Variational formulas for submanifolds of fixed degree
Giovanna Citti, Gianmarco Giovannardi, Manuel Ritor\'e

TL;DR
This paper develops variational formulas for submanifolds of fixed degree in graded manifolds, deriving conditions for admissible variations and computing the associated Euler-Lagrange equations, including a potentially third-order mean curvature operator.
Contribution
It introduces a framework for analyzing area functionals on degree-fixed submanifolds, establishing PDE conditions for variations and deformability, and deriving the Euler-Lagrange equations in this setting.
Findings
Derived PDE system for admissible variations.
Provided sufficient conditions for submanifold deformability.
Computed Euler-Lagrange equations and identified third-order mean curvature operator.
Abstract
We consider in this paper an area functional defined on submanifolds of fixed degree immersed into a graded manifold equipped with a Riemannian metric. Since the expression of this area depends on the degree, not all variations are admissible. It turns out that the associated variational vector fields must satisfy a system of partial differential equations of first order on the submanifold. Moreover, given a vector field solution of this system, we provide a sufficient condition that guarantees the possibility of deforming the original submanifold by variations preserving its degree. As in the case of singular curves in sub-Riemannian geometry, there are examples of isolated surfaces that cannot be deformed in any direction. When the deformability condition holds we compute the Euler-Lagrange equations. The resulting mean curvature operator can be of third order.
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Variational formulas for submanifolds of fixed degree
Giovanna Citti
Dipartimento di Matematica, Piazza di Porta S. Donato 5, 401 26 Bologna, Italy
,
Gianmarco Giovannardi
Departamento de Geometría y Topología & Research Unit MNat
Universidad de Granada
Granada
Spain
and
Manuel Ritoré
Departamento de Geometría y Topología & Research Unit MNat
Universidad de Granada
Granada
Spain
Abstract.
We consider in this paper an area functional defined on submanifolds of fixed degree immersed into a graded manifold equipped with a Riemannian metric. Since the expression of this area depends on the degree, not all variations are admissible. It turns out that the associated variational vector fields must satisfy a system of partial differential equations of first order on the submanifold. Moreover, given a vector field solution of this system, we provide a sufficient condition that guarantees the possibility of deforming the original submanifold by variations preserving its degree. As in the case of singular curves in sub-Riemannian geometry, there are examples of isolated surfaces that cannot be deformed in any direction. When the deformability condition holds we compute the Euler-Lagrange equations. The resulting mean curvature operator can be of third order.
Key words and phrases:
sub-Riemannian manifolds; graded manifolds; degree of a submanifold; area of given degree; admissible variations; isolated submanifolds
2000 Mathematics Subject Classification:
49Q05, 53C42, 53C17
The authors have been supported by Horizon 2020 Project ref. 777822: GHAIA, MEC-Feder grant MTM2017-84851-C2-1-P and PRIN 2015 “Variational and perturbative aspects of nonlinear differential problems” (GC and GG)
Contents
- 1 Introduction
- 2 Preliminaries
- 3 Area for submanifolds of given degree
- 4 Examples
- 5 Admissible variations for submanifolds
- 6 The structure of the admissibility system of first order PDEs
- 7 Integrability of admissible vector fields
- 8 First variation formula for submanifolds
1. Introduction
The aim of this paper is to study the critical points of an area functional for submanifolds of given degree immersed in an equiregular graded manifold. This can be defined as the structure , where is a smooth manifold and is a flag of sub-bundles of the tangent bundle satisfying when and , and when and . The considered area depends on the degree of the submanifold. The concept of pointwise degree for a submanifold immersed in a graded manifold was first introduced by Gromov in [28] as the homogeneous dimension of the tangent flag given by
[TABLE]
The degree of a submanifold is the maximum of the pointwise degree among all points in . An alternative way of defining the degree is the following: on an open neighborhood of a point we can always consider a local basis adapted to the filtration , so that each has a well defined degree. Following [36] the degree of a simple -vector is the sum of the degree of the vector fields of the adapted basis appearing in the wedge product. Since we can write a -vector tangent to with respect to the simple -vectors of the adapted basis, the pointwise degree is given by the maximum of the degree of these simple -vectors.
We consider a Riemannian metric on . For any , we get an orthogonal decomposition . Then we apply to a dilation induced by the grading, which means that, for any , we take the Riemannian metric making the subspaces orthogonal and such that
[TABLE]
Whenever is a bracket generating distribution the structure converges in Gromov-Hausdorff sense to the sub-Riemannian structure as . Therefore an immersed submanifold of degree has Riemannian area measure with respect to the metric . We define area measure of degree by
[TABLE]
when this limit exists and it is finite. In (3.7) we stress that the area measure of degree is given by integral of the norm the -orthogonal projection onto the subspace of -forms of degree equal to of the orthonormal -vector tangent to . This area formula was provided in [36, 35] for submanifolds immersed in Carnot groups and in [19] for intrinsic regular submanifolds in the Heisenberg groups.
Given a submanifold of degree immersed into a graded manifold , we wish to compute the Euler-Lagrange equations for the area functional . The problem has been intensively studied for hypersurfaces, and results appeared in [22, 15, 8, 9, 16, 2, 30, 31, 33, 48, 46, 37, 12]. For submanifolds of codimension greater than one in a sub-Riemannian structure only in the case of curves has been studied. In particular it is well know that there exists minimizers of the length functional which are not solutions of the geodesic equation: these curves, discovered by Montgomery in [38, 39] are called abnormal geodesics. In this paper we recognize that a similar phenomenon can arise while studying the first variational of area for surfaces immersed in a graded structure: there are isolated surfaces which does not admit degree preserving variations. Consequently we focus on smooth submanifolds of fixed degree, and admissible variations, which preserve it. The associated admissible vector fields, V=\frac{\partial\Gamma_{t}}{\partial t}\big{|}_{t=0} satisfies the system of partial differential equations of first order (5.3) on . So we are led to the central question of characterizing the admissible vector fields which are associated to an admissible variation.
The analogous integrability problem for geodesics in sub-Riemannian manifolds and, more generally, for functionals whose domain of definition consists of integral curves of an exterior differential system, was posed by E. Cartan [7] and studied by P. Griffiths [26], R. Bryant [3] and L. Hsu [32]. These one-dimensional problems have been treated by considering a holonomy map [32] whose surjectivity defines a regularity condition implying that any vector field satisfying the system (5.3) is integrable. In higher dimensions, there does not seem to be an acceptable generalization of such an holonomy map. However, an analysis of Hsu’s regularity condition led the authors to introduce a weaker condition named strong regularity in [11]. This condition can be generalized to higher dimensions and provides a sufficient condition to ensure the local integrability of any admissible vector field on , see Theorem 7.2. Indeed, in this setting the admissibility system (5.3) in coordinates is given by
[TABLE]
where are matrices, are the vertical components of the admissible vector field, are the horizontal control components and . Since the strong regularity tells us that the matrix has full rank we can locally write explicitly a part of the controls in terms of the vertical components and the other part of the controls, then applying the Implicit Function Theorem we produce admissible variations.
In Remark 7.6 we recognize that our definition of strongly regular immersion generalizes the notion introduced by [28] of regular horizontal immersions, that are submanifolds immersed in the horizontal distribution such that the degree coincides with the topological dimension . In [27], see also [43], the author shows a deformability theorem for regular horizontal immersions by means of Nash’s Implicit Function Theorem [41]. Our result is in the same spirit but for immersions of general degree.
For strongly regular submanifolds it is possible to compute the Euler-Lagrange equations to obtain a sufficient condition for stationary points of the area of degree . This naturally leads to a notion of mean curvature, which is not in general a second order differential operator, but can be of order three. This behavior doesn’t show up in the one-dimensional case where the geodesic equations for regular curves have order less than or equal to two, see [11, Theorem 7.2] or [32, Theorem 10].
These tools can be applied to mathematical model of perception in the visual cortex: G. Citti and A. Sarti in [12] showed that 2 dimensional minimal surfaces in the three-dimensional sub-Riemannian manifold play an important role in the completion process of images, taking orientation into account. Adding curvature to the model, a four dimensional Engel structure arises, see § 1.5.1.4 in [45], [17] and § 4.3 here. The previous surfaces, lifted in this structure are codimension 2, degree four strongly regular surfaces in the sense of our definition. On the other hand we are able to show that there are isolated surfaces which do not admit degree preserving variations. Indeed, in Example 7.8 we exhibit an isolated plane, immersed in the Engel group, whose only admissible normal vector field is the trivial one. Moreover, in analogy with the one-dimensional result by [4], Proposition 7.9 shows that this isolated plane is rigid in the topology, thus this plane is a local minimum for the area functional. Therefore we recognized that a similar phenomenon to the one of existence of abnormal curves can arise in higher dimension. Finally we conjecture that a bounded open set contained in this isolated plane is a global minimum among all possible immersed surfaces sharing the same boundary .
We have organized this paper into several sections. In the next one notation and basic concepts, such as graded manifolds, Carnot manifolds and degree of submanifolds, are introduced. In Section 3 we define the area of degree for submanifolds of degree immersed in a graded manifold endowed with a Riemannian metric. This is done as a limit of Riemannian areas. In addition, an integral formula for this area in terms of a density is given in formula (3.6). Section 4 is devoted to provide examples of submanifolds of certain degrees and the associated area functionals. In Sections 5 and 6 we introduce the notions of admissible variations, admissible vector fields and integrable vector fields and we study the system of first order partial differential equations defining the admissibility of a vector field. In particular, we show the independence of the admissibility condition for vector fields of the Riemannian metric in § 6.2. In Section 7 we give the notion of a strongly regular submanifold of degree , see Definition 7.1. Then we prove in Theorem 7.2 that the strong regularity condition implies that any admissible vector vector is integrable. In addition, we exhibit in Example 7.8 an isolated plane whose only admissible normal vector field is the trivial one. Finally in Section 8 we compute the Euler-Lagrange equations of a strongly regular submanifold and give some examples.
2. Preliminaries
Let be an -dimensional smooth manifold. Given two smooth vector fields on , their commutator or Lie bracket is defined by . An increasing filtration of the tangent bundle is a flag of sub-bundles
[TABLE]
such that
- (i)
2. (ii)
for ,
where . Moreover, we say that an increasing filtration is locally finite when
- (iii)
for each there exists an integer , the step at , satisfying . Then we have the following flag of subspaces
[TABLE]
A graded manifold is a smooth manifold endowed with a locally finite increasing filtration, namely a flag of sub-bundles (2.1) satisfying (i),(ii) and (iii). For the sake of brevity a locally finite increasing filtration will be simply called a filtration. Setting , the integer list is called the growth vector of the filtration (2.1) at . When the growth vector is constant in a neighborhood of a point we say that is a regular point for the filtration. We say that a filtration on a manifold is equiregular if the growth vector is constant in . From now on we suppose that is an equiregular graded manifold.
Given a vector in we say that the degree of is equal to if and . In this case we write . The degree of a vector field is defined pointwise and can take different values at different points.
Let be an equiregular graded manifold. Take and consider an open neighborhood of where a local frame generating is defined. Clearly the degree of , for , is equal to one since the vector fields belong to . Moreover the vector fields also lie in , we add some vector fields so that generate . Reducing if necessary we have that generate in . Iterating this procedure we obtain a basis of in a neighborhood of
[TABLE]
such that the vector fields have degree equal to , where . The basis obtained in (2.3) is called an adapted basis to the filtration .
Given an adapted basis , the degree of the simple -vector field is defined by
[TABLE]
Any -vector can be expressed as a sum
[TABLE]
where , , is an ordered multi-index, and . The degree of at with respect to the adapted basis is defined by
[TABLE]
It can be easily checked that the degree of is independent of the choice of the adapted basis and it is denoted by .
If is an -vector expressed as a linear combination of simple -vectors , its projection onto the subset of -vectors of degree is given by
[TABLE]
and its projection over the subset of -vectors of degree larger than by
[TABLE]
In an equiregular graded manifold with a local adapted basis , defined as in (2.3), the maximal degree that can be achieved by an -vector, , is the integer defined by
[TABLE]
2.1. Degree of a submanifold
Let be a submanifold of class immersed in an equiregular graded manifold such that . Then, following [34, 36], we define the degree of at a point by
[TABLE]
where is a basis of . Obviously, the degree is independent of the choice of the basis of . Indeed, if we consider another basis of , we get
[TABLE]
where denotes the change of basis matrix. Since , we conclude that is well-defined. The degree of a submanifold is the integer
[TABLE]
We define the singular set of a submanifold by
[TABLE]
Singular points can have different degrees between and .
In [28, 0.6.B] Gromov considers the flag
[TABLE]
where and . Then he defines the degree at by
[TABLE]
setting . It is easy to check that our definition of degree is equivalent to Gromov’s one, see [23, Chapter 2.2]. As we already pointed out, is a graded manifold.
Let us check now that the degree of a vector field and the degree of points in a submanifold are lower semicontinuous functions.
Lemma 2.1**.**
Let be a graded manifold regular at . Let be a vector field defined on a open neighborhood of . Then we have
[TABLE]
Proof.
As is regular, there exists a local adapted basis in an open neighborhood of . We express the smooth vector field in as
[TABLE]
on with respect to an adapted basis , where . Suppose that the degree of at is equal to . Then, there exists an integer such that and for all and . By continuity, there exists an open neighborhood such that for each in . Therefore for each in the degree of is greater than or equal to the degree of ,
[TABLE]
Taking limits we get
[TABLE]
Remark 2.2**.**
In the proof of Lemma 2.1, could be strictly greater than in case there were a coefficient with satisfying .
Proposition 2.3**.**
Let be a immersed submanifold in a graded manifold . Assume that is regular at . Then we have
[TABLE]
Proof.
The proof imitates the one of Lemma 2.1 and it is based on the fact that the degree is defined by an open condition. Let be a tangent -vector in an open neighborhood of , where a local adapted basis is defined. The functions are continuous on . Suppose that the degree at in is equal to . This means that there exists a multi-index such that and . Since the function is continuous there exists a neighborhood such that in . Therefore, and taking limits we have
[TABLE]
Corollary 2.4**.**
Let be a submanifold immersed in an equiregular graded manifold. Then
* is a lower semicontinuous function on .* 2. 2.
The singular set defined in (2.6) is closed in .
Proof.
The first assertion follows from Proposition 2.3 since every point in an equiregular graded manifold is regular. To prove 2, we take . By 1, there exists a open neighborhood of in such that each point in has degree equal to . Therefore we have and hence is an open set. ∎
2.2. Carnot manifolds
Let be an -dimensional smooth manifold. An -dimensional distribution on assigns smoothly to every an -dimensional vector subspace of . We say that a distribution complies Hörmander’s condition if any local frame spanning satisfies
[TABLE]
where is the linear span of the vector fields and their commutators of any order.
A Carnot manifold is a smooth manifold endowed with an -dimensional distribution satisfying Hörmander’s condition. We refer to as the horizontal distribution. We say that a vector field on is horizontal if it is tangent to the horizontal distribution at every point. A path is horizontal if the tangent vector is everywhere tangent to the horizontal distribution. A sub-Riemannian manifold is a Carnot manifold endowed with a positive-definite inner product on . Such an inner product can always be extended to a Riemannian metric on . Alternatively, any Riemannian metric on restricted to provides a structure of sub-Riemannian manifold. Chow’s Theorem assures that in a Carnot manifold the set of points that can be connected to a given point by a horizontal path is the connected component of containing , see [40]. Given a Carnot manifold , we have a flag of subbundles
[TABLE]
defined by
[TABLE]
where
[TABLE]
The smallest integer satisfying is called the step of the distribution at the point . Therefore, we have
[TABLE]
The integer list is called the* growth vector* of at . When the growth vector is constant in a neighborhood of a point we say that is a regular point for the distribution. This flag of sub-bundles (2.9) associated to a Carnot manifold gives rise to the graded structure . Clearly an equiregular Carnot manifold of step is an equiregular graded manifold . In particular a Carnot group turns out to be an equiregular graded manifold.
Given a connected sub-Riemannian manifold , and a horizontal path , we define the length of by
[TABLE]
By means of the equality
[TABLE]
this length defines a distance function (see [5, § 2.1.1,§ 2.1.2]) usually called the Carnot-Carathéodory distance, or CC-distance for short. See [40, Chapter 1.4] for further details.
3. Area for submanifolds of given degree
In this section we shall consider a graded manifold endowed with a Riemannian metric , and an immersed submanifold of dimension .
We recall the following construction from [28, 1.4.D]: given , we recursively define the subspaces , , for . Here means perpendicular with respect to the Riemannian metric . Therefore we have the decomposition of into orthogonal subspaces
[TABLE]
Given , a unique Riemannian metric is defined under the conditions: (i) the subspaces are orthogonal, and (ii)
[TABLE]
When we consider Carnot manifolds, it is well-known that the Riemannian distances of uniformly converge to the Carnot-Carathéodory distance of , [28, p. 144].
Working on a neighborhood of where a local frame generating the distribution is defined, we construct an orthonormal adapted basis for the Riemannian metric by choosing orthonormal bases in the orthogonal subspaces , . Thus, the -vector fields
[TABLE]
where for , are orthonormal with respect to the extension of the metric to the space of -vectors. We recall that the metric is extended to the space of -vectors simply defining
[TABLE]
for and in . Observe that the extension is denoted the same way.
3.1. Area for submanifolds of given degree
Assume now that is an immersed submanifold of dimension in a equiregular graded manifold equipped with the Riemannian metric . We take a Riemannian metric on . For any we pick a -orthonormal basis in . By the area formula we get
[TABLE]
where is a bounded measurable subset of and is the -dimensional area of with respect to the Riemannian metric .
Now we express
[TABLE]
From (3.3) we get , and so . Moreover, as is an orthonormal basis for , we have
[TABLE]
Therefore, we have
[TABLE]
By Lebesgue’s dominated convergence theorem we obtain
[TABLE]
Definition 3.1**.**
If is an immersed submanifold of degree in an equiregular graded manifold endowed with a Riemannian metric , the degree area is defined by
[TABLE]
for any bounded measurable set .
Equation (3.6) provides an integral formula for the area . An immediate consequence of the definition is the following
Remark 3.2**.**
Setting we have by equation (3.6) and the notation introduced in (2.4) that the degree area is given by
[TABLE]
for any bounded measurable set . When the ambient manifold is a Carnot group this area formula was obtained by [36]. Notice that the area is given by the integral of the -form
[TABLE]
where is a basis of .
In a more general setting, an -dimensional submanifold in a Riemannian manifold is an -current (i.e., an element of the dual of the space of -forms), and the area is the mass of this current (for more details see [18]). Similarly, a natural generalization of an -dimensional submanifold of degree immersed in a graded manifold is an -current of degree whose mass should be given by . In [19] the authors studied the theory of -currents in the Heisenberg group. Their mass coincides with our area (3.7) on intrinsic submanifolds. However in (3.8) we consider all possible -forms and not only the intrinsic -forms in the Rumin’s complex [49, 42, 1].
Corollary 3.3**.**
Let be an -dimensional immersed submanifold of degree in a graded manifold endowed with a Riemannian metric . Let be the closed set of singular points of . Then .
Proof.
Take an orthonormal basis of at and express . When is a singular point, and so whenever .
Since is measurable, from (3.6) we obtain
[TABLE]
and so . ∎
Remark 3.4**.**
Another easy consequence of the definition is the following: if is an immersed submanifold of degree in graded manifold with a Riemannian metric, then for any open set when . This follows easily since in the expression
[TABLE]
we would have summands with negative exponent for .
In the following example, we exhibit a Carnot manifold with two different Riemannian metrics that coincide when restricted to the horizontal distribution, but yield different area functionals of a given degree
Example 3.5**.**
We consider the Carnot group , which is the direct product of two Heisenberg groups. Namely, let be the -dimensional Euclidean space with coordinates . We consider the -dimensional distribution generated by
[TABLE]
The vector fields and are the only non trivial commutators that generate, together with , the subspace . Let be a bounded open set of and a smooth function on such that . We consider the immersed surface
[TABLE]
whose tangent vectors are
[TABLE]
Thus, the -vector tangent to is given by
[TABLE]
When is different from zero the degree is equal to , since both and have degree equal to . Points of degree corresponds to the zeroes of . We define a -parameter family of Riemannian metrics on , for , by the conditions (i) is an orthonormal basis of , (ii) , are orthogonal to , and (iii) , and . Therefore, the degree area of with respect to the metric is given by
[TABLE]
As we shall see later, these different functionals will not have the same critical points, that would depend on the election of Riemannian metric.
4. Examples
4.1. Degree of a hypersurface in a Carnot manifold
Let be a hypersurface immersed in an equiregular Carnot manifold , where is a bracket generating -dimensional distribution. Let be the homogeneous dimension of and .
Let us check that . The pointwise degree of is given by
[TABLE]
where with . Recall that . As is a hyperplane of we have that either and , or is a hyperplane of and . On the other hand,
[TABLE]
Writing
[TABLE]
for non-negative integers and adding up on from to we get
[TABLE]
since and . We conclude that there exists such that and for all . This implies
[TABLE]
If for all , then , a contradiction since is a bracket-generating distribution. We conclude that and so
[TABLE]
4.2. -area of a hypersurface in a -dimensional contact manifold
A contact manifold is a smooth manifold of odd dimension endowed with a one form such that is non-degenerate when restricted to . Since it holds
[TABLE]
for , the distribution is non-integrable and satisfies Hörmander rank condition by Frobenius theorem. When we define a horizontal metric on the distribution then is a sub-Riemannian structure. It is easy to prove that there exists an unique vector field on so that
[TABLE]
where is the Lie derivative and is any vector field on . This vector field is called the Reeb vector field. We can always extend the horizontal metric to the Riemannian metric making a unit vector orthogonal to .
Let be a hypersurface immersed in . In this setting the singular set of is given by
[TABLE]
and corresponds to the points in of degree . Observe that the non-integrability of implies that the set is not empty in any hypersurface .
Let be the unit vector field normal to at each point, then on the regular set the -orthogonal projection of onto the distribution is different from zero. Therefore out of the singular set we define the horizontal unit normal by
[TABLE]
and the vector field
[TABLE]
which is tangent to and belongs to . Moreover, has dimension equal to one and equal to , thus the degree of the hypersurface out of the singular set is equal to . Let be an orthonormal basis in . Then is an orthonomal basis of and we have
[TABLE]
Hence we obtain
[TABLE]
In [20] Galli obtained this formula as the perimeter of a set that has boundary and in [50] Shcherbakova as the limit of the volume of a -cylinder around over its height equal to . This formula was obtain for surfaces in a -dimensional pseudo-hermitian manifold in [9] and by S. Pauls in [44]. This is exactly the area formula independently established in recent years in the Heisenberg group , that is the prototype for contact manifolds (see for instance [15, 9, 10, 47, 30]).
Example 4.1** (The roto-translational group).**
Take coordinates in the -dimensional manifold . We consider the contact form
[TABLE]
the horizontal distribution , is spanned by the vector fields
[TABLE]
and the horizontal metric that makes and orthonormal.
Therefore endowed with this one form is a contact manifold. Moreover has a sub-Riemannian structure which is also a Lie group known as the roto-translational group. A mathematical model of simple cells of the visual cortex V1 using the sub-Riemannian geometry of the roto-translational Lie group was proposed by Citti and Sarti (see [13], [14]). Here the Reeb vector field is given by
[TABLE]
Let be an open set of and be a function of class . When we consider a graph given by the zero set level of the function
[TABLE]
the projection of the unit normal onto the horizontal distribution is given by
[TABLE]
Hence the -area functional is given by
[TABLE]
4.3. -area of a ruled surface immersed in an Engel structure
Let be a smooth manifold with coordinates . We set , where
[TABLE]
Therefore is a Carnot manifold, indeed satisfy the Hörmander rank condition since and
[TABLE]
generate all the tangent bundle. Here we follow a computation developed by Le Donne and Magnani in [34] in the Engel group. Let be an open set of endowed with the Lebesgue measure. Since we are particularly interested in applications to the visual cortex (see [23],[45, 1.5.1.4] to understand the reasons) we consider the immersion given by and we set . The tangent vectors to are
[TABLE]
In order to know the dimension of it is necessary to take in account the rank of the matrix
[TABLE]
Obviously , indeed we have
[TABLE]
Moreover, it holds
[TABLE]
Since we are inspired by the foliation property of hypersurface in the Heisenberg group and roto-translational group, in the present work we consider only surface verifying the foliation condition . Thus, we have
[TABLE]
By the foliation condition (4.6) we have that the coefficient of is always equal to zero, then we deduce that . Moreover, the coefficient of never vanishes, therefore and there are not singular points in . When a tangent basis of adapted to 2.7 is given by
[TABLE]
When we fix the Riemannian metric that makes orthonormal we have that the -area of is given by
[TABLE]
When we fix the Euclidean metric that makes we have that the -area of is given by
[TABLE]
5. Admissible variations for submanifolds
Let us consider an -dimensional manifold and an immersion into an equiregular graded manifold endowed with a Riemannian metric . We shall denote the image by and . In this setting we have the following definition
Definition 5.1**.**
A smooth map is said to be an admissible variation of if , defined by , satisfies the following properties
- (i)
, 2. (ii)
is an immersion of the same degree as for small enough , and 3. (iii)
for outside a given compact subset of .
Definition 5.2**.**
Given an admissible variation , the associated variational vector field is defined by
[TABLE]
The vector field is an element of : i.e., a smooth map such that for all . It is equal to [math] outside a compact subset of .
Let us see now that the variational vector field associated to an admissible variation satisfies a differential equation of first order. Let for some , and an adapted frame in a neighborhood of . Take a basis of and let for . As is a submanifold of the same degree as for small , there follows
[TABLE]
for all , with , such that . Taking the derivative with respect to in equality (5.2) and evaluating at we obtain the condition
[TABLE]
for all such that . In the above formula, indicates the scalar product in the space of -vectors induced by the Riemannian metric . The symbol denotes, in the left summand, the Levi-Civita connection associated to and, in the right summand, the covariant derivative of vectors in induced by . Thus, if a variation preserves the degree then the associated variational vector field satisfies the above condition and we are led to the following definition.
Definition 5.3**.**
Given an immersion , a vector field is said to be admissible if it satisfies the system of first order PDEs
[TABLE]
where , and . We denote by the set of admissible vector fields.
It is not difficult to check that the conditions given by (5.3) are independent of the choice of the adapted basis.
Thus we are led naturally to a problem of integrability: given such that the first order condition (5.3) holds, we ask whether an admissible variation whose associated variational vector field is exists.
Definition 5.4**.**
We say that an admissible vector field is integrable if there exists an admissible variation such that the associated variational vector field is .
Proposition 5.5**.**
Let be an immersion into a graded manifold. Then a vector field is admissible if and only if its normal component is admissible.
Proof.
Since the Levi-Civita connection and the covariant derivative are additive we deduce that the admissibility condition (5.3) is additive in . We decompose in its tangent and normal components and observe that is always admissible since the flow of is an admissible variation leaving invariant with variational vector field . Hence, satisfies (5.3) if and only if verifies (5.3). ∎
6. The structure of the admissibility system of first order PDEs
Let us consider an open set where a local adapted basis is defined. We know that the simple -vectors generate the space of -vectors. At a given point , its dimension is given by the formula
[TABLE]
Given two -vectors , it is easy to check that , and that when and [math] otherwise. This implies that the set
[TABLE]
is a vector subspace of . To compute its dimension we let and we check that a basis of is composed of the vectors
[TABLE]
To get an -vector in such a basis we pick any of the vectors in and, for , we pick any of the vectors on , so that
- •
, and
- •
.
So we conclude, taking , that
[TABLE]
When we consider two simple -vectors and , their scalar product is [math] or , the latter case when, after reordering if necessary, we have for . This implies that the orthogonal subspace of in is generated by the -vectors
[TABLE]
Hence we have
[TABLE]
with . Since is equiregular, is constant on . Then we can choose an orthonormal basis in at each point .
6.1. The admissibility system with respect to an adapted local basis
In the same conditions as in the previous subsection, let and an orthonormal basis of . Any vector field can be expressed in the form
[TABLE]
where . We take and, reducing if necessary, a local adapted basis of in . Hence the admissibility system (5.3) is equivalent to
[TABLE]
where
[TABLE]
and
[TABLE]
In the above equation we have extended the vector fields in a neighborhood of in , denoting them in the same way.
Definition 6.1**.**
Let be the dimension of , , where we consider the flag defined in (2.7). Then we set
[TABLE]
and
[TABLE]
Remark 6.2**.**
In the differential system (6.2), derivatives of the function appear only when some coefficient is different from [math]. For fixed , notice that , for all , and in if and only if
[TABLE]
This property is equivalent to
[TABLE]
So we have in for all if and only if .
We write
[TABLE]
so that the local system (6.2) can be written as
[TABLE]
where is defined in (6.3) and, for ,
[TABLE]
where is defined in (6.4). We denote by the matrix whose entries are , by the whose entries are and for we denote by the matrix . Setting
[TABLE]
the admissibility system (6.2) is given by
[TABLE]
6.2. Independence on the metric
Let and be two Riemannian metrices on and be orthonormal adapted basis with respect to and with respect to . Clearly we have
[TABLE]
for some square invertible matrix of order . Since and are adapted basis, is a block matrix
[TABLE]
where for are square matrices of orders . Let be the integer defined in (6.1), then we define , and . Let us express as a linear combination of
[TABLE]
then we set
[TABLE]
and and as in (6.8).
Given with , we have
[TABLE]
Since the adapted change of basis preserves the degree of the -vectors, the square matrix of order acting on the -vector is given by
[TABLE]
where and are square matrices of order and respectively and is a matrix of order . Moreover the matrix is invertible since both and are basis of the vector space of -vectors.
Remark 6.3**.**
One can easily check that the inverse of is given by the block matrix
[TABLE]
Setting we have
[TABLE]
Thus it follows
[TABLE]
Let be the associated matrix
[TABLE]
Setting
[TABLE]
and , a straightforward computation shows
[TABLE]
By Remark 6.3 we obtain
[TABLE]
Preliminary we notice that if we have
[TABLE]
Therefore, setting
[TABLE]
and
[TABLE]
by (6.12) we gain
[TABLE]
Let be the associated matrix
[TABLE]
Setting
[TABLE]
it is immediate to obtain the following equality
[TABLE]
Let be the associated matrix
[TABLE]
A straightforward computation shows
[TABLE]
By Remark 6.3 we obtain
[TABLE]
Finally, we have and .
Proposition 6.4**.**
Let and be two different metrics, then a vector fields is admissible w.r.t. if and only if is admissible w.r.t. .
Proof.
We remind that an admissible vector field
[TABLE]
w.r.t. satisfies
[TABLE]
By (6.11), (6.14) and (6.13) we have
[TABLE]
In the previous equation we used that , and
[TABLE]
for all , that follows by . Then the admissibility system (6.15) w.r.t. is equal to zero if and only if the admissibility system (6.16) w.r.t. . ∎
Remark 6.5**.**
When the metric is fixed and and are orthonormal adapted basis w.r.t , the matrix is a block diagonal matrix given by
[TABLE]
where and are square orthogonal matrices of orders and , respectively. From equations (6.11), (6.14), (6.13) it is immediate to obtain the following equalities
[TABLE]
6.3. The admissibility system with respect to the intrinsic basis of the normal space
Let be the dimension of and an orthonormal basis of simple -vector fields. Let be a point in and . Let be an adapted basis of that we extend to adapted vector fields tangent to on . Let be a basis of that we extend to vector fields normal to on , where we possibly reduced the neighborhood of in . Then any vector field in is given by
[TABLE]
where . By Proposition 5.5 we deduce that is admissible if and only if is admissible. Hence we obtain that the system (5.3) is equivalent to
[TABLE]
where
[TABLE]
and
[TABLE]
Definition 6.6**.**
Let be the integer defined in 6.1. Then we set .
Assume that , and write
[TABLE]
and the local system (6.18) is equivalent to
[TABLE]
where is defined in (6.19) and, for ,
[TABLE]
We denote by the matrix whose entries are , by the whose entries are and for every by the matrix with entries Setting
[TABLE]
the admissibility system (6.2) is given
[TABLE]
Remark 6.7**.**
We can define the matrices , , with respect to the tangent projection in a similar way to the matrices , , . First of all we notice that the entries
[TABLE]
for and are all equal to zero. Therefore the matrices and are equal to zero. On the other hand, is the -matrix whose entries are given by
[TABLE]
for and . Frobenius Theorem implies that the Lie brackets are all tangent to for , and so all the entries of are equal to zero.
7. Integrability of admissible vector fields
In general, given an admissible vector field , the existence of an admissible variation with associated variational vector field is not guaranteed. The next definition is a sufficient condition to ensure the integrability of admissible vector fields.
Definition 7.1**.**
Let be an immersion of degree of an -dimensional manifold into a graded manifold endowed with a Riemannian metric . Let for all and set in (6.1). When we say that is strongly regular at if
[TABLE]
where is the matrix appearing in the admissibility system (6.9).
The rank of is independent of the local adapted basis chosen to compute the admissibility system (6.9) because of equations (6.17). Next we prove that strong regularity is a sufficient condition to ensure local integrability of admissible vector fields.
Theorem 7.2**.**
Let be a smooth immersion of an -dimensional manifold into an equiregular graded manifold endowed with a Riemannian metric . Assume that the immersion of degree is strongly regular at . Then there exists an open neighborhood of such every admissible vector field with compact support on is integrable.
Proof.
Let . First of all we consider an open neighborhood of such that an adapted orthonormal frame is well defined. Since is strongly regular at there exist indexes in such that the submatrix
[TABLE]
is invertible. By a continuity argument there exists an open neighborhood such that for each .
We can rewrite the system (6.9) in the form
[TABLE]
where are the indexes of the columns of that do not appear in and is the matrix given by the columns of . The vectors form an orthonormal basis of near .
On the neighborhood we define the following spaces
, is the set of vector fields compactly supported on taking values in . 2. 2.
. 3. 3.
4. 4.
. 5. 5.
6. 6.
Given , we set
[TABLE]
and consider the map
[TABLE]
defined by
[TABLE]
where is the projection in the space of -forms with compact support in onto , and
[TABLE]
where . Observe that if and only if the submanifold has degree less or equal to . We consider on each space the corresponding or norm, and a product norm.
Then
[TABLE]
where we write in coordinates
[TABLE]
Following the same argument we used in Section 5, taking the derivative at of (5.2), we deduce that the differential is given by
[TABLE]
Oberve that if and only if is an admissible vector field, namely solves (7.1).
Our objective now is to prove that the map is an isomorphism of Banach spaces.
Indeed suppose that . This implies that and are equal zero. By the admissible equation (7.1) we have that also is equal to zero, then is injective. Then fix , where , , we seek such that . We notice that is equivalent to
[TABLE]
where with an abuse of notation we identify and . Since is invertible we have the following system
[TABLE]
Clearly fixes in (7.3), and fixes the first and second term of the right hand side in (7.3). Since the right side terms are given we have determined , i.e. , such that solves (7.3). Therefore is surjective. Thus we have proved that is a bijection.
Let us prove now that is a continuous and open map. Letting , we first notice is a continuous map since identity maps are continuous and, by (7.3), there exists a constant such that
[TABLE]
Moreover, is an open map since we have
[TABLE]
This implies that is an isomorphism pf Banach spaces.
Let now us consider an admissible vector field with compact support on . We consider the map
[TABLE]
defined by
[TABLE]
The map is continuous with respect to the product norms (on each factor we put the natural norm, the Euclidean one on the intervals and and in the spaces of vectors on ). Moreover
[TABLE]
since has degree . Denoting by the differential with respect to the last three variables of we have that
[TABLE]
is a linear isomorphism. We can apply the Implicit Function Theorem to obtain unique maps
[TABLE]
such that . This implies that , , and that
[TABLE]
Differentiating this formula at we obtain
[TABLE]
Since is admissible we deduce
[TABLE]
Since , where , equation (7.1) implies for each . Therefore it follows .
Hence the variation coincides with for and , it has degree and its variational vector fields is given by
[TABLE]
Moreover, . Indeed, if , the unique vector field , such , is equal to [math] at . ∎
Remark 7.3**.**
In Proposition 5.5 we stressed the fact that a vector field is admissible if and only if is admissible. This follows from the additivity in of the admissibility system (5.3) and the admissibility of . Instead of writing with respect to the adapted basis we consider the basis described in Section 6.3.
Let be the matrices defined in (6.22), be the one described in Remark 6.7 and be the matrix with respect to the basis defined in (6.7). When we change only the basis for the vector field by (6.11) we obtain . Since is the null matrix and we conclude that . Furthermore is strongly regular at if and only if , where is the integer defined in 6.6.
7.1. Some examples of regular submanifolds
Example 7.4**.**
Consider a hypersurface immersed in an equiregular Carnot manifold , then we have that always has degree equal to , see 4.1. Therefore the dimension , defined in Section 6, of is equal to zero. Thus any compactly supported vector field is admissible and integrable. When the Carnot manifold is a contact structure , see 4.2, the hypersurface has always degree equal to .
Example 7.5**.**
Let be the Carnot manifold described in Section 4.3 where and the distribution is generated by
[TABLE]
Clearly is an adapted basis for . Moreover the others no-trivial commutators are given by
[TABLE]
Let be an open set. We consider the surface where
[TABLE]
and such that . Therefore the and its tangent vectors are given by
[TABLE]
Let be the metric that makes orthonormal the adapted basis . Since the only no-trivial coefficient , for are given by
[TABLE]
On the other hand for each , since we can not reach the degree if one of the two vector fields in the wedge has degree one. Therefore the only equation in (6.2) is given by
[TABLE]
Since we have for each . Since for each and we have
[TABLE]
Thus, we deduce
[TABLE]
Hence the equation (7.5) is equivalent to
[TABLE]
Since , we have , where is the natural number defined in (6.1). In this setting the matrix is given by
[TABLE]
Then the matrices and are given by
[TABLE]
[TABLE]
Since and the matrix , defined in the proof of Theorem 7.2, is equal to for each we have that is strongly regular at each point in and the open set . Hence by Theorem 7.2 each admissible vector field on is integrable.
On the other hand we notice that . By the Gram-Schmidt process an orthonormal basis with respect to the metric is given by
[TABLE]
where we set
[TABLE]
Since it holds
[TABLE]
then a vector field normal to is admissible if and only if verify
[TABLE]
That is equivalent to
[TABLE]
where and
[TABLE]
In particular, since we have that for all . Along the integral curve on the equation (7.7) reads
[TABLE]
where we set for each function .
Remark 7.6**.**
Let be a Carnot manifold such that where is a one form. Following [28, 43] we say that an immersion is horizontal when the pull-back and, given a point , the subspace is regular if the map
[TABLE]
is onto for each horizontal vector on . Let be an horizontal extension of on and be another horizontal vector field on , then
[TABLE]
Assume that the local frame generate at then the map (7.8) is given by for each . In [24, Section 3] the author notice that there exist special coordinates adjusted to the admissibility system such that the entries of the control matrix are , where are vector fields in the normal bundle. In this notation the surjectivity of this map coincides with the pointwise condition of maximal rank of the matrix . Since by equation (6.17) the rank of is independent of the metric we deduce that this regularity notion introduced by [28, 27] is equivalent to strongly regularity at (Definition 7.1) for the class of horizontal immersions.
7.2. An isolated plane in the Engel group
Definition 7.7**.**
We say that an immersion in an equiregular graded manifold is isolated if the only admissible variation normal to is the trivial one.
Here we provide an example of isolated surface immersed in the Engel group.
Example 7.8**.**
Let and , where
[TABLE]
and and . We denote by the Engel group given by . Let be the immersion given by
[TABLE]
Since the degree , where is a plane. An admissible vector field verifies the system (6.2) that is given by
[TABLE]
for , and . Therefore (7.9) is equivalent to
[TABLE]
Let . First of all we have . Since there follows
[TABLE]
Then let we consider the curve
[TABLE]
along which and are constant. Since and are compactly supported at the end point, we have . Therefore we gain . Therefore the only admissible vector fields are tangent to . Assume that there exists an admissible variation for , then its associated variational vector field is admissible. However we proved that the only admissible vector fields are tangent to , therefore the admissible variation has to be tangent to and the only normal one a trivial variation, hence we conclude that the plane is isolated.
Moreover, we have that and the matrix defined in 7.1 is given by
[TABLE]
Since we deduce that is not strongly regular at any point in .
In analogy with the rigidity result by [4], here we prove that is isolated without using the admissibility system. This also implies that the plane is rigid in the topology.
Proposition 7.9**.**
Let be the Engel group given by , where the distribution is generated by
[TABLE]
Let be a bounded open set. Then the immersion of degree given by
[TABLE]
is isolated.
Proof.
An admissible normal variation of has to have the same degree of and has to share the same boundary , where clearly . For a fix , we can parametrize by
[TABLE]
where . Since we gain
[TABLE]
where
[TABLE]
and
[TABLE]
Denoting by the projection over the -vectors of degree larger than , we have
[TABLE]
Therefore (7.10) is equivalent to
[TABLE]
The second equation implies that (7.11) is equivalent to
[TABLE]
Then we notice that the first and the third equations implies the second one as it follows
[TABLE]
Therefore the immersion has degree three if and only if
[TABLE]
Only when the compatibility conditions ([29, Eq. (1.4), Chapter VI]) for linear system of first order are given we have a solution of this system. However the compatibility condition is given by
[TABLE]
Since we obtain . Therefore also , then . Hence . ∎
8. First variation formula for submanifolds
In this section we shall compute a first variation formula for the area of a submanifold of degree . We shall give some definitions first. Assume that is an immersion of a smooth -dimensional manifold into an -dimensional equiregular graded manifold endowed with a Riemannian metric . Let . Fix and let . Take a -orthonormal basis in and define for . Then the degree area density is defined by
[TABLE]
where is an orthonormal adapted basis of . Then we have
[TABLE]
Assume now that , then we set
[TABLE]
Finally, define the linear function by
[TABLE]
Then we have the following result
Theorem 8.1**.**
Let be an immersion of degree of a smooth -dimensional manifold into an equiregular graded manifold equipped with a Riemannian metric . Assume that there exists an admissible variation with associated variational field with compact support. Then
[TABLE]
Proof.
Fix a point . Clearly, , , are vector fields along the curve . Therefore, the first variation is given by
[TABLE]
The derivative of the last integrand is given by
[TABLE]
Using (8.2) and (8.3) we obtain (8.4). ∎
Definition 8.2**.**
Let be an immersion of degree of a smooth -dimensional manifold into an equiregular graded manifold equipped with a Riemannian metric . We say that is -stationary, or simply stationary, if it is a critical point of the area for any admissible variation.
Proposition 8.3**.**
Let be an immersion of degree of a smooth -dimensional manifold into an equiregular graded manifold equipped with a Riemannian metric . Let be admissible variation whose variational field is compactly supported and tangent to . Then we have
[TABLE]
Proof.
Since for all , the vector field is tangent to and we have
[TABLE]
∎
Lemma 8.4**.**
Let and be a tangential vector field in . Then there holds,
- (i)
, 2. (ii)
.
Proof.
By the definition of divergence we obtain (i) as follows
[TABLE]
To deduce (ii) we apply twice (i) as follows
[TABLE]
Theorem 8.5**.**
Let be an immersion of degree of a smooth -dimensional manifold into an equiregular graded manifold equipped with a Riemannian metric . Assume that there exists an admissible variation with associated variational field with compact support. Then
[TABLE]
where is the vector field
[TABLE]
In this formula, is a local orthonormal basis of and a local orthonormal basis of . The functions are given by
[TABLE]
Proof.
Since our computations are local and immersions are local embeddings, we shall identify locally and to simplify the notation.
We decompose in its tangential and perpendicular parts. Since and the functional defined in (8.3) are additive, we use the first variation formula (8.4) and Proposition 8.3 to obtain
[TABLE]
To compute this integrand we consider a local orthonormal basis in around and a local orthonormal basis of with . We have
[TABLE]
We compute first
[TABLE]
as
[TABLE]
that it is equal to
[TABLE]
The group of summands in the second line of (8.8) is equal to , where
[TABLE]
To treat the group of summands in the first line of (8.8) we use (ii) in Lemma 8.4. recalling (8.7) we have
[TABLE]
so that applying the Divergence Theorem we have that the integral in of the first group of summands in (8.8) is equal to
[TABLE]
where
[TABLE]
We treat finally the summand
[TABLE]
where
[TABLE]
This implies the result since . ∎
In the following result we obtain a slightly different expression for the mean curvature in terms of Lie brackets. This expression is sometimes more suitable for computations.
Corollary 8.6**.**
Let be an immersion of degree of a smooth -dimensional manifold into an equiregular graded manifold equipped with a Riemannian metric , . We consider an extension of a local orthonormal basis of and respectively an extension of a local orthonormal basis of to an open neighborhood of . Then the vector field defined in (8.6) is equal to
[TABLE]
where is defined in (8.7).
Proof.
Keeping the notation used in the proof of Theorem 8.5 we consider
[TABLE]
Writing
[TABLE]
we gain
[TABLE]
Let us consider
[TABLE]
Since the Levi-Civita connection preserves the metric, we have
[TABLE]
Putting the first term of the right hand side of (8.12) in (8.11) we obtain
[TABLE]
On the other hand writing
[TABLE]
we deduce
[TABLE]
Therefore we obtain
[TABLE]
Since the Levi-Civita connection is torsion-free we have
[TABLE]
Since we conclude that is equal to (8.9). ∎
8.1. First variation formula for strongly regular submanifolds
Definition 8.7**.**
Let be a strongly regular immersion (see § 7) at , be an orthonormal adapted basis of the normal bundle and be the integer defined in 6.6. Let be a local adapted frame of the normal bundle so that . By Remark 7.3 the immersion is strongly regular at if and only if . Then there exists a partition of into sub-indices and such that the matrix
[TABLE]
is invertible. The mean curvature vector of degree defined in Theorem 8.5 is given by
[TABLE]
Then we decompose into the following three components
[TABLE]
with respect to .
Theorem 8.8**.**
Let be a strongly regular immersion at in an equiregular graded manifold. Then is a critical point of if and only if the immersion verifies
[TABLE]
and
[TABLE]
where is the adjoint operator of for and , and are defined in (8.14), , in 6.3, in (8.13) and is the matrix given by the columns of .
Proof.
Since is a normal strongly regular immersion then by Theorem 7.2 each normal admissible vector field
[TABLE]
is integrable. Keeping in mind the sub-indices in Definition 8.7, we set
[TABLE]
Since the immersion is strongly regular, the admissibility condition (6.24) for is equivalent to
[TABLE]
By Theorem 8.5 the first variational formula is given by
[TABLE]
for every . By the arbitrariness of and , the immersion is a critical point of the area if and only if it satisfies equations (8.15) and (8.16) on . ∎
Example 8.9** (First variation for a hypersurface in a contact manifold).**
Let be a contact manifold such that , see § 4.2. Let be the Reeb vector associated to this contact geometry and the Riemannian metric on that extends a given metric on and makes orthonormal to . Let be the Riemannian connection associated to .
Let us consider a hypersurface immersed in . As we showed in § 4.2, the degree of is maximum and equal to , thus each compactly supported vector field on is admissible. Following § 4.2, we consider the unit normal to and its horizontal projection . As in § 4.2, we consider the vector fields and an orthonormal basis of . A straightforward computation, contained in [25], shows that the mean curvature deduced in (8.9) coincide with
[TABLE]
When we obtain well known horizontal divergence of the horizontal normal. This definition of mean curvature for an immersed hypersurface was first given by S.Pauls [44] for graphs over the -plane in , later extended by J.-H. Cheng, J.-F. Hwang, A. Malchiodi and P. Yang in [9] in a -dimensional pseudo-hermitian manifold. In a more general setting this formula was deduced in [30, 15]. For more details see also [21, 6, 50, 20, 47, 48].
Example 8.10** (First variation for ruled surfaces in an Engel Structure).**
Here we compute the mean curvature equation for the surface of degree introduced in Section 4.3. In (4.8) we determined the tangent adapted basis
[TABLE]
A basis for the space is given by
[TABLE]
By the Gram–Schmidt process we obtain an orthonormal basis with respect to the metric as follows
[TABLE]
where we set
[TABLE]
and
[TABLE]
Since the degree of is equal to we deduce that
[TABLE]
then it follows and
[TABLE]
A straightforward computation shows that for defined in (8.9) are given by
[TABLE]
Since we have
[TABLE]
and
[TABLE]
it follows that the third component of is equal to
[TABLE]
and the fourth component of is equal to
[TABLE]
Then first variation formula is given by
[TABLE]
for each satisfying (7.7). Following Theorem 7.2 for each we deduce
[TABLE]
since .
Lemma 8.11**.**
Keeping the previous notation. Let be functions in and
[TABLE]
Then there holds
[TABLE]
By Lemma 8.11 and the admissibility equation (8.21) we deduce that (8.20) is equivalent to
[TABLE]
for each . Therefore a straightforward computation shows that minimal -graphs for the area functional verify the following third order PDE
[TABLE]
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