By resolving light into its component frequencies, spectrographs can reveal, for example, the Doppler shift in light that travels to Earth from other solar systems with orbiting exoplanets or from the far reaches of the universe. But before it can be put to work, a spectrograph must be calibrated, and that process inevitably introduces measurement uncertainty. To reduce those uncertainties, Tilo Steinmetz and colleagues developed a calibration procedure that can dramatically improve spectroscopic precision, and they demonstrated their technique by obtaining the most accurate spectrum of the Sun’s photosphere to date. The key ingredient is a laser frequency comb, a series of equally spaced, precisely known frequency spikes that, as the white stripes in the figure show, can serve as a template with which astrophysical spectra can be compared (see Physics Today, June 2000, page 19 , and Physics Today December 2005, page 19 ). Because the comb is...
Skip Nav Destination
Article navigation
1 October 2008
October 01 2008
Frequency combs help untangle astrophysical spectra
Physics Today 61 (10), 24 (2008);
Citation
Steven K. Blau; Frequency combs help untangle astrophysical spectra. Physics Today 1 October 2008; 61 (10): 24. https://doi.org/10.1063/1.3001857
Download citation file:
Sign in
Don't already have an account? Register
Sign In
You could not be signed in. Please check your credentials and make sure you have an active account and try again.
PERSONAL SUBSCRIPTION
Purchase an annual subscription for $25. A subscription grants you access to all of Physics Today's current and backfile content.
33
Views
Citing articles via
Going with the flow in unstable surroundings
Savannah D. Gowen; Thomas E. Videbæk; Sidney R. Nagel
Measuring violin resonances
Elizabeth M. Wood
Focus on cryogenics, vacuum equipment, materials, and semiconductors
Andreas Mandelis