Successful Start of Dark Energy Spectroscopic Instrument (DESI) Follows Record-Setting Trial Run
A five-year quest to map the universe and unravel the mysteries of dark energy officially began on May 17, at Kitt Peak National Observatory near Tucson, Arizona. To complete its quest, the Dark Energy Spectroscopic Instrument (DESI) will capture and study the light from tens of millions of galaxies and other distant objects in the universe.
DESI is an international science collaboration managed by the Department of Energy’s Lawrence Berkeley National Laboratory (Berkeley Lab) with primary funding for construction and operations from DOE’s Office of Science.
By gathering light from some 30 million galaxies, project scientists said DESI will help them construct a 3D map of the universe with unprecedented detail. The data will help them better understand the repulsive force associated with dark energy that drives the acceleration of the expansion of the universe across vast cosmic distances.
What sets DESI apart from previous sky surveys? The project director, Berkeley Lab’s Michael Levi, said, “We will measure 10 times more galaxy spectra than ever obtained. These spectra get us a third dimension.” Instead of two-dimensional images of galaxies, quasars, and other distant objects, he explained, the instrument collects light, or spectra, from the cosmos, such that it “becomes a time machine where we place those objects on a timeline that reaches as far back as 11 billion years ago.”
“DESI is the most ambitious of a new generation of instruments aimed at better understanding the cosmos – in particular, its dark energy component,” said project co-spokesperson Nathalie Palanque-Delabrouille, a cosmologist at France’s Alternative Energies and Atomic Energy Commission (CEA). She said the scientific program – including her own interest in quasars – will allow researchers to address with precision two primary questions: what dark energy is, and the degree to which gravity follows the laws of general relativity, which form the basis of our understanding of the cosmos.
“I’m super excited about it,” said Risa Wechsler, director of the Kavli Institute for Particle Astrophysics and Cosmology at DOE’s SLAC National Accelerator Laboratory and Stanford University, who was also DESI’s first co-spokesperson. “I spent several years helping to design the survey, get the project approved, and help the collaboration get ready for science, so I’m over the moon to see the survey start. Even in the first year of DESI, we’re going to learn so much.”
The formal start of DESI’s five-year survey follows a four-month trial run of its custom instrumentation that captured four million spectra of galaxies – more than the combined output of all previous spectroscopic surveys. “We already have a bunch of data, and it looks phenomenal,” Wechsler said.
Chia-Hsun Chuang, a research scientist at KIPAC, is co-chairing the DESI cosmological simulation working group that is preparing simulated galaxy catalogs to validate the data analysis pipeline. He pointed out the gargantuan task ahead as the main survey data comes in: “Building the telescope and collecting the data are incredible challenges. Our next challenge is analyzing that data to obtain the most precise dark energy constraints ever made.”
The DESI instrument was installed on the Nicholas U. Mayall 4-meter Telescope at Kitt Peak National Observatory, a program of the National Science Foundation’s (NSF) NOIRLab, which has allowed the Department of Energy to operate the Mayall Telescope for the DESI survey. The instrument includes new optics that increase the field of view of the telescope and includes 5,000 robotically controlled optical fibers to gather spectroscopic data from an equal number of objects in the telescope’s field of view.
“We’re not using the biggest telescopes,” said Berkeley Lab’s David Schlegel, who is DESI project scientist. “It’s that the instruments are better and very highly multiplexed, meaning that we can capture the light from many different objects at once.”
In fact, the telescope “is literally pointing at 5,000 different galaxies simultaneously,” Schlegel said. On any given night, he explains, as the telescope is moved into a target position, the optical fibers align to collect light from galaxies as it is reflected off the telescope mirror. From there, the light is fed into a bank of spectrographs and CCD cameras for further processing and study.
“It’s really a factory that we have – a spectra factory,” said survey validation lead, Christophe Yeche, also a cosmologist at CEA. “We can collect 5,000 spectra every 20 minutes. In a good night, we collect spectra from some 150,000 objects.”
“But it’s not just the instrument hardware that got us to this point – it’s also the instrument software, DESI’s central nervous system,” said Klaus Honscheid, a professor of physics at Ohio State University who directed the design of the DESI instrument control and monitoring systems. He credits scores of people in his group and around the world who have built and tested thousands of DESI’s component parts, most of which are unique to the instrument.
Spectra collected by DESI are the components of light corresponding to the colors of the rainbow. Their characteristics, including wavelength, reveal information such as the chemical composition of objects being observed as well as information about their relative distance and velocity.
As the universe expands, galaxies move away from each other, and their light is shifted to longer, redder wavelengths. The more distant the galaxy, the greater its redshift. By measuring galaxy redshifts, DESI researchers will create a 3D map of the universe. The detailed distribution of galaxies in the map is expected to yield new insights on the influence and nature of dark energy.
“Dark energy is one of the key science drivers for DESI,” said project co-spokesperson Kyle Dawson, a professor of physics and astronomy at University of Utah. “The goal is not so much to find out how much there is – we know that about 70% of the energy in the universe today is dark energy – but to study its properties.”
The universe is expanding at a rate determined by its total energy contents, Dawson explains. As the DESI instrument looks out in space and time, he said, “we can literally take snapshots today, yesterday, 1 billion years ago, 2 billion years ago – as far back in time as possible. We can then figure out the energy content in these snapshots and see how it is evolving.”
Jim Siegrist, associate director for High Energy Physics at DOE, said, “We are excited to see the start of DESI, the first next-generation dark energy project to begin its science survey. Along with its primary mission of dark energy studies, the data set will be of use by the wider scientific community for a multitude of astrophysics studies.
DESI is supported by the DOE Office of Science and by the National Energy Research Scientific Computing Center, a DOE Office of Science user facility. Additional support for DESI is provided by the U.S. National Science Foundation, the Science and Technologies Facilities Council of the United Kingdom, the Gordon and Betty Moore Foundation, the Heising-Simons Foundation, the French Alternative Energies and Atomic Energy Commission (CEA), the National Council of Science and Technology of Mexico, the Ministry of Economy of Spain, and by the DESI member institutions.
The DESI collaboration is honored to be permitted to conduct astronomical research on Iolkam Du’ag (Kitt Peak), a mountain with particular significance to the Tohono O’odham Nation.
The dark energy has following proporties-
1.This is a kind of magnet come in new physics.
2.This magnetism is a function of temperatùre,expressed in degree absolute f(k) and has maximum value at k=⁰ degree (of absolute scale of temperature).But, this can has certaìn quantum states,say 0 or maximum value.
3.The vaĺue of gravity does not change due to dark energy.
So dark energý is appeared in a basìc charge(electron/muon),which is one of constituent particle of all visible matter ànd ìs a function of temperature has fìxed quantum ststes, also has no effect on gravity.Symmetry is a property,which makes the concept of dark energy applicable in universal way to aĺl matter via other basic or fundamental particles.
It isn’t a magnet, since it is not particulate but has constant energy density [ https://en.wikipedia.org/wiki/Dark_energy ].
The current research to unravel the ultimate nature of Dark Energy and of Dark Matter will lead to negative results for an obvious reason which my coming second book will describe in significant details. The Theory and the search for Dark Energy are totally defective as it is for Dark Matter as well. I have two chapters of my coming second book and significant other discussions that show the Dark Matter and Dark Energy cannot be elucidated under current concepts. My book will be published wthin the coming few months and we can then all discuss Dark Matter and Dark Energy together. The universe and its origin are very mysterious as my book will reveal very comprehensively.
As we can see in the article current cosmology is ever more sure on its result (currently at 1 %).
And pseudoscience is not an alternative.