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Molecule hydrogen bonding

Figure 10. Hydrogen adsorption in one- (a), four- (b), six- (c), and eight- (c) Sc-Cp-grafted structures. E is the average adsorption energy, rl is the average hydrogen molecule bond length, and r2 is the average distance between Hi and Sc. Figure 10. Hydrogen adsorption in one- (a), four- (b), six- (c), and eight- (c) Sc-Cp-grafted structures. E is the average adsorption energy, rl is the average hydrogen molecule bond length, and r2 is the average distance between Hi and Sc.
The representation of molecular properties on molecular surfaces is only possible with values based on scalar fields. If vector fields, such as the electric fields of molecules, or potential directions of hydrogen bridge bonding, need to be visualized, other methods of representation must be applied. Generally, directed properties are displayed by spatially oriented cones or by field lines. [Pg.137]

One widely used valence bond theory is the generalised valence bond (GVB) method of Goddard and co-workers [Bobrowicz and Goddard 1977]. In the simple Heitler-London treatment of the hydrogen molecule the two orbitals are the non-orthogonal atomic orbitals on the two hydrogen atoms. In the GVB theory the analogous wavefunction is written ... [Pg.145]

We shall examine the simplest possible molecular orbital problem, calculation of the bond energy and bond length of the hydrogen molecule ion Hj. Although of no practical significance, is of theoretical importance because the complete quantum mechanical calculation of its bond energy can be canied out by both exact and approximate methods. This pemiits comparison of the exact quantum mechanical solution with the solution obtained by various approximate techniques so that a judgment can be made as to the efficacy of the approximate methods. Exact quantum mechanical calculations cannot be carried out on more complicated molecular systems, hence the importance of the one exact molecular solution we do have. We wish to have a three-way comparison i) exact theoretical, ii) experimental, and iii) approximate theoretical. [Pg.301]

Hydrogen molecule covalent bonding by way of a shared electron pair... [Pg.12]

Step 1 Hydrogen molecules react with metal atoms at the catalyst surface The relatively strong hydrogen-hydrogen c bond IS broken and replaced by two weak metal-hydrogen bonds... [Pg.232]

If a covalent bond is broken, as in the simple case of dissociation of the hydrogen molecule into atoms, then theRHFwave function without the Configuration Interaction option (see Extending the Wave Function Calculation on page 37) is inappropriate. This is because the doubly occupied RHFmolecular orbital includes spurious terms that place both electrons on the same hydrogen atom, even when they are separated by an infinite distance. [Pg.46]

The simplest example of covalent bonding is the hydrogen molecule. The proximity of the two nuclei creates a new electron orbital, shared by the two atoms, into which the two electrons go (Fig. 4.5). This sharing of electrons leads to a reduction in energy, and a stable bond, as Fig. 4.6 shows. The energy of a covalent bond is well described by the empirical equation... [Pg.39]

Fig. 4.5. The formation of o covalent bond - in this case between two hydrogen atoms, making a hydrogen molecule. Fig. 4.5. The formation of o covalent bond - in this case between two hydrogen atoms, making a hydrogen molecule.
The concepts of directed valence and orbital hybridization were developed by Linus Pauling soon after the description of the hydrogen molecule by the valence bond theory. These concepts were applied to an issue of specific concern to organic chemistry, the tetrahedral orientation of the bonds to tetracoordinate carbon. Pauling reasoned that because covalent bonds require mutual overlap of orbitals, stronger bonds would result from better overlap. Orbitals that possess directional properties, such as p orbitals, should therefore be more effective than spherically symmetric 5 orbitals. [Pg.4]

In structure II (numbered 13 in the IRC output), the C-H bond has lengthened with respect to the transition structure (1.23 versus 1.09A), while theC-O bond length has contracted slightly. Both changes are what would be expected as formaldehyde dissociates to form carbon monoxide and hydrogen molecule. ... [Pg.178]

The species H2 and H3+ are important as model systems for chemical bonding theory. The hydrogen molecule ion H2+ comprises 2 protons and 1 electron and is extremely unstable even in a low-pressure gas discharge system the energy of dissociation and the intemuclear distance (with the corresponding values for H2 in parentheses) are ... [Pg.37]

See other pages where Molecule hydrogen bonding is mentioned: [Pg.1301]    [Pg.22]    [Pg.18]    [Pg.1301]    [Pg.22]    [Pg.18]    [Pg.703]    [Pg.111]    [Pg.324]    [Pg.35]    [Pg.214]    [Pg.239]    [Pg.175]    [Pg.308]    [Pg.313]    [Pg.108]    [Pg.12]    [Pg.35]    [Pg.231]    [Pg.415]    [Pg.338]    [Pg.22]    [Pg.75]    [Pg.124]    [Pg.220]    [Pg.3]    [Pg.5]    [Pg.190]    [Pg.24]    [Pg.12]    [Pg.299]    [Pg.35]   
See also in sourсe #XX -- [ Pg.960 , Pg.961 , Pg.962 , Pg.963 ]



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Bonding molecules

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Covalent bonds bonding forces, hydrogen molecule

Covalent bonds hydrogen molecule

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Hydrogen Bonding Between two H2O Molecules

Hydrogen Bonds in Biological Molecules

Hydrogen bond acceptor molecules

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Hydrogen bond, between two water molecules

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Hydrogen bonding between water molecules

Hydrogen bonding in biological molecules

Hydrogen bonding self-assembled molecules, chirality

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Hydrogen bonds and van der Waals molecules

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Hydrogen bonds, per water molecule

Hydrogen fluoride molecules, bonding

Hydrogen molecul

Hydrogen molecule

Hydrogen molecule bond enthalpy

Hydrogen molecule valence bond method

Hydrogen molecule valence bond potential energy

Hydrogen molecule, bond length

Hydrogen molecule, bond length molecular orbitals

Hydrogen molecule, bond orbitals

Hydrogen-Bonding Arrangements of Molecules ROH

Hydrogen-bonded interactions among water molecules

Hydrogen-bonded molecules

Hydrogen-bonded molecules

Hydrogen-bonded molecules calculation protocol

Hydrogen-bonded molecules complex permittivity

Hydrogen-bonded molecules dielectric relaxation

Hydrogen-bonded molecules distributions

Hydrogen-bonded molecules interaction

Hydrogen-bonded molecules model

Hydrogen-bonded molecules response

Hydrogen-bonded molecules stretching/bending vibrations

Hydrogen-bonded water molecules

Hydrogens molecule bond

Interactions between molecules hydrogen-bonding

Ionic liquids hydrogen-bonding molecules

Nanotubes from Hydrogen Bonded Cyclic Molecules

Ordered molecules, hydrogen bonds

Polar Molecules and Hydrogen Bonds

Polar molecule hydrogen-bonding effects

Reorientation lifetime hydrogen bond molecules

Reversible Attachment of Guest Molecules via Hydrogen Bonding

Self-Assembly by Hydrogen-Bonding. Janus Molecules

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The bonded hydrogen molecule

Tropolone molecule, hydrogen bonds

Water Molecules and Hydrogen Bonding

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Water molecules hydrogen bonds

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