2. Preliminaries

Suppose that $\mathfrak{A}$ is a Banach algebra. It is known that the projective tensor product $\mathfrak{A} \hat{\otimes} \mathfrak{A}$ is a Banach $\mathfrak{A}$-bimodule in the canonical way. There is a continuous linear $\mathfrak{A}$-bimodule homomorphism $\pi:\mathfrak A\widehat\otimes\mathfrak A\longrightarrow\mathfrak A$ such that $ \pi ( a \otimes b) = ab$ for $a,b \in \mathfrak{A}$. If E is a Banach $\mathfrak{A}$-bimodule, then so is the dual space $E^*$. A continuous linear map $D:\mathfrak{A} \longrightarrow E$ is a derivation if it satisfies $ D(ab) = D(a) \ . \ b + a \ . \ D(b) $ for all $a,b \in \mathfrak{A}$. We call D inner if there is $x \in E$ such that $ D(a) = ad_x(a) := a \ . \ x - x \ . \ a$ for every $a \in \mathfrak{A}$.

Let X be a Banach space. We simply denote by wk and $w^*$, the $\sigma( X, X^*)$-topology and the $\sigma( X^*, X)$-topology on X and $X^*$, respectively.

Let $\mathfrak{A}$ be a Banach algebra. A Banach $\mathfrak{A}$-bimodule E is dual if there is a closed submodule $E_*$ of $E^*$ such that $E = (E_*)^*$. We call $E_*$ the predual of E. A Banach algebra $\mathfrak{A}=(\mathfrak{A}_*) ^*$ is dual if it is dual as a Banach $\mathfrak{A}$-bimodule. Equivalently, a Banach algebra $\mathfrak{A}$ is dual if it is a dual Banach space such that its multiplication is separately continuous in the $w^*$-topology.

Let $\mathfrak{A}$ be a dual Banach algebra, and let E be a dual Banach $\mathfrak{A}$-bimodule. Then, we say that E is normal if the module actions of $\mathfrak{A}$ on E are $w^*$–$w^*$ continuous.

Let $\mathfrak{A} = (\mathfrak{A}_*)^*$ be a dual Banach algebra and let E be a Banach $\mathfrak{A}$-bimodule. We write $\sigma wc(E)$ for the set of all elements $ x \in E$ such that the maps

\begin{equation*} \mathfrak{A} \longrightarrow E \ \ , \ \ \ a \longmapsto \left \{ \begin{array}{ll} a \cdot x \\ x \cdot a \end{array} \right. \ , \end{equation*}

are $w^*$–wk continuous. It is well known that $\sigma wc(E)$ is a closed submodule of E, and $\sigma wc(E)^*$ is always normal. It is shown in [Reference Runde16, Corollary 4.6] that $ \pi^*(\mathfrak{A}_*) \subseteq \sigma wc(\mathfrak{A} \hat{\otimes} \mathfrak{A} )^*$. Taking adjoints, we can extend π to an $\mathfrak{A}$-bimodule homomorphism $\pi_{\sigma wc}$ from $ \sigma wc((\mathfrak{A} \hat{\otimes} \mathfrak{A})^*)^*$ to $\mathfrak{A}$. A $\sigma wc$-virtual diagonal for a dual Banach algebra $\mathfrak{A}$ is an element $M \in \sigma wc((\mathfrak{A} \hat{\otimes} \mathfrak{A})^*)^*$ such that $ a \cdot M = M \cdot a$ and $ a \pi_{\sigma wc} (M) = a$ for $a \in \mathfrak{A}$. It is known that Connes amenability of $\mathfrak{A}$ is equivalent to existence of a $\sigma wc$-virtual diagonal for $\mathfrak{A}$ [Reference Runde16].

Our comprehensive references on amenability of Banach algebras are [Reference Dales2, Reference Runde17].

3. Weak Connes amenability

Let $\mathfrak{A} = (\mathfrak{A}_*)^*$ be a dual Banach algebra, and let E be a Banach $\mathfrak{A}$-bimodule. We denote by $j_E : E^* \longrightarrow \sigma wc (E)^* $ the adjoint of the inclusion map $ \sigma wc (E) \hookrightarrow E$. It is clear that j_E is an $\mathfrak{A}$-bimodule homomorphism and $ \langle x , j_E (f) \rangle = f (x)$ for all $x \in \sigma wc (E)$ and $ f \in E^*$.

We start with the following observation.

Proof. (i) For every $a, b \in \mathfrak{A} $ and $ x \in \sigma wc (E )$ we have

\begin{align*} \langle x , a \cdot (j_{E} \circ D ) (b) + (j_{E} \circ D ) (a) \cdot b \rangle &= \langle x , j_{E}( a \cdot D (b) ) + j_{E} ( D (a) \cdot b ) \rangle \\ &= \langle x , a \cdot D (b) + D (a) \cdot b \rangle \\ &= \langle x , D (a b) \rangle = \langle x , ( j_{E} \circ D ) (a b) \rangle \ , \end{align*}

and hence $j_{E} \circ D$ is a derivation.

(ii) This is a simple calculation.

(iii) It follows from (ii) and normality of $ \sigma wc (E )^* $.

Remark 3.3. For a dual Banach algebra $\mathfrak{A} $, $\sigma wc (\mathfrak{A} )$ is a closed (two-sided) ideal of $\mathfrak{A} $. To see this, take $a \in \sigma wc (\mathfrak{A} )$, $b \in \mathfrak{A} $, and let $ c_\alpha \stackrel{w^*} \longrightarrow c $ in $\mathfrak{A} $. Because $c_\alpha a \stackrel{wk} \longrightarrow c a $, for every $\varphi \in \mathfrak{A}^*$, we have

\begin{equation*} lim_\alpha \langle \varphi , c_\alpha (a b ) \rangle = lim_\alpha \langle b \cdot \varphi , c_\alpha a \rangle = \langle b \cdot \varphi , c a \rangle = \langle \varphi , c (a b ) \rangle \end{equation*}

so that $ a b \in \sigma wc (\mathfrak{A} )$. Next, by $w^*$-continuity of the multiplication, $ c_\alpha b \stackrel{w^*} \longrightarrow c b$. Then, $c_\alpha ( b a) = (c_\alpha b ) a \stackrel{wk} \longrightarrow ( c b ) a = c ( b a)$, which means $ b a \in \sigma wc (\mathfrak{A} )$.

For a given dual Banach algebra $\mathfrak{A} $, it would be interesting to determine the set $\sigma wc (\mathfrak{A} )$. However, special care should be taken with the trivial cases $\sigma wc (\mathfrak{A} ) = \{0 \}$ and $\sigma wc (\mathfrak{A} ) = \mathfrak{A}$, as follows.

As the name suggests, weak Connes amenability is weaker than Connes amenability.

For dual Banach algebras, weak amenability implies weak Connes amenability as follows.

It is well known that the measure algebra M(G) of a locally compact group G is a dual Banach algebra with predual $C_0(G)$.

We shall require the following, pointed out by the referee.

To end the current section, we wish to include an example of a dual Banach algebra which is not weakly Connes amenable. Indeed, Remark 3.8 is one way to find such examples: It suffices to give an example of a finite-dimensional Banach algebra, which is not weakly amenable.

Example 3.9. (Suggested by the referee) Let $\mathfrak{A}$ be the $\mathbb{C}$-algebra generated by an identity element e and a non-zero, square-zero element a. Define a linear map $D: \mathfrak{A} \longrightarrow \mathfrak{A}^*$ by

\begin{equation*} \langle e, D(e) \rangle = \langle a, D(a) \rangle = \langle a, D(e) \rangle = 0, \ \text{and} \ \langle e, D(a) \rangle =1 .\end{equation*}

Then, a direct calculation shows that D is a non-zero derivation from $\mathfrak{A}$ into $\mathfrak{A}^*$. Since $\mathfrak{A}$ is commutative, D is a non-inner derivation. Thus, $\mathfrak{A}$ is not weakly Connes amenable by Remark 3.8.

4. Hereditary properties and relations

Suppose that $\mathfrak{A}$ is a Banach algebra and that E is a Banach $\mathfrak{A}$-bimodule. A derivation $D:\mathfrak{A} \longrightarrow E^*$ is $w^*$-approximately inner if there exists a net $(f_\alpha)_\alpha \subseteq E^*$ such that $ D (a) =w^*-\lim_\alpha ad_{f_\alpha} ( a )$ for all $a \in \mathfrak{A}$ [Reference Ghahramani and Loy8]. The concept of $w^*$-approximate Connes amenability was introduced in [Reference Mahmoodi14]. A dual Banach algebra $\mathfrak{A}$ is $w^*$-approximately Connes amenable if for every normal, dual Banach $\mathfrak{A}$-bimodule E, every $w^*$–$w^*$ continuous derivation $D : \mathfrak{A} \longrightarrow E$ is $w^*$-approximately inner.

Suppose that $\mathfrak{A}=(\mathfrak{A}_*)^*$ and $\mathfrak{B} = (\mathfrak{B}_*)^*$ are dual Banach algebras. We consider the $\ell^1$-direct sum $\mathfrak{A} \oplus^1 \mathfrak{B}$ with norm $ || (a , b) || = || a|| + ||b||$ for $a \in \mathfrak{A}$ and $b \in \mathfrak{B}$. This is a dual Banach algebra under pointwise-defined operations and with predual the $\ell^\infty$-direct sum $\mathfrak{A}_* \oplus^\infty \mathfrak{B}_*$, where the norm $||.||_\infty$ is defined through $ ||(\phi , \psi )||_\infty = \max ( ||\phi|| , ||\psi||)$ for $\phi \in \mathfrak{A}_*$ and $\psi \in \mathfrak{B}_*$. The duality is given by

\begin{equation*} \langle (a , b) , (\phi , \psi ) \rangle = \langle a , \phi \rangle + \langle b , \psi \rangle \ \ \ \ ( a \in \mathfrak{A}, \ b \in \mathfrak{B}, \ \phi \in \mathfrak{A}_*, \ \psi \in \mathfrak{B}_*) \ .\end{equation*}

We write $ \imath_{\mathfrak{A}} : \mathfrak{A} \longrightarrow \mathfrak{A} \oplus^1 \mathfrak{B}$ for the natural injective homomorphism. It is obvious that $ \imath_{\mathfrak{A}}^*( \varphi , \psi) = \varphi$ for $ ( \varphi , \psi) \in \mathfrak{A}^* \oplus^\infty \mathfrak{B}^* = (\mathfrak{A} \oplus^1 \mathfrak{B} )^*$. It follows from [Reference Mahmoodi14, Lemma 2.6] that $ \sigma wc (\mathfrak{A} \oplus \mathfrak{B} )= \sigma wc (\mathfrak{A})\oplus \sigma w c (\mathfrak{B})$. We also denote by $ \nu_{\mathfrak{A}} : \sigma wc (\mathfrak{A} \oplus^1 \mathfrak{B} )^* = \sigma wc (\mathfrak{A} )^* \oplus^\infty \sigma wc (\mathfrak{B} )^* \longrightarrow \sigma wc (\mathfrak{A} )^*$ the adjoint of the natural embedding $ \sigma wc (\mathfrak{A} ) \hookrightarrow \sigma wc (\mathfrak{A} ) \oplus^1 \sigma wc (\mathfrak{B} ) = \sigma wc (\mathfrak{A} \oplus^1 \mathfrak{B} )$, so that $ \nu_{\mathfrak{A}} ( \varphi , \psi) = \varphi$ for $ ( \varphi , \psi) \in \sigma wc (\mathfrak{A} ) ^* \oplus^\infty \sigma wc (\mathfrak{B} ) ^* $. Similarly, we define $ \imath_{\mathfrak{B}}$ and $\nu_{\mathfrak{B}}$.

Proof. We only prove (i). For every $a \in \mathfrak{A}$, $b \in \mathfrak{B} $, and $c \in \sigma wc (\mathfrak{A}) $, we have

\begin{align*} \langle c , j_{\mathfrak{A}} \circ ( \imath_{\mathfrak{A}}^* \circ D ) (a, b) \rangle &= \langle c , ( \imath_{\mathfrak{A}}^* \circ D ) (a, b) \rangle = \langle (c , 0 ) , D (a , b) \rangle \\ &= \langle (c , 0 ) , (j_{\mathfrak{A} \oplus^1 \mathfrak{B}} \circ D ) (a , b) \rangle = \langle c , \nu_{\mathfrak{A}} \circ (j_{\mathfrak{A} \oplus^1 \mathfrak{B}} \circ D ) (a , b) \rangle \ , \end{align*}

as required.

Proof. Take a derivation $D :\mathfrak{A} \oplus^1 \mathfrak{B} \longrightarrow (\mathfrak{A} \oplus^1 \mathfrak{B} )^* = \mathfrak{A}^* \oplus^\infty \mathfrak{B}^*$ for which $j_{\mathfrak{A} \oplus^1 \mathfrak{B}} \circ D :\mathfrak{A} \oplus^1 \mathfrak{B} \longrightarrow \sigma wc (\mathfrak{A} \oplus^1 \mathfrak{B} )^* = \sigma wc (\mathfrak{A} )^* \oplus^\infty \sigma wc (\mathfrak{B} )^* $ is $w^*$-$w^*$ continuous. Then, $ \imath_{\mathfrak{A}}^* \circ D \circ \imath_{\mathfrak{A}} :\mathfrak{A} \longrightarrow \mathfrak{A}^*$ is a derivation. An easy calculation shows that $j_{\mathfrak{A}} \circ ( \imath_{\mathfrak{A}}^* \circ D \circ \imath_{\mathfrak{A}} ) : \mathfrak{A} \longrightarrow \sigma wc (\mathfrak{A} )^*$ is $w^*$-$w^*$ continuous. Since $\mathfrak{A}$ is weakly Connes amenable, there exists $ \varphi \in \sigma wc (\mathfrak{A} )^*$ such that $j_{\mathfrak{A}} \circ ( \imath_{\mathfrak{A}}^* \circ D) (a , 0) = ad_\varphi (a)$ and then, by Lemma 4.2(i), $\nu_{\mathfrak{A}} \circ (j_{\mathfrak{A} \oplus^1 \mathfrak{B}} \circ D ) (a , 0) = ad_\varphi (a)$ for every $a \in \mathfrak{A}$. We regard $\varphi = (\varphi , 0 )$ as an element of $\sigma wc (\mathfrak{A} )^* \oplus^\infty \sigma wc (\mathfrak{B} )^* $. Then it is easily checked that $\nu_{\mathfrak{A}} \circ (j_{\mathfrak{A} \oplus^1 \mathfrak{B}} \circ ( D - ad_\varphi ) ) (a , 0) = 0$. So, by replacing D by $D-ad_\varphi$, we may suppose that $\nu_{\mathfrak{A}} \circ (j_{\mathfrak{A} \oplus^1 \mathfrak{B}} \circ D ) (a , 0) =0$ for every $a \in \mathfrak{A}$. For each $ a_1 , a_2 \in \mathfrak{A}$, $ a \in \sigma wc (\mathfrak{A} )$ and $b \in \sigma wc (\mathfrak{B} )$, we see that

\begin{align*} \langle (a , b) , (j_{\mathfrak{A} \oplus^1 \mathfrak{B}} \circ D ) (a_1 a_2, 0) \rangle &= \langle (a , b) , j_{\mathfrak{A} \oplus^1 \mathfrak{B}} ( ( a_1 , 0) \cdot D(a_2 , 0 )+ D(a_1 , 0 ) \cdot (a_2 , 0 ) ) \rangle \\ &= \langle (a , b) , ( a_1 , 0) \cdot (j_{\mathfrak{A} \oplus^1 \mathfrak{B}} \circ D ) (a_2 , 0 )\nonumber \\ & \quad\qquad + (j_{\mathfrak{A} \oplus^1 \mathfrak{B}} \circ D ) (a_1 , 0 ) \cdot (a_2 , 0 ) \rangle \\ &= \langle (a a_1 , 0),\nonumber \\ & \quad\qquad (j_{\mathfrak{A} \oplus^1 \mathfrak{B}} \circ D ) (a_2 , 0 ) + ( a_2 a , 0), (j_{\mathfrak{A} \oplus^1 \mathfrak{B}} \circ D ) (a_1 , 0 ) \rangle \\ &= \langle a a_1, \nu_{\mathfrak{A}} \circ (j_{\mathfrak{A} \oplus^1 \mathfrak{B}} \circ D ) (a_2 , 0 ) \rangle\nonumber \\ & \quad\qquad + \langle a_2 a, \nu_{\mathfrak{A}} \circ (j_{\mathfrak{A} \oplus^1 \mathfrak{B}} \circ D ) (a_1 , 0 ) \rangle \\ &= 0 + 0 = 0 , \ \ ( a a_1, a_2 a \in \sigma wc (\mathfrak{A} ) \ \text{by Remark} \ 3.3 ) \end{align*}

and whence $ (j_{\mathfrak{A} \oplus^1 \mathfrak{B}} \circ D ) (a_1 a_2, 0) = 0$ for all $ a_1 , a_2 \in \mathfrak{A}$. Now, it follows from $w^*$-density of $\mathfrak{A}^2$ and $w^*$-continuity of $ j_{\mathfrak{A} \oplus^1 \mathfrak{B}} \circ D $ that $ (j_{\mathfrak{A} \oplus^1 \mathfrak{B}} \circ D ) (a, 0) = 0$ for every $ a \in \mathfrak{A}$.

A similar argument, with $\mathfrak{B} $ in place of $\mathfrak{A} $, shows that $ (j_{\mathfrak{A} \oplus^1 \mathfrak{B}} \circ D ) (0, b) = 0$ for every $ b \in \mathfrak{B}$. It follows that $ j_{\mathfrak{A} \oplus^1 \mathfrak{B}} \circ D = 0$, and hence $\mathfrak{A} \oplus^1 \mathfrak{B}$ is weakly Connes amenable.

Let $\mathfrak{A}$ be a Banach algebra. We write $ WAP (\mathfrak{A}^*)$ for the space of all weakly almost periodic functionals on $\mathfrak{A}$. It is noted by Runde that $ WAP (\mathfrak{A}^*)^*$ is a dual Banach algebra with a universal property [Reference Runde16, Theorem 4.10]. Later, Daws called $ WAP (\mathfrak{A}^*)^*$ the dual Banach algebra enveloping algebra of $\mathfrak{A}$ [Reference Daws6, Definition 2.10]. There is a (continuous) homomorphism $ \kappa : \mathfrak{A} \longrightarrow WAP (\mathfrak{A}^*)^*$ whose range is $w^*$-dense. Indeed, the map κ was obtained by composing the canonical inclusion $ \mathfrak{A} \longrightarrow \mathfrak{A}^{**}$ with the adjoint of the inclusion map $ WAP (\mathfrak{A}^*) \hookrightarrow \mathfrak{A} ^*$ [Reference Runde16].

5. More examples

In this section, we give some examples to compare weak Connes amenability and some older notions such as Connes amenability, weak amenability and pseudo (Connes) amenability.

Let $\mathfrak{A}$ be a dual Banach algebra. Composing the canonical inclusion $ \mathfrak{A} \hat{\otimes} \mathfrak{A} \longrightarrow ( \mathfrak{A} \hat{\otimes} \mathfrak{A})^{**}$ with the quotient map $ ( \mathfrak{A} \hat{\otimes} \mathfrak{A})^{**} \longrightarrow \sigma wc ( ( \mathfrak{A} \hat{\otimes} \mathfrak{A})^*)^*$, we obtain an $\mathfrak{A}$-bimodule homomorphism $\zeta : \mathfrak{A} \hat{\otimes} \mathfrak{A} \longrightarrow \sigma wc ( (\mathfrak{A} \hat{\otimes} \mathfrak{A}) ^*)^*$ with $w^*$-dense range.

We write $ \mathfrak{A}^\sharp$ for the unitization of an algebra $ \mathfrak{A}$.