QuantumPhysics.dvi

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6 Quantum Mechanics Systems


Quantum systems associated with systems of classical mechanics are fundamental. In fact, it


is for these systems that we write the Schr ̈odinger equation; they will also admit a formulation


in terms of functional integrations over all possible paths, to be discussed in 221B. It is useful


to begin with a brief review of Lagrangian and Hamiltonian mechanics.


6.1 Lagrangian mechanics


At a most basic level, we describe systems by the time-evolution of the individual particles


that make up the system. Particlenis characterized in classical mechanics by its position


rn(t) at any given timet. It is a fact of Nature that its basic laws involve equations that are


first or second order in time derivatives, but not higher. Newton’s force lawF=Ma, for


example, is second order in time derivatives. As a result, the initial conditions of a classical


system are the positionsrnand velocitiesr ̇nof each of its constituent particles. The laws of


physics then yield the positions at later times.


The starting point of Lagrangian mechanics is a set of generalized positionsqi with


i= 1,···,N, describing all the degrees of freedom of classical particles. Fornparticles


in 3-dimensional space, for example, we useN = 3ngeneralized position variablesqi. The


associated generalized velocities are denoted by ̇qi=dqi/dt. Under the assumption of at most


second order time derivative evolution equations, Lagrangian mechanics will be completely


specified by a single function,


L(q,q ̇;t) =L(q 1 ,···,qN,q ̇ 1 ,···,q ̇N;t) (6.1)


referred to asthe Lagrangian. The associated Euler-Lagrange equations


d


dt


(

∂L


∂q ̇i


)


∂L


∂qi


= 0 i= 1,···,N (6.2)


arise as the solution to a variational principle of the action functional


S[q] =S[q 1 ,···,qN] =


∫t 2

t 1

dtL(q 1 ,···,qN,q ̇ 1 ,···,q ̇N;t) (6.3)


The notationS[q 1 ,···,qN] indicated that S is a functional of the path (q 1 (t),···,qN(t))


spanned fort∈[t 1 ,t 2 ]. To derive the Euler-Lagrange equations from the action, we perform


a variationδqi(t) on the pathqi(t), keeping the end points fixed,


δqi(t 1 ) =δqi(t 2 ) = 0 (6.4)

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