Does the Brouwer fixed point theorem hold for the torus minus an open disk?

Let's express $T^2$ by letting $H \subset \mathbb{R}^2$ be a regular hexagon centered at the origin, and then gluing opposite sides of $H$ by translations.

Let $q : H \to T^2$ be the quotient map of this gluing.

Let $D^2 \subset \mathbb{R}^2$ be a small round open disc centered at the origin and contained in the interior of $H$, and so we may regard $D^2$ as embedded in $T^2$ by the map $q$. Then, as you say, we remove the interior of $D^2$ to obtain the surface $S$.

Now let $R : H \to H$ be a rotation of angle $2 \pi / 6$. The map $R$ induces a homeomorphism $S \mapsto S$ having no fixed points.


Let's sit your torus $T^2$ inside $\Bbb{C} \times \Bbb{C}$ as the subset $S^1 \times S^1$, where $S^1 = \{ z \mid |z|= 1\}$ and let's sit your disk $D^2$ so that it doesn't meet the circle $\{(z, 1) \mid z \in S^1\}$. Then the function $(z, w) \mapsto (iz,1)$ has no fixed points on any subset of $T^2$.

Tags:

General Topology

Fixed Point Theorems

Related

Why is the Axiom of Choice not needed when the collection of sets is finite? Dual Commutes with Base Change Conditional expectation of a joint normal distribution Why aren't all functions considered a power function of 1 and integrated using some sort of chain rule? A question about differentiating equations that are impossible to solve for a variable Integrating $e^x / (e^x - 2)$ Laplace transform of Bessel function of order zero Use integration to estimate $\sum\limits_{n=0}^{+\infty}(-1)^n\frac 1 {n+1}\sum\limits_{k=0}^n \frac 1 {k+1}$ $\int \sec^3x dx$ in disguise Proving an inequality by mathematical induction Existence of group $G$ with $|G|>2$ and automorphism group of odd order Find the limit $\lim_\limits{n\to{\infty}}n^2(\sqrt[n]{x}-\sqrt[{n + 1}]{x})$ and my inquiry about Stolz-Cesàro theorem

Recent Posts