Quantum Mechanical Foundations of Molecular Spectroscopy. Max DiemЧитать онлайн книгу.

alt="left-bracket ModifyingAbove p With Ì‚ Subscript x Baseline comma ModifyingAbove x With Ì‚ right-bracket"/> of the momentum operator

and the position operator ModifyingAbove x With Ì‚

when applied to a function f(x), i.e. determine

(E2.2.1) ModifyingAbove p With Ì‚ Subscript x Baseline ModifyingAbove x With Ì‚ f left-parenthesis x right-parenthesis minus ModifyingAbove x With Ì‚ ModifyingAbove p With Ì‚ Subscript x Baseline f left-parenthesis x right-parenthesis equals

(E2.2.2) equals minus i normal h with stroke StartFraction normal d Over normal d x EndFraction left-parenthesis ModifyingAbove x With Ì‚ f left-parenthesis x right-parenthesis right-parenthesis minus ModifyingAbove x With Ì‚ left-parenthesis minus i normal h with stroke StartFraction normal d Over normal d x EndFraction f left-parenthesis x right-parenthesis right-parenthesis

Answer:

The derivative of the product left-parenthesis ModifyingAbove x With Ì‚ f left-parenthesis x right-parenthesis right-parenthesis needs to be evaluated using the product rule of differentiation. Thus,

(E2.2.3) equals minus i normal h with stroke left-parenthesis f left-parenthesis x right-parenthesis plus ModifyingAbove x With Ì‚ StartFraction normal d f left-parenthesis x right-parenthesis Over normal d x EndFraction minus ModifyingAbove x With Ì‚ StartFraction normal d f left-parenthesis x right-parenthesis Over normal d x EndFraction right-parenthesis

(E2.2.4) equals minus i normal h with stroke f left-parenthesis x right-parenthesis equals StartFraction normal h with stroke Over i EndFraction f left-parenthesis x right-parenthesis

Thus, the commutator

(E2.2.5) left-bracket ModifyingAbove p With Ì‚ Subscript x Baseline comma ModifyingAbove x With Ì‚ right-bracket equals minus i normal h with stroke f left-parenthesis x right-parenthesis equals StartFraction normal h with stroke Over i EndFraction f left-parenthesis x right-parenthesis not-equals 0

which predicts that the position and momentum of a moving particle cannot be determined simultaneously. This was stated earlier in Eq. (2.1) as the Heisenberg uncertainty principle as

(2.1) normal upper Delta p Subscript x Baseline normal upper Delta x greater-than-or-equal-to StartFraction normal h with stroke Over 2 EndFraction

To show the equivalency of Eqs. (E2.2.5) and (2.1), one has to determine the standard deviations in momentum and position σ_p and σ_x that can be related to the uncertainties Δp_x and Δx.

Schematic illustration of the potential energy functions and analytical expressions for (a) molecular vibrations and (b) an electron in the field of a nucleus. Here, f is a force constant, k is the Coulombic constant, and e is the electron charge.

Figure 2.1 Potential energy functions and analytical expressions for (a) molecular vibrations and (b) an electron in the field of a nucleus. Here, f is a force constant, k is the Coulombic constant, and e is the electron charge.

2.2 The Potential Energy and Potential Functions

In Postulate 2, the kinetic energy T was substituted by the operator

(2.4) ModifyingAbove upper T With Ì‚ equals minus StartFraction normal h with stroke squared Over 2 m EndFraction StartFraction partial-differential squared Over partial-differential x squared EndFraction

but the potential energy V was left unchanged, since it does not include the momentum of a moving particle. The potential energy, however, depends on the particular interactions describing the problem, for example, the potential energy an electron experiences in the field of a nucleus or the potential energy exerted by a chemical bond between two vibrating nuclei. The shape of these potential energy curves are shown in Figure 2.1 along with the potential energy equations.

When these potential energy expressions are substituted into the Schrödinger equation

(2.7) ModifyingAbove upper H With Ì‚ normal psi left-parenthesis x right-parenthesis equals left-brace minus StartFraction normal h with stroke squared Over 2 m EndFraction StartFraction partial-differential squared Over partial-differential x squared EndFraction plus upper V right-brace normal psi left-parenthesis x right-parenthesis equals upper E normal psi left-parenthesis x right-parenthesis

one obtains a differential equation:

(2.15)

for the harmonic oscillation of a diatomic molecule and

(2.16)

for the electron in a hydrogen atom. In Eqs. (2.15) and (2.16), f and k are constants that will be introduced later, and e is the electronic charge, e = 1.602 × 10⁻¹⁹ [C]. Equation (2.16) is not strictly correct since the potential energy is a spherical function in the distance r from the nucleus, but is presented here and in Figure 2.1 as a one‐dimensional quantity. Also, the mass in the denominator of the kinetic energy operator needs to be substituted by the reduced mass to be introduced later.

Due

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