Representation electronically diabatic

This makes it desirable to define other representations in addition to the electronically adiabatic one [Eqs. (9)-(12)], in which the adiabatic electronic wave function basis set used in the Bom-Huang expansion (12) is replaced by another basis set of functions of the electronic coordinates. Such a different electronic basis set can be chosen so as to minimize the above mentioned gradient term. This term can initially be neglected in the solution of the / -electionic-state nuclear motion Schrodinger equation and reintroduced later using perturbative or other methods, if desired. This new basis set of electronic wave functions can also be made to depend parametrically, like their adiabatic counterparts, on the internal nuclear coordinates q that were defined after Eq. (8). This new electronic basis set is henceforth refened to as diabatic and, as is obvious, leads to an electronically diabatic representation that is not unique unlike the adiabatic one, which is unique by definition. 

Quantum reaction dynamics, electronic states (Continued) diabatization matrix, 295-300 electronically diabatic representation, 292-293... 

In what follows we introduce the model Hamiltonian using both diabatic and adiabatic representations. Adopting diabatic electronic basis states /j ), the molecular model Hamiltonian can be written as [162, 163]... 

In principle, the time evolution of a particular linear superposition on the molecular base states will reflect a chemical process via the changes shown by the amplitudes. This represents a complete quantum mechanical representation of the chemical processes in Hilbert space. The problem is that the separability cannot be achieved in a complete and exact manner. One way to introduce a model that is able to keep as much as possible of the linear superposition principle is to use generalized electronic diabatic base functions. 

The non-adiabatic character of the process under study is included in the present approach in the evaluation of the initial wavepacket in Eq.(7). In an electronic diabatic representation, the electronic wavefunctions are considered to do not depend on the nuclear coordinates, so that the coupling between different states is only given by the electronic Hamiltonian, being of potential-type character. 

Similar results have been found[58] in recent semiclassical simulations even when some variation was obtained depending on the particular method and on the electronic representation, either diabatic or adiabatic. The electronic representa-... 

Under the conditions of validity of the two-electronically-adiabatic-state approximation it is possible to change from the i]/al,ad(r q) (n = i, j) electronically adiabatic representation to a diabatic one 1,ad(r q) (n = i, j) for which the VR Xn(R) terms in the corresponding diabatic nuclear motion equations are significantly smaller than in the adiabatic equation or, for favorable conditions, vanish [24-26]. Such an electronically diabatic representation is usually more convenient for scattering calculations involving two electronically adiabatic PESs, but not for those involving a single adiabatic PES. This matter will be further discussed in Sec. III.B.3 for the case in which a conical intersection between the E ad(q) and Ejad(q) PESs occurs. 

The following part of this section describes our recent advances in applying accurate quantum wave packet methods to compute rate constants and to understand nonadiabatic effects in tri-atomic and tetra-atomic molecular reactions. The quantum nonadiabatic approaches that we present here are based on solving the time-dependent Schrodinger equation formulated within an electronically diabatic representation. 

Here, the scaled Hamiltonian H (m matrix form) is obtained by scaling and shifting the real Hamiltonian H (matrix form in electronic diabatic representation) of an A + BC reaction system with the two parameters as and bs ... 

A special situation is encountered in the formation of a K-shell vacancy in systems with several equivalent corehole sites.Owing to the localization of the core orbitals in space, there will always exist several near-degenerate electronic states which can interact through vibrational modes of suitable symmetry. In this case, however, the vibronic Hamiltonian can be diagonalized by transforming to a suitable diabatic representation. These diabatic electronic states correspond to core holes localized on the equivalent sites. From the dynamical point of view, we are dealing here with a multidimensional weakly avoided crossing. From the structural... 

So far, we have treated the case n = /lo, which was termed the adiabatic representation. We will now consider the diabatic case where n is still a variable but o is constant as defined in Eq. (B.3). By multiplying Eq. (B.7) by j e I o) I arid integrating over the electronic coordinates, we get... 

To obtain potential surfaces for two electronic states that will be degenerate at these points, we write a Hamiltonian as a 2 x 2 matrix in a diabatic representation in the following form ... 

The simplest way to write down the 2 x 2 Hamiltonian for two states such that its eigenvalues coincide at trigonally symmetric points in (x,y) or (q, ( )), plane is to consider the matrices of vibrational-electronic coupling of the e Jahn-Teller problem in a diabatic electronic state representation. These have been constructed by Haiperin, and listed in Appendix TV of [157], up to the third... 

U(qJ is referred to as an adiabatic-to-diabatic transformation (ADT) matrix. Its mathematical sbucture is discussed in detail in Section in.C. If the electronic wave functions in the adiabatic and diabatic representations are chosen to be real, as is normally the case, U(q ) is orthogonal and therefore has n n — l)/2 independent elements (or degrees of freedom). This transformation mabix U(qO can be chosen so as to yield a diabatic electronic basis set with desired properties, which can then be used to derive the diabatic nuclear motion Schrodinger equation. By using Eqs. (27) and (28) and the orthonormality of the diabatic and adiabatic electronic basis sets, we can relate the adiabatic and diabatic nuclear wave functions through the same n-dimensional unitary transformation matrix U(qx) according to... 

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