oppczeroo

Description: Zero objects are zero in the opposite category. Remark 7.8 of Adamek p. 103. (Contributed by Zhi Wang, 27-Oct-2025)

		Ref	Expression
	Assertion	oppczeroo	$⊢ I \in ZeroO (C) \leftrightarrow I \in ZeroO (oppCat (C))$

Proof

Step	Hyp	Ref	Expression
1		zeroorcl	$⊢ I \in ZeroO (C) \to C \in Cat$
2		zeroorcl	$⊢ I \in ZeroO (oppCat (C)) \to oppCat (C) \in Cat$
3		eqid	$⊢ oppCat (C) = oppCat (C)$
4		eqid	$⊢ {Base}_{C} = {Base}_{C}$
5	3 4	oppcbas	$⊢ {Base}_{C} = {Base}_{oppCat (C)}$
6	5	zeroo2	$⊢ I \in ZeroO (oppCat (C)) \to I \in {Base}_{C}$
7		elfvex	$⊢ I \in {Base}_{C} \to C \in V$
8		id	$⊢ C \in V \to C \in V$
9	3 8	oppccatb	$⊢ C \in V \to (C \in Cat \leftrightarrow oppCat (C) \in Cat)$
10	6 7 9	3syl	$⊢ I \in ZeroO (oppCat (C)) \to (C \in Cat \leftrightarrow oppCat (C) \in Cat)$
11	2 10	mpbird	$⊢ I \in ZeroO (oppCat (C)) \to C \in Cat$
12		oppcinito	$⊢ c \in InitO (C) \leftrightarrow c \in TermO (oppCat (C))$
13	12	eqriv	$⊢ InitO (C) = TermO (oppCat (C))$
14		oppctermo	$⊢ c \in TermO (C) \leftrightarrow c \in InitO (oppCat (C))$
15	14	eqriv	$⊢ TermO (C) = InitO (oppCat (C))$
16	13 15	ineq12i	$⊢ InitO (C) \cap TermO (C) = TermO (oppCat (C)) \cap InitO (oppCat (C))$
17		incom	$⊢ TermO (oppCat (C)) \cap InitO (oppCat (C)) = InitO (oppCat (C)) \cap TermO (oppCat (C))$
18	16 17	eqtri	$⊢ InitO (C) \cap TermO (C) = InitO (oppCat (C)) \cap TermO (oppCat (C))$
19		id	$⊢ C \in Cat \to C \in Cat$
20		eqid	$⊢ Hom (C) = Hom (C)$
21	19 4 20	zerooval	$⊢ C \in Cat \to ZeroO (C) = InitO (C) \cap TermO (C)$
22	3	oppccat	$⊢ C \in Cat \to oppCat (C) \in Cat$
23		eqid	$⊢ Hom (oppCat (C)) = Hom (oppCat (C))$
24	22 5 23	zerooval	$⊢ C \in Cat \to ZeroO (oppCat (C)) = InitO (oppCat (C)) \cap TermO (oppCat (C))$
25	18 21 24	3eqtr4a	$⊢ C \in Cat \to ZeroO (C) = ZeroO (oppCat (C))$
26	25	eleq2d	$⊢ C \in Cat \to (I \in ZeroO (C) \leftrightarrow I \in ZeroO (oppCat (C)))$
27	1 11 26	pm5.21nii	$⊢ I \in ZeroO (C) \leftrightarrow I \in ZeroO (oppCat (C))$

Metamath Proof Explorer

Theorem oppczeroo

Proof