Startseite Characterizations of *-antiderivable mappings on operator algebras
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Characterizations of *-antiderivable mappings on operator algebras

  • Guangyu An , Xueli Zhang und Jun He EMAIL logo
Veröffentlicht/Copyright: 29. Juni 2022
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Open Mathematics
Aus der Zeitschrift Open Mathematics Band 20 Heft 1

Abstract

Let A be a -algebra, be a - A -bimodule, and δ be a linear mapping from A into . δ is called a -derivation if δ ( A B ) = A δ ( B ) + δ ( A ) B and δ ( A ) = δ ( A ) for each A , B in A . Let G be an element in A , δ is called a -antiderivable mapping at G if A B = G δ ( G ) = B δ ( A ) + δ ( B ) A for each A , B in A . We prove that if A is a C -algebra, is a Banach - A -bimodule and G in A is a separating point of with A G = G A for every A in A , then every -antiderivable mapping at G from A into is a -derivation. We also prove that if A is a zero product determined Banach -algebra with a bounded approximate identity, is an essential Banach - A -bimodule and δ is a continuous -antiderivable mapping at the point zero from A into , then there exists a -Jordan derivation Δ from A into and an element ξ in such that δ ( A ) = Δ ( A ) + A ξ for every A in A . Finally, we show that if A is a von Neumann algebra and δ is a -antiderivable mapping (not necessary continuous) at the point zero from A into itself, then there exists a -derivation Δ from A into itself such that δ ( A ) = Δ ( A ) + A δ ( I ) for every A in A .

Keywords: *-derivation; *-antiderivable mapping; C*-algebra; von Neumann algebra
MSC 2010: 46L57; 47B47; 47C15; 16E50

1 Introduction

Throughout this paper, let A be an associative algebra over the complex field C and be an A -bimodule. A linear mapping δ from A into is called a derivation if

δ ( A B ) = A δ ( B ) + δ ( A ) B

for each A , B in A ; and δ is called a Jordan derivation if

δ ( A 2 ) = A δ ( A ) + δ ( A ) A

for every A in A . It follows from [1, Corollary 17] that every Jordan derivation from a C -algebra A into a Banach A -bimodule is a derivation.

Let G be an element in A , δ is called a derivable mapping at G if

A B = G δ ( G ) = A δ ( B ) + δ ( A ) B

for each A , B in A . In [2,3,4, 5,6,7, 8,9], the authors investigated derivable mappings at the point zero. In [10,11, 12,13,14, 15,16], the authors investigated derivable mappings at nonzero points.

A linear mapping δ from A into is called an antiderivable mapping at G if

A B = G δ ( G ) = B δ ( A ) + δ ( B ) A

for each A , B in A . In [6,7] and [17,18], the authors characterized antiderivable mappings at the point zero on properly infinite von Neumann algebras, C -algebras and group algebras.

By an involution on an algebra A , we mean a mapping from A into itself, such that

( λ A + μ B ) = λ ¯ A + μ ¯ B , ( A B ) = B A and ( A ) = A ,

whenever A , B in A , λ , μ in C and λ ¯ , μ ¯ denote the conjugate complex numbers. An algebra A equipped with an involution is called a -algebra. Moreover, let A be a -algebra, an A -bimodule is called a - A -bimodule if equipped with a -mapping from into itself, such that

( λ M + μ N ) = λ ¯ M + μ ¯ N , ( A M ) = M A , ( M A ) = A M and ( M ) = M ,

whenever A in A , M , N in and λ , μ in C .

An element A in a -algebra A is called Hermitian if A = A ; an element P in A is called an idempotent if P 2 = P ; and P is called a projection if P is both a self-adjoint element and an idempotent.

In [19], Kishimoto studied the -derivations on a C -algebra and proved that the closure of a normal -derivation on a UHF algebra satisfying a special condition is a generator of a one-parameter group of -automorphisms. Let A be a -algebra and be a - A -bimodule. A derivation δ from A into is called a -derivation if δ ( A ) = δ ( A ) for every A in A . Obviously, every derivation δ is a linear combination of two -derivations. In fact, we can define a linear mapping δ from A into by δ ( A ) = δ ( A ) for every A in A ; therefore, δ = δ 1 + i δ 2 , where δ 1 = 1 2 ( δ + δ ) and δ 2 = 1 2 i ( δ δ ) . It is easy to show that δ 1 and δ 2 are both -derivations.

Similar to derivable and antiderivable mappings, we can consider -derivable and -antiderivable mappings. Let A be a -algebra, be a - A -bimodule and G be an element in A . A linear mapping δ from A into is called a -derivable mapping at G if

A B = G δ ( G ) = A δ ( B ) + δ ( A ) B

for each A , B in A and δ is called a -antiderivable mapping at G if

A B = G δ ( G ) = B δ ( A ) + δ ( B ) A

for each A , B in A .

In [6], Ghahramani supposed that G is a locally compact group, L 1 ( G ) and M ( G ) denote the the group algebra and the measure convolution algebra of G , respectively, and showed that if δ is a -derivable mapping or a -antiderivable mapping at the point zero from L 1 ( G ) into M ( G ) , then there exist two elements B , C in M ( G ) such that δ ( A ) = A B C A for every A in L 1 ( G ) . In [7], Ghahramani and Pan supposed that A is a properly infinite W -algebra or a simple C -algebra with a nontrivial idempotent, and proved that if δ is a -derivable mapping at the point zero from A into itself, then there exist two elements B , C in A such that δ ( A ) = A B C A for every A in A ; if δ is a -antiderivable mapping at the point zero from A into itself, then δ ( A ) = δ ( I ) A for every A in A . In [17], Abulhamil et al. supposed that A is a C -algebra and is an essentially Banach A -bimodule, and proved that if δ is a continuous -antiderivable mapping at the point zero from A into , then there exists a -derivation Δ from A into and ξ in such that δ ( A ) = Δ ( A ) + A ξ for every A in A , where is the second dual of . In [18], Fadaee and Ghahramani supposed that A is a von Neumann algebra or a simple unital C -algebra, and proved that if δ is a -derivable mapping or a -antiderivable mapping at the point zero from A into itself, then there exist two elements B , C in A such that δ ( A ) = A B C A for every A in A .

For an algebra A and an A -bimodule , we call an element G in A a left (right) separating point of if G M = 0 ( M G = 0 ) implies M = 0 for every M in . It is easy to see that every left(right) invertible element in A is a left(right) separating point of . If G A is both the left and right separating point, then G is called a separating point of .

In Section 2, we prove that if A is a C -algebra, is a Banach - A -bimodule and G in A is a separating point of with A G = G A for every A A , then every -antiderivable mapping at G from A into is a -derivation.

In Section 3, we investigate -antiderivable mappings at the point zero and prove that if A is a zero product determined Banach -algebra with a bounded approximate identity, is an essential Banach - A -bimodule and δ is a continuous -antiderivable mapping at the point zero from A into , then there exists a -Jordan derivation Δ from A into and ξ in , such that δ ( A ) = Δ ( A ) + A ξ for every A in A , where stands for the second dual of M . Thus, we generalize [6, Theorem 3.2(2)] and [17, Theorem 9]. Finally, we prove that every -antiderivable mapping at the point zero from a von Neumann algebra A into itself satisfies that δ ( A ) = Δ ( A ) + A δ ( I ) for every A in A , where Δ is a -derivation from A into itself.

2 -Antiderivable mappings at a separating points

Before we give the main result in this section, we need to prove the following proposition.

Proposition 2.1

Suppose that A is a unital Banach algebra, is a unital Banach A -bimodule and G in A is a separating point of with A G = G A for every A in A . If δ and τ are two linear mappings from A into such that

A B = G δ ( G ) = B δ ( A ) + τ ( B ) A

for each A , B in A , then τ is a Jordan derivation, δ is a generalized Jordan derivation, that is, for every A in A , δ ( A 2 ) = A δ ( A ) + δ ( A ) A A δ ( I ) A . Moreover, the following identities hold:

τ ( A G ) = τ ( G ) A + G δ ( A ) A G δ ( I )

and

δ ( G A ) = A δ ( G ) + τ ( A ) G

for every A in A .

Proof

By I G = G I = G , we have that

(2.1) δ ( G ) = G δ ( I ) + τ ( G )

and

(2.2) δ ( G ) = δ ( G ) + τ ( I ) G .

Since G is a separating point for , by (2.2), we have τ ( I ) = 0 . Let T be a invertible element in A . By G T 1 T = T 1 G T = G , we obtain

(2.3) δ ( G ) = T δ ( G T 1 ) + τ ( T ) G T 1

and

(2.4) δ ( G ) = T 1 G δ ( T ) + τ ( T 1 G ) T .

Multiplying by T 1 from the left-hand side of (2.3), we can obtain that

(2.5) δ ( G T 1 ) = T 1 δ ( G ) T 1 τ ( T ) G T 1 .

Multiplying by T 1 from the right-hand side of (2.4), we have that

(2.6) τ ( T 1 G ) = δ ( G ) T 1 T 1 G δ ( T ) T 1 .

Let A be in A , n be a positive integer with n > ( A + 1 ) and B = n I + A . Then, both B and I B are invertible in A . By replacing T with B in (2.3), by (2.5) and τ ( I ) = 0 , we obtain

τ ( B ) G B 1 = δ ( G ) B δ ( G B 1 ) = δ ( G ) B δ ( G B 1 ( I B ) + G ) = ( I B ) δ ( G ) B δ ( G B 1 ( I B ) ) = ( I B ) δ ( G ) B [ B 1 ( I B ) δ ( G ) B 1 ( I B ) τ ( ( I B ) 1 B ) G B 1 ( I B ) ]

= ( I B ) τ ( ( I B ) 1 B ) G B 1 ( I B ) = ( I B ) τ ( ( I B ) 1 I ) G B 1 ( I B ) = ( I B ) τ ( ( I B ) 1 ) G B 1 ( I B ) .

Since A G = G A for every A in A , it follows that

(2.7) τ ( B ) B 1 G = ( I B ) τ ( ( I B ) 1 ) B 1 ( I B ) G .

By replacing T with B in (2.4), we obtain

B 1 G δ ( B ) = δ ( G ) τ ( B 1 G ) B = δ ( G ) τ ( B 1 ( I B ) G + G ) B = δ ( G ) τ ( G ) B τ ( B 1 ( I B ) G ) B .

By (2.6), it implies that

B 1 G δ ( B ) = δ ( G ) τ ( G ) B τ ( B 1 ( I B ) G ) B = δ ( G ) τ ( G ) B [ δ ( G ) B 1 ( I B ) B 1 ( I B ) G δ ( ( I B ) 1 B ) B 1 ( I B ) ] B = δ ( G ) τ ( G ) B δ ( G ) ( I B ) + B 1 ( I B ) G δ ( ( I B ) 1 B ) ( I B ) = ( δ ( G ) τ ( G ) ) B + B 1 ( I B ) G δ ( ( I B ) 1 I ) ( I B ) ,

and by (2.1), it follows that

B 1 G δ ( B ) = ( δ ( G ) τ ( G ) ) B + B 1 ( I B ) G δ ( ( I B ) 1 I ) ( I B ) = G δ ( I ) B B 1 ( I B ) G δ ( I ) ( I B ) + B 1 ( I B ) G δ ( ( I B ) 1 ) ( I B ) .

By A G = G A for every A in A , we can obtain that

(2.8) G B 1 δ ( B ) = G [ δ ( I ) B B 1 ( I B ) δ ( I ) ( I B ) + B 1 ( I B ) δ ( ( I B ) 1 ) ( I B ) ] .

Since G is a separating point of , by (2.7) and (2.8), we obtain

(2.9) τ ( B ) B 1 = ( I B ) τ ( ( I B ) 1 ) B 1 ( I B )

and

(2.10) B 1 δ ( B ) = δ ( I ) B B 1 ( I B ) δ ( I ) ( I B ) + B 1 ( I B ) δ ( ( I B ) 1 ) ( I B ) .

Multiplying by B from the right-hand side of (2.9) and from the left-hand side of (2.10), we can obtain that

(2.11) τ ( B ) = ( I B ) τ ( ( I B ) 1 ) ( I B )

and

(2.12) δ ( B ) = B δ ( I ) B ( I B ) δ ( I ) ( I B ) + ( I B ) δ ( ( I B ) 1 ) ( I B ) .

Multiplying by G from the right-hand side of (2.11) and by A G = G A , it follows that

τ ( B ) G = ( I B ) τ ( ( I B ) 1 ) ( I B ) G = ( I B ) τ ( ( I B ) 1 ) G ( I B ) .

By (2.3),

(2.13) τ ( B ) G = ( I B ) [ δ ( G ) ( I B ) 1 δ ( G ( I B ) ) ] = ( I B ) δ ( G ) δ ( G G B ) = δ ( G B ) B δ ( G ) .

Multiplying by G from the left of (2.12) and by A G = G A , it follows that

G δ ( B ) = G B δ ( I ) B G ( I B ) δ ( I ) ( I B ) + G ( I B ) δ ( ( I B ) 1 ) ( I B ) = G B δ ( I ) B G ( I B ) δ ( I ) ( I B ) + ( I B ) G δ ( ( I B ) 1 ) ( I B ) ,

and by (2.4),

G δ ( B ) = G B δ ( I ) B G ( I B ) δ ( I ) ( I B ) + [ δ ( G ) τ ( ( I B ) G ) ( I B ) 1 ] ( I B ) = G B δ ( I ) B G ( I B ) δ ( I ) + G ( I B ) δ ( I ) B + δ ( G ) δ ( G ) B τ ( G ) + τ ( B G ) = G B δ ( I ) B G δ ( I ) + G B δ ( I ) + G δ ( I ) B G B δ ( I ) B + δ ( G ) δ ( G ) B τ ( G ) + τ ( B G ) = G B δ ( I ) + [ δ ( G ) τ ( G ) G δ ( I ) ] + [ G δ ( I ) δ ( G ) ] B + τ ( B G ) ,

and by (2.1), it implies that

(2.14) G δ ( B ) = G B δ ( I ) τ ( G ) B + τ ( B G ) .

By (2.13), (2.14) and A G = G A , we have that

δ ( G B ) = B δ ( G ) + τ ( B ) G

and

τ ( B G ) = G δ ( B ) + τ ( G ) B B G δ ( I ) .

Since B = n I + A , we have the following two equations:

(2.15) δ ( G A ) = A δ ( G ) + τ ( A ) G

and

(2.16) τ ( A G ) = τ ( G ) A + G δ ( A ) A G δ ( I ) .

By (2.15), we know that for every invertible element T in A , it follows that

δ ( G ) = δ ( G T T 1 ) = T 1 δ ( G T ) + τ ( T 1 ) G T = T 1 [ T δ ( G ) + τ ( T ) G ] + τ ( T 1 ) T G = δ ( G ) + T 1 τ ( T ) G + τ ( T 1 ) T G .

Since G is a separating point,

(2.17) T 1 τ ( T ) + τ ( T 1 ) T = 0 .

By (2.16), we know that for every invertible element T in A , it follows that

δ ( G ) = δ ( T 1 T G ) = T G δ ( T 1 ) + τ ( T G ) T 1 = T G δ ( T 1 ) + [ τ ( G ) T + G δ ( T ) T G δ ( I ) ] T 1 = T G δ ( T 1 ) + τ ( G ) + G δ ( T ) T 1 T G δ ( I ) T 1 = G T δ ( T 1 ) + τ ( G ) + G δ ( T ) T 1 G T δ ( I ) T 1 .

Thus,

δ ( G ) τ ( G ) = G T δ ( T 1 ) + G δ ( T ) T 1 G T δ ( I ) T 1 .

By (2.1), we have that

G δ ( I ) = G T δ ( T 1 ) + G δ ( T ) T 1 G T δ ( I ) T 1 .

Since G is a separating point, we know that

(2.18) δ ( I ) = T δ ( T 1 ) + δ ( T ) T 1 T δ ( I ) T 1 .

It follows from (2.17), (2.18) and [13, Lemma 2.1] that τ and Δ ( A ) δ ( A ) A δ ( I ) both are Jordan derivations, and hence, δ is a generalized Jordan derivation.□

Let G = I in Proposition 2.1, we have the following result.

Corollary 2.2

Suppose A is a unital Banach algebra and is a unital Banach A -bimodule. If δ and τ are two linear mappings from A into , such that

A B = I δ ( I ) = B δ ( A ) + τ ( B ) A

for each A , B in A , then τ is a Jordan derivation and δ is a generalized Jordan derivation. Moreover, for every A in A , we have that

δ ( A ) = A δ ( I ) + τ ( A ) .

For every -antiderivable mapping at unit element from a unital Banach -algebra into its unital Banach - A -bimodule, we have the following result.

Corollary 2.3

Suppose that A is a unital Banach -algebra and is a unital Banach - A -bimodule. If δ is a linear mapping from A into such that

A B = I δ ( I ) = B δ ( A ) + δ ( B ) A

for each A , B in A , then δ is a -Jordan derivation.

Proof

Let τ be the linear mapping from A into such that for every A in A ,

δ ( A ) = δ ( A ) .

It follows that for each A , B in A , we have that

A B = I = A ( B ) = I δ ( I ) = B δ ( A ) + δ ( B ) A δ ( I ) = B δ ( A ) + δ ( B ) A .

It follows from Proposition 2.1 that δ is a Jordan derivation, and hence, δ is also a Jordan derivation.

Finally, we prove that δ is a -Jordan derivation, that is, δ ( A ) = δ ( A ) for every A in A . In fact, by δ ( I ) = 0 and Corollary 2.2, we have that δ ( A ) = δ ( A ) = δ ( A ) . It implies that δ ( A ) = δ ( A ) for every A in A .□

For every -antiderivable mapping from a unital C -algebra into its Banach - A -bimodule, we have the following theorem.

Theorem 2.4

Suppose that A is a unital C -algebra, is a unital Banach - A -bimodule and G in A is a separating point of with A G = G A for every A in A . If δ is a linear mapping from A into such that

A B = G δ ( G ) = B δ ( A ) + δ ( B ) A

for each A , B in A , then δ is a -derivation.

Proof

Let τ be a linear mapping from A into such that for every A in A

τ ( A ) = δ ( A ) .

It follows that for each A , B in A , we have that

A B = G = A ( B ) = G δ ( G ) = B δ ( A ) + δ ( B ) A δ ( G ) = B δ ( A ) + τ ( B ) A .

By Proposition 2.1, τ is a Jordan derivation, and hence, δ is also a Jordan derivation. Since A is a C -algebra, δ is a derivation.

Finally, we show that δ is a -derivation, that is, δ ( A ) = δ ( A ) for every A in A . Let A be an invertible element in A , by G A ( ( A 1 ) ) = G , we have that

δ ( G ) = A 1 δ ( G A ) + δ ( ( A 1 ) ) G A .

Since δ is a derivation and A G = G A , it follows that

δ ( G ) = δ ( ( A 1 ) ) A G + A 1 ( A δ ( G ) + δ ( A ) G ) ,

that is,

δ ( ( A 1 ) ) A G + A 1 δ ( A ) G = 0 .

Since G is a separating point, we have that

(2.19) δ ( ( A 1 ) ) A + A 1 δ ( A ) = 0 .

On the other hand, we can obtain that

(2.20) δ ( A 1 ) A + A 1 δ ( A ) = δ ( I ) = 0 .

By (2.19) and (2.20), we know that δ ( ( A 1 ) ) A = δ ( A 1 ) A , that is, δ ( ( A 1 ) ) = δ ( A 1 ) . Thus, for every invertible element A A , we have showed that δ ( A ) = δ ( A ) .

Since every element in a unital C -algebra is a linear combination of four unitaries [20], it follows that δ ( A ) = δ ( A ) for every A A .□

In particular, let G = I in Theorem 2.4, the following corollary holds.

Corollary 2.5

Suppose A is a unital C -algebra and is a unital Banach - A -bimodule. If δ is a linear mapping from A into such that

A B = I δ ( I ) = B δ ( A ) + δ ( B ) A

for each A , B in A , then δ is a -derivation.

Remark 2.6

Suppose that A is a unital -algebra, is a unital Banach - A -bimodule and δ is a linear mapping from A into . We should notice that the following two conditions are not equivalent:

  1. A , B A , A B = G B δ ( A ) + δ ( B ) A = δ ( G ) ;

  2. A , B A , A B = G B δ ( A ) + δ ( B ) A = δ ( G ) .

Hence, we also can define a -derivable mapping at G in A from A into by

A , B A , A B = G B δ ( A ) + δ ( B ) A = δ ( G ) .

Through the minor modifications, we can obtain the corresponding results.

3 -Antiderivable mappings at the point zero

A (Banach) algebra A is said to be zero product determined if every (continuous) bilinear mapping ϕ from A × A into any (Banach) linear space X satisfying

ϕ ( A , B ) = 0 , whenever A B = 0

can be written as ϕ ( A , B ) = T ( A B ) , for some (continuous) linear mapping T from A into X . In [21], Brešar showed that if A = J ( A ) , then A is a zero product determined, where J ( A ) is the subalgebra of A generated by all idempotents in A , and in [2], the authors proved that every C -algebra A is zero product determined.

Suppose that A is a Banach algebra and is a Banach- A -bimodule. is called an essential Banach A -bimodule if

= span ¯ { A N B : A , B A , N } ,

where span ¯ { } denotes the norm closure of the linear span of the set { } .

Let A be a Banach -algebra, a bounded approximate identity for A is a net ( e i ) i Γ of self-adjoint elements in A such that lim i A e i A = lim i e i A A = 0 for every A in A and sup i Γ e i K for some K > 0 .

Theorem 3.1

Suppose A is a zero product determined Banach -algebra with a bounded approximate identity and is an essential Banach - A -bimodule. If δ is a continuous linear mapping from A into such that

A B = 0 B δ ( A ) + δ ( B ) A = 0

for each A , B in A , then there are a -Jordan derivation Δ from A into and an element ξ in , such that

δ ( A ) = Δ ( A ) + A ξ

for every A in A . Furthermore, ξ can be chosen in in each of the following cases:

  1. A has an identity.

  2. is a dual - A -bimodule.

In [17, Section 4] and in [22, p. 720], the authors showed that is also a Banach - A -bimodule, where is the second dual space of . But, for the sake of completeness, we recall the argument here.

In fact, since is a Banach - A -bimodule, turns into a dual Banach A -bimodule with the operation defined by

A M = lim μ A M μ and M A = lim μ M μ A

for every A in A and every M in , where ( M μ ) is a net in with M μ M and ( M μ ) M in the weak -topology σ ( , ) .

We define an involution in by

( M ) ( ρ ) = M ( ρ ) ¯ , ρ ( M ) = ρ ( M ) ¯ ,

where M in , ρ in and M in . Moreover, if ( M μ ) is a net in and M is an element in such that M μ M in σ ( , ) , then for every ρ in , we have that

ρ ( M μ ) = M μ ( ρ ) M ( ρ ) .

It follows that

( M μ ) ( ρ ) = ρ ( M μ ) = ρ ( M μ ) ¯ M ( ρ ) ¯ = ( M ) ( ρ )

for every ρ in . It means that the involution in is continuous in σ ( , ) . Thus, we can obtain that

( A M ) = ( lim μ A M μ ) = lim μ M μ A = ( M ) A .

Similarly, we can show that ( M A ) = A ( M ) . It implies that is a Banach - A -bimodule.

In the following, we prove that Theorem 3.1.

Proof

Let ( e i ) i Γ be a bounded approximate identity of A . Since δ is a continuous mapping, ( δ ( e i ) ) i Γ is bounded in . Moreover, ( δ ( e i ) ) i Γ is also bounded in . By the Alaoglu-Bourbaki theorem, we may assume that ( δ ( e i ) ) i Γ converges to the element ξ in with the weak -topology σ ( , ) .

Since is an essential Banach- A -bimodule, M e i converges to M with respect to the weak -topology σ ( , ) for every M in . In fact, since = span ¯ { A N B : A , B A , N } , there exists a sequence M n = Σ k = 1 m n A k n N k n B k n converging to M in the norm topology, where A k n , B k n A and N k n , k = 1 , 2 , , m n , n = 1 , 2 , . Since ( A N B e i ) converges to A N B in the norm topology for each A , B A and N , it follows that M e i converges to in the norm topology for every M in .

Define a continuous bilinear mapping from A × A into by

ϕ ( A , B ) = δ ( B ) A + B δ ( A )

for every A , B in A . It follows that

A B = 0 ϕ ( A , B ) = 0 .

Since A is a zero product determined Banach algebra, there exists a continuous linear mapping T : A such that ϕ ( A , B ) = T ( A B ) for every A , B A . Moreover, for every A , B , C A , we have that

ϕ ( A B , C ) = ϕ ( A , B C ) .

That is,

(3.1) δ ( C ) A B + C δ ( A B ) = δ ( C B ) A + B C δ ( A ) .

Let A = e i in (3.1) and take the limit on both sides with the weak -topology σ ( , ) , we can obtain that

(3.2) δ ( C ) B + C δ ( B ) = δ ( C B ) + B C ξ .

Take the involution on both sides in (3.2), it implies that

(3.3) B δ ( C ) + δ ( B ) C = δ ( C B ) + ξ C B .

Let C = e i in (3.3) and take the limit on both sides of (3.3) with the weak -topology σ ( , ) , we can obtain that

B ξ + δ ( B ) = δ ( B ) + ξ B ,

that is,

(3.4) δ ( B ) B ξ = δ ( B ) ξ B .

Define a linear mapping Δ from A into by

Δ ( A ) = δ ( A ) A ξ

for every A in A . Next, we prove that Δ is a -Jordan derivation. By (3.4), we have that Δ ( A ) = Δ ( A ) for every A A .

By replacing C , B with A , B in (3.3), respectively, we can obtain that

B δ ( A ) + δ ( B ) A = δ ( A B ) + ξ A B ,

that is,

(3.5) δ ( A B ) = B δ ( A ) + δ ( B ) A ξ A B .

In the following, we prove that

Δ ( A 2 ) = A Δ ( A ) + Δ ( A ) A

for every A in A . By the definition of Δ and (3.5), we have the following two equations:

(3.6) Δ ( A 2 ) = δ ( A 2 ) A 2 ξ = A δ ( A ) + δ ( A ) A ξ A 2 A 2 ξ

and

(3.7) A Δ ( A ) + Δ ( A ) A = A ( δ ( A ) A ξ ) + ( δ ( A ) A ξ ) A = A δ ( A ) A 2 ξ + δ ( A ) A A ξ A .

By Δ ( A ) = Δ ( A ) , it implies that δ ( A ) A ξ = ( δ ( A ) A ξ ) , and

(3.8) δ ( A ) ξ A = δ ( A ) A ξ .

Multiplying by A from the right side of (3.8), we have that

(3.9) ( δ ( A ) ξ A ) A = ( δ ( A ) A ξ ) A .

Finally, by (3.6), (3.7), and (3.9), it follows that Δ ( A 2 ) = A Δ ( A ) + Δ ( A ) A . Thus, Δ is a -Jordan derivation.

Suppose that A is a unital Banach algebra, we can assume that ξ = δ ( I ) .

Suppose that is a dual essential Banach - A -bimodule and is the pre-dual space of , since δ is continuous, we can assume that the net ( δ ( e i ) ) i Γ converges to element ξ with the weak -topology σ ( , ) .□

Let G be a locally compact group. The group algebra and the measure convolution algebra of G , are denoted by L 1 ( G ) and M ( G ) , respectively. The convolution product is denoted by , and the involution is denoted by . It is well known that M ( G ) is a unital Banach -algebra, and L 1 ( G ) is a closed ideal in M ( G ) with a bounded approximate identity. By [23, Lemma 1.1], we know that L 1 ( G ) is zero product determined. By [24, Theorem 3.3.15(ii)], it follows that M ( G ) with respect to convolution product is the dual of C 0 ( G ) as a Banach M ( G ) -bimodule.

Since L 1 ( G ) is a semisimple algebra, we know from [25] that every continuous Jordan derivation from L 1 ( G ) into itself is a derivation. By [26, Corollary 1.2], we know that every continuous derivation Δ from L 1 ( G ) into M ( G ) is an inner derivation, that is, there exists μ in M ( G ) such that Δ ( f ) = f μ μ f for every f in L 1 ( G ) . Thus, by Theorem 3.1, we can rediscover [6, Theorem 3.2(ii)] as follows:

Corollary 3.2

[6, Theorem 3.2(ii)] Let G be a locally compact group. If δ is a continuous linear mapping from L 1 ( G ) into M ( G ) such that

f g = 0 δ ( g ) f + g δ ( f ) = 0 ,

for each f , g in L 1 ( G ) , then there exist two-element μ , ν M ( G ) such that

δ ( f ) = f ν μ f

for every f in L 1 ( G ) and Re μ Z ( M ( G ) ) .

Proof

By Theorem 3.1, we know that there exist a -derivation Δ from L 1 ( G ) into M ( G ) and an element ξ in M ( G ) such that

δ ( f ) = Δ ( f ) + ξ f

for every f in L 1 ( G ) . By [26, Corollary 1.2], it follows that there exists μ in M ( G ) such that Δ ( f ) = f μ μ f . Since Δ ( f ) = Δ ( f ) , we have that

f μ μ f = μ f f μ

for every f in L 1 ( G ) . By [23, Lemma 1.3(ii)], we know Re μ = 1 2 ( μ + μ ) Z ( M ( G ) ) . Let ν = μ ξ , from the definition of Δ , we have that δ ( f ) = f μ ν f for every f in L 1 ( G ) .□

In [2], the authors proved that every C -algebra A is zero product determined, and by [27, Corollary 7.5], we know that A has a bounded approximate identity. Thus, by Theorem 3.1, we can obtain a new proof of [17, Theorem 9] as follows:

Corollary 3.3

[17, Theorem 9] Let A be a C -algebra and an essential Banach - A -bimodule. If δ is a continuous linear mapping from A into such that

A B = 0 B δ ( A ) + δ ( B ) A = 0

for every A , B in A , then there exists a -derivation Δ from A into and ξ in such that

δ ( A ) = Δ ( A ) + A ξ

for every A in A . Furthermore, ξ can be chosen in in each of the following cases:

  1. A has an identity.

  2. is a dual - A -bimodule.

Suppose that A is a zero product determined unital -algebra and δ is a -antiderivable mapping from A into a - A -bimodule. Let ( e i ) i Γ = I and ξ = δ ( I ) in Theorem 3.1, we can obtain the following conclusion.

Corollary 3.4

Let A be a zero product determined unital -algebra and be a - A -bimodule. If δ is a linear mapping (continuity is not necessary) from A into such that

A B = 0 B δ ( A ) + δ ( B ) A = 0

for each A , B in A , then there exists a -Jordan derivation Δ from A into such that

δ ( A ) = Δ ( A ) + A δ ( I )

for every A in A .

Finally, we investigate -antiderivable mappings at the zero point on a von Neumann algebra. The following result is the second main theorem in this section.

Theorem 3.5

Let A be a von Neumann algebra. If δ is a linear mapping from A into itself, such that

A B = 0 B δ ( A ) + δ ( B ) A = 0

for each A , B in A , then there exists a -derivation Δ from A into such that

δ ( A ) = Δ ( A ) + A δ ( I )

for every A in A . In particular, δ is a -derivation when δ ( I ) = 0 .

Proof

Suppose that is a commutative von Neumann subalgebra of A . For each A , B in , we have that

A B = 0 A B = 0 A B = 0 A B = 0 .

Let A , B , C be in satisfying A B = B C = 0 . Since A B = 0 , we obtain B δ ( A ) + δ ( B ) A = 0 . By multiplying the previous identity by C form the left-hand side, we have C δ ( B ) A = 0 , equivalently, A δ ( B ) C = 0 . Therefore, [28, Theorem 2.12] implies that δ is automatically continuous, and by [17, Theorem 9], we can prove this theorem.□

Remark 3.6

Let A be a unital -algebra and be a unital Banach - A -bimodule. δ is a linear mapping from A into such that

A B = 0 B δ ( A ) + δ ( B ) A = 0 .

Through the minor modifications of Theorems 3.1 and 3.5, we can obtain the corresponding results.

Acknowledgements

The authors thank the referee for his or her suggestions. This research was partly supported by the National Natural Science Foundation of China (Grant Nos. 11801342 and 11801005); Natural Science Foundation of Shaanxi Province (Grant No. 2020JQ-693); Scientific research plan projects of Shannxi Education Department (Grant No. 19JK0130).

  1. Conflict of interest: The author states no conflict of interest.

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Received: 2021-06-30
Revised: 2022-02-16
Accepted: 2022-03-05
Published Online: 2022-06-29

© 2022 Guangyu An et al., published by De Gruyter

This work is licensed under the Creative Commons Attribution 4.0 International License.

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https://doi.org/10.1515/math-2022-0047
Schlagwörter für diesen Artikel
*-derivation; *-antiderivable mapping; C*-algebra; von Neumann algebra
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Artikel in diesem Heft

  1. Regular Articles
  2. A random von Neumann theorem for uniformly distributed sequences of partitions
  3. Note on structural properties of graphs
  4. Mean-field formulation for mean-variance asset-liability management with cash flow under an uncertain exit time
  5. The family of random attractors for nonautonomous stochastic higher-order Kirchhoff equations with variable coefficients
  6. The intersection graph of graded submodules of a graded module
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  9. On certain functional equation in prime rings
  10. General complex Lp projection bodies and complex Lp mixed projection bodies
  11. Some results on the total proper k-connection number
  12. The stability with general decay rate of hybrid stochastic fractional differential equations driven by Lévy noise with impulsive effects
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  15. Generic uniqueness of saddle point for two-person zero-sum differential games
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  18. The equivalent condition of G-asymptotic tracking property and G-Lipschitz tracking property
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  64. Generalized Munn rings
  65. Double domination in maximal outerplanar graphs
  66. Existence and uniqueness of solutions to the norm minimum problem on digraphs
  67. On the p-integrable trajectories of the nonlinear control system described by the Urysohn-type integral equation
  68. Robust estimation for varying coefficient partially functional linear regression models based on exponential squared loss function
  69. Hessian equations of Krylov type on compact Hermitian manifolds
  70. Class fields generated by coordinates of elliptic curves
  71. The lattice of (2, 1)-congruences on a left restriction semigroup
  72. A numerical solution of problem for essentially loaded differential equations with an integro-multipoint condition
  73. On stochastic accelerated gradient with convergence rate
  74. Displacement structure of the DMP inverse
  75. Dependence of eigenvalues of Sturm-Liouville problems on time scales with eigenparameter-dependent boundary conditions
  76. Existence of positive solutions of discrete third-order three-point BVP with sign-changing Green's function
  77. Some new fixed point theorems for nonexpansive-type mappings in geodesic spaces
  78. Generalized 4-connectivity of hierarchical star networks
  79. Spectra and reticulation of semihoops
  80. Stein-Weiss inequality for local mixed radial-angular Morrey spaces
  81. Eigenvalues of transition weight matrix for a family of weighted networks
  82. A modified Tikhonov regularization for unknown source in space fractional diffusion equation
  83. Modular forms of half-integral weight on Γ0(4) with few nonvanishing coefficients modulo
  84. Some estimates for commutators of bilinear pseudo-differential operators
  85. Extension of isometries in real Hilbert spaces
  86. Existence of positive periodic solutions for first-order nonlinear differential equations with multiple time-varying delays
  87. B-Fredholm elements in primitive C*-algebras
  88. Unique solvability for an inverse problem of a nonlinear parabolic PDE with nonlocal integral overdetermination condition
  89. An algebraic semigroup method for discovering maximal frequent itemsets
  90. Class-preserving Coleman automorphisms of some classes of finite groups
  91. Exponential stability of traveling waves for a nonlocal dispersal SIR model with delay
  92. Existence and multiplicity of solutions for second-order Dirichlet problems with nonlinear impulses
  93. The transitivity of primary conjugacy in regular ω-semigroups
  94. Stability estimation of some Markov controlled processes
  95. On nonnil-coherent modules and nonnil-Noetherian modules
  96. N-Tuples of weighted noncommutative Orlicz space and some geometrical properties
  97. The dimension-free estimate for the truncated maximal operator
  98. A human error risk priority number calculation methodology using fuzzy and TOPSIS grey
  99. Compact mappings and s-mappings at subsets
  100. The structural properties of the Gompertz-two-parameter-Lindley distribution and associated inference
  101. A monotone iteration for a nonlinear Euler-Bernoulli beam equation with indefinite weight and Neumann boundary conditions
  102. Delta waves of the isentropic relativistic Euler system coupled with an advection equation for Chaplygin gas
  103. Multiplicity and minimality of periodic solutions to fourth-order super-quadratic difference systems
  104. On the reciprocal sum of the fourth power of Fibonacci numbers
  105. Averaging principle for two-time-scale stochastic differential equations with correlated noise
  106. Phragmén-Lindelöf alternative results and structural stability for Brinkman fluid in porous media in a semi-infinite cylinder
  107. Study on r-truncated degenerate Stirling numbers of the second kind
  108. On 7-valent symmetric graphs of order 2pq and 11-valent symmetric graphs of order 4pq
  109. Some new characterizations of finite p-nilpotent groups
  110. A Billingsley type theorem for Bowen topological entropy of nonautonomous dynamical systems
  111. F4 and PSp (8, ℂ)-Higgs pairs understood as fixed points of the moduli space of E6-Higgs bundles over a compact Riemann surface
  112. On modules related to McCoy modules
  113. On generalized extragradient implicit method for systems of variational inequalities with constraints of variational inclusion and fixed point problems
  114. Solvability for a nonlocal dispersal model governed by time and space integrals
  115. Finite groups whose maximal subgroups of even order are MSN-groups
  116. Symmetric results of a Hénon-type elliptic system with coupled linear part
  117. On the connection between Sp-almost periodic functions defined on time scales and ℝ
  118. On a class of Harada rings
  119. On regular subgroup functors of finite groups
  120. Fast iterative solutions of Riccati and Lyapunov equations
  121. Weak measure expansivity of C2 dynamics
  122. Admissible congruences on type B semigroups
  123. Generalized fractional Hermite-Hadamard type inclusions for co-ordinated convex interval-valued functions
  124. Inverse eigenvalue problems for rank one perturbations of the Sturm-Liouville operator
  125. Data transmission mechanism of vehicle networking based on fuzzy comprehensive evaluation
  126. Dual uniformities in function spaces over uniform continuity
  127. Review Article
  128. On Hahn-Banach theorem and some of its applications
  129. Rapid Communication
  130. Discussion of foundation of mathematics and quantum theory
  131. Special Issue on Boundary Value Problems and their Applications on Biosciences and Engineering (Part II)
  132. A study of minimax shrinkage estimators dominating the James-Stein estimator under the balanced loss function
  133. Representations by degenerate Daehee polynomials
  134. Multilevel MC method for weak approximation of stochastic differential equation with the exact coupling scheme
  135. Multiple periodic solutions for discrete boundary value problem involving the mean curvature operator
  136. Special Issue on Evolution Equations, Theory and Applications (Part II)
  137. Coupled measure of noncompactness and functional integral equations
  138. Existence results for neutral evolution equations with nonlocal conditions and delay via fractional operator
  139. Global weak solution of 3D-NSE with exponential damping
  140. Special Issue on Fractional Problems with Variable-Order or Variable Exponents (Part I)
  141. Ground state solutions of nonlinear Schrödinger equations involving the fractional p-Laplacian and potential wells
  142. A class of p1(x, ⋅) & p2(x, ⋅)-fractional Kirchhoff-type problem with variable s(x, ⋅)-order and without the Ambrosetti-Rabinowitz condition in ℝN
  143. Jensen-type inequalities for m-convex functions
  144. Special Issue on Problems, Methods and Applications of Nonlinear Analysis (Part III)
  145. The influence of the noise on the exact solutions of a Kuramoto-Sivashinsky equation
  146. Basic inequalities for statistical submanifolds in Golden-like statistical manifolds
  147. Global existence and blow up of the solution for nonlinear Klein-Gordon equation with variable coefficient nonlinear source term
  148. Hopf bifurcation and Turing instability in a diffusive predator-prey model with hunting cooperation
  149. Efficient fixed-point iteration for generalized nonexpansive mappings and its stability in Banach spaces
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Heruntergeladen am 22.9.2025 von https://www.degruyterbrill.com/document/doi/10.1515/math-2022-0047/html?lang=de
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