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H-atoms

I.P.P.D and its relatives have become standard procedures for the characterization of the structure of both clean surfaces and those having an adsorbed layer. Somoijai and co-workers have tabulated thousands of LEED structures [75], for example. If an adsorbate is present, the substrate surface structure may be altered, or reconstructed, as illustrated in Fig. VIII-9 for the case of H atoms on a Ni(llO) surface. Beginning with the (experimentally) hypothetical case of (100) Ar surfaces. Burton and Jura [76] estimated theoretically the free energy for a surface transition from a (1 x 1) to a C(2x 1) structure as given by... [Pg.304]

Fig. VIII-9. Alteration of the structure of a Ni(llO) surface by H-atom adsorption (a) structure for 0 = 1 (b) structure for 0 > 1. [Reprinted with permission from G. Ertl, Langmuir, 3, 4 (1987). Copyright 1987, American Chemical Society.]... Fig. VIII-9. Alteration of the structure of a Ni(llO) surface by H-atom adsorption (a) structure for 0 = 1 (b) structure for 0 > 1. [Reprinted with permission from G. Ertl, Langmuir, 3, 4 (1987). Copyright 1987, American Chemical Society.]...
The technique of low-energy electron diffraction, LEED (Section VIII-2D), has provided a considerable amount of information about the manner in which a chemisorbed layer rearranges itself. Somotjai [13] has summarized LEED results for a number of systems. Some examples are collected in Fig. XVlII-1. Figure XVIII-la shows how N atoms are arranged on a Fe(KX)) surface [14] (relevant to ammonia synthesis) even H atoms may be located, as in Fig. XVIII-Ih [15]. Figure XVIII-Ic illustrates how the structure of the adsorbed layer, or adlayer, can vary wiA exposure [16].f There may be a series of structures, as with NO on Ru(lOTO) [17] and HCl on Cu(llO) [18]. Surface structures of... [Pg.686]

Studies to determine the nature of intermediate species have been made on a variety of transition metals, and especially on Pt, with emphasis on the Pt(lll) surface. Techniques such as TPD (temperature-programmed desorption), SIMS, NEXAFS (see Table VIII-1) and RAIRS (reflection absorption infrared spectroscopy) have been used, as well as all kinds of isotopic labeling (see Refs. 286 and 289). On Pt(III) the surface is covered with C2H3, ethylidyne, tightly bound to a three-fold hollow site, see Fig. XVIII-25, and Ref. 290. A current mechanism is that of the figure, in which ethylidyne acts as a kind of surface catalyst, allowing surface H atoms to add to a second, perhaps physically adsorbed layer of ethylene this is, in effect, a kind of Eley-Rideal mechanism. [Pg.733]

As an interesting footnote, Ceyer [291] has found that ethylene is hydrogenated by hydrogen absorbed in the bulk region just below a Ni(l 11) surface. In this case, the surface ethylenes are assumed to by lying flat, with the dissolved H atoms approaching the double bond from underneath. [Pg.733]

Rettner C T 1994 Reaction of an H-atom beam with Cl/Au(111)—dynamics of concurrent Eley-Rideal and Langmuir-Hinshelwood mechanisms J. Chem. Phys. 101 1529... [Pg.919]

Ashfold M N R, Mordaunt D H and WIson S H S 1996 Photodissociation dynamics of hydride molecules H atom photofragment translational spectroscopy Adv. Photochem. 21 217-95... [Pg.2088]

This kind of dynamieal speetroseopie analysis is not restrieted to fast primary IVR proeesses. It would apply just as well to the sPidy of eompletely unimoleeular reaetions, viz isomerizations sueh as H-atom transfer reaetions, for example CH2O f HCHO [97] HCN f HNC [98],and referenees eited therem), and HCCHf ... [Pg.2143]

Gamarnik A, Johnson B A and Garcia-Garibay M A 1998 Effect of solvents on the photoenolization of omicron-methylanthrone at low temperatures. Evidence for H-atom tunneling from nonequilibrating triplets J. Rhys. Chem. A102 5491... [Pg.2323]

Figure B3.5.2. Example Z matrix for fliioroethylene. Notation for example, line 4 of the Z matrix means that a H atom is bonded to earbon atom Cl with bond length L3 (angstroms), making an angle with earbon atom... Figure B3.5.2. Example Z matrix for fliioroethylene. Notation for example, line 4 of the Z matrix means that a H atom is bonded to earbon atom Cl with bond length L3 (angstroms), making an angle with earbon atom...
Point defects and complexes exliibit metastability when more than one configuration can be realized in a given charge state. For example, neutral interstitial hydrogen is metastable in many semiconductors one configuration has H at a relaxed bond-centred site, bound to the crystal, and the other has H atomic-like at the tetrahedral interstitial site. [Pg.2885]

It is beyond the scope of these introductory notes to treat individual problems in fine detail, but it is interesting to close the discussion by considering certain, geometric phase related, symmetry effects associated with systems of identical particles. The following account summarizes results from Mead and Truhlar [10] for three such particles. We know, for example, that the fermion statistics for H atoms require that the vibrational-rotational states on the ground electronic energy surface of NH3 must be antisymmetric with respect to binary exchange... [Pg.28]

Figure 2. Wavepacket dynamics of the H + H H2 + H scattering reaction, shown as snapshots of the density (wave packet amplitude squard) at various times, The coordinates, in au, are described in Figure la, and the wavepacket is initially moving to describe the H atom approaching the H2 molecule. The density has been integrated over the angular coordinate, The PES is plotted for the collinear interaction geometry, 0 180, ... Figure 2. Wavepacket dynamics of the H + H H2 + H scattering reaction, shown as snapshots of the density (wave packet amplitude squard) at various times, The coordinates, in au, are described in Figure la, and the wavepacket is initially moving to describe the H atom approaching the H2 molecule. The density has been integrated over the angular coordinate, The PES is plotted for the collinear interaction geometry, 0 180, ...
The most stable nuclear configuration of this system is a pair of H2 molecules. There are three possible spin coupling combinations for H4 corresponding to three distinct stable product H2 pairs H1 H2 with H3 H4, H1 H3 with H2 H4, and H1 H4 with H2 H3. Each H atom contributes one electron, the dot diagrams indicate spin pairing. The three combinations are designated as Hfl), HOT), and H(III), respectively. They may be interconverted via square transition states, Figure 2. [Pg.334]

The electronic wave functions of the different spin-paired systems are not necessarily linearly independent. Writing out the VB wave function shows that one of them may be expressed as a linear combination of the other two. Nevertheless, each of them is obviously a separate chemical entity, that can he clearly distinguished from the other two. [This is readily checked by considering a hypothetical system containing four isotopic H atoms (H, D, T, and U). The anchors will be HD - - TU, HT - - DU, and HU -I- DT],... [Pg.334]

Figure 19, The proposed phase-inverting loop for the helicopter-type elimination of H2 off CHDN, The asterisks denote the H atoms that were originally bonded in the 1,4 positions of CHDN. Parts (a) and are (b) the anchors and (c) is the loop. Figure 19, The proposed phase-inverting loop for the helicopter-type elimination of H2 off CHDN, The asterisks denote the H atoms that were originally bonded in the 1,4 positions of CHDN. Parts (a) and are (b) the anchors and (c) is the loop.
In order to allow any multiple chlorination of the biphenyl skeleton, the user may define an atom list (eonsisting of hydrogen and chlorine atoms) and substitute all H-atoms by this list. One may click on the drop-down selection box behind the element icons, select the options Generics. .set the user-defined atom to A1 and quit by the OK button. As a result this atom selection is active for the subsequent drawing steps. After this atom list is drawn ten times as the ten substituents, its composition has to be defined by clicking the A, icon on the left-hand side of the structure editor and by selecting H and Cl in the periodic table (Figure 5-16). [Pg.250]

The hydrogen atom attached to an alkane molecule vibrates along the bond axis at a frequency of about 3000 cm. What wavelength of electromagnetic radiation is resonant with this vibration What is the frequency in hertz What is the force constant of the C II bond if the alkane is taken to be a stationary mass because of its size and the H atom is assumed to execute simple harmonic motion ... [Pg.166]

In the late 1920s, it was shown that the chemical bond existing between two identical hydrogen atoms in H2 can be described mathematically by taking a linear combination of the Is orbitals [Pg.176]


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Abstraction of H atoms

Abstraction, hydrogen atom, from O—H bonds

Amino acids, bromination, solid-phase H-atom transfer

Atomic H generation

C-H Bonds Adjacent to a Nitrogen Atom

Chemisorbed H-atoms

Diffusion of H atoms

Distribution of Atom Types H-bond Donors and Acceptors

Distribution of H atoms

Exchangeable H-atom

Excited-state intramolecular H-atom transfer

H Atoms, H2, and

H atom Schrodinger equation

H atom abstraction reaction

H atom beams

H atom recombination

H atom scavengers

H atom transfer reactions

H atom tunneling

H atom yields

H atomic orbital

H atoms reaction with

H atoms, reactions

H-Atom Abstraction by Bis (trifluoromethyl) Nitroxide in the Liquid Phase

H-Atom Abstraction by Methyl Radicals in Organic Glasses

H-Atom transfer to alkoxy radicals

H-atom Rydberg tagging technique

H-atom Rydberg “tagging

H-atom abstraction

H-atom ejection

H-atom energy levels

H-atom transfers

H-transfers Coupled to Major Heavy Atom Motions

H. Stoll, Electronic structure calculations for molecules containing lanthanide atoms

H/C atomic ratio

Hydrogen atom abstraction from 0-H bonds

Intramolecular H-Atom Exchange

Intramolecular H-atom transfer to peroxy radicals

Labile H atoms

Location of H Atoms Using X-Ray Data

Metal-bound H-atoms

Methane tetrahedral arrangement of H atoms

Migration of H atoms

Origins and Atomic Properties of H-Like Centres

O—H bonds, hydrogen atom abstraction

Photodissociation Dynamics of Hydride Molecules H Atom Photofragment Translational Spectroscopy (Ashfold, Mordaunt, and Wilson)

Radical species formed by H atom extraction from methane

Recombination of H atoms on glass and silica

Recombination of H atoms on metals

Rules of thumb for substituting an H-atom by a group

Spin-Orbit Coupling in the H Atom

The H Atom

The Spheroidal H Atom

Tunnelling of H atoms

Vibration, H atom

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