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Electronic states occupied

The application of static pressures in the range of 5 000 to 50 000 bar has relatively speaking only the small effect of pressing the substance together and bending of the bonds. These effects can also be achieved by changing the temperature at ambient pressure. When the pressure reaches 500 000 bar, a completely new situation arises old bonds can be broken, new bonds made and new electronic states occupied, which result in drastic changes to the physical properties of the substance. [Pg.207]

Fig. 7.29 Band theory for insulators, semiconductors, and metals. The shaded areas represent electronic states occupied by electrons. Eg is the energy gap between occupied and empty states. Metals have partly filled bands. Typically, Eg is over 4 eV for an insulator and below 2 eV for a semiconductor. Fig. 7.29 Band theory for insulators, semiconductors, and metals. The shaded areas represent electronic states occupied by electrons. Eg is the energy gap between occupied and empty states. Metals have partly filled bands. Typically, Eg is over 4 eV for an insulator and below 2 eV for a semiconductor.
To improve upon die mean-field picture of electronic structure, one must move beyond the singleconfiguration approximation. It is essential to do so to achieve higher accuracy, but it is also important to do so to achieve a conceptually correct view of the chemical electronic structure. Although the picture of configurations in which A electrons occupy A spin orbitals may be familiar and usefiil for systematizing the electronic states of atoms and molecules, these constructs are approximations to the true states of the system. They were introduced when the mean-field approximation was made, and neither orbitals nor configurations can be claimed to describe the proper eigenstates T, . It is thus inconsistent to insist that the carbon atom... [Pg.2163]

In practice, each CSF is a Slater determinant of molecular orbitals, which are divided into three types inactive (doubly occupied), virtual (unoccupied), and active (variable occupancy). The active orbitals are used to build up the various CSFs, and so introduce flexibility into the wave function by including configurations that can describe different situations. Approximate electronic-state wave functions are then provided by the eigenfunctions of the electronic Flamiltonian in the CSF basis. This contrasts to standard FIF theory in which only a single determinant is used, without active orbitals. The use of CSFs, gives the MCSCF wave function a structure that can be interpreted using chemical pictures of electronic configurations [229]. An interpretation in terms of valence bond sti uctures has also been developed, which is very useful for description of a chemical process (see the appendix in [230] and references cited therein). [Pg.300]

Fig. 12. A possible mechanism for the dye-induced photooxidation of a silver center, x represents the distance across a silver haUde surface to which aggregated dye molecules are adsorbed. Steps 1, 4, and 5 represent the photohole (Q) formation, photohole migration, and silver oxidation processes which can ultimately lead to the total regression of the silver aggregate ( ) represents an energy state occupied by an electron. Fig. 12. A possible mechanism for the dye-induced photooxidation of a silver center, x represents the distance across a silver haUde surface to which aggregated dye molecules are adsorbed. Steps 1, 4, and 5 represent the photohole (Q) formation, photohole migration, and silver oxidation processes which can ultimately lead to the total regression of the silver aggregate ( ) represents an energy state occupied by an electron.
Fig. 2. (a) Energy, E, versus wave vector, k, for free particle-like conduction band and valence band electrons (b) the corresponding density of available electron states, DOS, where Ep is Fermi energy (c) the Fermi-Dirac distribution, ie, the probabiUty P(E) that a state is occupied, where Kis the Boltzmann constant and Tis absolute temperature ia Kelvin. The tails of this distribution are exponential. The product of P(E) and DOS yields the energy distribution... [Pg.344]

Consider now the behaviour of the HF wave function 0 (eq. (4.18)) as the distance between the two nuclei is increased toward infinity. Since the HF wave function is an equal mixture of ionic and covalent terms, the dissociation limit is 50% H+H " and 50% H H. In the gas phase all bonds dissociate homolytically, and the ionic contribution should be 0%. The HF dissociation energy is therefore much too high. This is a general problem of RHF type wave functions, the constraint of doubly occupied MOs is inconsistent with breaking bonds to produce radicals. In order for an RHF wave function to dissociate correctly, an even-electron molecule must break into two even-electron fragments, each being in the lowest electronic state. Furthermore, the orbital symmetries must match. There are only a few covalently bonded systems which obey these requirements (the simplest example is HHe+). The wrong dissociation limit for RHF wave functions has several consequences. [Pg.111]

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Electron states singly occupied

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