In knot theory, a branch of mathematics, a pretzel link is a special kind of link. A pretzel link which is also a knot (i.e. a link with one component) is a pretzel knot.
In the standard projection of the pretzel link, there are left-handed crossings in the first tangle, in the second, and, in general, in the nth.
A pretzel link can also be described as a Montesinos link with integer tangles.
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The pretzel link is a knot iff both and all the are odd or exactly one of the is even.[1]
The pretzel link is split if at least two of the are zero; but the converse is false.
The pretzel link is the mirror image of the pretzel link.
The pretzel link is link-equivalent (i.e. homotopy-equivalent in S3) to the pretzel link. Thus, too, the pretzel link is link-equivalent to the pretzel link.[1]
The pretzel link is link-equivalent to the pretzel link. However, if one orients the links in a canonical way, then these two links have opposite orientations.
The (−1, −1, −1) pretzel knot is the trefoil; the (0, 3, −1) pretzel knot is its mirror image.
The (5, −1, −1) pretzel knot is the stevedore knot (61).
If p, q, r are distinct odd integers greater than 1, then the (p, q, r) pretzel knot is a non-invertible knot.
The (2p,\ 2q, 2r) pretzel link is a link formed by three linked unknots.
The (−3, 0, −3) pretzel knot is the connected sum of two trefoil knots.
The (0, q, 0) pretzel link is the split union of an unknot and another knot.
(−2, 3, 2n + 1) pretzel links are especially useful in the study of 3-manifolds. Many results have been stated about the manifolds that result from Dehn surgery on the (−2,3,7) pretzel knot in particular.
Pretzel knots can be used to introduce students to the essentials of knot theory by making edible pretzels.