In mathematics, a dendroid is a type of topological space, satisfying the properties that it is hereditarily unicoherent (meaning that every subcontinuum of X is unicoherent), arcwise connected, and forms a continuum. [1] The term dendroid was introduced by Bronisław Knaster lecturing at the University of Wrocław, [2] although these spaces were studied earlier by Karol Borsuk and others. [3] [4]
Borsuk (1954) proved that dendroids have the fixed-point property: Every continuous function from a dendroid to itself has a fixed point. [3] Cook (1970) proved that every dendroid is tree-like, meaning that it has arbitrarily fine open covers whose nerve is a tree. [1] [5] The more general question of whether every tree-like continuum has the fixed-point property, posed by Bing (1951), [6] was solved in the negative by David P. Bellamy, who gave an example of a tree-like continuum without the fixed-point property. [7]
In Knaster's original publication on dendroids, in 1961, he posed the problem of characterizing the dendroids which can be embedded into the Euclidean plane. This problem remains open. [2] [8] Another problem posed in the same year by Knaster, on the existence of an uncountable collection of dendroids with the property that no dendroid in the collection has a continuous surjection onto any other dendroid in the collection, was solved by Minc (2010) and Islas (2007), who gave an example of such a family. [9] [10]
A locally connected dendroid is called a dendrite. A cone over the Cantor set (called a Cantor fan) is an example of a dendroid that is not a dendrite. [11]
In mathematics, a dendroid is a type of topological space, satisfying the properties that it is hereditarily unicoherent (meaning that every subcontinuum of X is unicoherent), arcwise connected, and forms a continuum. [1] The term dendroid was introduced by Bronisław Knaster lecturing at the University of Wrocław, [2] although these spaces were studied earlier by Karol Borsuk and others. [3] [4]
Borsuk (1954) proved that dendroids have the fixed-point property: Every continuous function from a dendroid to itself has a fixed point. [3] Cook (1970) proved that every dendroid is tree-like, meaning that it has arbitrarily fine open covers whose nerve is a tree. [1] [5] The more general question of whether every tree-like continuum has the fixed-point property, posed by Bing (1951), [6] was solved in the negative by David P. Bellamy, who gave an example of a tree-like continuum without the fixed-point property. [7]
In Knaster's original publication on dendroids, in 1961, he posed the problem of characterizing the dendroids which can be embedded into the Euclidean plane. This problem remains open. [2] [8] Another problem posed in the same year by Knaster, on the existence of an uncountable collection of dendroids with the property that no dendroid in the collection has a continuous surjection onto any other dendroid in the collection, was solved by Minc (2010) and Islas (2007), who gave an example of such a family. [9] [10]
A locally connected dendroid is called a dendrite. A cone over the Cantor set (called a Cantor fan) is an example of a dendroid that is not a dendrite. [11]