Spahn reflective subcategory of a topos (changes)

Showing changes from revision #13 to #14: Added | ~~Removed~~ | ~~Chan~~ged

The following lemma improves on the statement

A reflective subcategory of a topos is a topos if the reflector is left exact.

Lemma

Let $(L\dashv R):E\stackrel{\R}{\hookrightarrow} H$ be a reflective subcategory of a topos.

Then $E$ is a topos if $L$ preserves pullbacks in the image of $a_H\circ R_!$ where

$(a_H\dashv Y_H):H\to Psh(H)$ is the left adjoint of the Yoneda embedding of $H$ .
$R_!:=Lan_{Y_E} Y_H\circ R$ is the left Kan extension of $Y_H\circ R$ along the Yoneda embedding of $E$ .

\array{ Psh(E)&\stackrel{a_E\dashv Y_E}{\to}&E \\ \downarrow^{R_!}&&\downarrow^{L\dashv R} \\ Psh(H)&\stackrel{a_H\dashv Y_H}{\to}&H }

Proof

The Yoneda embeddings of $E$ and $H$ both posess left adjoints: $H$ and $E$ are total: Since $H$ is a topos, $H$ is total, since $E$ is a reflective subcategory of a total category $E$ is total. By the adjoint functor theorem for total categories this implies that the Yoneda embeddings of $E$ and $H$ both posess left adjoints.
We have $a_E\simeq L\circ a_H\circ R_!$ . ~~sends~~ If ~~colimits~~ this ~~into~~ composite ~~limits,~~ is ~~since~~ left exact it exhibits $a_{E} E$ ~~a_E~~ E is as a left ~~adjoint.~~ exact localization of a category of presheaves and hence in this case $E$ is a topos.
$a_{H} \circ R_{!}$ a_H\circ R_! ~~preserves~~ sends colimits to limits, since ~~Yoneda~~ ~~extension~~ ~~always~~ ~~commutes~~ ~~with~~ ~~small~~ ~~colimits.~~ ~~And~~ $R_!$ ~~restricts~~ (as to every Yoneda extension) commutes with colimits and $R a_{H}$ R a_H on as ~~representables.~~ a left adjoint sends colimits to limits.
~~$a_H$~~ Hence ~~sends colimits to limits~~ $a_E\simeq L\circ a_H\circ R_!$ is left exact iff $L$ preserves limits in the image of $a_H\circ R_!$ .
~~Hence~~ Since a reflector always preserves terminal objects (and all finite limits can be constructed from pullbacks and the terminal object), it is sufficient to check if $L$ ~~needs~~ preserves to pullbacks ~~send~~ ~~limits~~ in the image of $a_H\circ R_!$ . to ~~limits.~~

Since a reflector always preserves the terminal object (and all finite limits can be constructed from pullbacks and the terminal object), it is sufficient for the previous point 5. that $L$ preserves pullbacks in the image of $a_H\circ R_!$ .

Let $J$ denote the canonical topology on $H$ st. $Sh_J(H)\simeq \Psh_J(H)\simeq H$ and $a_H\simeq Sh_J(-)$ . $Psh(E)$ is cocomplete and hence every diagram $D:I\to Psh(E)$ has a colimit which is preserved by $R_!$ and $a_H$ .

(If $\circ$ denotes a duality and $l\dashv r$ then $r^\circ\dashv l^\circ$ . Hence if $R_!$ has a left adjoint, then $R$ has a right adjoint. Every subcategory of a category of presheaves which is reflective and coreflective is itself a category of presheaves (this is quoted at reflective subcategory as Bashir Velebil). In particular $E$ is a topos.)

Last revised on December 10, 2012 at 17:27:14. See the history of this page for a list of all contributions to it.