Concetti Chiave
A 3-dimensional Riemannian manifold (M, g, Q) with a tensor structure Q whose fourth power is the identity is associated with a Riemannian almost product manifold (M, g, P), where P = Q^2. The almost product manifold (M, g, P) is shown to belong to the class of locally conformal Riemannian product manifolds.
Sintesi
The paper studies the geometric properties of a 3-dimensional Riemannian manifold (M, g, Q) equipped with a tensor structure Q whose fourth power is the identity. An associated Riemannian almost product manifold (M, g, P) is also investigated, where P = Q^2.
Key highlights:
- The manifold (M, g, P) is shown to be a locally conformal Riemannian product manifold, with the fundamental tensor F satisfying a specific identity.
- Necessary and sufficient conditions are obtained for the structures Q and P to be parallel with respect to the Levi-Civita connection.
- Classes of almost Einstein and Einstein manifolds are determined, and their curvature properties are studied.
- Special bases in the tangent space TpM are introduced, and relations between Ricci curvatures and sectional curvatures are established.
- An example of the considered manifolds is provided by a 3-dimensional catenoid hypersurface embedded in a 4-dimensional Euclidean space.
Statistiche
A > 0, B > 0
x3(x1)^2 + (x2)^2 ≠ 0
cos φ > 0, cos ψ < cos φ, where φ = ∠(x, Qx) and ψ = ∠(x, Q^2x)
Citazioni
"Every basis of type {x, Qx, Q^2x}, {x, Q^2x, Q^3x}, {x, Qx, Q^3x} and {Qx, Q^2x, Q^3x} of TpM (p ∈ M) is called a Q-basis. In this case we say that the vector x induces a Q-basis of TpM."
"If the Ricci tensor ρ on (M, g, Q) has the form (36), then the sectional curvatures of the 2-planes, determined by the basis vectors, are k(x, Qx) = k(Qx, Q^2x) = k(x, Q^3x) = k(Q^2x, Q^3x) = k(x, Q^2x) = k(Qx, Q^3x) = -τ/6."