Scalar curvature of a Levi-Civita connection on the Cuntz algebra with three generators

We prove a Koszul formula for the Levi-Civita connection for any pseudo-Riemannian bilinear metric on a class of centered bimodule of noncommutative one-forms. As an application to the Koszul formula, we show that our Levi-Civita connection is a bimodule connection. We construct a spectral triple on a fuzzy sphere and compute the scalar curvature for the Levi-Civita connection associated to a canonical metric.

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Certain inequalities for the Casorati curvatures of submanifolds of generalized (k,μ)-space-forms

Asian-European Journal of Mathematics ◽

10.1142/s1793557120500400 ◽

2018 ◽

Vol 13 (02) ◽

pp. 2050040

Author(s):

Shyamal Kumar Hui ◽

Pradip Mandal ◽

Ali H. Alkhaldi ◽

Tanumoy Pal

Keyword(s):

Scalar Curvature ◽

Space Form ◽

Space Forms ◽

Civita Connection ◽

Metric Connection ◽

Levi Civita Connection ◽

Casorati Curvature ◽

Optimal Inequalities

The paper deals with the study of Casorati curvature of submanifolds of generalized [Formula: see text]-space-form with respect to Levi-Civita connection as well as semisymmetric metric connection and derived two optimal inequalities between scalar curvature and Casorati curvature of such space forms. The equality cases are also considered.

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Totally real submanifolds of (LCS)n-manifolds

Facta Universitatis Series Mathematics and Informatics ◽

10.22190/fumi1802141h ◽

2018 ◽

Vol 33 (2) ◽

pp. 141

Author(s):

Shyamal Kumar Hui ◽

Tanumoy Pal

Keyword(s):

Scalar Curvature ◽

Real Submanifolds ◽

Civita Connection ◽

Metric Connection ◽

Levi Civita Connection ◽

Totally Real

The present paper deals with the study of totally real submanifolds and C-totally real submanifolds of (LCS)n-manifolds withrespect to Levi-Civita connection as well as quarter symmetric metric connection. It is proved that scalar curvature of C-totally real submanifolds of (LCS)n-manifold with respect to both the said connections are same.

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A quarter-symmetric metric connection on almost contact B-metric manifolds

Filomat ◽

10.2298/fil1916181b ◽

2019 ◽

Vol 33 (16) ◽

pp. 5181-5190

Author(s):

Şenay Bulut

Keyword(s):

Scalar Curvature ◽

Curvature Tensor ◽

Ricci Tensor ◽

Civita Connection ◽

Metric Connection ◽

Levi Civita Connection

The aim of this paper is to study the notion of a quarter-symmetric metric connection on an almost contact B-metric manifold (M,?,?,?,g). We obtain the relation between the Levi-Civita connection and the quarter-symmetric metric connection on (M,?,?,?,g).We investigate the curvature tensor, Ricci tensor and scalar curvature tensor with respect to the quarter-symmetric metric connection. In case the manifold (M,?,?,?,g) is a Sasaki-like almost contact B-metric manifold, we get some formulas. Finally, we give some examples of a quarter-symmetric metric connection.

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Levi-Civita connections for conformally deformed metrics on tame differential calculi

International Journal of Mathematics ◽

10.1142/s0129167x21500889 ◽

2021 ◽

pp. 2150088

Author(s):

Jyotishman Bhowmick ◽

Debashish Goswami ◽

Soumalya Joardar

Keyword(s):

Scalar Curvature ◽

Differential Calculus ◽

Invertible Element ◽

Conformal Deformation ◽

Noncommutative Algebra ◽

Connection Formula ◽

Civita Connection ◽

Canonical Metric ◽

Negative Constant ◽

Levi Civita Connection

Given a tame differential calculus over a noncommutative algebra [Formula: see text] and an [Formula: see text]-bilinear metric [Formula: see text] consider the conformal deformation [Formula: see text] [Formula: see text] being an invertible element of [Formula: see text] We prove that there exists a unique connection [Formula: see text] on the bimodule of one-forms of the differential calculus which is torsionless and compatible with [Formula: see text] We derive a concrete formula connecting [Formula: see text] and the Levi-Civita connection for the metric [Formula: see text] As an application, we compute the Ricci and scalar curvatures for a general conformal perturbation of the canonical metric on the noncommutative [Formula: see text]-torus as well as for a natural metric on the quantum Heisenberg manifold. For the latter, the scalar curvature turns out to be a negative constant.

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Curvature Invariants of Statistical Submanifolds in Kenmotsu Statistical Manifolds of Constant ϕ-Sectional Curvature

Entropy ◽

10.3390/e20070529 ◽

2018 ◽

Vol 20 (7) ◽

pp. 529 ◽

Cited By ~ 11

Author(s):

Simona Decu ◽

Stefan Haesen ◽

Leopold Verstraelen ◽

Gabriel-Eduard Vîlcu

Keyword(s):

Scalar Curvature ◽

Sectional Curvature ◽

Totally Geodesic ◽

Curvature Invariants ◽

Statistical Manifolds ◽

Civita Connection ◽

Levi Civita Connection ◽

Curvature Tensors

In this article, we consider statistical submanifolds of Kenmotsu statistical manifolds of constant ϕ-sectional curvature. For such submanifold, we investigate curvature properties. We establish some inequalities involving the normalized δ-Casorati curvatures (extrinsic invariants) and the scalar curvature (intrinsic invariant). Moreover, we prove that the equality cases of the inequalities hold if and only if the imbedding curvature tensors h and h∗ of the submanifold (associated with the dual connections) satisfy h=−h∗, i.e., the submanifold is totally geodesic with respect to the Levi–Civita connection.

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Curvature of quaternionic Kähler manifolds with $$S^1$$-symmetry

manuscripta mathematica ◽

10.1007/s00229-021-01294-7 ◽

2021 ◽

Author(s):

V. Cortés ◽

A. Saha ◽

D. Thung

Keyword(s):

Curvature Tensor ◽

Decomposition Theorem ◽

Kähler Manifolds ◽

Kahler Manifolds ◽

Riemann Curvature ◽

Riemann Curvature Tensor ◽

Cohomogeneity One ◽

Civita Connection ◽

Levi Civita Connection ◽

Quaternionic Kähler

AbstractWe study the behavior of connections and curvature under the HK/QK correspondence, proving simple formulae expressing the Levi-Civita connection and Riemann curvature tensor on the quaternionic Kähler side in terms of the initial hyper-Kähler data. Our curvature formula refines a well-known decomposition theorem due to Alekseevsky. As an application, we compute the norm of the curvature tensor for a series of complete quaternionic Kähler manifolds arising from flat hyper-Kähler manifolds. We use this to deduce that these manifolds are of cohomogeneity one.

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ON THE GAUSS–BONNET FORMULA IN RIEMANN–FINSLER GEOMETRY

Bulletin of the London Mathematical Society ◽

10.1112/s002460930100892x ◽

2002 ◽

Vol 34 (3) ◽

pp. 329-340 ◽

Cited By ~ 4

Author(s):

BRAD LACKEY

Keyword(s):

Finsler Space ◽

Finsler Geometry ◽

Euler Class ◽

Constant Volume ◽

Finsler Spaces ◽

Chern Connection ◽

Civita Connection ◽

Levi Civita Connection ◽

Riemannian Case ◽

Torsion Free

Using Chern's method of transgression, the Euler class of a compact orientable Riemann–Finsler space is represented by polynomials in the connection and curvature matrices of a torsion-free connection. When using the Chern connection (and hence the Christoffel–Levi–Civita connection in the Riemannian case), this result extends the Gauss–Bonnet formula of Bao and Chern to Finsler spaces whose indicatrices need not have constant volume.

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CAN TORSION BE TREATED AS JUST ANOTHER TENSOR FIELD?

International Journal of Modern Physics Conference Series ◽

10.1142/s2010194512004229 ◽

2012 ◽

Vol 07 ◽

pp. 158-164 ◽

Cited By ~ 3

Author(s):

JAMES M. NESTER ◽

CHIH-HUNG WANG

Keyword(s):

Gauge Theory ◽

Tensor Field ◽

Affine Connection ◽

Cartan Geometry ◽

Civita Connection ◽

Levi Civita Connection ◽

Alternative Gravity Theories ◽

Theory Of Gravity ◽

Gauge Theory Of Gravity ◽

Alternative Gravity

Many alternative gravity theories use an independent connection which leads to torsion in addition to curvature. Some have argued that there is no physical need to use such connections, that one can always use the Levi-Civita connection and just treat torsion as another tensor field. We explore this issue here in the context of the Poincaré Gauge theory of gravity, which is usually formulated in terms of an affine connection for a Riemann-Cartan geometry (torsion and curvature). We compare the equations obtained by taking as the independent dynamical variables: (i) the orthonormal coframe and the connection and (ii) the orthonormal coframe and the torsion (contortion), and we also consider the coupling to a source. From this analysis we conclude that, at least for this class of theories, torsion should not be considered as just another tensor field.

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The affine connection

10.1093/oso/9780192895646.003.0010 ◽

2021 ◽

pp. 121-132

Author(s):

Andrew M. Steane

Keyword(s):

Covariant Derivative ◽

Affine Connection ◽

Connection Coefficients ◽

Civita Connection ◽

Levi Civita Connection ◽

Coordinate Basis ◽

Basis Vectors

The connection and the covariant derivative are treated. Connection coefficients are introduced in their role of expressing the change in the coordinate basis vectors between neighbouring points. The covariant derivative of a vector is then defined. Next we relate the connection to the metric, and obtain the Levi-Civita connection. The logic concerning what is defined and what is derived is explained carefuly. The notion of a derivative along a curve is defined. The emphasis through is on clarity and avoiding confusions arising from the plethora of concepts and symbols.

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