Given a Banach space $\mathcal N$, as contraction semigroup is defined as a set of bounded operators $P^t$, $0\le t\le+\infty$ defined everywhere in $\mathcal N$, such that \begin{equation*} P^0=1, \hspace{5mm} P^tP^s=P^{t+s}, \hspace{5mm} t\ge 0, \;\; s\in\mathbb R \end{equation*} We can associate to these operators a norm defined by \begin{equation*} ||P^t||=\inf_{\beta\in\mathbb R^+}\left\{\beta:||P^t\phi||\le \beta||\phi||\; \forall \phi\in \mathcal V, ||\phi||\le 1\right\} \end{equation*} and we can define generators of such contractions as \begin{align}\label{gen_Pt} A\psi&=\lim_{t\to 0}\frac{P^t\psi-\psi}{t} \end{align} Now, I am trying to see whether given these definitions it also holds $P^t=e^{At}$. I think this should be valid, as it seems to me that a contraction groups equipped with such norm is also a strongly continuous semigroup. For this last class of semigroups for the identity with the exponential of the generator is known to hold. Strong continuity should in particular be valid as \begin{align} \lim_{t\to 0+}||{P^t-1}||&=\lim_{t\to 0+}\inf_{\beta\in\mathbb R^+}\{\beta:||{(P^t-1)\phi}||\le \beta||{\phi}||\; \forall \phi\in\mathcal N,\||{\phi}||\le 1\}=\\ &= \inf_{\beta\in\mathbb R^+}\{\beta:\lim_{t\to 0+}||{(P^t-1)\phi||}\le \beta||{\phi}||\; \forall \phi\in\mathcal N,||{\phi}||\le 1\}= \label{inflim}\\ &= \inf_{\beta\in\mathbb R^+}\{\beta: 0\le \beta||{\phi}||\; \forall \phi\in\mathcal N,||{\phi}||\le 1\}=0 \end{align} I assume the exchage between the $\lim$ and $\inf$ should hold as their argument is continuous in both parameters.
Are these arguments correct?