Proof It suffices to show that $\Vert av_n\Vert ^2 \leq \Vert b v_n \Vert ^2$ for every n. Observe first that

$$ \begin{align*}\Vert a v_n \Vert^2 =\Vert (a v_n)^\star(a v_n)\Vert=\Vert ( v_n^\star a)(a v_n)\Vert=\Vert v_n^\star a^2 v_n\Vert .\end{align*} $$

Since $ a^2\leq b^2$ , we have $v_n^\star a^2 v_n\leq v_n^\star b^2 v_n$ and hence $ \Vert v_n^\star a^2 v_n \Vert \leq \Vert v_n^\star b^2 v_n \Vert =\Vert b v_n \Vert ^2 $ . Consequently, we get $ \Vert a v_n \Vert ^2 \leq \Vert b v_n \Vert ^2$ .

Proof Clearly, $\mathbf {0} \leq (\vert a \vert -a)^2 \leq (2\vert a \vert )^2$ . Invoking Lemma 3.1, we infer that $\lim _n (\vert a \vert -a)v_n= \mathbf {0} \implies \lim _n a v_n= \mathbf {0} $ .

Proof We shall prove the result where a is any positive element of A: by the Gelfand–Naimark theorem, we can assume, without loss of generality, that A is commutative so that $A=C(X)$ for some compact set X. For each $n\in \mathbb N$ , define $b_n=a e^{-na} $ and $c_n=a \left (\mathbf {1}+in a\right )^{-1}$ . Then

$$ \begin{align*} \Vert b_n \Vert=\sup_{}\left\{ a(x)e^{-na(x)}: x \in X \right\}\leq \sup_{}\left\{ te^{-nt} : t \geq 0 \right\} \leq \frac{e^{-1}}{n}, \end{align*} $$

and hence $\lim _n b_n=\mathbf {0}.$ Similarly,

$$ \begin{align*} \Vert c_n \Vert=\sup_{}\left\{ \frac{a(x)}{ \vert 1 +i na(x) \vert } : x \in X\right\} \leq \sup_{ }\left\{ \frac{t}{ \vert 1 +i n t \vert }: t \geq 0 \right\} \leq \frac{1}{n}, \end{align*} $$

so that $\lim _n c_n=\mathbf {0}.$ Since $\vert x \vert $ is positive, we have the result.

Proof We know that $\psi _\phi (x) = 0=\psi _\phi \left ( R+i I\right)\hspace{-1.2pt}{,}$ which implies that $\psi _\phi \left ( R\right )=\psi _\phi \left ( I\right )=0.$ For each $n\in \mathbb N$ , let $W_n:=e^{-n \sqrt {\vert R \vert ^2+\vert I \vert ^2} }$ and observe, using Theorem 2.1, that $\phi \left ( W_n\right )=\psi _\phi \left ( W_n\right )=1$ . From (P1), it follows that

(3.1) $$ \begin{align} \phi(x)=\phi(x)\phi\left( W_n\right)\in \sigma\left( xW_n\right)=\sigma\left(RW_n +iIW_n\right)\hspace{-1pt}. \end{align} $$

Using Lemmas 3.1 and 3.3 and Corollary 3.2, we deduce that

$$ \begin{align*}\lim_n \sqrt{\vert R \vert^2+\vert I \vert^2}\,W_n=\mathbf{0}\implies \lim_n \vert R \vert W_n=\mathbf 0\implies \lim_n R W_n=\mathbf 0,\end{align*} $$

and similarly, $\lim _n I W_n= \mathbf {0}.$ Thus,

$$ \begin{align*}\lim_n xW_n= \lim_n \left(RW_n +iIW_n\right)= \mathbf{0}.\end{align*} $$

Using (3.1), we have that $\vert \phi (x)\vert \leq \|xW_n\|$ and so, by taking the limit as $n\to \infty $ , we get $\phi (x)=0$ .

Proof Let $\alpha $ be an arbitrary nonzero complex number. With $W_n$ defined as in the proof of Lemma 3.4, let $Y_n:=\frac {1}{ \alpha }xW_n$ , and set $c_\alpha :=\frac {1}{ \alpha }\phi (\alpha \mathbf {1}+x)$ . Then, using (P1) together with $\phi \left (W_n \right )=1$ , for each $n\in \mathbb N$ ,

(3.2) $$ \begin{align} c_\alpha= \frac{1}{ \alpha }\phi(\alpha\mathbf{1}+x)\phi\left(W_n \right) \in \sigma\left( W_n+ Y_n \right)\hspace{-1.5pt}. \end{align} $$

Observe, from the proof of Lemma 3.4, that $\lim _n Y_n = \mathbf {0}$ . To show that $c_\alpha \in [0,1],$ assume, to the contrary, that $c_\alpha \notin [0, 1].$ For each n, we have that $W_n\in {\mathcal S}_A$ and $\sigma (W_n ) \subseteq [0,1] $ . From (3.2), we see that

$$ \begin{align*}c_\alpha\mathbf{1} -W_n -Y_n \notin G(A) \;\mbox{ implying that } \;\mathbf{1} -Y_n( c_\alpha\mathbf{1} -W_n)^{-1} \notin G(A).\end{align*} $$

Since $( c_\alpha \mathbf {1} -W_n)^{-1}$ is normal for each $n,$ we have the estimation

$$ \begin{align*}\left\Vert\left( c_\alpha\mathbf{1} -W_n\right)^{-1} \right\Vert=\rho\big( ( c_\alpha\mathbf{1} -W_n)^{-1} \big) \leq \frac{1}{\operatorname{\mathrm{dist}}\big([0,1] , \{c_\alpha\}\big) }\end{align*} $$

from which it follows that $\lim _n Y_n( c_\alpha \mathbf {1} -W_n)^{-1} =\mathbf {0}$ , hence contradicting the fact that $ G(A) $ is open. Therefore, $c_\alpha \in [0,1]$ , and thus $\phi (\alpha \mathbf {1}+x)=c_\alpha \alpha .$

Proof For each $n\in \mathbb N$ , let $V_n:=\left (\mathbf {1}+in\sqrt {\vert R \vert ^2+\vert I \vert ^2} \right )^{-1}\hspace{-2pt}.$ Again, using Lemmas 3.1 and 3.3 and Corollary 3.2, we have that

$$ \begin{align*}\lim_n\sqrt{\vert R \vert^2+\vert I \vert^2}\, V_n=\mathbf{0} \implies \lim_n \vert R \vert V_n=\mathbf{0}\implies \lim_n R V_n=\mathbf{0}.\end{align*} $$

Similarly, $\lim _n I V_n=\mathbf {0} $ . Observe that each $V_n$ belongs to $ G_{\mathbf 1}(A)$ , whence it follows that $\phi (V_n) = \psi _\phi (V_n)=1 $ . Let $\alpha \neq 0 $ . From Lemma 3.5, we have that $\phi (\alpha \mathbf {1}+x)=c_\alpha \alpha $ , with $c_\alpha \in [0,1]$ . To obtain the result, we have to show that $c_\alpha \in \{0,1\}$ : For the sake of a contradiction, assume that $ 0< c_\alpha <1$ . If we set $Z_n:=\frac {1}{\alpha }xV_n=\frac {1}{\alpha }(R+iI) V_n$ , then

(3.3) $$ \begin{align} c_\alpha=\frac{1}{\alpha}\phi(\alpha\mathbf{1}+x)\phi(V_n)\in \sigma\left(V_n+Z_n\right). \end{align} $$

The first paragraph of the proof shows that $\lim _n Z_n=\mathbf {0}$ , and (3.3) shows that $c_\alpha \mathbf {1}-V_n-Z_n \notin G(A) $ . From the definition of $V_n$ , we have that $\sigma \left (V_n\right ) \subseteq C_r $ , where $C_r$ is the circle in $\mathbb C$ with center $\frac {1}{2}$ and radius $\frac {1}{2}$ : indeed, if $\theta \in \sigma \left (V_n\right )$ , then $\theta =\frac {1}{1+v^2} +i\frac {-v}{1+v^2}$ , for some $v \geq 0$ , and so $\left ( \operatorname {\mathrm {Re}}(\theta )-\frac {1}{2}\right )^2+\left ( \operatorname {\mathrm {Im}}(\theta )\right )^2=\frac {1}{4} $ . Owing to the fact that $C_r \cap \mathbb {R} =\{ 0,1\} $ , we infer that $c_\alpha \notin \sigma \left (V_n\right )$ . Thus,

$$ \begin{align*}c_\alpha\mathbf{1} -V_n-Z_n \notin G(A) \mbox{ and } c_\alpha\mathbf{1} -V_n \in G(A) ,\end{align*} $$

which together implies that $ \mathbf {1}-Z_n\left ( c_\alpha \mathbf {1} -V_n\right )^{-1} \notin G(A) .$ Since $V_n$ is normal, we obtain the estimate

$$ \begin{align*}\left\Vert \left( c_\alpha\mathbf{1} -V_n\right)^{-1}\right\Vert =\rho\left( \left( c_\alpha\mathbf{1} -V_n\right)^{-1} \right) \leq \frac{1}{\operatorname{\mathrm{dist}}(C_r,\{ c_\alpha \} ) }\end{align*} $$

from which it follows that $\lim _n Z_n\left ( c_\alpha \mathbf {1} -V_n\right )^{-1}= \mathbf {0}$ , contradicting the fact that $G(A)$ is open. Subsequently, $c_\alpha \in \{0,1\}$ , and $\phi (\alpha \mathbf {1}+x)\in \{0, \alpha \}$ follows as advertised.

Proof For $x\in A$ , define $K_x:=\{\alpha \in \mathbb {C} : \phi (\alpha \mathbf {1}+x)=0\}$ , and assume first that $\psi _\phi (x)=0$ . Our aim is to prove that $K_x=\{0\}$ . Observe that $0 \in K_x$ (by Lemma 3.4), $K_x \subseteq \sigma (-x)$ (by P(1) and P(2)), and $K_x$ is closed (since $\phi $ is continuous). Thus, $K_x$ is nonempty and compact. Let m be a maximum modulus element of $K_x$ . From the definition of m, there is a sequence $(k_n) \subset \mathbb C\setminus K_x$ which converges to m. Therefore, by Lemma 3.6, $\lim _n\phi \big (k_n\mathbf {1}+x \big )=\lim _n k_n =m $ , and by continuity of $\phi $ , $\lim _n\phi \big (k_n\mathbf {1}+x \big )=\phi \big (m\mathbf {1}+x \big )=0 $ . Thus, $m=0$ from which it follows that $K_x=\{0\}$ . Invoking Lemma 3.6 again, we then obtain $\phi (\alpha \mathbf {1}+x)=\alpha $ for each $\alpha \in \mathbb C$ . For any value of $ \psi _\phi (x) $ , we use the first part of the proof to deduce that

$$ \begin{align*}\phi(x)=\phi\left( \psi_\phi(x)\mathbf{1}+\left[x-\psi_\phi(x)\mathbf{1}\right] \right)= \psi_\phi(x).\\[-36pt]\end{align*} $$

Proof If $\phi $ is spectrally multiplicative, then either $\phi $ or $-\phi $ is multiplicatively spectral. The result then follows from Theorem 3.7.

Proof Let $\chi $ be an arbitrary character of B. Then $\chi \circ \phi $ is a continuous multiplicatively spectral functional on A. Hence, by Theorem 3.7, $\chi \circ \phi $ is a character. The result then follows from the semisimplicity of B.