Erastus O. Haven Professor
PhD, University of Illinois, 1997
Maria Goeppert Mayer Award
David and Lucille Packard Fellow
Annie J. Cannon Award in Astronomy
NSF Faculty Early Career Development Award
Kalogera Research Page
Vicky Kalogera is interested in the physics of compact astrophysical objects: white dwarfs, neutron stars, and black holes. In binary systems, where two stars orbit each other, the interactions of compact objects are especially interesting. They can include a wide variety of violent phenomena such as powerful X-ray emission, supernova explosions, black hole formation, and mergers. Kalogera's research is focused mainly on how such systems are born, how they evolve, and how they end their lives. She is also interested in how the properties of such systems are affected by their galactic environments.
Kalogera studies compact objects in three main contexts: as sources of X-ray emission, radio pulses, and gravitational waves. Her research goals include the understanding of X-ray binary observations with NASA's Chandra Observatory in the Milky Way and other galaxies, of current discoveries of binary pulsar systems, and the prediction of anticipated event rates for current and future gravitational wave detectors.
The direct detection of gravitational waves is a unique development in physics anticipated in the coming decade. Binaries with two neutron stars or black holes are primary sources for such detection. Over hundreds of millions of years, such binaries slowly spiral inward towards each other, eventually colliding and producing some of the most violent events in the Universe. General relativity predicts that this happens because massive objects moving at high velocities should emit gravity waves, thus slowly sapping the system of energy and forcing an inward spiral. There is considerable indirect evidence to support the relativistic theory, the most important derived from observations of relativistic binary pulsars. Ambitious efforts are currently under way with the Laser Interferometer Gravitational-Wave Observatory (LIGO) and with the planned Laser Interferometer Space Antenna (LISA) to make the first direct detections of gravitational wave sources and create gravitational wave astronomy. Kalogera is a member of the LIGO Scientific Collaboration and works on the theoretical understanding of gravitational wave sources and the development of optimal detection methods.
- D. W. Kim, G. Fabbiano, V. Kalogera, et al.
Probing the Low-Luminosity X-Ray Luminosity Function in Normal Elliptical Galaxies
Astrophysical Journal 652, 1090 (2006)
- Eccentricities of Double Neutron Star Binaries
Astrophysical Journal 652, 540 (2006)
- M. Freitag, P. Amaro-Seoane, and V. Kalogera
Stellar Remnants in Galactic Nuclei: Mass Segregation
Astrophysical Journal 649, 91 (2006)
- J. Sepinsky, V. Kalogera, and K. Belczynski
Are Supernova Kicks Responsible for X-ray Binary Ejection from Young Clusters?
Astrophysical Journal 621, L37 (2005)
- B. Willems, V. Kalogera, and M. Henninger
Pulsar Kicks and Spin Tilts in the Close Double Neutron Stars PSR J0737-3039, PSR B1534+12, and PSR B1913+16
Astrophysical Journal 616, 414 (2004)
- V. Kalogera, et al.
The Cosmic Coalescence Rate for Double Neutron Star Binaries
Astrophys. J. Lett. 601, Issue 2, L179 (2004)
- V. Kalogera, M. Henninger, N. Ivanova, and A. R. King
An Observational Diagnostic for Ultraluminous X-Ray Sources
Astrophys. J. Lett. 603, Issue 1, L41 (2004)