Hubert Bray

  • Professor of Mathematics
External address: 189 Physics Bldg, Durham, NC 27710
Internal office address: Box 90320, Durham, NC 27708-0320
Phone: (919) 757-8428
Office Hours: 

Mondays, 4:30 - 6:30 p.m.

Research Areas and Keywords

Geometry: Differential & Algebraic
scalar curvature, minimal surfaces, geometric flows, conformal geometry, isoperimetric surfaces
Mathematical Physics
black holes, Einstein curvature, general relativity, quasi-local mass, dark matter, galactic curvature

Professor Bray uses differential geometry to understand general relativity, and general relativity to motivate interesting problems in differential geometry. In 2001, he published his proof of the Riemannian Penrose Conjecture about the mass of black holes using geometric ideas related to minimal surfaces, scalar curvature, conformal geometry, geometric flows, and harmonic functions. He is also interested in the large-scale unexplained curvature of the universe, otherwise known as dark matter, which makes up most of the mass of galaxies. Professor Bray has proposed geometric explanations for dark matter which he calls "wave dark matter," which motivate very interesting questions about geometric partial differential equations.

Education & Training
  • Ph.D., Stanford University 1997

  • B.A., Rice University 1992

Selected Grants

Time Flat Curves and Surfaces, Geometric Flows, and the Penrose Conjecture awarded by National Science Foundation (Principal Investigator). 2014 to 2018

Scalar Curvature, the Penrose Conjecture, and the Axioms of General Relativity awarded by National Science Foundation (Principal Investigator). 2010 to 2014

Geometric Analysis Applied to General Relativity awarded by National Science Foundation (Principal Investigator). 2007 to 2010

Scalar Curvature, Geometric Flow, and the General Penrose Conjecture awarded by National Science Foundation (Principal Investigator). 2005 to 2008

Bray, H. "On the Positive Mass, Penrose, and ZAS Inequalities in General Dimension." Surveys in Geometric Analysis and Relativity in Honor of Richard Schoen’s 60th Birthday. Ed. H Bray and W Minicozzi. Beijing and Boston: Higher Education Press and International Press, 2011.

Bray, H. "The Positve Energy Theorem and Other Inequalities." The Encyclopedia of Mathematical Physics. 2005.

Bray, H, and Chrusciel, PT. "The Penrose Inequality." The Einstein Equations and the Large Scale Behavior of Gravitational Fields (50 Years of the Cauchy Problem in General Relativity). Ed. PT Chrusciel and HF Friedrich. Birkhauser, 2004.

Bray, H, and Schoen, RM. "Recent Proofs of the Riemannian Penrose Conjecture." Current Developments in Mathematics. Somerville, MA: International Press, 1999. 1-36.

Bray, HL, Jauregui, JL, and Mars, M. "Time Flat Surfaces and the Monotonicity of the Spacetime Hawking Mass II." Annales Henri Poincaré 17.6 (June 2016): 1457-1475. Full Text

Martinez-Medina, LA, Bray, HL, and Matos, T. "On wave dark matter in spiral and barred galaxies." Journal of Cosmology and Astroparticle Physics 2015.12 (December 1, 2015): 025-025. Full Text

Bray, HL, and Jauregui, JL. "On curves with nonnegative torsion." Archiv der Mathematik 104.6 (June 2015): 561-575. Full Text

Bray, HL, and Jauregui, JL. "Time Flat Surfaces and the Monotonicity of the Spacetime Hawking Mass." Communications in Mathematical Physics 335.1 (April 2015): 285-307. Full Text

Bray, H, and Goetz, AS. "Wave Dark Matter and the Tully-Fisher Relation." (September 2014).

Bray, HL, and Jauregui, JL. "A geometric theory of zero area singularities in general relativity." Asian Journal of Mathematics 17.3 (2013): 525-560. Full Text

Bray, HL. "On Dark Matter, Spiral Galaxies, and the Axioms of General Relativity (Accepted)." AMS Contemporary Mathematics Volume 599.Geometric Analysis, Mathematical Relativity, and Nonlinear Partial Differential Equations (2013).

Bray, HL, and Khuri, MA. "P. D. E. 'S which imply the penrose conjecture." Asian Journal of Mathematics 15.4 (2011): 557-610.

Bray, HL, and Khuri, MA. "A jang equation approach to the penrose inequality." Discrete and Continuous Dynamical Systems 27.2 (2010): 741-766. Full Text

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