Group ring

∗-representations of the complex group ring

Let 𝐺 be a finite group, and Γ :𝐺 →GL(𝑉) be a Unitary representation, and ℂ[𝐺] be the complex Group ring. Then Γ induces a ∗-representation of the group ring Γℂ[𝐺] :ℂ[𝐺] →GL(𝑉) rep where

Γℂ[𝐺](𝑎)=∑𝑔∈𝐺𝑎(𝑔)Γ(𝑔)

which satisfies the following properties for 𝑎,𝑏 ∈ℂ[𝐺] 1. Γℂ[𝐺](𝑎 +𝑏) =Γℂ[𝐺](𝑎) +Γℂ[𝐺](𝑏) 2. Γℂ[𝐺](𝑎 ∗𝑏) =Γℂ[𝐺](𝑎)Γℂ[𝐺](𝑏) 3. Γℂ[𝐺](𝑎†) =Γℂ[𝐺](𝑎)† 4. Γℂ[𝐺](𝛿𝑒) =𝐈

Conversely, any representation of the group ring with these properties corresponds to a Unitary representation,¹ defined by

Γ(𝑔)=Γℂ[𝐺](𝛿𝑔)

Proof

Let Γℂ[𝐺](𝑎) =∑𝑔∈𝐺𝑎(𝑔)Γ(𝑔). Then

Γℂ[𝐺](𝑎+𝑏)=∑𝑔∈𝐺𝑎(𝑔)Γ(𝑔)+∑ℎ∈𝐺𝑏(ℎ)Γ(ℎ)=Γℂ[𝐺](𝑎)+Γℂ[𝐺](𝑏)

satisfying property 1; and

Γℂ[𝐺](𝑎∗𝑏)=∑𝑥∈𝐺∑𝑦∈𝐺𝑎(𝑥𝑦−1)𝑏(𝑦)𝑈(𝑥)=∑𝑔∈𝐺∑ℎ∈𝐺𝑎(𝑔)𝑏(ℎ)𝑈(𝑔ℎ)=(∑𝑔∈𝐺𝑎(𝑔)𝑈(𝑔))(∑ℎ∈𝐺𝑏(ℎ)𝑈(ℎ))=Γℂ[𝐺](𝑎)Γℂ[𝐺](𝑏)

satisfying property 2; and

Γℂ[𝐺](𝑎†)=∑𝑔∈𝐺――――𝑎(𝑔−1)Γ(𝑔)=∑ℎ∈𝐺―――𝑎(ℎ)Γ(ℎ)†=Γℂ[𝐺](𝑎)†

satisfying property 3; and

Γℂ[𝐺](𝛿𝑒)=∑𝑔∈𝐺𝛿𝑒(𝑔)Γ(𝑔)=Γ(𝑒)=𝐈

satisfying property 4.

For the converse, let Γℂ[𝐺] :ℂ[𝐺] →GL(𝑉) be a ∗-representation obeying properties 1–4. We define Γ(𝑔) =Γℂ[𝐺](𝛿𝑔). It follows that

∑𝑔∈𝐺𝑎(𝑔)Γ(𝑔)=∑𝑔∈𝐺𝑎(𝑔)Γℂ[𝐺](𝛿𝑔)=Γℂ[𝐺](∑𝑔∈𝐺𝑎(𝑔)𝛿𝑔)=Γℂ[𝐺](𝑎)

as required above, but is Γ a unitary representation? From the property 2 it follows that Γ(𝑔ℎ) =Γℂ[𝐺](𝛿𝑔 ∗𝛿ℎ) =Γℂ[𝐺](𝛿𝑔)Γℂ[𝐺](𝛿ℎ) =Γ(𝑔)Γ(ℎ), so Γ is indeed a representation of 𝐺. From property 3 it follows that Γ(𝑔)† =Γℂ[𝐺](𝛿𝑔)† =Γℂ[𝐺](𝛿†𝑔) =Γ(𝑔−1), so Γ is unitary as required.

The Regular group representation is a ∗-representation of the group ring carried by the group ring itself.

Properties

• Invariant subspaces of ∗-representations and unitary representations coïncide. Thus Γ is an irrep iff Γℂ[𝐺] is irreducible.

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Footnotes

1. 1996, Representations of finite and compact groups, §II.3, p 26 ↩