Homotopically equivalent simple loops on 2-bridge spheres in 2-bridge link complements (I)

“…This paper, as a continuation of [2], uses the same notation and terminology as in [2] without specifically mentioning. We begin with the following question, providing whose answer is the purpose of this series of papers.…”

“…In the first paper [2], we treated the case when r = 1/p for some p ∈ Z, and obtained a complete answer (see [2,Main Theorem 2.7]). In the present paper, we solve the above question for the 2-bridge links K(n/(2n + 1)) and K((n + 1)/(3n + 2)), where n ≥ 2 is an arbitrary integer.…”

“…Proof. By [2,Convention 4.3], each of the words φ(e 2i−1 ), φ(e 2i ), φ(e ′ 2i ) and φ(e ′ 2i−1 ) is a piece of the cyclic word (u ±1 r ). So, the assertion follows from (the only if part) of [2, Corollary 3.25 (1)].…”

“…Proof. By [2,Convention 4.3], each of the words φ(∂D + i ) and φ(∂D − i ) is not a piece. So, by (the if part of) [2, Corollary 3.25(1)], each S(φ(∂D ± i )) contains S 1 or (ℓ, S 2 , ℓ ′ ) (ℓ, ℓ ′ ∈ Z + ) as a subsequence.…”

“…Let K be a 2-bridge link in S 3 and let S be a 4-punctured sphere in S 3 − K obtained from a 2-bridge sphere of K. In [1], we gave a complete characterization of those essential simple loops in S which are null-homotopic in S 3 − K. The purpose of this series of papers starting from [2] and ending with [3], including the present paper as the second one, is to give a necessary and sufficient condition for two essential simple loops on S to be homotopic in S 3 − K. In the first paper [2] of the series, we treated the case when the 2-bridge link is a (2, p)-torus link. In this paper, we treat the case of 2-bridge links of slope n/(2n + 1) and (n + 1)/(3n + 2), where n ≥ 2 is an arbitrary integer.…”

Homotopically equivalent simple loops on 2-bridge spheres in 2-bridge link complements (II)

“…This paper, as a continuation of [2], uses the same notation and terminology as in [2] without specifically mentioning. We begin with the following question, providing whose answer is the purpose of this series of papers.…”

“…In the first paper [2], we treated the case when r = 1/p for some p ∈ Z, and obtained a complete answer (see [2,Main Theorem 2.7]). In the present paper, we solve the above question for the 2-bridge links K(n/(2n + 1)) and K((n + 1)/(3n + 2)), where n ≥ 2 is an arbitrary integer.…”

“…Proof. By [2,Convention 4.3], each of the words φ(e 2i−1 ), φ(e 2i ), φ(e ′ 2i ) and φ(e ′ 2i−1 ) is a piece of the cyclic word (u ±1 r ). So, the assertion follows from (the only if part) of [2, Corollary 3.25 (1)].…”

“…Proof. By [2,Convention 4.3], each of the words φ(∂D + i ) and φ(∂D − i ) is not a piece. So, by (the if part of) [2, Corollary 3.25(1)], each S(φ(∂D ± i )) contains S 1 or (ℓ, S 2 , ℓ ′ ) (ℓ, ℓ ′ ∈ Z + ) as a subsequence.…”

“…Let K be a 2-bridge link in S 3 and let S be a 4-punctured sphere in S 3 − K obtained from a 2-bridge sphere of K. In [1], we gave a complete characterization of those essential simple loops in S which are null-homotopic in S 3 − K. The purpose of this series of papers starting from [2] and ending with [3], including the present paper as the second one, is to give a necessary and sufficient condition for two essential simple loops on S to be homotopic in S 3 − K. In the first paper [2] of the series, we treated the case when the 2-bridge link is a (2, p)-torus link. In this paper, we treat the case of 2-bridge links of slope n/(2n + 1) and (n + 1)/(3n + 2), where n ≥ 2 is an arbitrary integer.…”

Homotopically equivalent simple loops on 2-bridge spheres in 2-bridge link complements (II)

Homotopically equivalent simple loops on 2-bridge spheres in 2-bridge link complements (III)

Epimorphisms between 2-bridge link groups: homotopically trivial simple loops on 2-bridge spheres