The setting consists of a Banach space $X$, a possibly unbounded, densely defined operator $A:X \rightarrow X$ with domain $D(A)$ and an evolution equation \[ \frac{d}{dt}u(t) = Au(t) \] for all $t>0$ and initial condition $u(0)=x \in X$ (not only $D(A)$). A solution to this problem is denoted $u(t)=T(t)x$ with an evolution operator that forms an evolution semigroup. The operator $A$ is then called the generator.
Definition. A one-parameter family $T(t)$, $t \geq 0$, in $\mathcal{B}(X,X)$ is called a $\mathcal{C}^0$ semigroup (strongly continuous semigroup) if
Definition. The infinitesimal generator $A$ of a $\mathcal{C}^0$ semigroup $T(t)$ is defined by \[ Ax = \lim_{t \rightarrow 0} \frac{1}{t}(T(t)x-x) \] with domain $D(A)$, i.e. all $x\in X$ for which the limit exists.
Theorems that show the existence of such a semigroup by demanding specific properties from its generator are called generation theorems. An example is Stone's theorem in the Hilbert space case and the theorems of Hille–Yoshida and Lumer–Phillips in the more general setting of Banach spaces. The important relation between the semigroup and the Cauchy problem above is given by the following theorem with two different types of solutions (discussed later).
Theorem. Let $T(t)$ be a $\mathcal{C}^0$ semigroup and $A$ its infinitesimal generator. Then it holds for $t>0$ that
Proof. (1.) Take $h >0$, then \begin{align*} \frac{T(h)-\mathrm{id}}{h} \int_0^t T(s) x \,ds &= \frac{1}{h} \int_0^t (T(s+h)x-T(s)x) \,ds \\ &= \frac{1}{h} \int_t^{t+h} T(s) x \,ds - \frac{1}{h} \int_0^h T(s) x \,ds \end{align*} and with $h \searrow 0$ the right-hand side goes to $T(t)x-x$.
(2.) Now because of boundedness of $T(t)$ we have as $h \searrow 0$ \[ \frac{T(h)-\mathrm{id}}{h} T(t) x = T(t) \frac{T(h)-\mathrm{id}}{h} x \longrightarrow T(t) A x \] thus $T(t)x \in D(A)$ and $AT(t)x = T(t)Ax$ as well as the right derivative of $T(t)x$ fulfilling \[ \frac{d^+}{dt} T(t)x = A T(t) x = T(t) A x. \] To conclude we have to show the same for the left derivative. \begin{align*} &\lim_{h \searrow 0} \frac{T(t)x-T(t-h)x}{h} - T(t)Ax \\ &= \lim_{h \searrow 0} T(t-h) \left( \frac{T(h)x-x}{h} - Ax \right) + \lim_{h \searrow 0} (T(t-h)Ax - T(t)Ax) \end{align*} Both limit terms vanish, the first due to $x \in D(A)$ and boundedness of $T(t-h)$, the second by strong continuity of $T(t)$. $\Box$
That such a semigroup really always is linked to a usefully defined generator is secured by the next theorem.
Theorem. The generator of a $\mathcal{C}^0$ semigroup is always densely defined and closed.
Proof. Like before it holds \[ x = \lim_{h \searrow 0}\frac{1}{h} \int_0^h T(s) x \,ds \] and by (1.) above the argument of the limit is in $D(A)$. Hence any $x \in X$ can be approached by a limit sequence and $D(A)$ is dense in $X$. Assume now such a sequence $x_n \in D(A), x_n \rightarrow x$ and $Ax_n \rightarrow y$. Then integrating out part (2.) over the time interval $[0,h]$ we can write \[ T(h)x_n-x_n = \int_0^h T(s) A x_n \,ds. \] In the limit $n \rightarrow \infty$ this yields \[ T(h)x - x = \int_0^h T(s) y \,ds. \] Finally we divide by $h$ and let $h \searrow 0$ and get \[ Ax = \lim_{h \searrow 0} \frac{1}{h} \int_0^h T(s) y \,ds = y. \] This shows closedness. $\Box$
We can find two types of solutions to the Cauchy problem formulated here:
\[ A\int_0^t u(s)\,ds = u(t)-x. \] (Such solutions of an integral equation are called mild.)