infpnlem2

Description: Lemma for infpn . For any positive integer N , there exists a prime number j greater than N . (Contributed by NM, 5-May-2005)

		Ref	Expression
	Hypothesis	infpnlem.1	$⊢ K = N! + 1$
	Assertion	infpnlem2	$⊢ N \in ℕ \to \exists j \in ℕ (N < j \land \forall k \in ℕ (\frac{j}{k} \in ℕ \to (k = 1 \lor k = j)))$

Proof

Step	Hyp	Ref	Expression
1		infpnlem.1	$⊢ K = N! + 1$
2		nnnn0	$⊢ N \in ℕ \to N \in ℕ_{0}$
3	2	faccld	$⊢ N \in ℕ \to N! \in ℕ$
4	3	peano2nnd	$⊢ N \in ℕ \to N! + 1 \in ℕ$
5	1 4	eqeltrid	$⊢ N \in ℕ \to K \in ℕ$
6	3	nnge1d	$⊢ N \in ℕ \to 1 \leq N!$
7		1nn	$⊢ 1 \in ℕ$
8		nnleltp1	$⊢ (1 \in ℕ \land N! \in ℕ) \to (1 \leq N! \leftrightarrow 1 < N! + 1)$
9	7 3 8	sylancr	$⊢ N \in ℕ \to (1 \leq N! \leftrightarrow 1 < N! + 1)$
10	6 9	mpbid	$⊢ N \in ℕ \to 1 < N! + 1$
11	10 1	breqtrrdi	$⊢ N \in ℕ \to 1 < K$
12		nncn	$⊢ K \in ℕ \to K \in ℂ$
13		nnne0	$⊢ K \in ℕ \to K \neq 0$
14	12 13	jca	$⊢ K \in ℕ \to (K \in ℂ \land K \neq 0)$
15		divid	$⊢ (K \in ℂ \land K \neq 0) \to \frac{K}{K} = 1$
16	5 14 15	3syl	$⊢ N \in ℕ \to \frac{K}{K} = 1$
17	16 7	eqeltrdi	$⊢ N \in ℕ \to \frac{K}{K} \in ℕ$
18		breq2	$⊢ j = K \to (1 < j \leftrightarrow 1 < K)$
19		oveq2	$⊢ j = K \to \frac{K}{j} = \frac{K}{K}$
20	19	eleq1d	$⊢ j = K \to (\frac{K}{j} \in ℕ \leftrightarrow \frac{K}{K} \in ℕ)$
21	18 20	anbi12d	$⊢ j = K \to ((1 < j \land \frac{K}{j} \in ℕ) \leftrightarrow (1 < K \land \frac{K}{K} \in ℕ))$
22	21	rspcev	$⊢ (K \in ℕ \land (1 < K \land \frac{K}{K} \in ℕ)) \to \exists j \in ℕ (1 < j \land \frac{K}{j} \in ℕ)$
23	5 11 17 22	syl12anc	$⊢ N \in ℕ \to \exists j \in ℕ (1 < j \land \frac{K}{j} \in ℕ)$
24		breq2	$⊢ j = k \to (1 < j \leftrightarrow 1 < k)$
25		oveq2	$⊢ j = k \to \frac{K}{j} = \frac{K}{k}$
26	25	eleq1d	$⊢ j = k \to (\frac{K}{j} \in ℕ \leftrightarrow \frac{K}{k} \in ℕ)$
27	24 26	anbi12d	$⊢ j = k \to ((1 < j \land \frac{K}{j} \in ℕ) \leftrightarrow (1 < k \land \frac{K}{k} \in ℕ))$
28	27	nnwos	$⊢ \exists j \in ℕ (1 < j \land \frac{K}{j} \in ℕ) \to \exists j \in ℕ ((1 < j \land \frac{K}{j} \in ℕ) \land \forall k \in ℕ ((1 < k \land \frac{K}{k} \in ℕ) \to j \leq k))$
29	23 28	syl	$⊢ N \in ℕ \to \exists j \in ℕ ((1 < j \land \frac{K}{j} \in ℕ) \land \forall k \in ℕ ((1 < k \land \frac{K}{k} \in ℕ) \to j \leq k))$
30	1	infpnlem1	$⊢ (N \in ℕ \land j \in ℕ) \to (((1 < j \land \frac{K}{j} \in ℕ) \land \forall k \in ℕ ((1 < k \land \frac{K}{k} \in ℕ) \to j \leq k)) \to (N < j \land \forall k \in ℕ (\frac{j}{k} \in ℕ \to (k = 1 \lor k = j))))$
31	30	reximdva	$⊢ N \in ℕ \to (\exists j \in ℕ ((1 < j \land \frac{K}{j} \in ℕ) \land \forall k \in ℕ ((1 < k \land \frac{K}{k} \in ℕ) \to j \leq k)) \to \exists j \in ℕ (N < j \land \forall k \in ℕ (\frac{j}{k} \in ℕ \to (k = 1 \lor k = j))))$
32	29 31	mpd	$⊢ N \in ℕ \to \exists j \in ℕ (N < j \land \forall k \in ℕ (\frac{j}{k} \in ℕ \to (k = 1 \lor k = j)))$

Metamath Proof Explorer

Theorem infpnlem2

Proof