Abstract
We investigate the completeness and completions of the normed algebras $D^{(1)}(X)$ for perfect, compact plane sets $X$. In particular, we construct a radially self-absorbing, compact plane set $X$ such that the normed algebra $D^{(1)}(X)$ is not complete. This solves a question of Bland and Feinstein. We also prove that there are several classes of connected, compact plane sets $X$ for which the completeness of $D^{(1)}(X)$ is equivalent to the pointwise regularity of $X$. For example, this is true for all rectifiably connected, polynomially convex, compact plane sets with empty interior, for all star-shaped, compact plane sets, and for all Jordan arcs in $\mathbb{C}$. In an earlier paper of Bland and Feinstein, the notion of an $\mathcal{F}$-derivative of a function was introduced, where $\mathcal{F}$ is a suitable set of rectifiable paths, and with it a new family of Banach algebras $D_{\mathcal{F}}^{(1)}(X)$ corresponding to the normed algebras $D^{(1)}(X)$. In the present paper, we obtain stronger results concerning the questions when $D^{(1)}(X)$ and $D_{\mathcal{F}}^{(1)}(X)$ are equal, and when the former is dense in the latter. In particular, we show that equality holds whenever $X$ is '$\mathcal{F}$-regular'. An example of Bishop shows that the completion of $D^{(1)}(X)$ need not be semisimple. We show that the completion of $D^{(1)}(X)$ is semisimple whenever the union of all the rectifiable Jordan arcs in $X$ is dense in $X$. We prove that the character space of $D^{(1)}(X)$ is equal to $X$ for all perfect, compact plane sets $X$, whether or not $D^{(1)}(X)$ is complete. In particular, characters on the normed algebras $D^{(1)}(X)$ are automatically continuous.
Highlights
Throughout this paper, by a compact space we shall mean a non-empty, compact, Hausdorff topological space; by a compact plane set we shall mean a non-empty, compact subset of the complex plane
We prove that the character space of (1)( ) is equal to for all perfect, compact plane sets, whether or not ( (1)( ), ∥ ⋅ ∥) is complete
We shall see an interesting relationship between the geometry of a compact plane set and the properties of the normed algebra ( (1)( ), ∥ ⋅ ∥)
Summary
Throughout this paper, by a compact space we shall mean a non-empty, compact, Hausdorff topological space; by a compact plane set we shall mean a non-empty, compact subset of the complex plane. Let be a perfect, compact plane set, and let (1)( ) be the normed algebra of all continuously differentiable, complex-valued functions on. These algebras (and others) were discussed by Dales and Davie in [7]. We shall see an interesting relationship between the geometry of a compact plane set and the properties of the normed algebra ( (1)( ), ∥ ⋅ ∥). For each connected, compact plane set with more than one point, ( (1)( ), ∥ ⋅ ∥) is complete if and only if is pointwise regular. We shall answer a problem raised in [3] by constructing a radially self-absorbing, compact plane set such that ( (1)( ), ∥ ⋅ ∥) is not complete
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