Hamiltonian Monodromy and Morse Theory

We show that Hamiltonian monodromy of an integrable two degrees of freedom systemwith a global circle action can be computed by applyingMorse theory to the Hamiltonian of the system. Our proof is based on Takens’s index theorem, which specifies how the energy-h Chern number changes when h passes a non-degenerate critical value, and a choice of admissible cycles in Fomenko–Zieschang theory. Connections of our result to some of the existing approaches to monodromy are discussed.

At the most fundamental level, a local understanding of such systems is provided by the Arnol'd-Liouville theorem [2,3,37,46]. This theorem states that integrable systems are generically foliated by tori, given by the compact and regular joint level sets of the integrals of motion, and that such foliations are always locally trivial (in the symplectic sense). A closely related consequence of the Arnol'd-Liouville theorem, is the local existence of the action coordinates given by the formula where α i , i = 1, . . . , n, are independent homology cycles on a given torus T n of the foliation.
Passing from the local to the global description of integrable Hamiltonian systems, naturally leads to questions on the geometry of the foliation of the phase space by Arnol'd-Liouville tori. For instance, the question of whether the bundles formed by Arnol'd-Liouville tori come from a Hamiltonian torus action, is closely connected to the existence of global action coordinates and Hamiltonian monodromy [20]. In the present work, we shall review old and discuss new ideas related to this classical invariant.
Monodromy was introduced by Duistermaat in [20] and it concerns a certain 'holonomy' effect that appears when one tries to construct global action coordinates for a given integrable Hamiltonian system. If the homology cycles α i appearing in the definition of the actions I i cannot be globally defined along a certain closed path in phase space, then the monodromy is non-trivial; in particular, the system has no global action coordinates and does not admit a Hamiltonian torus action of maximal dimension (the system is not toric).
In the context of monodromy and its generalizations, it is natural to ask how one can compute this invariant for a given class of integrable Hamiltonian systems. Since Duistermaat's work [20], a number of different approaches to this problem, ranging from the residue calculus to algebraic and symplectic geometry, have been developed. The very first topological argument that allows one to detect non-trivial monodromy in the spherical pendulum has been given by Richard Cushman. Specifically, he observed that, for this system, the energy hyper-surfaces H −1 (h) for large values of the energy h are not diffeomorphic to the energy hyper-surfaces near the minimum where the pendulum is at rest. This property is incompatible with the triviality of monodromy; see [20] and Sect. 3 for more details. This argument demonstrates that the monodromy in the spherical pendulum is non-trivial, but does not compute it.
Cushman's argument had been sleeping for many years until Floris Takens [57] proposed the idea of using Chern numbers of energy hyper-surfaces and Morse theory for the computation of monodromy. More specifically, he observed that in integrable systems with a Hamiltonian circle action (such as the spherical pendulum), the Chern number of energy hyper-surfaces changes when the energy passes a critical value of the Hamiltonian function. The main purpose of the present paper is to explain Takens's theorem and to show that it allows one to compute monodromy in integrable systems with a circle action.
We note that the present work is closely related to the works [30,40], which demonstrate how one can compute monodromy by focusing on the circle action and without using Morse theory. However, the idea of computing monodromy through energy hypersurfaces and their Chern numbers can also be applied when we do not have a detailed knowledge of the singularities of the system; see Remark 8. In particular, it can be applied to the case when we do not have any information about the fixed points of the circle action. We note that the behaviour of the circle action near the fixed points is important for the theory developed in the works [30,40].
The paper is organized as follows. In Sect. 2 we discuss Takens's idea following [57]. In particular, we state and prove Takens's index theorem, which is central to the present work. In Sect. 3 we show how this theorem can be applied to the context of monodromy. We discuss in detail two examples and make a connection to the Duistermaat-Heckman theorem [22]. In Sect. 4 we revisit the symmetry approach to monodromy presented in the works [30,40], and link it to the rotation number [15]. The paper is concluded with a discussion in Sect. 5. Background material on Hamiltonian monodromy and Chern classes is presented in the Appendix.

Takens's Index Theorem
We consider an oriented 4-manifold M and a smooth Morse function H on this manifold. We recall that H is called a Morse function if for any critical (= singular) point x of H, the Hessian is non-degenerate. We shall assume that H is a proper 1 function and that it is invariant under a smooth circle action G : M × S 1 → M that is free outside the critical points of H . Note that the critical points of H are the fixed points of the circle action.

Remark 1 (Context of integrable Hamiltonian systems).
In the context of integrable systems, the function H is given by the Hamiltonian of the system or another first integral, while the circle action comes from the (rotational) symmetry. For instance, in the spherical pendulum [15,20], which is a typical example of a system with monodromy, one can take the function H to be the Hamiltonian of the system; the circle action is given by the component of the angular momentum along the gravitational axis. We shall discuss this example in detail later on. In the Jaynes-Cummings model [23,33,49], one can take the function H to be the integral that generates the circle action, but one can not take H to be the Hamiltonian of the system since the latter function is not proper.   [9]) it follows that in a small equivariant neighbourhood of this point the action can be linearized. Thus, in appropriate complex coordinates (z, w) ∈ C 2 the action can be written as for some integers m and n. By our assumption, the circle action is free outside the (isolated) critical points of the Morse function H . Hence, near each such critical point the action can be written as in appropriate complex coordinates (z, w) ∈ C 2 . The two cases can be mapped to each other through an orientation-reversing coordinate change.

Definition 2.
A singular point P is called positive if the local circle action is given by (z, w) → (e −it z, e it w) and negative if the action is given by (z, w) → (e it z, e it w) in a coordinate chart having the positive orientation with respect to the orientation of M. Remark 3. The Hopf fibration is defined by the circle action (z, w) → (e it z, e it w) on the sphere The circle action (z, w) → (e −it z, e it w) defines the anti-Hopf fibration on S 3 [58]. If the orientation is fixed, these two fibrations are different. Lemma 1. The Chern number of the Hopf fibration is equal to −1, while for the anti-Hopf fibration it is equal to 1.

Proof. See Appendix B.
Theorem 1 (Takens's index theorem [57] Here the sign is plus if the circle action defines the anti-Hopf fibration near the critical point and minus for the Hopf fibration.
Proof. The main idea is to apply Morse theory to the function H . The role of Euler characteristic in standard Morse theory will be played by the Chern number. We note that the Chern number, just like the Euler characteristic, is additive.
From Morse theory [44], we have that the manifold up to a diffeomorphism. We note that by the construction, the intersection of the handle ; see [44]. For simplicity, we shall assume that the handle is disjoint from H −1 (h c + ε). By taking the boundary in Eq. (1), we get that Here the union Since we assumed the existence of a global circle action on M, we can choose the handle and its boundary S 3 to be invariant with respect to this action [62]. This will allow us to relate the Chern numbers of H −1 (h c + ε) and H −1 (h c − ε) using Eq. (2). Specifically, due to the invariance under the circle action, the sphere S 3 has a well-defined Chern number. Moreover, since the action is assumed to be free outside the critical points of H , this Chern number c(S 3 ) = ±1, depending on whether the circle action defines the anti-Hopf or the Hopf fibration on S 3 ; see Lemma 1. From Eq. (2) and the additive property of the Chern number, we get It is left to show that c(h c + ε) = c(∂ X ) (we note that even though we know that H −1 (h c + ε) and ∂ X are diffeomorphic, we cannot yet conclude that they have the same Chern numbers).
Let the subset Y ⊂ M be defined as the closure of the set We observe that Y is a compact submanifold of M and that Remark 4. We note that (an analogue of) Theorem 1 holds also when the Hamiltonian function H has k > 1 isolated critical points on a critical level. In this case where s k = ±1 corresponds to the kth critical point.

Morse Theory Approach to Monodromy
The goal of the present section is to show how Takens's index theorem can be used to compute Hamiltonian monodromy. First, we demonstrate our method on a famous example of a system with non-trivial monodromy: the spherical pendulum. Then, we give a new proof of the geometric monodromy theorem along similar lines. We also show that the jump in the energy level Chern number manifests non-triviality of Hamiltonian monodromy in the general case. This section is concluded with studying Hamiltonian monodromy in an example of an integrable system with two focus-focus points.

Spherical pendulum.
The spherical pendulum describes the motion of a particle moving on the unit sphere in the linear gravitational potential V (x, y, z) = z. The corresponding Hamiltonian system is given by is the total energy of the pendulum and Ω is the standard symplectic structure. We observe that the function J = x p y − yp x (the component of the total angular momentum about the z-axis) is conserved. It follows that the system is Liouville integrable. The bifurcation diagram of the energy-momentum map that is, the set of the critical values of this map, is shown in Fig. 1.
From the bifurcation diagram we see that the set R ⊂ image(F) of the regular values of F (the shaded area in Fig. 2) is an open subset of R 2 with one puncture. Topologically, R is an annulus and hence π 1 (R, f 0 ) = Z for any f 0 ∈ R. We note that the puncture (the black dot in Fig. 1) corresponds to an isolated singularity; specifically, to the unstable equilibrium of the pendulum.
Consider the closed path γ around the puncture that is shown in Fig. 1. Since J generates a Hamiltonian circle action on T * S 2 , any orbit of this action on F −1 (γ (0)) can be transported along γ . Let (a, b) be a basis of H 1 (F −1 (γ (0))), where b is given by for some integer m γ . It was shown in [20] that m γ = 1 (in particular, global action coordinates do not exist in this case). Below we shall show how this result follows from Theorem 1. First we recall the following argument due to Cushman, which shows that the monodromy along the loop γ is non-trivial; the argument appeared in [20].
Using Takens's index theorem 1, we shall now make one step further and compute the monodromy index m γ . By Takens's index theorem, the energy-level Chern numbers are related via Bifurcation diagram for the spherical pendulum, the energy levels, the curves γ 1 and γ 2 , and the loop γ around the focus-focus singularity since the critical point P c is of focus-focus type. Note that focus-focus points are positive by Theorem 3; for a definition of focus-focus points we refer to [10].
Consider again the curves γ 1 and γ 2 shown in Fig. 2. Observe that F −1 (γ 1 ) and F −1 (γ 2 ) are invariant under the circle action given by the Hamiltonian flow of J . Let c 1 and c 2 denote the corresponding Chern numbers. By the isotopy, we have that c 1 = c(1 + ε) and c 2 = c(1 − ε). In particular, c 1 = c 2 + 1.
Let δ > 0 be sufficiently small. Consider the following set where j min is the minimum value of the momentum J on F −1 (γ 1 ). Similarly, we define the set By the construction of the curves γ i , the sets S − and S + are contained in both F −1 (γ 1 ) and F −1 (γ 2 ). Topologically, these sets are solid tori. Let (a − , b − ) be two basis cycles on ∂ S − such that a − is the meridian and b − is an orbit of the circle action. Let (a + , b + ) be the corresponding cycles on ∂ S + . The preimage F −1 (γ i ) is homeomorphic to the space obtained by gluing these pairs of cycles by where c i is the Chern number of F −1 (γ i ). It follows that the monodromy matrix along γ is given by the product Since c 1 = c 2 + 1, we conclude that the monodromy matrix Remark 6 (Fomenko-Zieschang theory). The cycles a ± , b ± , which we have used when expressing F −1 (γ i ) as a result of gluing two solid tori, are admissible in the sense of Fomenko-Zieschang theory [10,32]. It follows, in particular, that the Liouville fibration of F −1 (γ i ) is determined by the Fomenko-Zieschang invariant (the marked molecule) with the n-mark n i given by the Chern number c i . (The same is true for the regular energy levels H −1 (h).) Therefore, our results show that Hamiltonian monodromy is also given by the jump in the n-mark. We note that the n-mark and the other labels in the Fomenko-Zieschang invariant are also defined in the case when no global circle action exists.

Geometric monodromy theorem.
A common aspect of most of the systems with non-trivial Hamiltonian monodromy is that the corresponding energy-momentum map has focus-focus points, which, from the perspective of Morse theory, are saddle points of the Hamiltonian function.
The following result, which is sometimes referred to as the geometric monodromy theorem, characterizes monodromy around a focus-focus singularity in systems with two degrees of freedom.

where m is the number of the focus-focus points on the singular fiber.
A related result in the context of the focus-focus singularities is that they come with a Hamiltonian circle action [63,64].

Theorem 3 (Circle action near focus-focus, [63,64]). In a neighbourhood of a focusfocus fiber, 2 there exists a unique (up to orientation reversing) Hamiltonian circle action which is free everywhere except for the singular focus-focus points. Near each singular point, the momentum of the circle action can be written as
for some local canonical coordinates (q 1 , p 1 , q 2 , p 2 ). In particular, the circle action defines the anti-Hopf fibration near each singular point. One implication of Theorem 3 is that it allows to prove the geometric monodromy theorem by looking at the circle action. Specifically, one can apply the Duistermaat-Heckman theorem in this case; see [64]. A slight modification of our argument, used in the previous Sect. 3.1 to determine monodromy in the spherical pendulum, results in another proof of the geometric monodromy theorem. We give this proof below.
Proof of Theorem 2 By applying integrable surgery, we can assume that the bifurcation diagram consists of a square of elliptic singularities and a focus-focus singularity in the middle; see [64]. In the case when there is only one focus-focus point on the singular focus-focus fiber, the proof reduces to the case of the spherical pendulum. Otherwise the configuration is unstable. Instead of a focus-focus fiber with m singular points, one can consider a new S 1 -invariant fibration such that it is arbitrary close to the original one and has m simple (that is, containing only one critical point) focus-focus fibers; see Fig. 3.
As in the case of the spherical pendulum, we get that the monodromy matrix around each of the simple focus-focus fibers is given by the matrix Since the new fibration is S 1 -invariant, the monodromy matrix around m focus-focus fibers is given by the product of m such matrices, that is,

The result follows.
Remark 7 (Duistermaat-Heckman). Consider a symplectic 4-manifold M and a proper function J that generates a Hamiltonian circle action on this manifold. Assume that the fixed points are isolated and that the action is free outside these points. From the Duistermaat-Heckman theorem [22] it follows that the symplectic volume vol( j) of J −1 ( j)/S 1 is a piecewise linear function. Moreover, if j = 0 is a critical value with m positive fixed points of the circle action, then vol( j) + vol(− j) = 2 vol(0) − m j.
As was shown in [64], this result implies the geometric monodromy theorem since the symplectic volume can be viewed as the affine length of the line segment {J = j} in the image of F. The connection to our approach can be seen from the observation that the derivative vol ( j) coincides with the Chern number of J −1 ( j). We note that for the spherical pendulum, the Hamiltonian does not generate a circle action, whereas the z-component of the angular momentum is not a proper function. Therefore, neither of these functions can be taken as 'J '; in order to use the Duistermaat-Heckman theorem, one needs to consider a local model first [64]. Our approach, based on Morse theory, can be applied directly to the Hamiltonian of the spherical pendulum, even though it does not generate a circle action.

Remark 8 (Generalization).
We observe that even if a simple closed curve γ ⊂ R bounds some complicated arrangement of singularities or, more generally, if the interior of γ in R 2 is not contained in the image of the energy-momentum map F, the monodromy along this curve can still be computed by looking at the energy level Chern numbers. Specifically, the monodromy along γ is given by is the difference between the Chern numbers of two (appropriately chosen) energy levels.
Remark 9 (Planar scattering). We note that a similar result holds in the case of mechanical Hamiltonian systems on T * R 2 that are both scattering and integrable; see [41]. For such systems, the roles of the compact monodromy and the Chern number are played by the scattering monodromy and Knauf's scattering index [34], respectively.

Remark 10 (Many degrees of freedom).
The approach presented in this paper depends on the use of energy-levels and their Chern numbers. For this reason, it cannot be directly generalized to systems with many degrees of freedom. An approach that admits such a generalization was developed in [30,40]; we shall recall it in the next section.

Example: a system with two focus-focus points.
Here we illustrate the Morse theory approach that we developed in this paper on a concrete example of an integrable system that has more than one focus-focus point. The system was introduced in [55]; it is an example of a semi-toric system [24,54,60] with a special property that it has two distinct focus-focus fibers, which are not on the same level of the momentum corresponding to the circle action. Let S 2 be the unit sphere in R 3 and let ω denote its volume form, induced from R 3 . Take the product S 2 × S 2 with the symplectic structure ω ⊕ 2ω. The system introduced in [55] is an integrable system on S 2 × S 2 defined in Cartesian coordinates (x 1 , y 1 , z 1 , x 2 , y 2 , z 2 ) ∈ R 3 ⊕ R 3 by the Poisson commuting functions H = 1 4 z 1 + 1 4 z 2 + 1 2 (x 1 x 2 + y 1 y 2 ) and J = z 2 + 2z 2 . The bifurcation diagram of the corresponding energy-momentum map F = (H, J ) : S 2 × S 2 → R 2 is shown in Fig. 4. The system has 4 singular points: two focus-focus and two elliptic-elliptic points. These singular points are (S, S), (N , S), (S, N ) and (N , N ), where S and N are the South and the North poles of S 2 . Observe that these points are the fixed points of the circle action generated by the momentum J . The focus-focus points are positive fixed points (in the sense of Definition 2) and the elliptic-elliptic points are negative. Takens's index theorem implies that the topology of the regular J -levels are S 3 , S 2 × S 1 , and S 3 ; the corresponding Chern numbers are −1, 0, and 1, respectively. Invoking the argument in Sect. 3.1 for the spherical pendulum (see also Sect. 3.2), we conclude 3 that the monodromy matrices along the curves γ 1 and γ 2 that encircle the focus-focus points (see Fig. 4) are Here the homology basis (a, b) is chosen such that b is an orbit of the circle action.

Remark 11
Observe that the regular H -levels have the following topology: S 2 ×S 1 , S 3 , S 3 , and S 2 × S 1 . We see that the energy levels do not change their topology as the value of H passes the critical value 0, which corresponds to the two focus-focus points. Still, the monodromy around γ 3 is nontrivial. Indeed, in view of Eq. (3) and the existence of a global circle action [19], the monodromy along γ 3 is given by 3 We note that Eq. 3 follows also from the geometric monodromy theorem since the circle action gives a universal sign for the monodromy around the two focus-focus points [19]. Our aim is to prove Eq. 3 by looking at the topology of the energy levels.
The apparent paradox is resolved when one looks at the Chern numbers: the Chern number of the 3-sphere below the focus-focus points is equal to − 1, whereas the Chern number of the 3-sphere above the focus-focus points is equal to + 1. (The Chern number of S 2 × S 1 is equal to 0 in both cases.) We note that a similar kind of example of an integrable system for which the monodromy is non-trivial and the energy levels do not change their topology, is given in [15] (see Burke's egg (poached)). In the case of Burke's egg, the energy levels are non-compact; in the case of the system on S 2 × S 2 they are compact.

Symmetry Approach
We note that one can avoid using energy levels by looking directly at the Chern number of F −1 (γ ), where γ is the closed curve along which Hamiltonian monodromy is defined. This point of view was developed in the work [30]. It is based on the following two results.
where m is the Chern number of the principal circle bundle ρ : F −1 (γ ) → F −1 (γ )/S 1 , defined by reducing the circle action.
In the case when the curve γ bounds a disk D ⊂ image(F), the Chern number m can be computed from the singularities of the circle action that project into D. Specifically, there is the following result. We note that Theorems 4 and 5 were generalized to a much more general setting of fractional monodromy and Seifert fibrations; see [40]. Such a generalization allows one, in particular, to define monodromy for circle bundles over 2-dimensional surfaces (or even orbifolds) of genus g ≥ 1; in the standard case the genus g = 1.
Let us now give a new proof of Theorem 4, which makes a connection to the rotation number. First we shall recall this notion.
We assume that the energy-momentum map Theorem 6 (Monodromy and rotation number, [15]). The Hamiltonian monodromy of the torus bundle F : F −1 (γ ) → γ is given by where −m is the variation of the rotation number Θ.
Proof First we note that since the flow of J is periodic on F −1 (γ ), the monodromy matrix is of the form for some integer m .
Fix a starting point f 0 ∈ γ. Choose a smooth branch of the rotation number Θ on γ \ f 0 and define the vector field X S on F −1 (γ \ f 0 ) by By the construction, the flow of X S is periodic. However, unlike the flow of X J , it is not globally defined on F −1 (γ ). Let α 1 and α 0 be the limiting cycles of this vector field on F −1 ( f 0 ), that is, let α 0 be given by the flow of the vector field X S for f → f 0 + and let α 1 be given by the flow of X S for f → f 0 −. Then where −m is the variation of the rotation number along γ . Indeed, if the variation of the rotation number is −m, then the vector field Since α 1 is the result of the parallel transport of α 0 along γ , we conclude that m = m. The result follows.
We are now ready to prove Theorem 4.
Proof Take an invariant metric g on F −1 (γ ) and define a connection 1-form σ of the principal S 1 bundle ρ : E γ → E γ /S 1 as follows: where e is orthogonal to X J and X H with respect to the metric g. Since the flows ϕ t H and ϕ τ J commute, σ is indeed a connection one-form. By the construction, Since α 0 α 1 bounds a cylinder C ⊂ F −1 (γ \ f 0 ), we also have where c 1 is the Chern class of the circle bundle ρ : E γ → E γ /S 1 . The result follows.

Discussion
In this paper we studied Hamiltonian monodromy in integrable two-degree of freedom Hamiltonian systems with a circle action. We showed how Takens's index theorem, which is based on Morse theory, can be used to compute Hamiltonian monodromy. In particular, we gave a new proof of the monodromy around a focus-focus singularity using the Morse theory approach. An important implication of our results is a connection of the geometric theory developed in the works [29,40] to Cushman's argument, which is also based on Morse theory. New connections to the rotation number and to Duistermaat-Heckman theory were also discussed.
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A Hamiltonian monodromy
A typical situation in which monodromy arises is the case of an integrable system on a 4-dimensional symplectic manifold (M 4 , Ω). Such a system is specified by the energymomentum (or the integral) map Here H is the Hamiltonian of the system and the momentum J is a 'symmetry' function, that is, the Poisson bracket vanishes. We will assume that the map F is proper, that is, that preimages of compact sets are compact, and that the fibers F −1 ( f ) of F are connected. Then near any regular value of F the functions H and J can be combined into new functions I 1 = I 1 (H, J ) and I 2 = I 2 (H, J ) such that the symplectic form has the canonical form for some angle coordinates ϕ 1 , ϕ 2 on the fibers of F. This follows from the Arnol'd-Liouville theorem [3]. We note that the regular fibers of F are tori and that the motion on these tori is quasi-periodic. The coordinates I i that appear in the Arnol'd-Liouville theorem are called action coordinates. It can be shown that if pdq is a local primitive 1-from of the symplectic form, then these coordinates are given by the formula We observe that this map is a torus bundle: locally it is a direct product D n × T n , the trivialization being achieved by the action-angle coordinates. Hamiltonian monodromy is defined as a representation of the fundamental group π 1 (R, f 0 ) in the group of automorphisms of the integer homology group H 1 (F −1 ( f 0 )). Each element γ ∈ π 1 (R, f 0 ) acts via parallel transport of integer homology cycles α i ; see [20]. We note that the appearance of the homology groups is due to the fact that the action coordinates (5) depend only on the homology class of α i on the Arnol'd-Liouville torus. We observe that since the fibers of F are tori, the group H 1 (F −1 ( f 0 )) is isomorphic to Z 2 . It follows that the monodromy along a given path γ is characterized by an integer matrix M γ ∈ GL(2, Z), called the monodromy matrix along γ . It can be shown that the determinant of this matrix equals 1.

Remark 12 (Examples and generalizations).
Non-trivial monodromy has been observed in various examples of integrable systems, including the most fundamental ones, such as the spherical pendulum [15,20], the hydrogen atom in crossed fields [18] and the spatial Kepler problem [26,39]. This invariant has also been generalized in several different directions, leading to the notions of quantum [16,59], fractional [28,40,48] and scattering [5,25,29,39] monodromy. Remark 13 (Topological definition of monodromy). Topologically, one can define Hamiltonian monodromy along a loop γ as monodromy of the torus (in the non-compact case -cylinder) bundle over this loop. More precisely, consider a T 2 -torus bundle It can be obtained from a trivial bundle [0, 2π ] × T 2 by gluing the boundary tori via a homeomorphism f , called the monodromy of F. In the context of integrable systems (when F is the energy-momentum map and γ is a loop in the set of the regular values) the matrix of the push-forward map f : H 1 (T 2 ) → H 1 (T 2 ) coincides with the monodromy matrix along γ in the above sense. It follows, in particular, that monodromy can be defined for any torus bundle.

B Chern classes
Let M be an S 1 -invariant submanifold of M which does not contain the critical points of H . The circle action on M is then free and we have a principal circle bundle Let X J denote the vector field on M corresponding to the circle action (such that the flow of X J gives the circle action) and let σ be a 1-form on M such that the following two conditions hold (i) σ (X J ) = i and (ii) R * g (σ ) = σ. Here i ∈ iR -the Lie algebra of S 1 = {e iϕ ∈ C | ϕ ∈ [0, 2π ]} and R g is the (right) action of S 1 . The Chern (or the Euler) class 4 can then defined as is the principal circle bundle S 3 → S 2 obtained by reducing the circle action (z, w) → (e it z, e it w). The circle action (z, w) → (e −it z, e it w) defines the anti-Hopf fibration of S 3 .

Lemma 2
The Chern number of the Hopf fibration is equal to −1, while for the anti-Hopf fibration it is equal to 1.
Proof Consider the case of the Hopf fibration (the anti-Hopf case is analogous). Its projection map h : S 3 → S 2 is defined by h(z, w) = (z : w) ∈ CP 1 = S 2 . Put Now, the gluing cocycle t 12 : S 1 = U 1 ∩ U 2 → S 1 corresponding to the sections s 1 and s 2 is given by t 12 ((u : 1)) = exp (−iArg u).
If follows that the winding number equals −1 (the loop α in Definition 1 is given by the equator S 1 = U 1 ∩ U 2 in this case).