Garnavich has been a co-author on over 900 papers, a first author on over 200 papers, and has an
h-index of 99 according to
Google Scholar. Garnavich served as a research associate at the
Space Telescope Science Institute (STSI) from 1983 to 1985. for the
Hubble Space Telescope. Following the completion of his Ph.D., Garnavich was a postdoctoral fellow at
Dominion Astrophysical Observatory from 1992 to 1995. Garnavich also obtained
spectra of bright supernova
SN 1993J located in nearby
galaxy M81. Garnavich was also a fellow at the
Center for Astrophysics Harvard & Smithsonian from 1995 to 1999. In 1998, Garnavich led a team that used the Hubble Space Telescope to observe three distant high-redshift supernovae, the first published results of the
High-Z Supernova Search Team. These images were also featured on the January 14, 1998
Astronomy Picture of the Day internet site. Garnavich was a key member of the High-Z Supernova Search Team that discovered the acceleration of the expansion of the universe. That discovery was awarded the
2011 Nobel Prize in Physics, and the prize was given to High-Z team leader
Brian Schmidt and team member
Adam Reiss. Also receiving the prize was
Saul Perlmutter of the
Supernova Cosmology Project. As with this result, observations of
GRB 030329 in 2003 led Garnavich to suggest that the progenitor star was likely a
hypernova, an exploding star of
mass 20-50 times that of the Sun. In 2005, after joining the faculty of the University of Notre Dame, Garnavich used the Spitzer Space Telescope to measure the heat (afterglow) in
far-infrared of another gamma ray burst, GRB 050525a. In 2000, Garnavich joined the University of Notre Dame as an assistant professor and was promoted to associate professor in 2003. In 2008, he earned the rank of full professor. Garnavich was appointed chair of the Department of Physics in 2017. The current chair of the department is Morten Eskildsen. In 2003, working with colleagues from Harvard, Garnavich published results of a study of pre-main sequence star
KH 15D. As a binary star system, the team concluded that anomalous changes in brightness were likely caused by a disk of opaque matter occulting the star. Also at Notre Dame, Garnavich continued his supernova and
cosmology research. As a member of the ESSENCE Supernova Survey collaboration, Garnavich obtained the spectra and distances of 102
Type Ia supernovae. Some of these data were used to estimate the value of the "dark energy equation of state parameter" (w), a measure of the density of dark energy in an expanding universe. Using data from the SDSS-II Supernova Survey, Garnavich was able to link Type Ia supernova rates with galaxy characteristics. This work involved comparing the early behavior of supernova
light curves with models of the progenitor stars. The study of supernova rise times led to Brian Hayden's Ph.D. dissertation. Charlotte M. Wood of
Iowa State University and Benjamin Rose of
Baylor University earned their PhDs working under Garnavich at the University of Notre Dame in the field of supernova cosmology. Wood's dissertation concerned Type Ia supernovae in elliptical galaxies and the use of supernovae in measuring the Hubble constant. Benjamin Rose's dissertation addressed "systematic biases of Type Ia supernova distances used in observational cosmology". This setup enabled the first ever capture of a
Type II supernova shock wave. Using the Large Binocular Telescope, Garnavich and Colin Littlefield's observations of cataclysmic variable stars revealed the second only known "propeller star." The first known such star,
AE Aquarii, consists of a
white dwarf star orbiting a
red giant companion. Normally in such systems, material drawn off of the red giant's atmosphere becomes deposited onto the white dwarf. With propeller stars, the material is flung into space by the rotation of the white dwarf's
magnetic field and appears as a gaseous
prominence. This second-known propeller star is named LAMOST J024048.51+195226.9 (J0240 for short). Material flung from J0240 is moving at approximately 1% of the
speed of light. detailing the discovery of WR 142b, a rare
Wolf-Rayet star. Co-authors of the paper include Garnavich and Terrig Rettig of Notre Dame. In 2024, under Garnavich's tutelage, Notre Dame undergraduate McKenna Leichty discovered a potential planet within the cataclysmic variable star system V808 Aurigae. located in an observatory on the top of Notre Dame's Jordan Hall of Science. Garnavich also participated in public astronomy outreach events sponsored by the University of Notre Dame. In 2003, Garnavich operated Notre Dame's historic
Napoleon III Telescope to provide views of the planet
Mars during its historic close opposition. Garnavich provided a public lecture titled "Big Science: The Largest Telescope on Earth and in Space" at the Jordan Hall of Science on Oct 28, 2014. Telescope viewing on the roof of Jordan Hall was also scheduled for this event. == Awards & recognition ==