Proof. For each exponential m, the mapping $\mu \mapsto F(\widehat {\mu })(m)$ defines a continuous linear functional on the measure algebra $\mathcal M_c(G)$ . We conclude (see e.g. [Reference Rudin5, 3.10 Theorem]) that there exists a continuous function $\varphi _m:G\to \mathbb {C}$ such that

$$ \begin{align*} F(\widehat{\mu})(m)=\int \varphi_m(z)\,d\mu(z) \end{align*} $$

holds for each $\mu $ in $\mathcal M_c(G)$ . Then we have

$$ \begin{align*} \varphi_m(x)=\int \varphi_m(z)\,d\delta_x(z)=F(\widehat{\delta}_x)(m), \end{align*} $$

hence , which yields (2).

Proof. Let $\widehat {J}=\bigcap _m \widehat {I}_{\mathcal D,m}$ , and assume that $\widehat {J}\subseteq \widehat {I}$ . If the subspace spanned by all functions of the form with D in $\mathcal D$ is not dense in $\mathrm {Ann\,} I$ , then there exists a $\mu _0$ not in $\mathrm {Ann\,} \mathrm {Ann\,} I=I$ such that $\mu _0$ annihilates all functions of the form with D in $\mathcal D$ . In other words, for each x in G we have

In particular, for $x=0$

holds for each D in $\mathcal D$ and for every m. Consequently, $\widehat {\mu }_0$ is in $\widehat {I}_{\mathcal {D},m}$ for each m, hence it is in the set $\widehat {J}$ , but not in $\widehat {I}$ – a contradiction.

Conversely, assume that the subspace spanned by all functions of the form with D in $\mathcal D$ , is dense in $\mathrm {Ann\,} I$ . It follows that any $\mu $ in $\mathcal M_c(G)$ , which satisfies

(6)

for all D in $\mathcal D$ and x in G, belongs to $I=\mathrm {Ann\,} \mathrm {Ann\,} I$ . Now let $\widehat {\mu }$ be in $\widehat {I}_{\mathcal D,m}$ for some m, and suppose that D is in $\mathcal D$ . Then for each x in G, the function $\widehat {\mu }\cdot \widehat {\delta }_{-x}$ is in $\widehat {I}_{\mathcal D,m}$ , hence

that is, $\widehat {\mu }$ satisfies (6) for each D in $\mathcal D$ . This implies that $\mu $ is in I, and the theorem is proved.

Proof. Assume that $\mathrm {Ann\,} I$ is not synthesizable. Then the linear span of the exponential monomials in $\mathrm {Ann\,} I$ is not dense. In other words, there is a $\widehat {\nu }$ not in $\widehat {I}$ such that $\nu *pm=0$ for every polynomial p such that $pm$ is in $\mathrm {Ann\,} I$ . For each such $pm$ we consider the polynomial derivation

whenever $\widehat {\mu }$ is in $\mathcal A(G)$ . As $pm$ is in $\mathrm {Ann\,} I$ , hence D is in $\mathcal P_{\widehat {I},m}$ . On the other hand, every derivation in $\mathcal P_{\widehat {I},m}$ has this form with some $pm$ in $\mathrm {Ann\,} I$ . As $\nu *pm(0)=0$ for all these functions, we have

holds for each D in $\mathcal P_{\widehat {I},m}$ . This means that $\widehat {\nu }$ is annihilated by all derivations in $\mathcal P_{\widehat {I},m}$ , but $\widehat {\nu }$ is not in $\widehat {I}$ , which contradicts the localizability.

Now we assume that $\mathrm {Ann\,} I$ is synthesizable. This means that all functions of the form with m in $Z(\widehat {I})$ and D in $\mathcal P_{\widehat {I},m}$ span a dense subspace in the variety $\mathrm {Ann\,} I$ . By Corollary 1,

$$ \begin{align*} \widehat{I}=\bigcap_{m\in Z(\widehat{I})} \widehat{I}_{\mathcal P_{\widehat{I},m},m}. \end{align*} $$

We show that this ideal is localizable. Assuming the contrary, there is an exponential m in $Z(\widehat {I})$ and there is a $\widehat {\nu }$ not in $\widehat {I}_{\mathcal P_{\widehat {I},m},m}$ such that $D(\widehat {\nu })(m)=0$ for each derivation D in $\mathcal P_{\widehat {I},m}$ . In other words, $\widehat {\nu }$ is annihilated at m by all derivations in $\mathcal P_{\widehat {I},m}$ , and still $\widehat {\nu }$ is not in $\widehat {I}_{\mathcal P_{\widehat {I},m},m}$ – a contradiction.

Proof. If spectral synthesis holds on G, then it obviously holds on every continuous homomorphic image of G (see [Reference Székelyhidi11, Theorem 3.1]), in particular, it holds on $G/B$ .

Conversely, we assume that spectral synthesis holds on $G/B$ . This means that every closed ideal in the Fourier algebra of $G/B$ is localizable, and we need to show the same for all closed ideals of the Fourier algebra of G.

First we remark that the polynomial rings over G and over $G/B$ can be identified. Indeed, polynomials on G are built up from additive functions on G, which clearly vanish on compact elements, as the additive topological group of complex numbers has no nontrivial compact subgroups. Consequently, if a is an additive function and $x,y$ are in the same coset of B, then $x-y$ is in B, and $a(x-y)=0$ , which means $a(x)=a(y)$ . So, the additive functions on G arise from the additive functions of $G/B$ , hence the two polynomial rings can be identified.

Now we define a projection of the Fourier algebra of G into the Fourier algebra of $G/B$ as follows. Let $\Phi :G\to G/B$ denote the natural mapping. For each measure $\mu $ in $\mathcal M_c(G)$ we define $\mu _B$ as the linear functional

$$ \begin{align*} \langle \mu_B,\varphi\rangle=\langle \mu, \varphi\circ \Phi\rangle \end{align*} $$

whenever $\varphi :G/B\to \mathbb {C}$ is a continuous function. It is straightforward that the mapping $\widehat {\mu }\mapsto \widehat {\mu }_B$ is a continuous algebra homomorphism of the Fourier algebra of G into the Fourier algebra of $G/B$ . As $\Phi $ is an open mapping, closed ideals are mapped onto closed ideals.

For a given closed ideal $\widehat {I}$ in $\mathcal A(G)$ , we denote by $\widehat {I}_B$ the closed ideal in $\mathcal A(G/B)$ which corresponds to $\widehat {I}$ under the above homomorphism. If m is a root of the ideal $\widehat {I}_B$ , then $\widehat {\mu }_B(m)=0$ for each $\widehat {\mu }$ in $\widehat {I}$ . In other words,

hence $m\circ \Phi $ , which is clearly an exponential on G, is a root of $\widehat {I}$ . Suppose that D is a derivation in $\mathcal P_{\widehat {I},m\circ \Phi }$ , then it has the form

with some polynomial p on G. According to our remark above, the polynomial p can uniquely be written as $p_B\circ \Phi $ , where $p_B$ is a polynomial on $G/B$ . In other words,

which defines a derivation $D_B$ on $\mathcal A(G/B)$ with generating function $f_{D_B,m}=p_B$ .

It follows that every derivation in $\mathcal P_{\widehat {I},m\circ \Phi }$ arises from a derivation in $\mathcal P_{\widehat {I}_B,m}$ . On the other hand, if d is a derivation in $\mathcal P_{\widehat {I}_B,m}$ , then we have

which defines a derivation D in $\mathcal P_{\widehat {I},m\circ \Phi }$ .

We summarize our assertions. Let $\widehat {I}$ be a proper closed ideal in $\mathcal A(G)$ and assume that $\widehat {I}$ is nonlocalizable. It follows that there is a function $\widehat {\nu }$ not in $\widehat {I}$ which is annihilated at M by all polynomial derivations in $\mathcal P_{\widehat {I},M}$ , for each exponential M on G. In particular, $\widehat {\nu }$ is annihilated at $m\circ \Phi $ by all polynomial derivations in $\mathcal P_{\widehat {I},m\circ \Phi }$ , for each exponential m on $G/B$ . We have seen above that this implies that $\widehat {\nu }_B$ is annihilated at m by all polynomial derivations in $\mathcal P_{\widehat {I}_B,m}$ and for each exponential m on $G/B$ . As spectral synthesis holds on $G/B$ , the ideal $\widehat {I}_B$ is localizable, hence $\widehat {\nu }_B$ is in $\widehat {I}_B$ , but this contradicts the assumption that $\widehat {\nu }$ is not in $\widehat {I}$ . The proof is complete.

Proof. If the torsion free rank of G is infinite, then there is a generalized polynomial on G, which is not a polynomial (see [Reference Székelyhidi7]), hence there is a nonpolynomial derivation on the Fourier algebra. Consequently, we have the chain of inclusions

$$ \begin{align*} \widehat{I}\subseteq \widehat{I}_{\mathcal D_{{\widehat{I},m}},m}\subsetneq \widehat{I}_{\mathcal P_{{\widehat{I},m}},m}, \end{align*} $$

which implies that $\widehat {I}\ne \widehat {I}_{\mathcal P_{{\widehat {I},m}},m}$ , hence $\widehat {I}$ is not synthesizable.

Conversely, let G have finite torsion free rank. The subgroup B of compact elements coincides with the set T of all elements of finite order, and $G/T$ is a (continuous) homomorphic image of $\mathbb {Z}^n$ with some nonnegative integer n. As spectral synthesis holds on $\mathbb {Z}^n$ (see [Reference Lefranc2]), it holds on its homomorphic images.

Proof. We have for each f in $\mathcal C(G\times \mathbb {Z})$ :

$$ \begin{align*} \langle \mu_0*\delta_{(0,k)},f\rangle&= \int \int f(g+h,l+n)\,d\mu_0(g,l)\,d\delta_{(0,k)}(h,n)\\& = \int f(g,l+k)\,d\mu_0(g,l)=\int f(g,k)\,d\mu(g,l)=\langle \mu_k,f\rangle.\\[-43pt] \end{align*} $$

Proof. Clearly $\mu _G+\nu _G=(\mu +\nu )_G$ and $\lambda \cdot \mu _G=(\lambda \cdot \mu )_G$ . Let $\mu _G$ be in I and $\xi $ in $\mathcal M_c(G)$ . Then we have for each $\varphi $ in $\mathcal C(G)$ :

$$ \begin{align*} \langle \xi*\mu_G,\varphi\rangle=\int \int \varphi(g+h)\,d\xi(g)\,d\mu_G(h)=\int \int \varphi(g+h)\,d\xi(g)\,d\mu(h,l). \end{align*} $$

On the other hand, we extend $\xi $ from $\mathcal M_c(G)$ to $\mathcal M_c(G\times \mathbb {Z})$ by the definition

$$ \begin{align*} \langle \tilde{\xi},f\rangle=\int f(g,0)\,d\xi(g) \end{align*} $$

whenever f is in $\mathcal C(G\times \mathbb {Z})$ . Then

$$ \begin{align*} \langle \tilde{\xi}_{G},\varphi\rangle=\int \varphi(g)\,d\tilde{\xi}_0(g,l)=\int \varphi(g)\,d\xi(g)=\langle \xi,\varphi\rangle, \end{align*} $$

that is $\tilde {\xi }_{G}=\xi $ . Finally, a simple calculation shows that

$$ \begin{align*} \langle \xi*\mu_G,\varphi\rangle=\langle (\tilde{\xi}*\mu)_G,\varphi\rangle, \end{align*} $$

hence $\xi *\mu _G=(\tilde {\xi }*\mu )_G$ is in $I_G$ , as $\tilde {\xi }*\mu $ is in I.

Now we show that the ideal $I_G$ is closed. Assume that $(\mu _{\alpha })$ is a generalized sequence in I such that the generalized sequence $(\mu _{{\alpha },G})$ converges to $\xi $ in $\mathcal M_c(G)$ . This means that

$$ \begin{align*} \lim_{\alpha} \int \varphi(g)\,d\mu_{{\alpha},G}(g)=\int \varphi(g)\,d\xi(g) \end{align*} $$

holds for each $\varphi $ in $\mathcal C(G)$ . In particular, for each exponential m on G we have

In other words,

$$ \begin{align*} \lim_{\alpha} \widehat{\mu}_{{\alpha},0}=\widehat{\tilde{\xi}}_0 \end{align*} $$

holds. It follows

$$ \begin{align*} \lim_{\alpha} \mu_{i,0}=\tilde{\xi}_0, \end{align*} $$

consequently

$$ \begin{align*} \tilde{\xi}_k=\tilde{\xi}_0*\delta_{(0,k)}=\lim_{\alpha} \mu_{{\alpha},0}*\delta_{(0,k)}=\lim_{\alpha} \mu_{{\alpha},k}. \end{align*} $$

Then we infer

$$ \begin{align*} \tilde{\xi}=\sum_k \tilde{\xi}_k=\sum_k \lim_{\alpha} \mu_{{\alpha},k}=\lim_{\alpha} \sum_k \mu_{{\alpha},k}=\lim_{\alpha} \mu_{\alpha}, \end{align*} $$

where we can interchange the sum and the limit using the fact that in each sum the number of nonzero terms is finite. As I is closed, $\tilde {\xi }$ is in I, which proves that ${\xi }=\tilde {\xi }_{G}$ is in $I_G$ , that is, $I_G$ is closed.

Proof. If spectral synthesis holds on $G\times \mathbb{Z}$ , then it obviously holds on its continuous homomorphic images, in particular, it holds on G, which is the projection of $G\times \mathbb {Z}$ onto the first component.

Conversely, we assume that spectral synthesis holds on G. This means that every closed ideal in the Fourier algebra of G is localizable, and we need to show the same for all closed ideals of the Fourier algebra of $G\times \mathbb {Z}$ .

We consider the closed ideal $\widehat {I}$ in the Fourier algebra $\mathcal A(G\times \mathbb {Z})$ , and we assume that $\widehat {I}$ is nonlocalizable, that is, there is a measure $\nu $ in $\mathcal M_c(G\times \mathbb {Z})$ such that $\widehat {\nu }$ is annihilated by $\mathcal P_{\widehat {I},m,\lambda }$ for each m and $\lambda $ , but $\widehat {\nu }$ is not in $\widehat {I}$ . We show that $\widehat {\nu }_G$ is in $\widehat {I}_G$ ; then it will follow that $\widehat {\nu }$ is in $\widehat {I}$ , a contradiction.

Suppose that a polynomial derivation d annihilates $\widehat {I}_G$ at m. Then we have

for each $\widehat {\mu }$ in $\widehat {I}_G$ and for every exponential m on G, where $p_{d,m}:G\to \mathbb {C}$ is the generating polynomial of d at m. Then we define the polynomial derivation D on the Fourier algebra $\mathcal A(G\times \mathbb {Z})$ by

If $\widehat {\mu }$ is in $\widehat {I}$ , then we have

for each k in $\mathbb {Z}$ . As $\widehat {\mu }=\sum _{k\in \mathbb {Z}} \widehat {\mu }_k$ , it follows that $D\widehat {\mu }(m,\lambda )=0$ for each $\widehat {\mu }$ in $\widehat {I}$ . In other words, D is in $\mathcal P_{\widehat {I},m,\lambda }$ for each exponential m and nonzero complex number $\lambda $ . In particular, $\widehat {\nu }$ is annihilated by D:

It follows

As d is an arbitrary polynomial derivation which annihilates $\widehat {I}_G$ at m, we have that $\widehat {\nu }_G$ is annihilated by $\mathcal P_{\widehat {I}_G,m}$ for each m. As spectral synthesis holds on G, the ideal $\widehat {I}_G$ is localizable, consequently $\widehat {\nu }_G$ is in $\widehat {I}_G$ , which implies that $\widehat {\nu }$ is in $\widehat {I}$ , and our theorem is proved.

Proof. By the Structure Theorem of compactly generated locally compact Abelian groups (see [Reference Hewitt and Ross3, (9.8) Theorem]) G is topologically isomorphic to $ \mathbb {R}^a\times \mathbb {Z}^b\times F, $ where $a,b$ are nonnegative integers, and F is a compact Abelian group. If spectral synthesis holds on G, then it holds on its projection $\mathbb {R}^a$ . By the results in [Reference Schwartz1, Reference Gurevič6], spectral synthesis holds on $\mathbb {R}^a$ if and only if $a\leq 1$ , hence G is topologically isomorphic to $\mathbb {R}^a\times \mathbb {Z}^b\times F$ where $a\leq 1$ and b are nonnegative integers, and F is a compact Abelian group.

Conversely, let $G=\mathbb {R}\times \mathbb {Z}^b\times F$ with b a nonnegative integer, and F a compact Abelian group. By [Reference Schwartz1], spectral synthesis holds on $\mathbb {R}$ . By repeated application of Theorem 4, we have that spectral synthesis holds on $\mathbb {R}\times \mathbb {Z}^b$ with any nonnegative integer b. Finally, by Theorem 3, spectral synthesis holds on $\mathbb {R}\times \mathbb {Z}^b\times F$ . Our proof is complete.

Proof. First we prove the necessity. If spectral synthesis holds on G, then it holds on $G/B$ . By [Reference Hewitt and Ross3, (24.34) Theorem], $G/B$ has sufficiently enough real characters. By [Reference Hewitt and Ross3, (24.35) Corollary], $G/B$ is topologically isomorphic to $\mathbb {R}^n\times F$ , where n is a nonnegative integer, and F is a discrete torsion-free Abelian group. As spectral synthesis holds on $\mathbb {R}^n\times F$ , it holds on the continuous projections $\mathbb {R}^n$ and F. Then we have $n\leq 1$ , and the torsion-free rank of F is finite, by [Reference Laczkovich and Székelyhidi8].

For the sufficiency, if F is a torsion-free discrete Abelian group with finite rank, then it is the (continuous) homomorphic image of $\mathbb {Z}^k$ with some nonnegative integer k. By repeated application of Theorem 4, we have that spectral synthesis holds on $\mathbb {R}\times \mathbb {Z}^k$ , and then it holds on its continuous homomorphic image $\mathbb {R}\times F$ . Finally, by Theorem 3, we have that spectral synthesis holds on G.