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edit approved May 6, 2019 at 19:15
user64494
edit approved May 6, 2019 at 19:15
user64494
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Every Is every $b$-discrete space $X$ with countable injective weight is basically disconnected?

Recall that a space $X$ is called basically disconnected [1] if every cozero-set has an open closure. According to Tkačuk [2], a space $X$ said to be $b$-discrete if every countable subset of $X$ is closed (equivalently, closed and discrete) and $C^∗$-embedded in $X$. Note that if $X$ is basically disconnected then $X$ is $b$-discrete [1].

EveryIs every $b$-discrete space $X$ with countable injective weight is basically basically disconnected?

[1] L. Gillman, M. Jerison, Rings of continuous functions, The University Series in Higher Mathematics. Princeton, New Jersey: D. Van Nostrand Co., Inc., 1960. 300 p

[2] V.V. Tkachuk, The spaces $C_p(X)$: decomposition into a countable union of bounded subspaces and completeness properties, Topology and its Applications, n 22, (1986), 241–253

Every $b$-discrete space $X$ with countable injective weight is basically disconnected?

Recall that a space $X$ is called basically disconnected [1] if every cozero-set has an open closure. According to Tkačuk [2], a space $X$ said to be $b$-discrete if every countable subset of $X$ is closed (equivalently, closed and discrete) and $C^∗$-embedded in $X$. Note that if $X$ is basically disconnected then $X$ is $b$-discrete [1].

Every $b$-discrete space $X$ with countable injective weight is basically disconnected?

[1] L. Gillman, M. Jerison, Rings of continuous functions, The University Series in Higher Mathematics. Princeton, New Jersey: D. Van Nostrand Co., Inc., 1960. 300 p

[2] V.V. Tkachuk, The spaces $C_p(X)$: decomposition into a countable union of bounded subspaces and completeness properties, Topology and its Applications, n 22, (1986), 241–253

Is every $b$-discrete space $X$ with countable injective weight basically disconnected?

Recall that a space $X$ is called basically disconnected [1] if every cozero-set has an open closure. According to Tkačuk [2], a space $X$ said to be $b$-discrete if every countable subset of $X$ is closed (equivalently, closed and discrete) and $C^∗$-embedded in $X$. Note that if $X$ is basically disconnected then $X$ is $b$-discrete [1].

Is every $b$-discrete space $X$ with countable injective weight basically disconnected?

[1] L. Gillman, M. Jerison, Rings of continuous functions, The University Series in Higher Mathematics. Princeton, New Jersey: D. Van Nostrand Co., Inc., 1960. 300 p

[2] V.V. Tkachuk, The spaces $C_p(X)$: decomposition into a countable union of bounded subspaces and completeness properties, Topology and its Applications, n 22, (1986), 241–253

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Bumped by Community user
Bumped by Community user
added links + I have added on purpose both spellings (Tkachuk and Tkačuk) so that people searching for either of them find this post
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Martin Sleziak
Martin Sleziak
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Recall that a space $X$ is called basically disconnected [1] if every cozero-set has an open closure. According to TkaˇcukTkačuk [2], a space $X$ said to be $b$-discrete if every countable subset of $X$ is closed (equivalently, closed and discrete) and $C^∗$-embedded in $X$. Note that if $X$ is basically disconnected then $X$ is $b$-discrete [1].

Every $b$-discrete space $X$ with countable injective weight is basically disconnected  ?

[1] L. Gillman, M. Jerison,Rings Rings of continuous functions, The UniversitySeriesUniversity Series in Higher Mathematics. Princeton, New Jersey: D. Van NostrandCoNostrand Co., Inc., 1960. 300 p

[2] V.V. TkaˇcukTkachuk,The spacesCp(X): decomposition into a countable unionof bounded subspaces and completeness properties The spaces $C_p(X)$: decomposition into a countable union of bounded subspaces and completeness properties, Topology and its Ap-plicationsApplications, n 22, (1986), 241–253

Recall that a space $X$ is called basically disconnected [1] if every cozero-set has an open closure. According to Tkaˇcuk [2], a space $X$ said to be $b$-discrete if every countable subset of $X$ is closed (equivalently, closed and discrete) and $C^∗$-embedded in $X$. Note that if $X$ is basically disconnected then $X$ is $b$-discrete [1].

Every $b$-discrete space $X$ with countable injective weight is basically disconnected  ?

[1] L. Gillman, M. Jerison,Rings of continuous functions, The UniversitySeries in Higher Mathematics. Princeton, New Jersey: D. Van NostrandCo., Inc., 1960. 300 p

[2] V.V. Tkaˇcuk,The spacesCp(X): decomposition into a countable unionof bounded subspaces and completeness properties, Topology and its Ap-plications, n 22, (1986), 241–253

Recall that a space $X$ is called basically disconnected [1] if every cozero-set has an open closure. According to Tkačuk [2], a space $X$ said to be $b$-discrete if every countable subset of $X$ is closed (equivalently, closed and discrete) and $C^∗$-embedded in $X$. Note that if $X$ is basically disconnected then $X$ is $b$-discrete [1].

Every $b$-discrete space $X$ with countable injective weight is basically disconnected?

[1] L. Gillman, M. Jerison, Rings of continuous functions, The University Series in Higher Mathematics. Princeton, New Jersey: D. Van Nostrand Co., Inc., 1960. 300 p

[2] V.V. Tkachuk, The spaces $C_p(X)$: decomposition into a countable union of bounded subspaces and completeness properties, Topology and its Applications, n 22, (1986), 241–253

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Alexander Osipov
Alexander Osipov
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Every $b$-discrete space $X$ with countable injective weight is basically disconnected?

Recall that a space $X$ is called basically disconnected [1] if every cozero-set has an open closure. According to Tkaˇcuk [2], a space $X$ said to be $b$-discrete if every countable subset of $X$ is closed (equivalently, closed and discrete) and $C^∗$-embedded in $X$. Note that if $X$ is basically disconnected then $X$ is $b$-discrete [1].

Every $b$-discrete space $X$ with countable injective weight is basically disconnected ?

[1] L. Gillman, M. Jerison,Rings of continuous functions, The UniversitySeries in Higher Mathematics. Princeton, New Jersey: D. Van NostrandCo., Inc., 1960. 300 p

[2] V.V. Tkaˇcuk,The spacesCp(X): decomposition into a countable unionof bounded subspaces and completeness properties, Topology and its Ap-plications, n 22, (1986), 241–253