Difference between revisions of "P-Sasakian manifold"
m (texified) |
(details) |
||
Line 1: | Line 1: | ||
− | A manifold similar to a [[ | + | A manifold similar to a [[Sasakian manifold]]. However, by its topological and geometric properties, such a manifold is closely related to a product manifold (unlike the Sasakian manifold, which is related to a [[complex manifold]]). |
− | A [[ | + | A [[Riemannian manifold]] $(M,g)$ endowed with an endomorphism $\phi$ of the tangent bundle $TM$, a vector field $\xi$ and a $1$-form $\eta$ which satisfy the conditions |
− | \begin{equation}\phi^2=I-\eta\bigotimes\xi,\\\eta(\xi)=1,\phi\xi=0,\eta\circ\phi=0,d\eta=0,g(\phi X,\phi Y)=h(X,Y)-\eta(X)\eta(Y),\\(\nabla_X\phi)Y=\{-g(X,Y)+2\eta(X)\eta(Y)\}\xi-\eta(Y)X,\end{equation} | + | \begin{equation} |
+ | \label{eq1} | ||
+ | \phi^2=I-\eta\bigotimes\xi,\\\eta(\xi)=1,\phi\xi=0,\eta\circ\phi=0,d\eta=0,g(\phi X,\phi Y)=h(X,Y)-\eta(X)\eta(Y),\\(\nabla_X\phi)Y=\{-g(X,Y)+2\eta(X)\eta(Y)\}\xi-\eta(Y)X, | ||
+ | \end{equation} | ||
− | for any vector fields $X$, $Y$ tangent to $M$, where $I$ and $\nabla$ denote the identity transformation on $TM$ and the [[ | + | for any vector fields $X$, $Y$ tangent to $M$, where $I$ and $\nabla$ denote the identity transformation on $TM$ and the [[Riemannian connection]] with respect to $g$, respectively, is called a P-Sasakian manifold [[#References|[a3]]]. |
The structure group of the [[Tangent bundle|tangent bundle]] $TM$ is reducible to $O(h)\times O(n-h-1)\times1$, where $h$ is the multiplicity of the eigenvalue $1$ of the characteristic equation of $\phi$ and $n=\text{dim}M$. | The structure group of the [[Tangent bundle|tangent bundle]] $TM$ is reducible to $O(h)\times O(n-h-1)\times1$, where $h$ is the multiplicity of the eigenvalue $1$ of the characteristic equation of $\phi$ and $n=\text{dim}M$. | ||
Line 17: | Line 20: | ||
where $x\in H^n$, $i,j=1,...,n$. The characteristic vector field $\xi=(0,...,0,x^n)$, and $\phi X=\nabla_X\xi$ for any vector field $X$ tangent to $H^n$. | where $x\in H^n$, $i,j=1,...,n$. The characteristic vector field $\xi=(0,...,0,x^n)$, and $\phi X=\nabla_X\xi$ for any vector field $X$ tangent to $H^n$. | ||
− | The warped product $\ | + | The warped product $\mathbf{R}\times_f T^{n-1}$ of a real line $\mathbf{R}$ and an $(n-1)$-dimensional flat torus $T^{n-1}$, with $f(x)=e^{-2x}$. |
==Properties.== | ==Properties.== |
Latest revision as of 15:54, 16 March 2024
A manifold similar to a Sasakian manifold. However, by its topological and geometric properties, such a manifold is closely related to a product manifold (unlike the Sasakian manifold, which is related to a complex manifold).
A Riemannian manifold $(M,g)$ endowed with an endomorphism $\phi$ of the tangent bundle $TM$, a vector field $\xi$ and a $1$-form $\eta$ which satisfy the conditions
\begin{equation} \label{eq1} \phi^2=I-\eta\bigotimes\xi,\\\eta(\xi)=1,\phi\xi=0,\eta\circ\phi=0,d\eta=0,g(\phi X,\phi Y)=h(X,Y)-\eta(X)\eta(Y),\\(\nabla_X\phi)Y=\{-g(X,Y)+2\eta(X)\eta(Y)\}\xi-\eta(Y)X, \end{equation}
for any vector fields $X$, $Y$ tangent to $M$, where $I$ and $\nabla$ denote the identity transformation on $TM$ and the Riemannian connection with respect to $g$, respectively, is called a P-Sasakian manifold [a3].
The structure group of the tangent bundle $TM$ is reducible to $O(h)\times O(n-h-1)\times1$, where $h$ is the multiplicity of the eigenvalue $1$ of the characteristic equation of $\phi$ and $n=\text{dim}M$.
Examples.
The hyperbolic $n$-space form $H^n$. As a model, one can take the upper half-space $x^n>0$ in the sense of Poincaré's representation (cf. also Poincaré model). The metric of $H^n$ is given by
\begin{equation}g_{ij}(x)=(x^n)^{-2}\delta_{ij}\end{equation}
where $x\in H^n$, $i,j=1,...,n$. The characteristic vector field $\xi=(0,...,0,x^n)$, and $\phi X=\nabla_X\xi$ for any vector field $X$ tangent to $H^n$.
The warped product $\mathbf{R}\times_f T^{n-1}$ of a real line $\mathbf{R}$ and an $(n-1)$-dimensional flat torus $T^{n-1}$, with $f(x)=e^{-2x}$.
Properties.
If a P-Sasakian manifold is a space form (cf. Space forms), then its sectional curvature is $-1$ [a2].
The characteristic vector field $\xi$ of a P-Sasakian manifold is an exterior concurrent vector field [a2].
On a compact orientable P-Sasakian manifold, the characteristic vector field $\xi$ is harmonic [a5].
A projectively flat P-Sasakian manifold is a hyperbolic space form of constant curvature $-1$ [a5].
For the de Rham cohomology of a P-Sasakian manifold, the following result is known [a1]: Let $M$ be a compact P-Sasakian manifold such that the distribution annihilated by $\eta$ is minimal. Then the first Betti number $b_1$ does not vanish.
References
[a1] | I. Mihai, R. Rosca, L. Verstraelen, "Some aspects of the differential geometry of vector fields" , PADGE , 2 , KU Leuven&KU Brussel (1996) |
[a2] | R. Rosca, "On para Sasakian manifolds" Rend. Sem. Mat. Messina , 1 (1991) pp. 201–216 |
[a3] | I. Sato, "On a structure similar to the almost contact structure I; II" Tensor N.S. , 30/31 (1976/77) pp. 219–224; 199–205 |
[a4] | I. Sato, "On a Riemannian manifold admitting a certain vector field" Kodai Math. Sem. Rep. , 29 (1978) pp. 250–260 |
[a5] | I. Sato, K. Matsumoto, "On P-Sasakian manifolds satisfying certain conditions" Tensor N.S. , 33 (1979) pp. 173–178 |
P-Sasakian manifold. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=P-Sasakian_manifold&oldid=55645