Highest occupied molecular orbital spectroscopy

Hartree-Fock wave functions, 269 High resolution electron energy loss spectroscopy, HREELS, 43, 69 Highest occupied molecular orbital, HOMO, 269... [Pg.570]

Dealing with a molecular ion it is necessary to identify its ground state, that is to remove an electron from the highest occupied molecular orbital (HOMO). The most favorable sites for the charge and unpaired electron localization may be established by taking away an electron with minimal ionization energy. The energy requirements in this case are similar to these known in UV-spectroscopy for the electron transitions a < tt< n. [Pg.149]

In absorption and fluorescence spectroscopy, two important types of orbitals are considered the Highest Occupied Molecular Orbitals (HOMO) and the Lowest Unoccupied Molecular Orbitals (LUMO). Both of these refer to the ground state of the molecule. For instance, in formaldehyde, the HOMO is the n orbital and the LUMO is the n orbital (see Figure 2.1). [Pg.21]

Photoelectron spectroscopy (PES) is also carried out in the gas phase photons of known energy (E/,v), for example, the He(I) line (21.21 eV), ionize a substrate the kinetic energy (Eyn) of the emitted electrons is measured and the vertical ionization potentials (/y) derived (Eq. 13). The PES provides information on the energies of occupied molecular orbitals (MOs) " the highest occupied molecular orbital (HOMO) of the parent reveals the bond(s) likely to be weakened or broken upon ionization. The PES data reflect the geometries of the parent molecule and need not have any bearing on the equilibrium structure of the radical cation. [Pg.211]

The highest occupied molecular orbital (HOMO) in formaldehyde and heteroaldehydes, H2C=E, is the lone pair at E (nE), and the second highest MO (SOMO) is the C=E 77-bonding orbital. The LUMO is the 77 CE orbital composed of the antibonding combination of pz(C) and pz(E). The ionization energy of the HOMO in formaldehyde is 10.88 eV and of the SOMO 14.5 eV, as determined by photoelectron spectroscopy.33 The ionization energy of the HOMO and the SOMO both decrease considerably when the oxygen atom in formaldehyde is replaced by sulfur or selenium (see Fig. 1, data are compiled from Refs. 33-37). [Pg.127]

It is also worthwhile to compare the ferrocenyl ethylene (vinylferrocene) anion radicals and cation radicals. For the cyano vinylferrocene anion radical, the strong delocalization of an unpaired electron was observed see Section 1.2.2. This is accompanied by effective cis —> trans conversion (the barrier of rotation around the —C=C— bond is lowered). As for the cation radicals of the vinylferrocene series, a single electron remains in the highest molecular orbital formerly occupied by two electrons. According to photoelectron spectroscopy and quantum mechanical calculations, the highest occupied molecular orbital is mostly or even exclusively the orbital of iron (Todres et al. 1992). This orbital is formed without participation of the ethylenic fragment. The situation is quite different from the arylethylene radical cations, in which all ir-orbitals overlap. [Pg.413]

Photoelectron spectroscopy reveals that the highest occupied molecular orbital (HOMO) in NHC is the lone pair in the sp hybrid orbital of the carbene carbon atom (see Figure 1.18). However, a molecular orbital with jt symmetry centred around the N-C-N heteroallyl system is of almost equal energy. This gives the carbene the ability to engage in n-face donor interactions with the transition metal fragment. For unsaturated NHC these n-face donor interactions are more favourable than for saturated ones [104]. [Pg.20]

Ultraviolet (UV) spectroscopy is a method cd structure determination applicable specifically to conjugated systems. When a coi jugated molecule is irradiated with ultraviolet light, ener gy absorption occurs and a it electron is promoted from the highest occupied molecular orbital tHOMOl to the lowest unoccupied molecular orbital (L.UMO1. For I,3< butadiene, radiation of 217 nm ia required. As a general rule, the... [Pg.571]

DFT = density functional theory HMQC = heteronuclear multiple quantum coherence SOMO = singly occupied molecular orbital PES = photoelectron spectroscopy Cl = configuration interaction LUMO = lowest unoccupied molecular orbital HOMO = highest occupied molecular orbital TLC = thin layer chromatography. [Pg.4644]

ADE = adiabatic detachment energies ESC A = electron spectroscopy for chemical analysis HOMO = highest occupied molecular orbitals MAES = metastable atom electron spectroscopy MIES = metastable ionization electron spectroscopy OAT = oxygen atom transfer PES = photoelectron spectra PEI = pulsed field ionization PIES = Penning ionization electron spectroscopy QM = quantum-mechanical REMPI = resonantly enhanced multiphoton ionization SC = semiclassical VDE = vertical detachment energies XPS = x-ray photoelectron spectroscopy ZEKE = zero electron kinetic energy Cp = cyclopentadienyl, Ph = phenyl, CeHs Tp =... [Pg.6299]

Abbreviations BCC. body centered cubic DOS. density of states ESR. electron spin resonance HX.AI S, extended X-ray absorption fine structure F CC. face centered cubic (a crystal structure). FID, free induction decay FT, Fourier transform FWHM, full width at half maximum HCP, hexagonal close packed HOMO, highest occupied molecular orbital IR, Infrared or infrared spectroscopy LDOS, local density of states LUMO, lowest unoccupied molecular orbital MAS. magic angle spinning NMR. nuclear magnetic resonance PVP. poly(vinyl pyrrolidone) RF. Radiofrequency RT, room temperature SEDOR, spin echo double resonance Sf, sedor fraction SMSI, strong metal-support interaction TEM. transmission electron microscopy TOSS, total suppression of sidebands. [Pg.1]