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Difference between revisions of "Bernstein problem in differential geometry"

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It is a well-known and elementary fact in complex analysis that a bounded and [[Holomorphic function|holomorphic function]] on the whole plane must be a constant (cf. [[Liouville theorems|Liouville theorems]]). S.N. Bernstein proved an analogous result in [[Differential geometry|differential geometry]] (cf. [[#References|[a2]]]), saying that a [[Smooth function|smooth function]] <img align="absmiddle" border="0" src="https://www.encyclopediaofmath.org/legacyimages/b/b110/b110360/b1103601.png" /> defined on the whole plane and whose graph is a [[Minimal surface|minimal surface]], must be a constant (see [[Bernstein theorem|Bernstein theorem]]). The classical Bernstein problem asks whether the corresponding result also holds for functions of <img align="absmiddle" border="0" src="https://www.encyclopediaofmath.org/legacyimages/b/b110/b110360/b1103602.png" /> variables, <img align="absmiddle" border="0" src="https://www.encyclopediaofmath.org/legacyimages/b/b110/b110360/b1103603.png" />. More precisely, is it true that entire solutions (cf. also [[Entire function|Entire function]]) of the minimal equation
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{{MSC|53A10}}
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[[Category:Differential geometry]]
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[[Category:Partial differential equations]]
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{{TEX|done}}
  
<table class="eq" style="width:100%;"> <tr><td valign="top" style="width:94%;text-align:center;"><img align="absmiddle" border="0" src="https://www.encyclopediaofmath.org/legacyimages/b/b110/b110360/b1103604.png" /></td> </tr></table>
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It is a well-known and elementary fact in complex analysis that a bounded and [[Holomorphic function|holomorphic function]] on the whole plane must be a constant (cf. [[Liouville theorems|Liouville theorems]]). In fact, more generally an holomorphic function with polynomial growth is necessarily a polynomial. The same property can be then inferred for (real-valued) harmonic functions.
  
where <img align="absmiddle" border="0" src="https://www.encyclopediaofmath.org/legacyimages/b/b110/b110360/b1103605.png" />, <img align="absmiddle" border="0" src="https://www.encyclopediaofmath.org/legacyimages/b/b110/b110360/b1103606.png" />, must necessarily be a linear function? This equation is the condition that the [[Mean curvature|mean curvature]] of the graph of the function in <img align="absmiddle" border="0" src="https://www.encyclopediaofmath.org/legacyimages/b/b110/b110360/b1103607.png" /> vanishes everywhere.
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S.N. Bernstein proved an analogous result in [[Differential geometry|differential geometry]] (cf. {{Cite|Be}}), saying that,
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if the graph of a $C^2$ function $f: \mathbb R^2\to \mathbb R$ is a [[Minimal surface|minimal surface]] (i.e. its mean curvature vanishes everywhere), then $f$ must be an affine function (see [[Bernstein theorem|Bernstein theorem]]). The question whether the corresponding statement holds or not in higher dimensions became famous in the last century as the Bernstein problem and was completely solved at the end of the sixties. More precisely, since the condition that the [[Mean curvature|mean curvature]] of a graph can be explicitely computed in terms of first and second derivatives of $f$, the Bernstein problem can be stated in the following terms.
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'''Problem 1'''
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Is it true that $C^2$ solutions $f: \mathbb R^n \to \mathbb R$ (cf. also [[Entire function|Entire function]]) of the minimal surface equation
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\begin{equation}\label{e:min_surf}
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{\rm div}\, \frac{\nabla f}{\sqrt{1+|\nabla f|^2}
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\end{equation}
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are necessarily affine functions?
  
 
The answer to the above question is affirmative in the range <img align="absmiddle" border="0" src="https://www.encyclopediaofmath.org/legacyimages/b/b110/b110360/b1103608.png" />; the proof of this is the result of the successive efforts of Bernstein [[#References|[a2]]], W.H. Fleming [[#References|[a7]]], [[#References|[a8]]], E. DeGiorgi [[#References|[a9]]], F. Almgren [[#References|[a1]]], and J. Simons [[#References|[a16]]]. On the other hand, a counterexample for <img align="absmiddle" border="0" src="https://www.encyclopediaofmath.org/legacyimages/b/b110/b110360/b1103609.png" />, which in turn renders a counterexample for each <img align="absmiddle" border="0" src="https://www.encyclopediaofmath.org/legacyimages/b/b110/b110360/b11036010.png" /> by a standard construction, was obtained in 1969 by E. Bombieri, DeGiorgi and E. Giusti, cf. [[#References|[a3]]]. The complete solution of the classical Bernstein problem constitutes, indeed, an exciting chapter of global differential geometry, involving geometric measure theory and non-linear analysis (cf. also [[Plateau problem|Plateau problem]]).
 
The answer to the above question is affirmative in the range <img align="absmiddle" border="0" src="https://www.encyclopediaofmath.org/legacyimages/b/b110/b110360/b1103608.png" />; the proof of this is the result of the successive efforts of Bernstein [[#References|[a2]]], W.H. Fleming [[#References|[a7]]], [[#References|[a8]]], E. DeGiorgi [[#References|[a9]]], F. Almgren [[#References|[a1]]], and J. Simons [[#References|[a16]]]. On the other hand, a counterexample for <img align="absmiddle" border="0" src="https://www.encyclopediaofmath.org/legacyimages/b/b110/b110360/b1103609.png" />, which in turn renders a counterexample for each <img align="absmiddle" border="0" src="https://www.encyclopediaofmath.org/legacyimages/b/b110/b110360/b11036010.png" /> by a standard construction, was obtained in 1969 by E. Bombieri, DeGiorgi and E. Giusti, cf. [[#References|[a3]]]. The complete solution of the classical Bernstein problem constitutes, indeed, an exciting chapter of global differential geometry, involving geometric measure theory and non-linear analysis (cf. also [[Plateau problem|Plateau problem]]).

Revision as of 07:44, 3 November 2013

2020 Mathematics Subject Classification: Primary: 53A10 [MSN][ZBL]

It is a well-known and elementary fact in complex analysis that a bounded and holomorphic function on the whole plane must be a constant (cf. Liouville theorems). In fact, more generally an holomorphic function with polynomial growth is necessarily a polynomial. The same property can be then inferred for (real-valued) harmonic functions.

S.N. Bernstein proved an analogous result in differential geometry (cf. [Be]), saying that, if the graph of a $C^2$ function $f: \mathbb R^2\to \mathbb R$ is a minimal surface (i.e. its mean curvature vanishes everywhere), then $f$ must be an affine function (see Bernstein theorem). The question whether the corresponding statement holds or not in higher dimensions became famous in the last century as the Bernstein problem and was completely solved at the end of the sixties. More precisely, since the condition that the mean curvature of a graph can be explicitely computed in terms of first and second derivatives of $f$, the Bernstein problem can be stated in the following terms.

Problem 1 Is it true that $C^2$ solutions $f: \mathbb R^n \to \mathbb R$ (cf. also Entire function) of the minimal surface equation \begin{equation}\label{e:min_surf} {\rm div}\, \frac{\nabla f}{\sqrt{1+|\nabla f|^2} \end{equation} are necessarily affine functions?

The answer to the above question is affirmative in the range ; the proof of this is the result of the successive efforts of Bernstein [a2], W.H. Fleming [a7], [a8], E. DeGiorgi [a9], F. Almgren [a1], and J. Simons [a16]. On the other hand, a counterexample for , which in turn renders a counterexample for each by a standard construction, was obtained in 1969 by E. Bombieri, DeGiorgi and E. Giusti, cf. [a3]. The complete solution of the classical Bernstein problem constitutes, indeed, an exciting chapter of global differential geometry, involving geometric measure theory and non-linear analysis (cf. also Plateau problem).

Among the various generalizations of the above problem, the so-called spherical Bernstein problem is a natural and challenging one in the realm of global differential geometry. Let the -sphere be imbedded as a minimal hypersurface of the Euclidean n-sphere . Is it necessarily an equator?

This problem is due to S.S. Chern (cf. [a5]; he also proposed it at the International Congress of Mathematicians at Nice (1970), cf. [a6]). The problem has, for example, a direct bearing on the possible local structures of isolated singularities of minimal hypersurfaces in a general Riemannian manifold. Indeed, the (regular) tangent cone of at the singularity is a minimal cone in , whose intersection with is a minimal hypersurface.

By the Almgren–Calabi theorem [a1], [a4], an immersion (cf. Immersion of a manifold) of into must, in fact, be an equator. Thus, at least the beginning case of the spherical Bernstein problem was known to have a positive answer. However, no further progress was made until 1983, when Wu-yi Hsiang, in the framework of equivariant differential geometry, constructed infinitely many mutually non-congruent minimal imbeddings of into , for each (cf. [a11], [a12]). The basic ideas of this approach, which was initiated by Hsiang and H.B. Lawson [a10], is to choose an orthogonal representation with codimension-two principal orbits, and to search for solutions of the geometric problem which are invariant under the induced orthogonal transformation group . Thus, the original partial differential equation associated with the minimal hypersurface condition is reduced to an ordinary second-order differential equation on the -dimensional orbit space , which is geometrically a spherical lune. Here, the "closed" (in a certain sense) solution curves represent minimal hypersurfaces, and they will have the correct topology of thanks to the trivial summand added to .

During the 1980s, Hsiang and his collaborators obtained further results related to the spherical Bernstein problem, by investigating equivariant systems of the above type, as well as additional isoparametric foliations on . For instance, many new examples of imbedded as well as immersed minimal hyperspheres in have been constructed, and moreover, the stability of the singularity at the origin of the corresponding minimal cone in has been investigated, see, e.g., [a13]. P. Tomter [a15] has shown the existence of a minimal and imbedded hypersphere in which is not an equator, for each even . On the other hand, although the methods give infinitely many non-congruent minimal immersions of for each , the problem of finding a non-equatorial imbedded sphere in for odd remains open.

Finally, as a generalization of the spherical Bernstein problem, it is also natural to replace the ambient space by a simply-connected, compact symmetric space. See [a14] for some recent results in this direction.

References

[a1] F.J. Almgren, Jr., "Some interior regularity theorems for minimal surfaces and an extension of the Bernstein's theorem" Ann. of Math. , 85 (1966) pp. 277–292 MR200816
[a2] S.N. Bernstein, "Sur une théorème de géometrie et ses applications aux dérivées partielles du type elliptique" Comm. Inst. Sci. Math. Mech. Univ. Kharkov , 15 (1915–17) pp. 38–45
[a3] E. Bombieri, E. DeGiorgi, E. Giusti, "Minimal cones and the Bernstein problem" Invent. Math. , 7 (1969) pp. 243–268 MR0250205 Zbl 0183.25901
[a4] E. Calabi, "Minimal immersions of surfaces in euclidean spaces" J. Diff. Geom. , 1 (1967) pp. 111–125
[a5] S.S. Chern, "Brief survey of minimal submanifolds" Tagungsbericht Oberwolfach (1969) MR0358634 MR0358635 Zbl 0218.53070
[a6] S.S. Chern, "Differential geometry, its past and its future" , Actes Congres Intern. Mathem. , 1 (1970) pp. 41–53 MR0428217 Zbl 0232.53001
[a7] W.H. Fleming, "On the oriented Plateau problem" Rend. Circ. Mat. Palermo , II (1962) pp. 1–22 MR0157263 Zbl 0107.31304
[a8] W.H. Fleming, "Flat chains over a finite coefficient group" Trans. Amer. Math. Soc. , 121 (1966) pp. 160–186 MR0185084 Zbl 0136.03602
[a9] E. DeGiorgi, "Una estensione del teoreme di Bernstein" Ann. Sc. Norm. Sup. Pisa , 19 (1965) pp. 79–85
[a10] W.Y. Hsiang, H.B. Lawson, Jr., "Minimal submanifolds of low cohomogeneity" J. Diff. Geom. , 5 (1971) pp. 1–38 MR0298593 Zbl 0219.53045
[a11] W.Y. Hsiang, "Minimal cones and the spherical Bernstein problem I" Ann. of Math. , 118 (1983) pp. 61–73 MR0707161 MR0724010 Zbl 0522.53051
[a12] W.Y. Hsiang, "Minimal cones and the spherical Bernstein problem II" Invent. Math. , 74 (1983) pp. 351–369 MR0707161 MR0724010 Zbl 0532.53045
[a13] W.Y. Hsiang, I. Sterling, "Minimal cones and the spherical Bernstein problem III" Invent. Math. , 85 (1986) pp. 223–247 MR0846927 Zbl 0615.53054
[a14] W.Y. Hsiang, W.T. Hsiang, P. Tomter, "On the existence of minimal hyperspheres in compact symmetric spaces" Ann. Sci. Ecole Norm. Sup. , 21 (1988) pp. 287–305 MR0956769 Zbl 0652.53040
[a15] P. Tomter, "The spherical Bernstein problem in even dimensions and related problems" Acta Math. , 158 (1987) pp. 189–212 MR0892590 Zbl 0631.53047
[a16] Simons, J., "Minimal varieties in Riemannian manifolds" Ann. of Math. , 88 (1968) pp. 62–105 MR233295 Zbl 0181.49702
How to Cite This Entry:
Bernstein problem in differential geometry. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Bernstein_problem_in_differential_geometry&oldid=24374
This article was adapted from an original article by E. Straume (originator), which appeared in Encyclopedia of Mathematics - ISBN 1402006098. See original article