Sorgenfrey line: Difference between revisions
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==Definition== | ==Definition== | ||
The '''Sorgenfrey line''' is defined as follows: as a set, it is the real line, and its basis of open sets is taken as all the | The '''Sorgenfrey line''' is defined as follows: as a set, it is the real line, and its basis of open sets is taken as all the right-open, left-closed intervals, viz., sets of the form <math>[a,b)</math>. Equivalently, we can say that it is obtained by giving the [[lower limit topology]] corresponding to the usual ordering on the real line. | ||
The product of two copies of the Sorgenfrey line is the [[Sorgenfrey plane]], which is ''not'' normal. This gives an example of the fact that a product of two normal spaces need not be normal. | The product of two copies of the Sorgenfrey line is the [[Sorgenfrey plane]], which is ''not'' normal. This gives an example of the fact that a product of two normal spaces need not be normal. | ||
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* [[Metrizable space]] | * [[Metrizable space]] | ||
* [[Elastic space]] | * [[Elastic space]] | ||
==References== | |||
===Textbook references=== | |||
* {{booklink-defined|Munkres}} | |||
Revision as of 17:36, 20 July 2008
This article describes a standard counterexample to some plausible but false implications. In other words, it lists a pathology that may be useful to keep in mind to avoid pitfalls in proofs
View other standard counterexamples in topology
Definition
The Sorgenfrey line is defined as follows: as a set, it is the real line, and its basis of open sets is taken as all the right-open, left-closed intervals, viz., sets of the form . Equivalently, we can say that it is obtained by giving the lower limit topology corresponding to the usual ordering on the real line.
The product of two copies of the Sorgenfrey line is the Sorgenfrey plane, which is not normal. This gives an example of the fact that a product of two normal spaces need not be normal.
Topological space properties
Properties it does satisfy
- Totally disconnected space: The Sorgenfrey line is totally disconnected; given any two points, we can separate them by disjoint open sets.
- First-countable space
- Separable space
- Lindelof space
- Paracompact Hausdorff space
- Baire space
- Perfectly normal space
- Monotonically normal space
Properties it does not satisfy
References
Textbook references
- Topology (2nd edition) by James R. MunkresMore info