- All News
- Search News
- Archived News
- Physicist Steven Cundiff Elected as Fellow of AAAS
- Observing the Dance of Ten Million Quantum Dots
- Physics Professor Tim McKay Explains ECoach Tool Now Used for All First-Year U-M Students
- Physicist Mark Newman's Scientific Cartogram Maps Featured in Washington Post
- U-M Physics Professor Tim McKay Developed Coaching Software to Help Students
- 11 Surprising Predictions for 2017 From Some of The Biggest Names In Science
- All Events
- Special Lectures
- K-12 Programs
- Saturday Morning Physics
- Seminars & Colloquia
The University of Michigan has signed on to be a major player in a new instrument that aims to help answer a burning scientific question: Why is the expansion of the universe accelerating? Cosmologists suspect a mysterious property called dark energy. Although it is thought to comprise 75 percent of the universe, its nature and the physics behind it are still a mystery.
The Dark Energy Spectroscopic Instrument (DESI) will address this mystery by creating a high-definition, 3-D map of a swath of the universe going back 10 billion light-years. By exploring how structure in the universe has evolved through time, scientists hope to uncover the tug-of-war between the forces of gravity and dark energy (see Testing for Dark Energy).
Testing for Dark Energy
DESI aims to precisely measure the evolution of structure in the universe. Because galaxy clustering represents the result of a competition between gravity working to pull galaxies together and dark energy working to stretch space-time apart, the measurement of structure over time helps reveal how dark energy operates.
As galaxies move away from Earth, the light they emit is stretched into longer wavelengths by the Doppler Effect, making them appear redder. The amount of this “redshift” can tell scientists how far away a galaxy is from us. Scientists currently have a good 2-D map of the universe but need precision depth measurements for a large number of galaxies to map the universe’s structure in three dimensions.
To see how this structure has evolved over time, scientists use a naturally occurring standard ruler of the distance between clusters of matter called “baryon acoustic oscillations.” At a unique point in cosmological history – about 380,000 years after the Big Bang, when the hot plasma of the early universe cooled and atoms formed – small fluctuations in matter density that had been carried along by sound waves became frozen into a pattern on the sky. These ripples of more concentrated matter formed the seeds from which galaxies grew, and the space between galaxies still reflects this pattern today. Measuring how this pattern has stretched through time provides insight into the nature of dark energy.
U-M was chosen to build a
major system for this Department of Energy (DoE) project, and seven faculty members from the Departments of Physics and Astronomy have committed to support the project in related areas such as software development, survey planning, data distribution, and simulation work. They also plan to do ground-breaking science when DESI sees first light in 2018.
The instrument itself is a giant prism-like camera that will sit within the Mayall 4-meter Telescope at Kitt Peak National Observatory in Arizona. It will contain 5,000 optical fibers, each of which can be pointed at an individual galaxy, thanks to the unique positioning system U-M was chosen to develop.
“Our system features an array of 5,000 little robots that will simultaneously position each optical fiber on a galaxy,” says Gregory Tarlé, physics professor and member of the DESI Executive Committee, who is heading this effort. “The light will be routed to spectrographs, which will measure each galaxy’s ‘redshift’ and precisely determine its distance from us."
Over five years of operation, DESI will determine the 3-D position of 30 million galaxies, providing scientists an unprecedentedly large and high-quality data set to work with.
"This is what makes the project such a big leap,” says Chris Miller, assistant professor of astronomy and DESI Data Distribution Committee co-chair. “In just a couple of decades, we’ve gone from collecting spectra from one object to 500 at a time. Having a dedicated 4-meter class telescope collecting spectra for 5,000 galaxies every hour, every night will really drive the science forward."
U-M’s robotic positioner is key to making this happen, and the university’s culture of student engagement is in part what made U-M’s system a winner. “We were chosen for this effort because our design was small, durable, and simple – but also because we had a track record of engaging U-M students to build sophisticated systems like this,” Tarlé says.
In fact, student involvement will begin as early as next year, as Tarlé’s team begins building and testing its initial “proto-DESI” system. Undergraduate students will construct and test the robotic positioners while graduate students will help devise the hardware and data analysis systems. There will be an opportunity for more students to achieve hands-on physics experience by doing science at Kitt Peak National Observatory within the next year.
The contribution to DESI’s instrumentation has allowed U-M to become a full institutional member in the project. This means that U-M faculty interested in contributing to DESI and using it for science can join without the standard cost of individual membership.
U-M faculty currently committed to DESI include four physics and three astronomy faculty. On the Physics front Professor Gregory Tarlé will lead the effort at U-M in addition to overseeing DESI’s calibration program. Professor David Gerdes will devise software for the positioner system. Associate Professor Dragan Huterer intends to develop methodologies, algorithms, and software codes to study the growth of structure and the expansion rate of the universe. Dr. Michael Schubnell, Research Scientist, will be responsible for testing and quality control for the DESI fiber positioner production at Michigan. The Astronomy faculty include Chris Miller, Eric Bell, and Monica Valluri.
The University of Michigan’s involvement in the DESI project was made possible by the University of Michigan Departments of Astronomy and Physics; the U-M College of Literature, Science, and Arts; the U-M Office of Research; and the University administration. The research is funded by DESI and DOE, grant number DE-SC0007859. DESI is a $55 million international project that is managed by the Lawrence Berkeley National Laboratory. This research is supported by the Director, Office of Science, Office of High Energy Physics of the U.S. Department of Energy under Contract No. DE–AC02–05CH11231; additional support is provided by the U.S. National Science Foundation, Division of Astronomical Sciences under Contract No. AST-0950945 to the National Optical Astronomy Observatory; the Science and Technologies Facilities Council of the United Kingdom; the Gordon and Betty Moore Foundation; the Heising-Simons Foundation; and by the DESI Member Institutions.