axtcond

Description: A version of the Axiom of Transitive Containment with no distinct variable conditions. Usage of this theorem is discouraged because it depends on ax-13 . (Contributed by Matthew House, 6-Apr-2026) (New usage is discouraged.)

		Ref	Expression
	Assertion	axtcond	$⊢ \exists y \forall z ((z = x \lor z \in y) \to \forall x (x \in z \to x \in y))$

Proof

Step	Hyp	Ref	Expression
1		axtco2	$⊢ \exists w \forall v ((v = x \lor v \in w) \to \forall x (x \in v \to x \in w))$
2		nfnae	$⊢ Ⅎ y \neg \forall x x = y$
3		nfnae	$⊢ Ⅎ y \neg \forall x x = z$
4		nfnae	$⊢ Ⅎ y \neg \forall y y = z$
5	2 3 4	nf3an	$⊢ Ⅎ y (\neg \forall x x = y \land \neg \forall x x = z \land \neg \forall y y = z)$
6		nfv	$⊢ Ⅎ y \forall v ((v = t \lor v \in w) \to \forall t (t \in v \to t \in w))$
7		equequ2	$⊢ t = x \to (v = t \leftrightarrow v = x)$
8	7	orbi1d	$⊢ t = x \to ((v = t \lor v \in w) \leftrightarrow (v = x \lor v \in w))$
9		elequ1	$⊢ t = x \to (t \in v \leftrightarrow x \in v)$
10		elequ1	$⊢ t = x \to (t \in w \leftrightarrow x \in w)$
11	9 10	imbi12d	$⊢ t = x \to ((t \in v \to t \in w) \leftrightarrow (x \in v \to x \in w))$
12	11	cbvalvw	$⊢ \forall t (t \in v \to t \in w) \leftrightarrow \forall x (x \in v \to x \in w)$
13	12	a1i	$⊢ t = x \to (\forall t (t \in v \to t \in w) \leftrightarrow \forall x (x \in v \to x \in w))$
14	8 13	imbi12d	$⊢ t = x \to (((v = t \lor v \in w) \to \forall t (t \in v \to t \in w)) \leftrightarrow ((v = x \lor v \in w) \to \forall x (x \in v \to x \in w)))$
15	14	albidv	$⊢ t = x \to (\forall v ((v = t \lor v \in w) \to \forall t (t \in v \to t \in w)) \leftrightarrow \forall v ((v = x \lor v \in w) \to \forall x (x \in v \to x \in w)))$
16	6 15	dvelimnf	$⊢ \neg \forall y y = x \to Ⅎ y \forall v ((v = x \lor v \in w) \to \forall x (x \in v \to x \in w))$
17	16	naecoms	$⊢ \neg \forall x x = y \to Ⅎ y \forall v ((v = x \lor v \in w) \to \forall x (x \in v \to x \in w))$
18	17	3ad2ant1	$⊢ (\neg \forall x x = y \land \neg \forall x x = z \land \neg \forall y y = z) \to Ⅎ y \forall v ((v = x \lor v \in w) \to \forall x (x \in v \to x \in w))$
19		nfnae	$⊢ Ⅎ z \neg \forall x x = y$
20		nfnae	$⊢ Ⅎ z \neg \forall x x = z$
21		nfnae	$⊢ Ⅎ z \neg \forall y y = z$
22	19 20 21	nf3an	$⊢ Ⅎ z (\neg \forall x x = y \land \neg \forall x x = z \land \neg \forall y y = z)$
23		nfeqf2	$⊢ \neg \forall z z = y \to Ⅎ z w = y$
24	23	naecoms	$⊢ \neg \forall y y = z \to Ⅎ z w = y$
25	24	3ad2ant3	$⊢ (\neg \forall x x = y \land \neg \forall x x = z \land \neg \forall y y = z) \to Ⅎ z w = y$
26	22 25	nfan1	$⊢ Ⅎ z ((\neg \forall x x = y \land \neg \forall x x = z \land \neg \forall y y = z) \land w = y)$
27		simpl2	$⊢ ((\neg \forall x x = y \land \neg \forall x x = z \land \neg \forall y y = z) \land w = y) \to \neg \forall x x = z$
28		nfv	$⊢ Ⅎ z ((v = t \lor v \in w) \to \forall t (t \in v \to t \in w))$
29	28 14	dvelimnf	$⊢ \neg \forall z z = x \to Ⅎ z ((v = x \lor v \in w) \to \forall x (x \in v \to x \in w))$
30	29	naecoms	$⊢ \neg \forall x x = z \to Ⅎ z ((v = x \lor v \in w) \to \forall x (x \in v \to x \in w))$
31	27 30	syl	$⊢ ((\neg \forall x x = y \land \neg \forall x x = z \land \neg \forall y y = z) \land w = y) \to Ⅎ z ((v = x \lor v \in w) \to \forall x (x \in v \to x \in w))$
32		equequ1	$⊢ v = z \to (v = x \leftrightarrow z = x)$
33	32	adantl	$⊢ (w = y \land v = z) \to (v = x \leftrightarrow z = x)$
34		elequ12	$⊢ (v = z \land w = y) \to (v \in w \leftrightarrow z \in y)$
35	34	ancoms	$⊢ (w = y \land v = z) \to (v \in w \leftrightarrow z \in y)$
36	33 35	orbi12d	$⊢ (w = y \land v = z) \to ((v = x \lor v \in w) \leftrightarrow (z = x \lor z \in y))$
37	36	adantl	$⊢ ((\neg \forall x x = y \land \neg \forall x x = z) \land (w = y \land v = z)) \to ((v = x \lor v \in w) \leftrightarrow (z = x \lor z \in y))$
38		nfnae	$⊢ Ⅎ x \neg \forall x x = y$
39		nfnae	$⊢ Ⅎ x \neg \forall x x = z$
40	38 39	nfan	$⊢ Ⅎ x (\neg \forall x x = y \land \neg \forall x x = z)$
41		nfeqf2	$⊢ \neg \forall x x = y \to Ⅎ x w = y$
42	41	adantr	$⊢ (\neg \forall x x = y \land \neg \forall x x = z) \to Ⅎ x w = y$
43		nfeqf2	$⊢ \neg \forall x x = z \to Ⅎ x v = z$
44	43	adantl	$⊢ (\neg \forall x x = y \land \neg \forall x x = z) \to Ⅎ x v = z$
45	42 44	nfand	$⊢ (\neg \forall x x = y \land \neg \forall x x = z) \to Ⅎ x (w = y \land v = z)$
46	40 45	nfan1	$⊢ Ⅎ x ((\neg \forall x x = y \land \neg \forall x x = z) \land (w = y \land v = z))$
47		elequ2	$⊢ v = z \to (x \in v \leftrightarrow x \in z)$
48	47	adantl	$⊢ (w = y \land v = z) \to (x \in v \leftrightarrow x \in z)$
49		elequ2	$⊢ w = y \to (x \in w \leftrightarrow x \in y)$
50	49	adantr	$⊢ (w = y \land v = z) \to (x \in w \leftrightarrow x \in y)$
51	48 50	imbi12d	$⊢ (w = y \land v = z) \to ((x \in v \to x \in w) \leftrightarrow (x \in z \to x \in y))$
52	51	adantl	$⊢ ((\neg \forall x x = y \land \neg \forall x x = z) \land (w = y \land v = z)) \to ((x \in v \to x \in w) \leftrightarrow (x \in z \to x \in y))$
53	46 52	albid	$⊢ ((\neg \forall x x = y \land \neg \forall x x = z) \land (w = y \land v = z)) \to (\forall x (x \in v \to x \in w) \leftrightarrow \forall x (x \in z \to x \in y))$
54	37 53	imbi12d	$⊢ ((\neg \forall x x = y \land \neg \forall x x = z) \land (w = y \land v = z)) \to (((v = x \lor v \in w) \to \forall x (x \in v \to x \in w)) \leftrightarrow ((z = x \lor z \in y) \to \forall x (x \in z \to x \in y)))$
55	54	expr	$⊢ ((\neg \forall x x = y \land \neg \forall x x = z) \land w = y) \to (v = z \to (((v = x \lor v \in w) \to \forall x (x \in v \to x \in w)) \leftrightarrow ((z = x \lor z \in y) \to \forall x (x \in z \to x \in y))))$
56	55	3adantl3	$⊢ ((\neg \forall x x = y \land \neg \forall x x = z \land \neg \forall y y = z) \land w = y) \to (v = z \to (((v = x \lor v \in w) \to \forall x (x \in v \to x \in w)) \leftrightarrow ((z = x \lor z \in y) \to \forall x (x \in z \to x \in y))))$
57	26 31 56	cbvaldw	$⊢ ((\neg \forall x x = y \land \neg \forall x x = z \land \neg \forall y y = z) \land w = y) \to (\forall v ((v = x \lor v \in w) \to \forall x (x \in v \to x \in w)) \leftrightarrow \forall z ((z = x \lor z \in y) \to \forall x (x \in z \to x \in y)))$
58	57	ex	$⊢ (\neg \forall x x = y \land \neg \forall x x = z \land \neg \forall y y = z) \to (w = y \to (\forall v ((v = x \lor v \in w) \to \forall x (x \in v \to x \in w)) \leftrightarrow \forall z ((z = x \lor z \in y) \to \forall x (x \in z \to x \in y))))$
59	5 18 58	cbvexdw	$⊢ (\neg \forall x x = y \land \neg \forall x x = z \land \neg \forall y y = z) \to (\exists w \forall v ((v = x \lor v \in w) \to \forall x (x \in v \to x \in w)) \leftrightarrow \exists y \forall z ((z = x \lor z \in y) \to \forall x (x \in z \to x \in y)))$
60	1 59	mpbii	$⊢ (\neg \forall x x = y \land \neg \forall x x = z \land \neg \forall y y = z) \to \exists y \forall z ((z = x \lor z \in y) \to \forall x (x \in z \to x \in y))$
61	60	3exp	$⊢ \neg \forall x x = y \to (\neg \forall x x = z \to (\neg \forall y y = z \to \exists y \forall z ((z = x \lor z \in y) \to \forall x (x \in z \to x \in y))))$
62		nfae	$⊢ Ⅎ z \forall y y = z$
63		nfae	$⊢ Ⅎ x \forall y y = z$
64		elequ2	$⊢ y = z \to (x \in y \leftrightarrow x \in z)$
65	64	sps	$⊢ \forall y y = z \to (x \in y \leftrightarrow x \in z)$
66	65	biimprd	$⊢ \forall y y = z \to (x \in z \to x \in y)$
67	63 66	alrimi	$⊢ \forall y y = z \to \forall x (x \in z \to x \in y)$
68	67	a1d	$⊢ \forall y y = z \to ((z = x \lor z \in y) \to \forall x (x \in z \to x \in y))$
69	62 68	alrimi	$⊢ \forall y y = z \to \forall z ((z = x \lor z \in y) \to \forall x (x \in z \to x \in y))$
70	69	19.8ad	$⊢ \forall y y = z \to \exists y \forall z ((z = x \lor z \in y) \to \forall x (x \in z \to x \in y))$
71	70	a1i	$⊢ \forall x x = y \to (\forall y y = z \to \exists y \forall z ((z = x \lor z \in y) \to \forall x (x \in z \to x \in y)))$
72		ax-nul	$⊢ \exists y \forall u \neg u \in y$
73		nfv	$⊢ Ⅎ z \forall u \neg u \in t$
74		elequ2	$⊢ t = y \to (u \in t \leftrightarrow u \in y)$
75	74	notbid	$⊢ t = y \to (\neg u \in t \leftrightarrow \neg u \in y)$
76	75	albidv	$⊢ t = y \to (\forall u \neg u \in t \leftrightarrow \forall u \neg u \in y)$
77	73 76	dvelimnf	$⊢ \neg \forall z z = y \to Ⅎ z \forall u \neg u \in y$
78	77	naecoms	$⊢ \neg \forall y y = z \to Ⅎ z \forall u \neg u \in y$
79		elequ2	$⊢ z = y \to (u \in z \leftrightarrow u \in y)$
80	79	notbid	$⊢ z = y \to (\neg u \in z \leftrightarrow \neg u \in y)$
81	80	albidv	$⊢ z = y \to (\forall u \neg u \in z \leftrightarrow \forall u \neg u \in y)$
82	81	biimprcd	$⊢ \forall u \neg u \in y \to (z = y \to \forall u \neg u \in z)$
83		elirrv	$⊢ \neg x \in x$
84		elequ2	$⊢ x = z \to (x \in x \leftrightarrow x \in z)$
85	83 84	mtbii	$⊢ x = z \to \neg x \in z$
86	85	pm2.21d	$⊢ x = z \to (x \in z \to x \in y)$
87	86	alimi	$⊢ \forall x x = z \to \forall x (x \in z \to x \in y)$
88	87	a1d	$⊢ \forall x x = z \to (\forall u \neg u \in z \to \forall x (x \in z \to x \in y))$
89		nfv	$⊢ Ⅎ x \forall u \neg u \in t$
90		elequ2	$⊢ t = z \to (u \in t \leftrightarrow u \in z)$
91	90	notbid	$⊢ t = z \to (\neg u \in t \leftrightarrow \neg u \in z)$
92	91	albidv	$⊢ t = z \to (\forall u \neg u \in t \leftrightarrow \forall u \neg u \in z)$
93	89 92	dvelimnf	$⊢ \neg \forall x x = z \to Ⅎ x \forall u \neg u \in z$
94		elequ1	$⊢ u = x \to (u \in z \leftrightarrow x \in z)$
95	94	notbid	$⊢ u = x \to (\neg u \in z \leftrightarrow \neg x \in z)$
96	95	spvv	$⊢ \forall u \neg u \in z \to \neg x \in z$
97	96	pm2.21d	$⊢ \forall u \neg u \in z \to (x \in z \to x \in y)$
98	97	a1i	$⊢ \neg \forall x x = z \to (\forall u \neg u \in z \to (x \in z \to x \in y))$
99	39 93 98	alrimdd	$⊢ \neg \forall x x = z \to (\forall u \neg u \in z \to \forall x (x \in z \to x \in y))$
100	88 99	pm2.61i	$⊢ \forall u \neg u \in z \to \forall x (x \in z \to x \in y)$
101	82 100	syl6	$⊢ \forall u \neg u \in y \to (z = y \to \forall x (x \in z \to x \in y))$
102		elequ1	$⊢ u = z \to (u \in y \leftrightarrow z \in y)$
103	102	notbid	$⊢ u = z \to (\neg u \in y \leftrightarrow \neg z \in y)$
104	103	spvv	$⊢ \forall u \neg u \in y \to \neg z \in y$
105	104	pm2.21d	$⊢ \forall u \neg u \in y \to (z \in y \to \forall x (x \in z \to x \in y))$
106	101 105	jaod	$⊢ \forall u \neg u \in y \to ((z = y \lor z \in y) \to \forall x (x \in z \to x \in y))$
107	106	a1i	$⊢ \neg \forall y y = z \to (\forall u \neg u \in y \to ((z = y \lor z \in y) \to \forall x (x \in z \to x \in y)))$
108	21 78 107	alrimdd	$⊢ \neg \forall y y = z \to (\forall u \neg u \in y \to \forall z ((z = y \lor z \in y) \to \forall x (x \in z \to x \in y)))$
109	4 108	eximd	$⊢ \neg \forall y y = z \to (\exists y \forall u \neg u \in y \to \exists y \forall z ((z = y \lor z \in y) \to \forall x (x \in z \to x \in y)))$
110	72 109	mpi	$⊢ \neg \forall y y = z \to \exists y \forall z ((z = y \lor z \in y) \to \forall x (x \in z \to x \in y))$
111		nfae	$⊢ Ⅎ y \forall x x = y$
112		nfae	$⊢ Ⅎ z \forall x x = y$
113		equequ2	$⊢ x = y \to (z = x \leftrightarrow z = y)$
114	113	sps	$⊢ \forall x x = y \to (z = x \leftrightarrow z = y)$
115	114	orbi1d	$⊢ \forall x x = y \to ((z = x \lor z \in y) \leftrightarrow (z = y \lor z \in y))$
116	115	imbi1d	$⊢ \forall x x = y \to (((z = x \lor z \in y) \to \forall x (x \in z \to x \in y)) \leftrightarrow ((z = y \lor z \in y) \to \forall x (x \in z \to x \in y)))$
117	112 116	albid	$⊢ \forall x x = y \to (\forall z ((z = x \lor z \in y) \to \forall x (x \in z \to x \in y)) \leftrightarrow \forall z ((z = y \lor z \in y) \to \forall x (x \in z \to x \in y)))$
118	111 117	exbid	$⊢ \forall x x = y \to (\exists y \forall z ((z = x \lor z \in y) \to \forall x (x \in z \to x \in y)) \leftrightarrow \exists y \forall z ((z = y \lor z \in y) \to \forall x (x \in z \to x \in y)))$
119	110 118	imbitrrid	$⊢ \forall x x = y \to (\neg \forall y y = z \to \exists y \forall z ((z = x \lor z \in y) \to \forall x (x \in z \to x \in y)))$
120	71 119	pm2.61d	$⊢ \forall x x = y \to \exists y \forall z ((z = x \lor z \in y) \to \forall x (x \in z \to x \in y))$
121		nfae	$⊢ Ⅎ z \forall x x = z$
122	87	a1d	$⊢ \forall x x = z \to ((z = x \lor z \in y) \to \forall x (x \in z \to x \in y))$
123	121 122	alrimi	$⊢ \forall x x = z \to \forall z ((z = x \lor z \in y) \to \forall x (x \in z \to x \in y))$
124	123	19.8ad	$⊢ \forall x x = z \to \exists y \forall z ((z = x \lor z \in y) \to \forall x (x \in z \to x \in y))$
125	61 120 124 70	pm2.61iii	$⊢ \exists y \forall z ((z = x \lor z \in y) \to \forall x (x \in z \to x \in y))$

Metamath Proof Explorer

Theorem axtcond

Proof