How Does Sectional Curvature Define Spacetimes in General Relativity?

In summary, the terms elliptic, hyperbolic and euclidean geometry are defined according to the sectional curvature, which is a generalization of the Gaussian curvature of a surface. The Ricci scalar, being a function of the trace of the energy-momentum tensor R = - \kappa T^{\alpha}_{\alpha}, must be always positive? Can be the sectional curvature defined as a function of the Ricci scalar?This is the first time I've heard of sectional curvature. For a 2d manifold, there is only one tanget to the surface at any point, so there is only one component of the Riemann tensor.
  • #1
hellfire
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The terms elliptic, hyperbolic and euclidean geometry are defined according to the sectional curvature, which is a generalization of the Gaussian curvature of a surface. Are there any restrictions on the sectional curvature for spacetimes in general relativity?

The Ricci scalar, being a function of the trace of the energy-momentum tensor [tex]R = - \kappa T^{\alpha}_{\alpha}[/tex], must be always positive? Can be the sectional curvature defined as a function of the Ricci scalar?
 
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  • #2
This is the first time I've heard of sectional curvature. The thing I find interesting is that it does completely describe the Riemann - Google finds enough hits on the term that I'm sure it does , it's just not particularly obvious how.

For a 2d manifold, there is only one tanget to the surface at any point, so there is only one component of the Riemann tensor. So this case isn't very interesting.

Let's go up to a 3d manifold. Then we can describe a specific tangent 2-plane by two variables (angles, let's say), and the sectional curvature of this 2-plane will be a scalar. So the sectional curvature is a scalar function of two angles for a 3d manifold.

Somehow this scalar function of two angles has to give us the six independent components of the Riemann tensor in 3d. But how?
 
  • #3
To get the whole information about the curvature you need the Riemann curvature tensor. I guess it is possible to extract sectional curvatures of 2-planes within 3D or 4D spaces from the Riemann curvature tensor (but I do not know how to do this). May be my first question needs some clarification: I was wondering whether it exists a generalization of the sectional curvature which allows to clasify spacetimes in a similar way than elliptical, hyperbolical, etc. spaces are classified and what the physical meaning of such a quantity is (and, further on, whether there is some relation with the Ricci scalar and its sign).
 

FAQ: How Does Sectional Curvature Define Spacetimes in General Relativity?

What is sectional curvature in general relativity (GR)?

Sectional curvature in GR is a measure of the curvature of a 2-dimensional space within a 4-dimensional space-time. It describes how the geometry of this 2-dimensional space is distorted by the presence of matter and energy in the surrounding space-time.

How is sectional curvature related to the theory of general relativity?

Sectional curvature is a fundamental concept in the theory of general relativity. According to this theory, the curvature of space-time is directly related to the distribution of matter and energy in the universe. Sectional curvature allows us to calculate the effects of this curvature on smaller, 2-dimensional spaces within the larger 4-dimensional space-time.

What is the significance of sectional curvature in GR?

In GR, sectional curvature is important for understanding the behavior of objects in a curved space-time. It allows us to predict the path that an object will take as it moves through this space-time, and to calculate the gravitational forces acting on the object due to the curvature of space-time.

How is sectional curvature measured or calculated?

Sectional curvature can be mathematically calculated using the Riemann curvature tensor, which is a mathematical tool used to describe the curvature of space-time in general relativity. This tensor is derived from the metric tensor, which describes the distance between points in a space-time. The sectional curvature at a specific point is then calculated by plugging in the appropriate values for the metric tensor at that point.

What are some real-world applications of sectional curvature in GR?

Sectional curvature has a wide range of applications in astrophysics and cosmology. It is used to understand the dynamics of the universe, including the formation and evolution of galaxies and the behavior of black holes. It also plays a role in precision measurements, such as the precise timing of signals from pulsars, which can be affected by the curvature of space-time in their vicinity.

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