Properties of the density operator

The density operator on a Hilbert space, defined by Equation 5.4 satisfies

the following properties:

1. ˆρ is Hermitian.

Proof: ˆρ

†

=

X

n

p

∗

n

|ψ

n

i

†

hψ

n

|

†

=

X

n

p

n

|ψ

n

ihψ

n

| = ˆρ. (5.11)

2. ˆρ is non-negative, that is, for any vector |vi, hv|ˆρ|vi ≥ 0. (This translates

to its eigenvalues being non-negative, or det(ρ) ≥ 0.)

Proof: hv|ˆρ|vi =

X

n

hv|p

n

|ψ

n

ihψ

n

|vi

=

X

n

p

n

|hv|ψ

n

i|

2

≥ 0 (5.12)

since the right side is a sum of numbers that are always positive or zero.

3. It satisfies Trˆρ = 1.

Proof: In an orthonormal basis {|ii},

Trρ =

X

i

hi|

X

n

p

n

|ψ

n

ihψ

n

|

!

|ii

=

X

n

p

n

X

i

hi|ψ

n

ihψ

n

|ii

=

X

n

p

n

hψ

n

|

X

i

|iihi|

!

|ψ

n

i

=

X

n

p

n

hψ

n

|ψ

n

i = 1 (5.13)

In general, any operator on a Hilbert space satisfying these properties is

defined as a density operator and can be used to predict the probabilities of

outcomes of measurement on the system, bypassing the state-vector formalism

altogether.

Example 5.1.4. For a system described by continuous variables, for example

position x, the density operator will be expressed as

ρ =

Z

dx dx

0

ω(x, x

0

)|xihx

Mixed States, Open Systems, and the Density Operator 83

For a pure state, we will have

ρ =

Z

dx dx

0

ψ(x)ψ

∗

(x

0

)|xihx

0

|, (5.15)

where ψ(x) = hx|ψi.

Another property of the density operator that will be useful to us is con-

vexity:

Definition 5.3. Convexity: A set of operators {ˆρ

i

} form a convex set if

ρ = λρ

1

+ (1 − λ)ρ

2

, 0 < λ < 1, (5.16)

for every pair ρ

1

, ρ

2

∈ {ρ

i

}.

Convexity has a very simple meaning: any two members of a convex set

can be connected by a straight line without leaving the set. (See Figure 5.1.)

FIGURE 5.1: (a) A convex set, (b) A non-convex set.