From Classical Mechanics to Quantum Field Theory

24 From Classical Mechanics to Quantum Field Theory. A Tutorial

with∂z∂k≡^12

(∂

∂qk−i

∂

∂pk

)

,∂∂ ̄zk≡^12

(∂

∂qk+i

∂

∂pk

)

.Also:

J=−i

(

dzk⊗

∂

∂zk

−dz ̄k⊗

∂

∂z ̄k

)

. (1.98)

1.2.2.4 Geometric structures on the space of functions and operators

The geometric structures just examined allow us to introduce two (non-associative)
real brackets on smooth, real-valued functions onHR:

• the (symmetric) Jordan bracket{f,h}g≡G(df , d h);


• the (antisymmetric) Poisson bracket{f,h}ω≡Λ(df , d h).

By extending both these brackets to complex functions via complex linearity, we
eventually obtain a complex bracket{., .}Hdefined as:

{f,h}H=〈df , d h〉H∗R≡{f,h}g+i{f,h}ω. (1.99)

Explicitly, in complex coordinates, we can write:

{f,h}g=2

(

∂f

∂zk

∂h

∂z ̄k+

∂h

∂zk

∂f

∂ ̄zk

)

,{f,h}ω=

2

i

(

∂f

∂zk

∂h

∂z ̄k−

∂h

∂zk

∂f

∂z ̄k

)

.

(1.100)

In particular, if we associate to any operatorA∈gl(H) the quadratic function:

fA(x)=

1

2

〈x, Ax〉=

1

2

z†Az (1.101)

(
wherezis the column vector

(

z^1 , ..., zn

))

, it follows immediately from Eq. (1.100)
that, for anyA, B∈gl(H), we have:

{fA,fB}g=fAB+BA, (1.102)

{fA,fB}ω=fAB−iBA. (1.103)

This means that the Jordan bracket of any two quadratic functionsfAandfBis
related to the (commutative) Jordan bracket ofAandB,[A, B]+, defined as:

[A, B]+≡AB+BA, (1.104)

while their Poisson bracket is related to the commutator product (the Lie bracket)
[A, B]−defined as:

[A, B]−≡^1

i

(AB−BA). (1.105)