Bending the helicoid

Meeks, William H.; Weber, Matthias

doi:10.1007/s00208-007-0120-4

Cited by 26 publications

(31 citation statements)

References 11 publications

(12 reference statements)

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“…Discovered by Meeks and Weber [140] and independently by Mira [149], these are complete, immersed minimal annuli H n ⊂ R 3 with two non-embedded ends and finite total curvature; each of the surfaces H n contains the unit circle S 1 in the (x 1 , x 2 )-plane, and a neighborhood of S 1 in H n contains an embedded annulus H n which approximates, for n large, a highly spinning helicoid whose usual straight axis has been periodically bent into the unit circle S 1 (thus the name of bent helicoids); see Figure 2, right. Furthermore, the H n converge as n → ∞ to the foliation of R 3 minus the x 3 -axis by vertical half-planes with boundary the x 3 -axis, and with S 1 as the 1 that spins an arbitrary number n of times around the circle.…”

Section: The Bent Helicoidsmentioning

confidence: 96%

“…This construction also makes sense when n is half an integer; in the case n = 1 2 , H 1/2 is the double cover of the Meeks minimal Möbius strip described in the previous example. The bent helicoids H n play an important role in proving the converse of Meeks' C 1,1 -Regularity Theorem (Theorem 9.6 below) for the singular set of convergence in a Colding-Minicozzi limit minimal lamination (for this converse, see Meeks and Weber [140]). …”

Section: The Bent Helicoidsmentioning

confidence: 99%

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The classical theory of minimal surfaces

Meeks¹,

Pérez²

2011

Bull. Amer. Math. Soc.

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Abstract. We present here a survey of recent spectacular successes in classical minimal surface theory. We highlight this article with the theorem that the plane, the helicoid, the catenoid and the one-parameter family {R t } t∈(0,1) of Riemann minimal examples are the only complete, properly embedded, minimal planar domains in R 3 ; the proof of this result depends primarily on work of Colding and Minicozzi, Collin, López and Ros, Meeks, Pérez and Ros, and Meeks and Rosenberg. Rather than culminating and ending the theory with this classification result, significant advances continue to be made as we enter a new golden age for classical minimal surface theory. Through our telling of the story of the classification of minimal planar domains, we hope to pass on to the general mathematical public a glimpse of the intrinsic beauty of classical minimal surface theory and our own perspective of what is happening at this historical moment in a very classical subject.

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Section: The Bent Helicoidsmentioning

confidence: 96%

Section: The Bent Helicoidsmentioning

confidence: 99%

The classical theory of minimal surfaces

Meeks¹,

Pérez²

2011

Bull. Amer. Math. Soc.

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“…Bent helicoids along a generating curve have been studied quite a lot recently. Although we do not aim here to summarize any recent developments, in support to our claim we would like to remind just one direction of study, since bent helicoids along a circle play a central role in [17] as well as in [1]. This idea will motivate our Example 2.…”

Section: Introductionmentioning

confidence: 85%

On Chasles' Property of the Helicoid in Tri-Twisted Real Ambient Space

Odom

Suceavă

2015

Analele Universitatii "Ovidius" Constanta - Seria Matematica

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An elementary property of the helicoid is that at every point of the surface the following condition holds: cot θ = C · d, where d is the distance between an arbitrary point to the helicoid axis, and θ is the angle between the normal and the helicoid's axis. This rigidity property was discovered by M. Chasles in the first half of the XIXth century. Starting from this property, we give a characterization of the so-called tri-twisted metrics on the real three dimensional space with the property that a given helicoid satisfies the classical invariance condition. Similar studies can be pursued in other geometric contexts. Our most general result presents a property of surfaces of rotation observing an invariance property suggested by the analogy with Chasles's property.

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“…(1) Comparing with the bending helicoids in Euclidean space [11], and for small values of v, our examples give embedded strips of maximal surfaces only α is not a full circle, that is, only when α is a piece of length less than 2π because V (t) is not a periodic function. A way to get a periodic vector field V (t) is replacing the function ϕ(t) in (2) by a periodic function, as for example, ϕ(t) = cos(t).…”

Section: 1mentioning

confidence: 94%

New Examples of Maximal Surfaces in Lorentz-Minkowski Space

López¹,

Kaya

2017

Kyushu J. Math.

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Abstract. We use the Björling formula in Lorentz-Minkowski space to construct explicit parametrizations of maximal surfaces containing a circle and a helix. For Frenet curves, the orthogonal vector field along the core curve is a linear combination of the principal normal and binormal vectors where the coefficients are hyperbolic trigonometric functions. In the particular case that these coefficients are constant, we obtain all rotational maximal surfaces. We investigate the Weierstrass representation of these surfaces.

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Bending the helicoid

Cited by 26 publications

References 11 publications

The classical theory of minimal surfaces

The classical theory of minimal surfaces

On Chasles' Property of the Helicoid in Tri-Twisted Real Ambient Space

New Examples of Maximal Surfaces in Lorentz-Minkowski Space

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