Metamath Proof Explorer

Theorem nrmsep2

Description: In a normal space, any two disjoint closed sets have the property that each one is a subset of an open set whose closure is disjoint from the other. (Contributed by Jeff Hankins, 1-Feb-2010) (Revised by Mario Carneiro, 24-Aug-2015)

		Ref	Expression
	Assertion	nrmsep2	\|- ( ( J e. Nrm /\ ( C e. ( Clsd ` J ) /\ D e. ( Clsd ` J ) /\ ( C i^i D ) = (/) ) ) -> E. x e. J ( C C_ x /\ ( ( ( cls ` J ) ` x ) i^i D ) = (/) ) )

Proof

Step	Hyp	Ref	Expression
1		simpl	\|- ( ( J e. Nrm /\ ( C e. ( Clsd ` J ) /\ D e. ( Clsd ` J ) /\ ( C i^i D ) = (/) ) ) -> J e. Nrm )
2		simpr2	\|- ( ( J e. Nrm /\ ( C e. ( Clsd ` J ) /\ D e. ( Clsd ` J ) /\ ( C i^i D ) = (/) ) ) -> D e. ( Clsd ` J ) )
3		eqid	\|- U. J = U. J
4	3	cldopn	\|- ( D e. ( Clsd ` J ) -> ( U. J \ D ) e. J )
5	2 4	syl	\|- ( ( J e. Nrm /\ ( C e. ( Clsd ` J ) /\ D e. ( Clsd ` J ) /\ ( C i^i D ) = (/) ) ) -> ( U. J \ D ) e. J )
6		simpr1	\|- ( ( J e. Nrm /\ ( C e. ( Clsd ` J ) /\ D e. ( Clsd ` J ) /\ ( C i^i D ) = (/) ) ) -> C e. ( Clsd ` J ) )
7		simpr3	\|- ( ( J e. Nrm /\ ( C e. ( Clsd ` J ) /\ D e. ( Clsd ` J ) /\ ( C i^i D ) = (/) ) ) -> ( C i^i D ) = (/) )
8	3	cldss	\|- ( C e. ( Clsd ` J ) -> C C_ U. J )
9		reldisj	\|- ( C C_ U. J -> ( ( C i^i D ) = (/) <-> C C_ ( U. J \ D ) ) )
10	6 8 9	3syl	\|- ( ( J e. Nrm /\ ( C e. ( Clsd ` J ) /\ D e. ( Clsd ` J ) /\ ( C i^i D ) = (/) ) ) -> ( ( C i^i D ) = (/) <-> C C_ ( U. J \ D ) ) )
11	7 10	mpbid	\|- ( ( J e. Nrm /\ ( C e. ( Clsd ` J ) /\ D e. ( Clsd ` J ) /\ ( C i^i D ) = (/) ) ) -> C C_ ( U. J \ D ) )
12		nrmsep3	\|- ( ( J e. Nrm /\ ( ( U. J \ D ) e. J /\ C e. ( Clsd ` J ) /\ C C_ ( U. J \ D ) ) ) -> E. x e. J ( C C_ x /\ ( ( cls ` J ) ` x ) C_ ( U. J \ D ) ) )
13	1 5 6 11 12	syl13anc	\|- ( ( J e. Nrm /\ ( C e. ( Clsd ` J ) /\ D e. ( Clsd ` J ) /\ ( C i^i D ) = (/) ) ) -> E. x e. J ( C C_ x /\ ( ( cls ` J ) ` x ) C_ ( U. J \ D ) ) )
14		ssdifin0	\|- ( ( ( cls ` J ) ` x ) C_ ( U. J \ D ) -> ( ( ( cls ` J ) ` x ) i^i D ) = (/) )
15	14	anim2i	\|- ( ( C C_ x /\ ( ( cls ` J ) ` x ) C_ ( U. J \ D ) ) -> ( C C_ x /\ ( ( ( cls ` J ) ` x ) i^i D ) = (/) ) )
16	15	reximi	\|- ( E. x e. J ( C C_ x /\ ( ( cls ` J ) ` x ) C_ ( U. J \ D ) ) -> E. x e. J ( C C_ x /\ ( ( ( cls ` J ) ` x ) i^i D ) = (/) ) )
17	13 16	syl	\|- ( ( J e. Nrm /\ ( C e. ( Clsd ` J ) /\ D e. ( Clsd ` J ) /\ ( C i^i D ) = (/) ) ) -> E. x e. J ( C C_ x /\ ( ( ( cls ` J ) ` x ) i^i D ) = (/) ) )