and comparisons with other halomethanes.     

Konformationen von 1,3-dioxanen nach der kraftfeldmethode. nichtbindende wechselwirkungen von sauerstoff

The treatment of oxygen lone pairs in force field calculations is discussed. The geometries of 1,3-dioxanes can be calculated well without explicit account of lone pairs. For the calculation of conformational energies in 5-alkyl-1,3-dioxanes electrostatic interactions between point charges taken from quantum mechanical calculations must be included. Addition of van der Waals interactions of lone pairs as weak potentials further improves the calculated conformational energies.     

UV photoelectron spectroscopic study of substituent effects in quinoline derivatives

The molecular and electronic structure of eight substituted quinolines has been investigated by HeI/HeII photoelectron spectroscopy, Green's function calculations, and comparison with the spectra of related compounds. The correlation between nitrogen lone pair ionization energies and basicity in 18 substituted quinolines is discussed. The influence of different substituents has been quantified via the scheme that is based on experimental energy shifts. The relationships between nitrogen ionization energies, pK(a) values, and medicinal activity are also discussed.     

Water–Water and Water–Solute Interactions in Microsolvated Organic Complexes

A structural study of microsolvated clusters of β‐propiolactone (BPL) formed in a pulsed molecular jet expansion is presented. The rotational spectra of BPL–(H₂O)_n (n=1–5) adducts have been analyzed by broadband microwave spectroscopy. Unambiguous identification of the structures has been achieved using isotopic substitution and experimental measurements of the cluster dipole moment. The observed structures are discussed in terms of the different intermolecular interactions between water molecules and between water and BPL, which include n–π* interactions involving the lone pairs of electrons on water oxygen atoms and the antibonding orbital of the BPL carbonyl group. The changes induced in the structures of the water hydrogen‐bonding network by complexation to BPL indicate that water clusters adopt specific configurations to maximize their links to solute molecules.     

First-principles measurements of charge mobility in organic semiconductors: Valence hole–vibration coupling in organic ultrathin films

Although a great deal of research has been conducted on the electrical properties of organic devices, numerous crucial problems still remain. Of these, the study of charge mobility in organic semiconductor systems has been one of the most important subjects that has remained a puzzle for many years. It is essential to quantitatively understand conduction charge-molecular vibration coupling as well as the intermolecular interaction to discuss mobility. This article describes recent successes with direct measurements of valence hole–vibration coupling in ultrathin films of organic semiconductors with ultraviolet photoelectron spectroscopy (UPS), which can be used to experimentally study charge mobility based on energy and momentum conservation rules. The method may thus be categorized as a first-principles study of charge mobility. The detection of hole–vibration coupling of the highest occupied molecular orbital (HOMO) state in a thin film by UPS is essential to comprehending hole-hopping transport and polaron-related transport in organic semiconductors. We also need to experimentally determine energy-band dispersion or energy-level splitting in a molecular multilayer to obtain information on intermolecular interactions. Since the information on these is concealed behind the finite bandwidth of the HOMO in UPS spectra, we need to obtain high-resolution UPS measurements on organic thin films. Only careful measurements can attain the high-resolution spectra and provide these key parameters in hole-transport dynamics. A key method in achieving such high-resolution UPS measurements is also described.