O<\/span>ne afternoon in early 1994 a couple of astronomers sitting in an air-conditioned computer room at an observatory headquarters in the coastal town of La Serena, Chile, got to talking. Nicholas Suntzeff, an associate astronomer at the Cerro Tololo Inter-American Observatory, and Brian Schmidt, who had recently completed his doctoral thesis at the Center for Astrophysics | Harvard & Smithsonian, were specialists in supernovae\u2014exploding stars. Suntzeff and Schmidt decided that the time had finally come to use their expertise to tackle one of the fundamental questions in cosmology: What is the fate of the universe<\/a>?<\/p>\n Specifically, in a universe full of matter that is gravitationally attracting all other matter, logic dictates that the expansion of space\u2014which began at the big bang and has continued ever since\u2014would be slowing. But by how much? Just enough that the expansion will eventually come to an eternal standstill? Or so much that the expansion will eventually reverse itself in a kind of about-face big bang<\/a>?<\/p>\n They grabbed the nearest blue-and-gray sheet of IBM printout paper, flipped it over and began scribbling a plan: the telescopes to secure, the peers to recruit, the responsibilities to delegate.<\/p>\n Meanwhile some 9,600 kilometers up the Pacific Coast, a collaboration at Lawrence Berkeley National Laboratory in California, operating under the leadership of physicist Saul Perlmutter, was already pursuing the same goal, using the same supernova approach and relying on the same underlying logic. Suntzeff and Schmidt knew about Perlmutter’s Supernova Cosmology Project (SCP). But they also knew that the SCP team consisted primarily of physicists who, like Perlmutter himself, were learning astronomy on the fly. Surely, Schmidt and Suntzeff reassured each other, a team of actual astronomers could catch up.<\/p>\n And their team did, just in time. In 1998 the rival collaborations independently reached the same conclusion as to how much the expansion of the universe is slowing down: it’s not. It’s speeding up.<\/p>\n This year marks the 25th anniversary of the discovery of evidence for \u201cdark energy<\/a>\u201d\u2014a moniker for whatever is driving the acceleration that even then meant next to nothing yet encompassed nearly everything. The coinage was almost a joke, and the joke was on us. If dark energy were real<\/a>, it would constitute two thirds of all the mass and energy in the universe\u2014that is, two thirds of what people had always assumed, from the dawn of civilization onward, to be the universe in its entirety. Yet what that two thirds of the universe was remained a mystery.<\/p>\n A quarter of a century later that summary still applies. Which is not to suggest, however, that science has made no progress. Over the decades observers have gathered ever more convincing evidence of dark energy’s existence, and this effort continues to drive a significant part of observational cosmology while inspiring ever more ingenious methods to, if not detect, at least define it. But right from the start\u2014in the first months of 1998\u2014theorists recognized that dark energy presents an existential problem of more immediate urgency than the fate of the universe: the future of physics.<\/p>\n The mystery of why a universe full of matter gravitationally attracting all other matter hasn’t yet collapsed on itself has haunted astronomy at least since Isaac Newton’s introduction of a universal law of gravitation. In 1693, only six years after the publication of his Principia,<\/em> Newton acknowledged to an inquiring cleric that positing a universe in perpetual equilibrium is akin to making \u201cnot one Needle only, but an infinite number of them (so many as there are particles in an infinite Space) stand accurately poised upon their Points. Yet I grant it possible,\u201d he immediately added, \u201cat least by a divine Power.\u201d<\/p>\n \u201cIt was a great missed opportunity for theoretical physics,\u201d the late Stephen Hawking wrote in a 1999 introduction to a new translation of Principia.<\/em> \u201cNewton could have predicted the expansion of the universe.\u201d<\/p>\n So, too, Einstein. When, in 1917, he applied his equations for general relativity to cosmology, he confronted the same problem as Newton. Unlike Newton, though, Einstein added to the equation not a divine power but the Greek symbol lambda (\u039b), an arbitrary mathematical shorthand for whatever was keeping the universe in perfect balance.<\/p>\n The following decade astronomer Edwin Hubble seemingly rendered lambda superfluous through his twin discoveries that other \u201cisland universes,\u201d or galaxies, exist beyond our own Milky Way and that on the whole those galaxies appear to be receding from us in a fairly straightforward manner: the farther, the faster\u2014as if, perhaps, the universe had emerged from a single explosive event. The 1964 discovery of evidence supporting the big bang theory immediately elevated cosmology from metaphysics to hard science. Only six years later, in an essay in Physics Today<\/em> that set the agenda for a generation, astronomer (and onetime Hubble prot\u00e9g\u00e9) Allan Sandage defined the science of big bang cosmology as \u201cthe search for two numbers.\u201d One number was \u201cthe rate of expansion\u201d now. The second was the \u201cdeceleration in the expansion\u201d over time.<\/p>\n Decades would pass before the first real investigations into the second number got underway, but it was no coincidence that two collaborations more or less simultaneously started work on it at that point. Only then had advances in technology and theory made the search for the deceleration parameter feasible.<\/p>\n In the late 1980s and early 1990s the means by which astronomers gather light was making the transition from analog to digital\u2014from photographic plates, which could collect about 5 percent of the photons that hit them, to charge-coupled devices, which have a photon-collection rate upward of 80 percent. The greater a telescope’s light-gathering capacity, the deeper its view across the universe\u2014and deeper and deeper views across space and (because the speed of light is finite) time are what a search for the expansion rate of the universe requires.<\/p>\n The Hubble diagram, as cosmologists call the graph Hubble used in determining that the universe is expanding, plots two values: the velocities with which galaxies are apparently moving away from us on one axis and the distances of the galaxies from us on the other.<\/p>\n Astronomers can determine galaxies’ velocity\u2014the rate at which the stretching of space is carrying them away from us\u2014by measuring how much their light has shifted toward the red end of the visible portion of the electromagnetic spectrum (their \u201credshift\u201d).<\/p>\n Determining their distance from us, however, is trickier. It requires a \u201cstandard candle\u201d\u2014a class of objects whose light output doesn’t change. A 100-watt lightbulb, for instance, is a standard candle. If you know that its absolute luminosity is 100 watts, then you can apply the inverse-square law to its apparent luminosity\u2014how bright it looks to you at your current distance from it\u2014to calculate how far away it actually is.<\/p>\n The standard candle that Hubble used in plotting his diagram was a Cepheid variable, a star that brightens and dims at regular intervals. But Cepheid variables are difficult to detect at distances greater than 100 million light-years. Astronomers trying to measure the rate of expansion over the history of the universe would need a standard candle they could observe from billions of light-years away\u2014the kinds of distances that charge-coupled device detectors, with their superior photon-collecting power, could probe.<\/p>\n A candidate for a standard candle emerged in the late 1980s: a type Ia supernova, the explosion of a white dwarf when it accretes too much matter from a companion star. The logic seemed reasonable: if the cause of an explosion is always the same, then so should be the effect\u2014the explosion’s absolute luminosity. Yet further investigations determined that the effect was not uniform; both the apparent brightness and the length of time over which the visibility of the \u201cnew star\u201d faded differed from supernova to supernova.<\/p>\n In 1992, however, Mark Phillips, another astronomer at the Cerro Tololo Inter-American Observatory (and a future member of Suntzeff and Schmidt’s team), recognized a correlation between a supernova’s absolute luminosity and the trajectory of its apparent brightness from initial flare through diminution: bright supernovae decline gradually, whereas dim ones decline abruptly. So type Ia supernovae weren’t standard candles, but maybe they were standardizable.<\/p>\n For several years Perlmutter’s SCP collaboration had been banking on type Ia supernovae being standard candles.\u00a0\u201cThere is still some contention\u201d as to whether individual type Ia supernovae \u201cdo not fit the model,\u201d wrote Heidi Jo Newberg, an early member of the SCP team, in her 1992 doctoral thesis. But, she added, \u201cit is clear that the overwhelming majority of [them] are strikingly similar.\u201d These supernovae had to become standardizable, however, before Schmidt and Suntzeff\u2014as well as their eventual recruits to what they called the High-z<\/em> collaboration (z<\/em> being astronomical shorthand for redshift)\u2014could feel comfortable committing their careers to measuring the deceleration parameter.*<\/p>\n Hubble’s original diagram had indicated a straight-line correlation of velocity and distance (\u201cindicated\u201d because his error bars wouldn’t survive peer review today). The two teams in the 1990s chose to plot redshift (velocity) on the x<\/em> axis and apparent magnitude (distance) on the y<\/em> axis. Assuming that the expansion was in fact decelerating, at some point that line would have to deviate from its 45-degree beeline rigidity, bending downward to indicate that distant objects were brighter and therefore nearer than one might otherwise expect.<\/p>\n From 1994 to 1997 the two groups used the major telescopes on Earth and, crucially, the Hubble Telescope in space to collect data on dozens of supernovae that allowed them to extend the Hubble diagram farther and farther. By the first week of 1998 they both had found evidence that the line indeed diverged from 45 degrees. But instead of curving down, the line was curving up, indicating that the supernovae were dimmer than they expected and that the expansion therefore wasn’t decelerating but accelerating\u2014a conclusion as counterintuitive and, in its own way, revolutionary as Earth not being at the center of the universe.<\/p>\n Yet the astrophysics community accepted it with alacrity. By May, only five months after the discovery, Fermilab had convened a conference to discuss the results. In a straw poll at the end of the conference, two thirds of the attendees\u2014approximately 40 out of 60\u2014voted that they were willing to accept the evidence and consider the existence of \u201cdark energy\u201d (a term invented that year by University of Chicago theoretical cosmologist Michael Turner in a nod to dark matter). Einstein’s lambda, it seemed, was back.<\/p>\n S<\/span>ome of the factors leading to the swift consensus were sociological. Two teams had arrived at the same result independently, that result was the opposite of what they expected, they had used mostly different data (separate sets of supernovae), and everyone in the community recognized the intensity of competition between the two teams. \u201cTheir highest aspiration,\u201d Turner says, \u201cwas to get a different answer from the other group.\u201d<\/p>\n But one factor at least equally persuasive in consolidating consensus was scientific: the result answered some major questions in cosmology. How could a universe be younger than its oldest stars? How did a universe full of large-scale structures, such as superclusters of galaxies, mature so early as to reach the cosmological equivalent of puberty while it was still a toddler?<\/p>\n Problems solved! An expansion that is speeding up now implies an expansion that was growing less quickly in the past; therefore, more time has passed since the big bang than cosmologists had previously assumed. The universe is older than scientists had thought: that toddler was a teenager after all.<\/p>\n But maybe the most compelling reason scientists were willing to accept the existence of dark energy was that it made the universe add up. For years cosmologists had been wondering why the density of the universe seemed so low. According to the prevailing cosmological model at the time (and today), the universe underwent an \u201cinflation\u201d that started about 10\u221236<\/sup> second after the big bang (that is, at the fraction of a second that begins with a decimal point and ends 35 zeros and a 1 later) and finished, give or take, 10\u221233<\/sup> second after the big bang. In the interim the universe increased its size by a factor of 1026<\/sup>.<\/p>\n Inflation thereby would have \u201csmoothed out\u201d space so that the universe would look roughly the same in all directions, as it does for us, no matter where you are in it. In scientific terms, the universe should be flat. And a flat universe dictates that the ratio between its actual mass-energy density and the density necessary to keep it from collapsing should be 1.<\/p>\n Before 1998, observations had indicated that the composition of the universe was nowhere near this critical density. It was maybe a third of the way there. Some of it would be in the form of baryons, meaning protons and neutrons\u2014the stuff of you, me and our laptops, as well as of planets, galaxies and everything else accessible to telescopes. But most of it would be in the form of dark matter, a component of the universe that is not<\/em> accessible to telescopes in any part of the electromagnetic spectrum but is detectable, as astronomers had understood since the 1970s, indirectly, such as through gravitational effects on the rotation rates of galaxies. Dark energy would complete that equation: its contribution to the mass-energy density would indeed be in the two-thirds range, just enough to reach critical density.<\/p>\n Still, sociological influences and professional preferences aren’t part of the scientific method. (Well, they are, but that’s a separate discussion.) Where, astronomers needed to know, was the empirical evidence? Everywhere, it turned out.<\/p>\n One way to calculate the constitution of the universe is by studying the cosmic microwave background (CMB), the phenomenon discovered in 1964 that transformed cosmology into a science. The CMB is all-sky relic radiation dating to when the universe was only 379,000 years old, when atoms and light were emerging from the primordial plasma and going their separate ways. The CMB’s bath of warm reds and cool blues represents the temperature variations that are the matter-and-energy equivalent of the universe’s DNA. Take that picture, then compare it with simulations of millions of universes, each with its own amounts of baryonic matter, dark matter and dark energy. Hypothetical universes with no regular matter or dark matter and 100 percent dark energy, or with 100 percent regular matter and no matter or dark energy, or with any combination in between will all produce unique color patterns.<\/p>\n T<\/span>he Wilkinson Microwave Anisotropy Probe (WMAP), which launched in 2001 and delivered data from 2003 to 2012, provided one such census. Planck, an even more precise space observatory, began collecting its own CMB data in 2009 and released its final results in 2018, corroborating WMAP’s findings: the universe is 4.9 percent the stuff of us, 26.6 percent dark matter and 68.5 percent dark energy.<\/p>\n![\"Einstein\u2019s](\"https:\/\/static.scientificamerican.com\/sciam\/assets\/Image\/2023\/saw1223Pane31_d.jpg?w=1000\"\/)
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