(−2,3,7) pretzel knot
| (−2,3,7) pretzel knot | |
|---|---|
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| Arf invariant | 0 |
| Crosscap no. | 2 |
| Crossing no. | 12 |
| Hyperbolic volume | 2.828122088 |
| Unknotting no. | 5 |
| Conway notation | [7;-2 1;2] |
| Dowker notation | 4, 8, -16, 2, -18, -20, -22, -24, -6, -10, -12, -14 |
| D-T name | 12n242 |
| Last /Next | 12n241 / 12n243 |
| Other | |
| hyperbolic, fibered, pretzel, reversible | |
In geometric topology, a branch of mathematics, the (−2, 3, 7) pretzel knot, sometimes called the Fintushel–Stern knot (after Ron Fintushel and Ronald J. Stern), is an important example of a pretzel knot which exhibits various interesting phenomena under three-dimensional and four-dimensional surgery constructions.
Mathematical properties
The (−2, 3, 7) pretzel knot has 7 exceptional slopes, Dehn surgery slopes which give non-hyperbolic 3-manifolds. Among the enumerated knots, the only other hyperbolic knot with 7 or more is the figure-eight knot, which has 10. All other hyperbolic knots are conjectured to have at most 6 exceptional slopes.
Further reading
- Kirby, R., (1978). "Problems in low dimensional topology", Proceedings of Symposia in Pure Math., volume 32, 272-312. (see problem 1.77, due to Gordon, for exceptional slopes)
External links
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- 0 Arf invariant knots and links
- 2 crosscap number knots and links
- 12 crossing number knots and links
- 5 unknotting number knots and links
- Non-alternating knots and links
- Hyperbolic knots and links
- Fibered knots and links
- Pretzel knots and links (mathematics)
- Reversible knots and links
- Non-tricolorable knots and links
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- 2.82812 hyperbolic volume knots and links
